(a) Applicable areas and seasons. (1) The PCTC Program applies to the Pacific cod trawl catcher vessel sector in the BSAI as defined at § 679.20(a)(7)(ii)(A).

(2) The following fishing seasons apply to fishing under this subpart subject to other provisions of this part:

(i) Fishing by vessels participating in a cooperative is authorized for the PCTC Program A season from 1200 hours, A.l.t., January 20 through 1200 hours, A.l.t., April 1.

(ii) Fishing by vessels participating in a cooperative is authorized for the PCTC Program B season from 1200 hours, A.l.t., April 1 through 1200 hours, A.l.t., June 10.

(iii) The PCTC Program does not apply to the Pacific cod trawl catcher vessel C season, as defined at § 679.23(e)(5)(ii)(C)(1).

(b) Pacific cod legal landings. Pacific cod legal landings means the retained catch of Pacific cod caught using trawl gear in a management area in the BSAI by a catcher vessel during the directed fishing season for Pacific cod that:

(1) Was made in compliance with State and Federal regulations in effect at that time; and

(2) Was recorded on a State of Alaska fish ticket for shoreside deliveries or in observer data for mothership deliveries; and

(3) Was the predominately retained species on the fishing trip; and

(4) Was authorized by:

(i) An LLP license and caught in the A or B season of a Federal or parallel groundfish fishery during the qualifying years 2009 through 2019; or

(ii) An LLP license with a transferable AI endorsement prior to receiving the AI endorsement and was caught in a parallel fishery between January 20, 2004, and September 13, 2009; and

(5) Was not made in a CDQ fishery; and

(6) Was not made in a State of Alaska GHL fishery.

(c) Eligible PCTC Program harvesters. NMFS will assign Pacific cod legal landings to an LLP license only if the qualifying Pacific cod legal landings of BSAI trawl catcher vessel Pacific cod were made under the authority of a fully transferable LLP license endorsed for BS or AI Pacific cod with a trawl gear designation from 2009 through 2019 or under the authority of an LLP license endorsed for Pacific cod with a trawl gear designation prior to earning a transferable AI endorsement from 2004 through September 13, 2009;

(d) Assigning trawl catcher vessel Pacific cod legal landings to an LLP license. (1) NMFS will assign Pacific cod legal landings to an LLP license in the form of PCTC Program QS only if the holder of the LLP license that authorized those landings submits a timely and complete application for PCTC Program QS under paragraph (h) of this section that is approved by NMFS.

(2) NMFS will assign Pacific cod legal landings to an LLP license that meets the requirements of paragraph (b) of this section.

(3) NMFS will reissue LLP licenses to eligible harvesters that specify the number of PCTC Program QS units assigned to their LLP licenses.

(e) Eligible PCTC Program processors. NMFS will assign legal landings to an eligible PCTC Program processor if the processor operates under the authority of either a valid FPP or FFP and holds an LLP license with a BSAI Pacific cod trawl mothership endorsement, and received deliveries of legal landings of Pacific cod from the trawl catcher vessel sector from 2009 through 2019. A processor is ineligible to receive PCTC Program QS if it does not hold an active FFP or FPP as of September 7, 2023.

(f) Assigning Pacific cod processing history to an eligible processor. (1) NMFS will assign Pacific cod processing history to a processor in the form of PCTC Program QS only if the FFP or FPP holder submits a timely and complete application for PCTC Program QS that is approved by NMFS pursuant to paragraph (h) of this section.

(2) NMFS will assign Pacific cod processing history based on legal landings delivered to a processor authorized by an FPP or FFP that meets the requirements of this section.

(3) For the initial allocation of PCTC Program QS, qualifying processing history is attached to the processor at the time legal landings were received.

(4) An eligible processor will be issued a PCTC Program QS permit that specifies the number of QS units assigned to that processor.

(g) PCTC Program official record. (1) The PCTC Program official record will contain information used by the Regional Administrator to determine:

(i) The amount of Pacific cod legal landings as defined at in this section assigned to an LLP license;

(ii) The amount of Pacific cod processing history of legal landings as defined at § 679.130 assigned to an FPP or FFP;

(iii) The amount of PCTC Program QS resulting from Pacific cod legal landings assigned to an LLP license held by an eligible harvester, or QS resulting from Pacific cod processing history assigned to an FPP or FFP held by an eligible processor;

(iv) The amount of Pacific cod sideboard ratios assigned to LLP licenses;

(v) Eligibility to participate in the PCTC Program; and

(vi) QS assigned to PCTC Program participants.

(2) The PCTC Program official record is presumed to be correct. An applicant participating in the PCTC Program has the burden to prove otherwise.

(3) Only Pacific cod legal landings and processing history of legal landings, as described in paragraph (b) of this section, shall be used to establish an allocation of PCTC Program QS. Evidence of legal landings shall be limited to documentation of state or Federal catch reports that indicate the amount of Pacific cod harvested, the groundfish reporting area in which it was caught, the vessel and gear type used to catch it, and the date of harvesting, landing, or reporting.

(h) Application for PCTC Program quota share—(1) Submission of an application for PCTC Program quota share. A person who wishes to receive QS to participate in the PCTC Program as an eligible harvester or an eligible processor must submit a timely and complete application for PCTC Program QS. An application form will be provided by NMFS or available from NMFS Alaska Region website as defined at § 679.2. The acceptable submittal methods will be described on the application form.

(2) Deadline. A completed application for PCTC Program QS must be received by NMFS no later than 1700 hours, A.l.t., on October 10, 2023, or if sent by U.S. mail, postmarked by that time. Objective written evidence of timely application will be considered proof of a timely application.

(3) Contents of application. A timely and complete application must contain the information specified on the application for PCTC Program QS with all required documentation attached.

(i) Additional required documentation for LLP license holders. Vessel names, ADF&G vessel registration numbers, and USCG documentation numbers of all vessels that fished under the authority of each LLP license, including dates when landings were made under the authority of an LLP license from 2009 through 2019 or under the authority of an LLP license prior to earning a transferable AI endorsement from 2004-2019;

(ii) Additional required documentation for processors. Processor name, FFP or FPP number, and location of processing plant, including dates when landings were made under the authority of an LLP license from 2009 through 2019;

(iii) The applicant must sign and date the application certifying under penalty of perjury that all information is true and correct. If the application is completed by a designated representative, then explicit authorization signed by the applicant must accompany the application.

(4) Application evaluation. The Regional Administrator will evaluate applications and compare all claims of catch history or processing history in an application with the information in the PCTC Program official record. Application claims that are consistent with information in the PCTC Program official record will be approved by the Regional Administrator. Application claims that are inconsistent with the PCTC Program official record will not be approved unless supported by documentation sufficient to substantiate such claims. An applicant who submits claims of catch history or processing history that are inconsistent with the official record without sufficient evidence, or an applicant who fails to submit the information specified in paragraph (d) of this section, will be provided a single 30-day evidentiary period to submit the specified information, submit evidence to verify their claims of catch or processing history, or submit a revised application consistent with information in the PCTC Program official record. An applicant who claims catch or processing history that is inconsistent with information in the PCTC Program official record has the burden of proving that the submitted claims are correct. Any claims that remain unsubstantiated after the 30-day evidentiary period will be denied. All applicants will be notified of NMFS's final application determinations by an initial administrative determination (IAD), which will inform applicants of their appeal rights under 15 CFR part 906.

(5) Appeals. An applicant may appeal an IAD under the provisions in 15 CFR part 906.

(i) Assigning PCTC Program QS to Harvesters and Processors. The Regional Administrator will assign PCTC Program QS only to an eligible harvester or eligible processor who submits a timely application for PCTC Program QS that is approved by NMFS.

(1) Calculation of PCTC Program QS allocation to LLP licenses without a transferable AI endorsement. NMFS will assign a specific amount of PCTC Program QS units to each LLP license based on the Pacific cod legal landings of each LLP license using information from the PCTC Program official record according to the following procedures:

(i) Determine the Pacific cod legal landings for each LLP license for each calendar year from 2009 through 2019.

(ii) Select the 10 calendar years from the qualifying time period with the highest amount of legal landings for each LLP license, including years with zero metric tons if necessary.

(iii) Sum the Pacific cod legal landings of the highest 10 years for each LLP license. This yields the PCTC Program QS units (in metric tons) for each LLP license.

(2) Calculation of PCTC Program QS allocation to LLP licenses with a transferable AI endorsement. NMFS will assign a specific amount of PCTC Program QS units to each LLP license with a transferable AI endorsement based on the Pacific cod legal landings of each using information from the PCTC Program official record according to the following procedures:

(i) Determine the Pacific cod legal landings for each LLP license with a transferable AI endorsement for each calendar year from 2004 through 2019.

(ii) Select the fifteen calendar years that yield the highest amount of legal landings for each LLP license, including years with zero metric tons if necessary.

(iii) Sum the Pacific cod legal landings of the highest fifteen years for each LLP license with transferable AI endorsement. This yields the PCTC Program QS units (in metric tons) for each LLP license with a transferable AI endorsement.

(3) Official record date. The initial PCTC Program QS pool for all LLP licenses, with and without a transferable AI endorsement, is the sum of the sum of the PCTC Program QS units assigned to all LLP licenses in metric tons based on the PCTC Program official record as of December 31, 2022.

(4) Calculation of PCTC Program QS allocation to processors. NMFS will assign a specific amount of PCTC Program QS units to each eligible processor based on the Pacific cod legal landings delivered to each FPP or FFP using information from the PCTC Program official record according to the following procedures:

(i) Sum the Pacific cod legal landings delivered to each FPP or FFP for each calendar year from 2009 through 2019;

(ii) Select the ten calendar years that yield the highest amount of legal landings delivered to each FPP or FFP, including years with zero metric tons if necessary;

(iii) Sum the Pacific cod legal landings of the highest 10 years for each FPP or FFP. This yields the QS units for each eligible processor, which will be specified on a PCTC Program QS permit for that processor;

(iv) The PCTC Program QS pool for processors is the sum of all QS units assigned to processors in metric tons based on the PCTC official record as of December 31, 2022.

(5) Non-severability and exceptions. Pacific cod legal landings are non-severable from the LLP license, transferable AI endorsement, or FPP to which those Pacific cod legal landings are assigned in the PCTC Program official record except under the following provisions:

(i) If multiple LLP licenses authorized catch by a vessel, the LLP license holders must submit to NMFS an agreement specifying the amount of shared catch history to assign to each LLP license with the application for PCTC Program QS. In the absence of an agreement, the owner of the vessel that made the catch will assign qualifying catch history to each LLP license.

(ii) For the LLP licenses associated with non-exempt AFA catcher vessels, within 90 days of initial issuance of PCTC Program QS, the owners of the LLP licenses that are associated with AFA non-exempt catcher vessels that engaged in fish transfer agreements during the qualifying periods may transfer PCTC Program QS to other LLP licenses associated with AFA non-exempt vessels, subject to the ownership cap at § 679.133.

(A) NMFS will execute permanent transfers of PCTC Program QS between eligible LLP licenses during the 90-day transfer provision upon request. The transferor and transferee must show they agree to the one-time permanent transfer of PCTC Program QS, or show a transfer is authorized by an operation of law (e.g., a court order). Requests to transfer PCTC Program QS must specify which LLP license is transferring PCTC Program QS, which LLP license is receiving PCTC Program QS, and the amount of PCTC Program QS to be transferred.

(B) After the expiration of the 90-day transfer provision, PCTC Program QS will no longer be severable from the LLP license to which it is assigned unless authorized by the transfer rules specified in paragraph (j) or modification is supported by an operation of law.

(j) Transfer of PCTC Program QS. (1) Transfer of an LLP license with PCTC Program QS. A person may transfer an LLP license and the PCTC Program QS assigned to that LLP license under the provisions at § 679.4(k)(7), provided that the LLP license is not assigned PCTC Program QS in excess of the ownership cap specified at § 679.133 at the time of transfer.

(2) Transfer of PCTC Program QS assigned to LLP licenses that exceeds PCTC Program QS ownership caps.

(i) If an LLP license receives an initial allocation of PCTC Program QS that exceeds an ownership cap specified at § 679.133(a), upon transfer of the LLP license, the LLP license holder may transfer the amount of PCTC Program QS in excess of the ownership cap separately from the LLP license and assign it to one or more LLP licenses. However, a transfer will not be approved by NMFS if that transfer would cause the receiving LLP license to exceed an ownership cap specified at § 679.133(a).

(ii) Prior to the transfer of an LLP license that received an initial allocation of PCTC Program QS that exceeds an ownership cap specified at § 679.133(a), the LLP license holder must transfer the PCTC Program QS that is in excess of the ownership cap separately from that LLP license and assign it to one or more LLP licenses. On completion of the transfer of PCTC Program QS, the LLP license that was initially allocated an amount of PCTC Program QS in excess of the ownership cap may not exceed any ownership cap specified at § 679.133(a).

(iii) Any PCTC Program QS associated with the LLP license that is in excess of the ownership cap may be assigned to another LLP license through the application used to transfer LLP licenses, and only if the application is approved as specified at § 679.4(k)(7).

(iv) PCTC Program QS that is transferred from an LLP license that was initially allocated an amount of PCTC Program QS in excess of the ownership cap specified at § 679.133(a) and assigned to another LLP license may not be severed from the receiving LLP license.

(3) Transfer of processor PCTC Program QS Permits. A person may transfer a PCTC Program QS permit to another processor with an active FPP issued under § 679.4. A transfer of processor-held PCTC Program QS may not cause the receiver of the permit to exceed the ownership cap specified at § 679.133(a) at the time of transfer. A PCTC Program QS permit held by a processor and associated QS may be transferred only if the application for transfer of PCTC Program QS permit is filled out entirely. A PCTC Program QS permit initially issued to an FFP holder may be transferred to a processor with an active FPP issued under § 679.4 or to a processor with an active FFP that authorizes a vessel named on an LLP license with a BSAI Pacific cod trawl mothership endorsement.

(4) Transfer of PCTC Program QS assigned to a processor-held PCTC Program QS permit that exceeds PCTC Program ownership caps.

(i) If a PCTC Program QS permit receives an initial allocation of QS that exceeds an ownership cap specified at § 679.133(a), the processor may transfer QS in excess of the ownership cap separately from that PCTC Program QS permit and assign it to the PCTC Program QS permit of one or more processors with an active FPP or FFP. However, a transfer will not be approved by NMFS if that transfer would cause the receiving processor to exceed an ownership cap specified at § 679.133(a).

(ii) Prior to the transfer of a PCTC Program QS permit that received an initial allocation of QS that exceeds an ownership cap specified at § 679.133(a), the permit holder must transfer the QS that is in excess of the ownership cap separately from that PCTC Program QS permit and assign it to one or more PCTC Program QS permits. On completion of the transfer of QS, the PCTC Program QS permit that was initially allocated an amount of QS in excess of the ownership cap may not exceed any ownership cap specified at § 679.133(a).

(iii) Any QS associated with the PCTC Program QS permit held by a processor that is in excess of an ownership cap may be transferred only if the application for transfer of PCTC Program QS permit is filled out entirely.

(a) Assigning CQ to a PCTC Program cooperative—(1) General. (See also § 679.4(q)). (i) Every calendar year, PCTC Program QS assigned to LLP licenses and PCTC Program QS permits held by a PCTC Program processor must be assigned to a PCTC Program cooperative through a CQ permit to use the CQ derived from that PCTC Program QS to catch Pacific cod, crab PSC, or halibut PSC assigned to the PCTC Program.

(ii) NMFS will issue a CQ permit to a PCTC Program cooperative based on the aggregate PCTC Program QS of all LLP licenses and associated processors designated on an application for CQ that is approved by the Regional Administrator as described under paragraph (a)(4) of this section.

(iii) Processors must associate with a PCTC Program cooperative for the PCTC Program QS assigned to that processor's PCTC Program QS permit to be issued to a PCTC Program cooperative as CQ.

(2) PCTC Program QS issued after issuance of CQ or Pacific cod trawl catcher vessel sector TAC. Any PCTC Program QS assigned to an LLP license or PCTC Program QS permit after NMFS has issued CQ for a calendar year will not result in any additional CQ being issued to a PCTC Program cooperative even if that QS holder has assigned their LLP license or PCTC Program QS permit to a PCTC Program cooperative for that calendar year.

(3) Failure to designate QS to a PCTC Program cooperative. Failure to designate an LLP license with PCTC Program QS or a PCTC Program QS permit on a timely and complete application for CQ that is approved by the Regional Administrator as described under paragraph (a)(4) of this section, will result in the Regional Administrator not assigning that QS to a PCTC Program cooperative for the applicable calendar year.

(4) Application for PCTC Program CQ. PCTC Program cooperatives must submit a complete application by November 1 to receive CQ that includes the following:

(i) PCTC Program cooperative identification, including but not limited to the name of the cooperative and the taxpayer identification number;

(ii) PCTC Program QS holders and ownership documentation;

(iii) PCTC Program cooperative member vessels and LLP licenses;

(iv) PCTC Program cooperative associated processors;

(v) Vessels with FFPs on which the CQ issued to the PCTC Program cooperative will be used;

(vi) Certification of cooperative representative;

(vii) An attached copy of the membership agreement or contract that includes the following terms:

(A) How the cooperative intends to harvest its CQ;

(B) The obligations of QS holders who are members of a PCTC Program cooperative to ensure the full payment of PCTC Program fee liabilities that may be due;

(C) How cooperatives monitor and report leasing activity in GOA fisheries; and

(D) For a cooperative intending to harvest any amount of the CQ set-aside, the cooperative's plan for coordinating harvest and delivery of the CQ set-aside with an Aleutian Islands shoreplant as defined § 679.2.

(viii) Each year, all cooperatives must establish an inter-cooperative agreement. This inter-cooperative agreement must be included as part of each annual cooperative application and is required before NMFS will issue CQ. The inter-cooperative agreement must establish how the cooperatives intend to harvest the CQ set-aside in years when it applies and ensure harvests in the BS do not exceed the minimum set-aside as specified at § 679.132(a)(4)(i). For the calendar year 2023, NMFS will allow each cooperative to submit the inter-cooperative agreement prior to December 31, 2023.

(b) Allocations of Pacific cod to the PCTC Program—(1) General. Each calendar year, the Regional Administrator will determine the amount of the BSAI trawl catcher vessel sector's Pacific cod A and B season allocations that will be assigned to the PCTC Program as follows:

(i) Incidental catch allowance (ICA). For the A and B seasons, the Regional Administrator will establish an ICA to account for projected incidental catch of Pacific cod by trawl catcher vessels engaged in directed fishing for groundfish other than PCTC Program Pacific cod.

(ii) Directed fishing allowance (DFA). The remaining trawl catcher vessel sector's Pacific cod A and B season allocations are established as a DFA for the PCTC Program.

(2) Calculation—(i) Determination of Pacific cod trawl catcher vessel TAC allocated to the PCTC Program. NMFS will determine the Pacific cod trawl catcher vessel TAC in a calendar year in the annual harvest specification process at § 679.20.

(ii) Annual apportionment of Pacific cod trawl catcher vessel TAC. The annual apportionment of Pacific cod in the A and B seasons between the PCTC Program DFA and the ICA in a given calendar year is established in the annual harvest specifications.

(3) Allocations of Pacific Cod DFA to PCTC Program—(i) Harvester percentage of DFA. NMFS will assign 77.5 percent of the PCTC Program DFA to the QS attached to LLP licenses assigned to PCTC Program cooperatives. Each LLP license's QS units will correspond to a portion of the DFA according to the following equation: (LLP license QS units/(sum of all LLP license QS units)) × (.775 × DFA).

(ii) Processor percentage of DFA. NMFS will assign 22.5 percent of the PCTC Program DFA to the QS attached to PCTC Program QS permits assigned to PCTC Program cooperatives. Each QS permit's QS units will correspond to a portion of the DFA according to the following equation: (PCTC Program QS permit QS units/(sum of all PCTC Program QS permit QS units)) × (.225 × DFA).

(4) Allocation of CQ to PCTC Program cooperatives—(i) General. Annual CQ will be issued to each PCTC Program cooperative by NMFS based on the aggregate QS attached to LLP licenses and PCTC Program QS permits that are assigned to the cooperative. NMFS will issue CQ by A and B season and cooperatives will ensure the seasonal limits are not exceeded. Unused A season CQ may be rolled over to the B season. Annual CQ may be harvested from either BS or AI subareas subject to any limitations on BS harvest when the AI set-aside is in effect.

(ii) CQ allocation to PCTC Program cooperatives. The amount of CQ that is issued to a PCTC Program cooperative is calculated according to the following formula:

CQ derived from QS assigned to LLP holders = [(.775 × DFA) × (Total LLP license QS units assigned to that cooperative/sum of all LLP license QS units)] CQ derived from QS assigned to PCTC Program QS permit holders = [(.225 × DFA) × (Total PCTC Program Permit QS units assigned to that cooperative/sum of all PCTC Program QS permit QS units)] The total CQ issued to that cooperative = CQ derived from LLP license holders + CQ derived from PCTC Program QS permit holders

(iii) Issuance of CQ. A and B season trawl catcher vessel Pacific cod sector DFAs will be issued to PCTC Program cooperatives as CQ. Annual CQ for each PCTC cooperative will include separate A and B season CQ.

(iv) AI set-aside. When in effect, the AI set-aside will be established annually as specified further at § 679.132.

(c) Allocations of halibut PSC—(1) Halibut PSC limit for the PCTC Program. NMFS specifies the overall halibut PSC limit for the PCTC Program for each calendar year in the harvest specifications pursuant to the procedures specified at § 679.21(b). NMFS calculates the halibut PSC limit according to the formula described in this paragraph. NMFS assigns that halibut PSC limit to PCTC Program cooperatives pursuant to paragraph (a)(1)(i) of this section.

(i) Multiply the halibut PSC limit apportioned to the BSAI trawl limited access sector's Pacific cod fishery category by 98 percent, which yields the halibut PSC apportioned to the trawl catcher vessel sector. The remaining 2 percent is apportioned to the AFA catcher/processor sector as specified at § 679.21(b)(4).

(ii) Assign 95 percent of the trawl catcher vessel sector's halibut PSC limit to the A and B seasons and 5 percent to the C season.

(iii) Each year after apportioning halibut PSC to the trawl catcher vessel sector for the A and B season, apply one of the following reductions to the A and B season trawl catcher vessel halibut PSC limit to determine the overall PCTC Program halibut PSC limit:

(A) In the first year of the PCTC Program, reduce the A and B season halibut PSC limit by 12.5 percent.

(B) In the second year, and each year thereafter, reduce the A and B season halibut PSC limit by 25 percent.

(2) Halibut PSC assigned to each PCTC Program cooperative. For each calendar year, the amount of halibut PSC assigned to a cooperative is determined by the following procedure and the amount will be specified on the CQ permit:

(i) Divide the amount of CQ units assigned to each PCTC Program cooperative by the amount of CQ allocated to all cooperatives. This yields the percentage of CQ units held by each cooperative.

(ii) Multiply the overall PCTC Program halibut PSC limit by the percentage of the CQ assigned to a cooperative. This yields the amount of halibut PSC issued to that cooperative as CQ.

(3) Use of halibut PSC in the PCTC Program. Halibut PSC limits assigned to the CQ permit issued to a PCTC Program cooperative may only be used by the members of that PCTC Program cooperative while harvesting CQ in the BSAI. Any halibut PSC used by a cooperative must be deducted from the amount of halibut PSC on its CQ permit. Halibut PSC limits for cooperatives are not subject to seasonal apportionment under § 679.21. Halibut PSC limits are issued to the PCTC Program for the duration of the A and B seasons. Unused halibut PSC limits may be reapportioned to the C season.

(d) Allocations of crab PSC—(1) Crab PSC limits for the PCTC Program. NMFS specifies the overall crab PSC limit for the PCTC Program for each calendar year in the harvest specifications pursuant to the procedures specified at § 679.21(e). NMFS calculates the crab PSC limit according to the formula described in this paragraph. NMFS then assigns that crab PSC limit to PCTC Program cooperatives with CQ pursuant to paragraph (a)(1)(i) of this section.

(i) Multiply the crab PSC limit apportioned to the BSAI trawl limited access sector's Pacific cod fishery category by 90.6 percent, which yields the percentage of crab PSC apportioned to the trawl catcher vessel sector. The remaining 9.4 percent goes to the AFA catcher/processor sector as specified at § 679.21(b)(4).

(ii) Assign 95 percent of the trawl catcher vessel sector's crab PSC limit to the A and B seasons and 5 percent to the C season.

(iii) Reduce the A and B season trawl catcher vessel crab PSC limit by 35 percent to determine the overall PCTC Program crab PSC limit.

(2) Crab PSC assigned to each PCTC Program cooperative. For each calendar year, the amount of crab PSC limit assigned to a cooperative is determined by the following procedure and the amount will be specified on the CQ permit:

(i) Divide the amount of CQ assigned to each PCTC Program cooperative by the total CQ assigned to all cooperatives. This yields the percentage of CQ held by that cooperative.

(ii) Multiply the overall PCTC Program crab PSC limit by the percentage of the CQ pool assigned to a cooperative. This yields the crab PSC limit issued to that cooperative as CQ.

(3) Use of crab PSC in the PCTC Program. Crab PSC limits assigned to the CQ permit issued to a PCTC Program cooperative may only be used by the members of that PCTC Program cooperative while harvesting CQ in the BSAI. Any crab PSC used by a cooperative must be deducted from the amount of crab PSC limit on its CQ permit. Crab PSC limits for cooperatives are not subject to seasonal apportionment under § 679.21. Crab PSC limits are issued to the PCTC Program for the duration of the A and B seasons. Unused crab PSC limits may be reapportioned to the C season.

(e) Transfer of PSC limits. Halibut and crab PSC limits are transferable between cooperatives according to the same rules established for CQ in paragraph (i) of this section.

(f) Non-allocated Groundfish species. The PCTC Program allocations are for directed fishing for Pacific cod by trawl catcher vessels. All groundfish species not allocated to PCTC Program cooperatives are managed to the maximum retainable amounts (MRAs), as described under § 679.20(e).

(g) Rollover of Pacific cod. If, after June 10, the Regional Administrator determines that reallocating a portion of the Pacific cod ICA or DFA from the PCTC Program to the BSAI trawl limited access sector C season is appropriate, the Regional Administrator may do so through notification in the Federal Register consistent with regulations at § 679.20(a)(7)(iii).

(h) Rollover of PSC to the C Season. If, after June 10, the Regional Administrator determines that reallocating a portion of the halibut or crab PSC limits from the PCTC Program to the BSAI trawl limited access sector C season is appropriate, the Regional Administrator may do so through notification in the Federal Register consistent with regulations at § 679.91(f)(4) and (5).

(i) Process for inter-cooperative transfer of CQ. NMFS will process an application through the NMFS online system for an inter-cooperative transfer of CQ, including PSC, provided that all information is completed by the transferor and transferee, with all applicable fields accurately filled in, and all required documentation is provided.

(j) PCTC Program cooperatives—(1) General. This section governs the formation and operation of PCTC Program cooperatives. The regulations in this section apply only to PCTC Program cooperatives that have formed for the purpose of applying for and fishing with CQ issued annually by NMFS. PCTC Program cooperatives and cooperative members are responsible for ensuring the conduct of cooperatives is consistent with any relevant State or Federal antitrust laws. Membership in a cooperative is voluntary. No person may be required to join a cooperative. Any LLP license holder with PCTC Program QS may join a PCTC Program cooperative and assign their QS to that cooperative. Members may leave a cooperative, but any CQ derived from the QS held by that member will remain with that cooperative for the duration of the calendar year.

(2) Legal and organizational requirements. A PCTC Program cooperative must meet the following legal and organizational requirements before it is eligible to receive CQ:

(i) Each PCTC Program cooperative must be formed as a partnership, corporation, or other legal business entity that is registered under the laws of one of the 50 States or the District of Columbia;

(ii) Each PCTC Program cooperative must appoint an individual as the designated representative to act on the cooperative's behalf and to serve as a contact point for NMFS for questions regarding the operation of the cooperative. The designated representative may be a member of the cooperative, or some other individual designated by the cooperative to act on its behalf;

(iii) Each PCTC Program cooperative must submit a timely and complete application for CQ; and

(iv) Each PCTC Program cooperative must meet the mandatory requirements established in paragraph (j)(3) of this section.

(3) Elements of PCTC Program cooperatives. The following table describes the necessary elements to form and operate a PCTC Program cooperative:

(4) Successors-in-interest. If a member of a PCTC Program cooperative dies (in the case of an individual) or dissolves (in the case of a business entity), the CQ derived from the QS assigned to the cooperative for that year from that person remains under the control of the cooperative for the duration of that calendar year as specified in the cooperative contract. Each cooperative is free to establish its own internal procedures for admitting a successor-in-interest during the fishing season due to the death or dissolution of a cooperative member.

(a) Aleutian Islands CQ set-aside provisions in the PCTC Program—(1) Calculation of the Aleutian Islands Pacific cod non-CDQ ICA and DFA. Each year, during the annual harvest specifications process set forth at § 679.20(c), the Regional Administrator will specify the AI Pacific cod non-CDQ ICA, the DFA from the AI Pacific cod non-CDQ TAC, and the AI set-aside as follows:

(2) Aleutian Islands Pacific cod non-CDQ ICA. The AI Pacific cod non-CDQ ICA will be deducted from the aggregate portion of the AI Pacific cod non-CDQ TAC annually allocated to the non-CDQ sectors identified at § 679.20(a)(7)(ii)(A).

(3) Aleutian Islands Pacific cod non-CDQ DFA. The AI Pacific cod non-CDQ DFA will be the amount of the AI Pacific cod TAC remaining after subtraction of the AI Pacific cod CDQ reserve and the AI Pacific cod non-CDQ ICA.

(4) Calculation of the Aleutian Islands CQ set-aside. The Regional Administrator will specify the AI set-aside in either of the following ways:

(i) When the AI DFA exceeds 12 percent of A season CQ, the AI set-aside is 12 percent of the PCTC Program A season CQ and is in effect during the A and B seasons.

(ii) If the AI non-CDQ DFA is below 12 percent of the PCTC Program A season CQ, then the AI set-aside will be set equal to the AI non-CDQ DFA and is in effect during the A and B seasons. When the AI set-aside is in effect and set equal to the AI non-CDQ DFA, directed fishing for Pacific cod in the AI may only be conducted by PCTC Program vessels that deliver their catch of AI Pacific cod to an Aleutian Islands shoreplant. After June 10, the Regional Administrator may open directed fishing for AI non-CDQ Pacific cod for other sectors.

(b) Annual notice of intent to process Aleutian Islands Pacific cod—(1) Submission of notice. The provisions of this section will apply if a representative of either the City of Adak or the City of Atka submits to the Regional Administrator a timely and complete notice of its intent to process PCTC Program Pacific cod during the upcoming fishing year.

(2) Submission method and deadline. The notice of intent to process PCTC Program Pacific cod for the upcoming fishing year must be submitted in writing to the Regional Administrator by a representative of the City of Adak or the City of Atka no later than October 15 of each year in order for the provisions of this section to apply during the upcoming fishing year. Notices of intent to process received later than October 15 may not be accepted by the Regional Administrator.

(3) Contents of notice. A notice of intent to process PCTC Program Pacific cod for the upcoming fishing year must contain the following information:

(i) Date of submission,

(ii) Name of city,

(iii) Statement of intent to process PCTC Program Pacific cod,

(iv) Identification of the fishing year during which the city intends to process PCTC Program Pacific cod,

(v) Contact information for the representative of the city, and

(vi) Documentation of authority to represent the City of Adak or the City of Atka.

(4) NMFS confirmation and notice. On or before November 30, the Regional Administrator will notify the representative of the City of Adak or the City of Atka, confirming receipt of their official notice of intent to process PCTC Program Pacific cod. Then, NMFS will announce through notification in the Federal Register whether the AI set-aside will be in effect for the upcoming fishing year.

(5) AI CQ set-aside PCTC Program cooperative provisions. If the representative of the City of Adak or the City of Atka submits a timely and complete notice of intent to process in accordance of this section, then the following provisions will apply for the fishing year following the notice:

(i) The PCTC Program cooperative(s) are required to set-aside an amount of CQ calculated by the Regional Administrator pursuant to (a)(4) of this section for delivery to an Aleutian Islands shoreplant as defined at § 679.2.

(ii) All cooperatives must enter into an inter-cooperative agreement that describes how the AI set-aside will be administered by the cooperatives to ensure that the PCTC Program harvests from the BS do not exceed the minimum set-aside. This inter-cooperative agreement must establish how the cooperatives intend to harvest the AI set-aside when it applies. This inter-cooperative agreement must be provided as part of the annual PCTC Program cooperative application as specified at § 679.131(a)(4) and is required before NMFS can issue CQ.

(iii) The inter-cooperative agreement must establish how cooperatives would ensure that trawl catcher vessels less than 60 ft (18.3 m) LOA assigned to an LLP license with a transferable AI trawl endorsement have the opportunity to harvest 10 percent of the AI set-aside for delivery to an Aleutian Islands shoreplant.

(c) PCTC Program A season CQ set-aside limitations. (1) If the Regional Administrator has approved a notice of intent to process, vessels authorized under the PCTC Program shall not harvest the amount of the AI set-aside in the BS subarea.

(2) PCTC Program cooperatives may not deliver more than the PCTC A season CQ minus the AI set-aside established under this section to processors in the BS subarea when the AI CQ set-aside is in effect.

(3) The City of Adak or the City of Atka may withdraw their annual notice of intent to process prior to the end of B season.

(4) The Regional Administrator may remove the delivery requirement for some or all of the projected unused AI CQ set-aside if the Regional Administrator determines that the Aleutian Islands shoreplants will not process the entire AI CQ set-aside.

(5) In the event all notices of intent to process are withdrawn, the Regional Administrator will remove the delivery requirement for CQ that was set-aside for that calendar year.

(6) To remove the AI CQ set-aside delivery requirement for that calendar year, the Regional Administrator will publish a document in the Federal Register.

(a) Ownership and use caps—(1) General. (i) Ownership caps limit the amount of PCTC Program QS that may be owned by a harvester or processor and their affiliates. Use caps limit the amount of CQ that may be harvested by a vessel or received and processed by a processor.

(ii) Use caps do not apply to halibut or crab PSC CQ.

(iii) Ownership and use caps may not be exceeded except as provided under paragraph (a)(6) of this section.

(iv) All QS ownership caps are a percentage of the initial PCTC Program QS pool established by NMFS at § 679.130(e).

(v) The CQ processing use cap is a percentage of the total amount of CQ issued to cooperatives during a calendar year.

(vi) The vessel use cap is a percentage of the amount of CQ assigned to the PCTC Program during a calendar year.

(2) Harvester PCTC Program QS ownership cap. A person may not individually or collectively own more than 5 percent of the PCTC Program QS initially assigned to harvesters unless that person qualifies for an exemption to this ownership cap under paragraph (a)(6) of this section based on their qualifying catch history. Processor-issued QS does not count toward this ownership cap.

(3) Vessel use cap. A catcher vessel may not harvest an amount of CQ greater than 5 percent of the CQ issued to the PCTC Program during a calendar year unless that vessel qualifies for an exemption to this use cap under paragraph (a)(6) of this section based on their qualifying catch history.

(4) Processor ownership cap. A person may not individually or collectively own more than 20 percent of the PCTC Program QS initially assigned to processors unless that person qualifies for an exemption to this ownership cap under paragraph (a)(6) of this section based on their qualifying processing history.

(5) Processing use cap. A processor, at the firm or company level, may not process more than 20 percent of the CQ assigned to the PCTC Program during a calendar year unless that processor qualifies for an exemption to this use cap under paragraph (a)(6) of this section based on their qualifying processing history. The amount of CQ that is received by a PCTC Program processor is calculated based on the sum of all landings made with CQ received or processed by that processor and the CQ received or processed by any person affiliated with that processor as that term is defined at § 679.2.

(6) Cap exemptions. (i) A person may receive an initial allocation of PCTC Program QS in excess of the harvester ownership cap. This exemption is non-transferable.

(ii) A person may receive an initial allocation of PCTC Program QS in excess of the processor ownership cap. This exemption is non-transferable.

(iii) A vessel designated on an LLP license that received an initial allocation of PCTC Program QS in excess of the harvester ownership cap may harvest CQ in excess of the vessel use cap up to the amount of CQ resulting from QS assigned to the LLP license. This exemption is non-transferable.

(iv) Processor use cap exemptions. A processor that received an initial allocation of PCTC Program QS in excess of the processor ownership cap may process more than 20 percent of CQ during a calendar year up to an amount of CQ proportional to the ratio of QS held by the processor to the total amount of QS held by processors. This exemption is non-transferable. An Aleutian Islands shoreplant is not subject to this processor use cap.

(7) Transfer limitations. An eligible harvester that receives an initial allocation of PCTC Program QS that exceeds the ownership cap listed in paragraph (a)(2) of this section shall not receive any PCTC Program QS by transfer unless and until the eligible harvester's holdings of PCTC Program QS in the PCTC Program are reduced to an amount below the use cap specified in this paragraph (a).

(b) Sideboard limits—general. The regulations in this section restrict the holders of LLP licenses issued PCTC Program QS from using the increased flexibility provided by the PCTC Program to expand their level of participation in GOA groundfish fisheries.

(1) Sideboard limit restrictions for LLP licenses authorizing AFA non-exempt catcher vessels. LLP licenses that authorize AFA non-exempt catcher vessels will be subject to the sideboard limitations specified at § 679.64(b)(4)(i).

(2) At-Sea Processing Sideboard Limit. A sideboard limit will be specified on each LLP license with a BSAI Pacific cod trawl mothership endorsement. Each LLP license with a BSAI Pacific cod trawl mothership endorsement may receive CQ deliveries from a catcher vessel not to exceed 125 percent of a catcher/processor's processing history as defined at § 679.130 and subject to eligibility requirements under BSAI FMP Amendment 120 to limit CPs acting as motherships.

(a) Permits. For permit information, please see § 679.4(q).

(b) Catch monitoring requirements for PCTC Program catcher vessels. The owner and operator of a catcher vessel must ensure the vessel complies with the observer coverage requirements described at § 679.51(a)(2) at all times the vessel is participating in a PCTC Program cooperative.

(c) Catch monitoring requirements for motherships receiving unsorted codends from a PCTC Program catcher vessel—(1) Catch weighing. All catch, except halibut sorted on deck by vessels participating in the halibut deck sorting described at § 679.120, must be weighed on a NMFS-approved scale in compliance with the scale requirements at § 679.28(b). Each haul must be weighed separately and all catch must be made available for sampling by an observer.

(2) Additional catch monitoring requirements. Comply with catch monitoring requirements specified at § 679.93(c).

(d) Catch monitoring requirements for shoreside processors. All groundfish landed by catcher vessels described at § 679.51(a)(2) must be sorted, weighed on a scale approved by the State of Alaska as described at § 679.28(c), and be made available for sampling by an observer, NMFS staff, or any individual authorized by NMFS. Any of these persons must be allowed to test any scale used to weigh groundfish to determine its accuracy.

(e) Catch accounting—(1) Pacific cod. All Pacific cod harvests by a vessel that is named on a PCTC Program CQ application and fishing under a CQ permit will be debited against the CQ for that cooperative during the fishing seasons as defined at § 679.130(a)(2).

(2) PCTC Program halibut and crab PSC. All halibut and crab PSC used by a vessel that is named on an Application PCTC Program CQ and fishing under a CQ permit will be debited against the CQ for that cooperative during the fishing seasons as defined at § 679.130(a)(2).

(3) Groundfish sideboard limits. All groundfish harvests in the BSAI and GOA that are subject to a sideboard limit for that groundfish species as described under § 679.133(b), except groundfish harvested by a vessel when participating in the Central GOA Rockfish Program, will be debited against the applicable sideboard limit.

(f) Recordkeeping and reporting. The owners and operators of catcher vessels and processors authorized as participants in the PCTC Program must comply with the applicable recordkeeping and reporting requirements of this section and must assign all catch to a PCTC Program cooperative as applicable at the time of catch or receipt of Pacific cod. All owners of catcher vessels and processors authorized as participants in the PCTC Program must ensure that their designated representatives or employees comply with all applicable recordkeeping and reporting requirements.

(1) Logbook—(i) DFL. Operators of catcher vessels participating in the PCTC Program fishery must maintain a daily fishing logbook for trawl gear as described at § 679.5.

(ii) ELB. Operators of a catcher/processor designated on an LLP license with a BSAI Pacific cod trawl mothership endorsement or a mothership receiving CQ must use a combination of NMFS-approved catcher/processor trawl gear ELB and eLandings to record and report groundfish and PSC information as described at § 679.5 to record PCTC Program landings and production.

(2) eLandings. Managers of shoreside processors that receive Pacific cod in the PCTC Program must use eLandings or NMFS-approved software as described at § 679.5(e) to record PCTC Program landings and production.

(3) Production reports. Operators of a catcher/processor designated on an LLP license with a BSAI Pacific cod trawl mothership endorsement that receives and purchases landings of CQ must submit a production report as described at § 679.5(e)(10).

(4) Product transfer report (PTR), processors. Operators of a catcher/processor designated on an LLP license with a BSAI Pacific cod trawl mothership endorsement and managers of shoreside processors that receive and purchase landings of CQ must submit a PTR as described at § 679.5(g).

(5) Vessel monitoring system (VMS) requirements. Operators of catcher vessels assigned to a PCTC Program cooperative or that are subject to sideboard limits detailed at § 679.133 must use functioning VMS equipment as described at § 679.28(f) at all times when operating in a reporting area off Alaska during the A and B season.

(6) PCTC Program cost recovery fee submission (See § 679.135).

(7) Pacific cod Ex-vessel Volume and Value Report. A processor that receives and purchases landings of CQ must submit annually to NMFS a complete Pacific cod Ex-vessel Volume and Value Report, as described at § 679.5(u) for each reporting period for which the PCTC processor receives CQ.

[88 FR 53735, Aug. 8, 2023; 88 FR 57009, Aug. 22, 2023]

(a) Cost recovery fees—(1) Responsibility. Each PCTC Program cooperative must comply with the requirements of this section.

(i) Subsequent transfer of CQ or QS held by PCTC Program cooperative members does not affect the cooperative's liability for noncompliance with this section.

(ii) Non-renewal of a CQ permit does not affect the cooperative's liability for noncompliance with this section.

(iii) Changes in the membership in a PCTC Program cooperative, such as members joining or departing during the relevant year, or changes in the amount of QS holdings of those members does not affect the cooperative's liability for noncompliance with this section.

(2) Fee collection. PCTC Program cooperatives that receive CQ are responsible for submitting the cost recovery payment for all CQ landings made under the authority of their CQ permit.

(3) Payment. (i) A cooperative must submit any cost recovery fee liability payment(s) no later than August 31 following the calendar year in which the CQ landings were made.

(ii) Make electronic payment payable to NMFS.

(iii) Submit payment and related documents as instructed on the NMFS Alaska Region website as defined at § 679.2.

(iv) Payment must be made electronically in U.S. dollars using an approved payment method available on the payment website.

(b) Pacific cod standard ex-vessel value determination and use. NMFS will use the standard prices calculated for Pacific cod based on information provided in the Pacific Cod Ex-vessel Volume and Value Report described at § 679.5(u)(1) from the previous calendar year.

(c) PCTC Program fee percentage—(1) Fee percentage. The fee percentage is the amount as determined by the factors and methodology described in paragraph (c)(2) of this section. This amount will be announced by publication in the Federal Register. This amount must not exceed 3.0 percent of the gross ex-vessel value pursuant to 16 U.S.C. 1854(d)(2)(B).

(2) Calculating fee percentage value. Each year NMFS shall calculate and publish the fee percentage following the fishing season in which the CQ landings were made, according to the following factors and methodology:

(i) NMFS must use the following factors to determine the fee percentage:

(A) The catch to which the PCTC Program cost recovery fee will apply;

(B) The ex-vessel value of that catch; and

(C) The costs directly related to the management, data collection, and enforcement of the PCTC Program.

(ii) NMFS must use the following equations to determine the fee percentage:

100 × DPC/V where: DPC = the direct program costs for the PCTC Program for the previous calendar year with any adjustments to the account from payments received in the previous year. V = total of the standard ex-vessel value of the catch subject to the PCTC cost recovery fee liability for the current year.

(iii) The calculated fee percentage is applied to the ex-vessel value of CQ landings made in the previous calendar year.

(3) Applicable fee percentage. The cooperative must use the fee percentage applicable at the time a PCTC landing is debited from a CQ allocation to calculate the cost recovery fee liability for any retroactive payments for CQ landed.

(4) Fee liability determination for a cooperative. (i) All cooperatives are subject to a fee liability for any CQ debited from a CQ allocation during a calendar year.

(ii) The PCTC Program fee liability assessed to a PCTC Program cooperative is based on the proportion of the standard ex-vessel value of Pacific cod debited from the cooperative's CQ relative to all cooperatives during a calendar year as determined by NMFS.

(iii) NMFS will provide a fee liability summary letter to all cooperatives by no later than August 1 of each year. The summary will explain the fee liability determination including the current fee percentage, details of CQ pounds debited from CQ allocations by permit, species, date, and prices.

(d) Underpayment of fee liability. (1) Pursuant to § 679.131, no cooperative will receive any CQ unless that cooperative has made full payment of cost recovery liability at the time it applies for CQ.

(2) If a cooperative fails to submit full payment for PCTC Program cost recovery fee liability by the date described in paragraph (a)(3) of this section:

(i) At any time thereafter the Regional Administrator may send an IAD to the cooperative stating the amount of the cooperative's estimated fee liability that is past due and requesting payment. If payment is not received by the 30th day after the date on the IAD, the agency may pursue collection of the unpaid fees.

(ii) The Regional Administrator may disapprove any application to transfer CQ to or from the cooperative in accordance with § 679.130.

(iii) No CQ permit will be issued to that cooperative for that following calendar year and the Regional Administrator may continue to prohibit issuance of a CQ permit for any subsequent calendar years until NMFS receives the unpaid fees.

(iv) No CQ will be issued based on the QS held by the members of that PCTC Program cooperative to any other CQ permit for any subsequent calendar years until NMFS receives the unpaid fees.

(e) Over payment. Payment submitted to NMFS in excess of the annual PCTC Program cost recovery fee liability for a cooperative will be credited against the cooperative's future cost recovery fee liability unless the cooperative requests the agency refund the over payment. Payment processing fees may be deducted from any fees returned to the cooperative.

(f) Appeals. A cooperative that receives an IAD for incomplete payment of a fee liability may appeal the IAD pursuant to 15 CFR part 906.

(g) Annual report. Each year, NMFS will publish a report describing the PCTC Program cost recovery fee program.

[72 FR 52739, Sept. 14, 2007]

[73 FR 43370, July 25, 2008]

[75 FR 61652, Oct. 6, 2010]

[73 FR 43370, July 25, 2008]

[73 FR 43370, July 25, 2008]

[75 FR 61652, Oct. 6, 2010]

[76 FR 15840, Mar. 22, 2011]

[75 FR 61652, Oct. 6, 2010]

[83 FR 50002, Oct. 4, 2018]

[83 FR 50002, Oct. 4, 2018]

[84 FR 2729, Feb. 8, 2019]

[84 FR 2729, Feb. 8, 2019]

[84 FR 2730, Feb. 8, 2019, as amended at 88 FR 53744, Aug. 8, 2023]

[84 FR 70071, Dec. 20, 2019]

[89 FR 77035, Sept. 20, 2024]

Table of Contents 1. Introduction 2. Belt Scales 2.1 Applicability 2.2 Performance Requirements 2.2.1 Maximum Permissible Errors 2.2.1.1 Laboratory Tests 2.2.1.2 Zero Load Tests 2.2.1.3 Material Tests 2.2.2 Minimum Flow Rate (Σmin) 2.2.3 Minimum Totalized Load (Σmin) 2.2.4 Influence Quantities 2.2.4.1 Temperature 2.2.4.2 Power Supply 2.3 Technical Requirements 2.3.1 Indicators and Printers 2.3.1.1 General 2.3.1.2 Values Defined 2.3.1.3 Units 2.3.1.4 Value of the Scale Division 2.3.1.5 Range of Indication 2.3.1.6 Resettable and Non-resettable Values 2.3.1.7 Rate of Flow Indicator 2.3.1.8 Printed Information 2.3.1.9 Permanence of Markings 2.3.1.10 Power Loss 2.3.1.11 Adjustable Components 2.3.1.12 Audit Trail 2.3.1.13 Adjustments to Scale Weights 2.3.2 Weighing Elements 2.3.2.1 Speed Measurement 2.3.2.2 Conveyer Belt 2.3.2.3 Overload Protection 2.3.2.4 Speed Control 2.3.2.5 Adjustable Components 2.3.2.6 Motion Compensation 2.3.3 Installation Conditions 2.3.4 Marking 2.3.4.1 Presentation 2.4 Tests 2.4.1 Minimum Test Load 2.4.2 Laboratory Tests 2.4.2.1 Influence Quantity and Disturbance Tests 2.4.2.2 Zero-Load Tests 2.4.2.3 Material Tests 2.4.3 Annual Scale Inspections 2.4.3.1 Zero-Load Tests 2.4.3.2 Material Tests 3. Automatic Hopper Scales 3.1 Applicability 3.2 Performance Requirements 3.2.1 Maximum Permissible Errors 3.2.1.1 Laboratory Tests 3.2.1.2 Increasing and Decreasing Load Tests 3.2.2 Minimum Weighment (Σmin) 3.2.3 Minimum Totalized Load (Lot) 3.2.4 Influence Quantities 3.2.4.1 Temperature 3.2.4.1.1 Operating Temperature 3.2.4.2 Power Supply 3.3 Technical Requirements 3.3.1 Indicators and Printers 3.3.1.1 General 3.3.1.2 Values Defined 3.3.1.3 Units 3.3.1.4 Value of the Scale Division 3.3.1.5 Weighing Sequence 3.3.1.6 Printing Sequence 3.3.1.7 Printed Information 3.3.1.8 Permanence of Markings 3.3.1.9 Range of Indication 3.3.1.10 Non-resettable Values 3.3.1.11 Power Loss 3.3.1.12 Adjustable Components 3.3.1.13 Audit Trail 3.3.1.14 Zero-Load Adjustment 3.3.1.14.1 Manual 3.3.1.14.2 Semi-automatic 3.3.1.15 Damping Means 3.3.1.16 Adjustments to Scale Weights 3.3.2 Interlocks and Gate Control 3.3.3 Overfill Sensor 3.3.4 Weighing Elements 3.3.4.1 Overload Protection 3.3.4.2 Adjustable Components 3.3.4.3 Motion Compensation 3.3.5 Installation Conditions 3.3.6 Marking 3.3.6.1 Presentation 3.4 Tests 3.4.1 Standards 3.4.2 Laboratory Tests 3.4.2.1 Influence Quantity and Disturbance Tests 3.4.2.2 Performance Tests 3.4.3 Annual Scale Inspections 4. Platform Scales and Hanging Scales 4.1 Applicability 4.2 Performance Requirements 4.2.1 Maximum Permissible Errors 4.2.1.1 Laboratory Tests 4.2.1.2 Increasing and Decreasing Load and Shift Tests 4.2.2 Accuracy Classes 4.2.3 Minimum Load 4.2.4 Influence Quantities 4.2.4.1 Temperature 4.2.4.1.1 Operating Temperature 4.2.4.2 Power Supply 4.3 Technical Requirements 4.3.1 Indicators and Printers 4.3.1.1 General 4.3.1.2 Values Defined 4.3.1.3 Units 4.3.1.4 Value of the Scale Division 4.3.1.5 Printed Information 4.3.1.6 Permanence of Markings 4.3.1.7 Power Loss 4.3.1.8 Adjustable Components 4.3.1.9 Zero-Load Adjustment 4.3.1.9.1 Manual 4.3.1.9.2 Semi-automatic 4.3.1.10 Damping Means 4.3.2 Weighing Elements 4.3.2.1 Overload Protection 4.3.2.2 Adjustable Components 4.3.2.3 Motion Compensation 4.3.3 Installation Conditions 4.3.4 Marking 4.3.4.1 Presentation 4.4 Tests 4.4.1 Standards 4.4.2 Laboratory Tests 4.4.2.1 Influence Quantities and Disturbance Tests 4.4.2.2 Performance Tests 4.4.3 Annual Scale Inspections 5. Definitions Annex A of Appendix A to Part 679—Influence Quantity and Disturbance Tests A.1 General A.2 Test considerations A.3 Tests A.3.1 Static Temperatures A.3.2 Damp Heat, Steady State A.3.3 Power Voltage Variation A.3.4 Short Time Power Reduction A.3.5 Bursts A.3.6 Electrostatic Discharge A.3.7 Electromagnetic Susceptibility A.4 Bibliography 1. Introduction

(a) This appendix to part 679 contains the performance and technical requirements for scales to be approved by NMFS for use to weigh, at sea, catch from the groundfish fisheries off Alaska. The performance and technical requirements in this document have not been reviewed or endorsed by the National Conference on Weights and Measures. Regulations implementing the requirements of this appendix and additional requirements for and with respect to scales used to weigh catch at sea are found at 50 CFR 679.28(b).

(b) Revisions, amendments, or additions to this appendix may be made after notice and opportunity for public comments. Send requests for revisions, amendments, or additions to the Sustainable Fisheries Division, Alaska Region, NMFS, P.O. Box 21668, Juneau, AK 99802.

(c) Types of Scales Covered by Appendix—This appendix contains performance and technical requirements for belt, automatic hopper, platform, and hanging scales.

(d) Testing and Approval of Scales Used to Weigh Catch at Sea—Scales used to weigh catch at sea are required to comply with four categories of performance and technical requirements: (1) Type evaluation; (2) initial inspection after installation while the vessel is tied up at a dock and is not under power at sea; (3) annual reinspection while the vessel is tied up at a dock and is not under power at sea; and (4) daily at-sea tests of the scale's accuracy. This appendix contains only the performance and technical requirements for type evaluation and initial and annual reinspections by an authorized scale inspector.

2. Belt Scales

2.1 Applicability. The requirements in this section apply to a scale or scale system that employs a conveyor belt in contact with a weighing element to determine the weight of a bulk commodity being conveyed across the scale.

2.2 Performance Requirements—2.2.1 Maximum Permissible Errors. For laboratory tests of a scale and initial inspections and annual reinspections of an installed scale when the vessel is tied up at a dock and is not under power at sea, the following maximum permissible errors (MPEs) are specified:

2.2.1.1 Laboratory Tests. See annex A to this appendix A for procedures for disturbance tests and influence factors.

a. Disturbances. ±0.18 percent of the weight of the load totalized.

b. Influence Factors. ±0.25 percent of the weight of the load totalized.

c. Temperature Effect at Zero Flow Rate. The difference between the values obtained at zero flow rate taken at temperatures that differ by 10 °C ±0.2 °C must not be greater than 0.035 percent of the weight of the load totalized at the maximum flow-rate for the time of the test.

2.2.1.2 Zero Load Tests. For zero load tests conducted in a laboratory or on a scale installed on a vessel and conducted when the vessel is tied up at a dock and not under power at sea, ±0.1 percent of the value of the minimum totalized load or 1 scale division (d), whichever is greater.

2.2.1.3 Material Tests. For material tests conducted in a laboratory or on a scale installed on a vessel and conducted when the vessel is tied up at a dock and not under power at sea, ±1.0 percent of the known weight of the test material.

2.2.2 Minimum Flow Rate (Qmin). The minimum flow rate must be specified by the manufacturer and must not be greater than 35 percent of the rated capacity of the scale in kilograms per hour (kg/hr) or metric tons per hour (mt/hr).

2.2.3 Minimum Totalized Load (Σmin). The minimum totalized load must not be less than the greater of—

a. Two percent of the load totalized in 1 hour at the maximum flow rate;

b. The load obtained at the maximum flow rate in 1 revolution of the belt; or

c. A load equal to 800 scale divisions (d).

2.2.4 Influence Quantities. The following requirements apply to influence factor tests conducted in the laboratory.

2.2.4.1 Temperature. A belt scale must comply with the performance and technical requirements at a range of temperatures from −10 °C to + 40 °C. However, for special applications the temperature range may be different, but the range must not be less than 30 °C and must be so specified on the scale's descriptive markings.

2.2.4.2 Power Supply. A belt scale must comply with the performance and technical requirements when operated within a range of −15 percent to + 10 percent of the power supply specified on the scale's descriptive markings.

2.3.1 Technical Requirements.

2.3.1 Indicators and Printers.

2.3.1.1 General. A belt scale must be equipped with an indicator capable of displaying both the weight of fish in each haul or set and the cumulative weight of all fish or other material weighed on the scale between annual inspections (“the cumulative weight”), a rate of flow indicator, and a printer. The indications and printed representations must be clear, definite, accurate, and easily read under all conditions of normal operation of the belt scale.

2.3.1.2 Values Defined. If indications or printed representations are intended to have specific values, these must be defined by a sufficient number of figures, words, or symbols, uniformly placed with reference to the indications or printed representations and as close as practicable to the indications or printed representations but not so positioned as to interfere with the accuracy of reading.

2.3.1.3 Units. The weight of each haul or set must be indicated in kilograms, and the cumulative weight must be indicated in either kilograms or metric tons and decimal subdivisions.

2.3.1.4 Value of the Scale Division. The value of the scale division (d) expressed in a unit of weight must be equal to 1, 2, or 5, or a decimal multiple or sub-multiple of 1, 2, or 5.

2.3.1.5 Range of Indication. The range of the weight indications and printed values for each haul or set must be from 0 kg to 999,999 kg and for the cumulative weight must be from 0 to 99,999 metric tons.

2.3.1.6 Resettable and Non-resettable Values. The means to indicate the weight of fish in each haul or set must be resettable to zero. The means to indicate the cumulative weight must not be resettable to zero without breaking a security means and must be reset only upon direction of NMFS or an authorized scale inspector.

2.3.1.7 Rate of Flow Indicator. Permanent means must be provided to produce an audio or visual signal when the rate of flow is less than the minimum flow rate or greater than 98 percent of the maximum flow rate.

2.3.1.8 Printed Information. The information printed must include—

a. For catch weight:

i. The vessel name;

ii. The Federal fisheries or processor permit number of the vessel;

iii. The haul or set number;

iv. The total weight of catch in each haul or set;

v. The total cumulative weight of all fish or other material weighed on the scale; and

vi. The date and time the information is printed.

b. For the audit trail:

i. The vessel name;

ii. The Federal fisheries or processor permit number of the vessel;

iii. The date and time (to the nearest minute) that the adjustment was made;

iv. The name or type of adjustment being made; and

v. The initial and final values of the parameter being changed.

2.3.1.9 Permanence of Markings. All required indications, markings, and instructions must be distinct and easily readable and must be of such character that they will not tend to become obliterated or illegible.

2.3.1.10 Power Loss. In the event of a power failure, means must be provided to retain in a memory the weight of fish in each haul or set for which a printed record has not yet been made, the cumulative weight, and the information on the audit trail.

2.3.1.11 Adjustable Components. An adjustable component that when adjusted affects the performance or accuracy of the scale must be held securely in position and must not be capable of adjustment without breaking a security means unless a record of the adjustment is made on the audit trail described in 2.3.1.12.

2.3.1.12 Audit Trail. An audit trail in the form of an event logger must be provided to document changes made using adjustable components. The following information must be provided in an electronic form that cannot be changed or erased by the scale operator, can be printed at any time, and can be cleared by the scale manufacturer's representative upon direction by NMFS or by an authorized scale inspector:

a. The date and time (to the nearest minute) of the change;

b. The name or type of adjustment being made; and

c. The initial and final values of the parameter being changed.

2.3.1.13 Adjustments to Scale Weights. The indicators and printer must be designed so that the scale operator cannot change or adjust the indicated and printed weight values.

2.3.2 Weighing Elements.

2.3.2.1 Speed Measurement. A belt scale must be equipped with means to accurately sense the belt travel and/or speed whether the belt is loaded or empty.

2.3.2.2 Conveyer Belt. The weight per unit length of the conveyor belt must be practically constant. Belt joints must be such that there are no significant effects on the weighing results.

2.3.2.3 Overload Protection. The load receiver must be equipped with means so that an overload of 150 percent or more of the capacity does not affect the metrological characteristics of the scale.

2.3.2.4 Speed Control. The speed of the belt must not vary by more than 5 percent of the nominal speed.

2.3.2.5 Adjustable Components. An adjustable component that can affect the performance of the belt scale must be held securely in position and must not be capable of adjustment without breaking a security means.

2.3.2.6 Motion Compensation. A belt scale must be equipped with automatic means to compensate for the motion of a vessel at sea so that the weight values indicated are within the MPEs. Such means shall be a reference load cell and a reference mass weight or other equally effective means. When equivalent means are utilized, the manufacturer must provide NMFS with information demonstrating that the scale can weigh accurately at sea.

2.3.3 Installation Conditions. A belt scale must be rigidly installed in a level condition.

2.3.4 Marking. A belt scale must be marked with the—

a. Name, initials, or trademark of the manufacturer or distributer;

b. Model designation;

c. Non-repetitive serial number;

d. Maximum flow rate (Qmax);

e. Minimum flow rate (Qmin);

f. Minimum totalized load (Σmin);

g. Value of a scale division (d);

h. Belt speed;

i. Weigh length;

j. Maximum capacity (Max);

k. Temperature range (if applicable); and

l. Mains voltage.

2.3.4.1 Presentation. The markings must be reasonably permanent and of such size, shape, and clarity to provide easy reading in normal conditions of use. They must be grouped together in a place visible to the operator.

2.4 Tests.

2.4.1 Minimum Test Load. The minimum test load must be the greater of—

a. 2 percent of the load totalized in 1 hour at the maximum flow rate;

b. The load obtained at maximum flow rate in one revolution of the belt; or

c. A load equal to 800 scale divisions.

2.4.2 Laboratory Tests.

2.4.2.1 Influence Quantity and Disturbance Tests. Tests must be conducted according to annex A and the results of these tests must be within the values specified in section 2.2.1.1.

2.4.2.2 Zero-Load Tests. A zero-load test must be conducted for a time equal to that required to deliver the minimum totalized load (“min). At least two zero-load tests must be conducted prior to a material test. The results of these tests must be within the values specified in section 2.2.1.2.

2.4.2.3 Material Tests. At least one material test must be conducted with the weight of the material or simulated material equal to or greater than the minimum test load. The results of these tests must be within the values specified in section 2.2.1.3.

2.4.3 Annual Inspections.

2.4.3.1 Zero-Load Tests. A zero-load test must be conducted for a time equal to that required to deliver the minimum totalized load (Σmin). At least one zero-load test must be conducted prior to each material test. The results of this test must be within the values specified in section 2.2.1.2.

2.4.3.2 Material Tests. At least one material or simulated material test must be conducted with the weight of the material or simulated material equal to or greater than the minimum test load. The results of these tests must be within the values specified in section 2.2.1.3.

3. Automatic Hopper Scales

3.1 Applicability. The requirements in this section apply to a scale or scale system that is designed for automatic weighing of a bulk commodity in predetermined amounts.

3.2 Performance Requirements.

3.2.1 Maximum Permissible Errors. For laboratory tests of a scale and initial inspection and annual reinspections of an installed scale when the vessel is tied up at a dock and is not under power at sea, the following MPEs are specified:

3.2.1.1 Laboratory Tests. See annex A to appendix A for procedures for disturbance test and influence factors.

a. Disturbances. Significant fault (sf) (±scale division).

b. Influence Factors. ±1 percent of test load.

3.2.1.2 Increasing and Decreasing Load Tests. For increasing and decreasing load tests conducted in a laboratory or on a scale installed on a vessel tied up at a dock and not under power at sea, ±1.0 percent of the test load.

3.2.2 Minimum Weighment (Σmin). The minimum weighment must not be less than 20 percent of the weighing capacity, or a load equal to 100 scale intervals (d), except for the final weighment of a lot.

3.2.3 Minimum Totalized Load (Lot). The minimum totalized load must not be less than 4 weighments.

3.2.4 Influence Quantities. The following requirements apply to influence factor tests conducted in the laboratory:

3.2.4.1 Temperature. A hopper scale must comply with the metrological and technical requirements at temperatures from −10 °C to + 40 °C. However, for special applications the temperature range may be different, but the range must not be less than 30 °C and must be so specified on the scale's descriptive markings.

3.2.4.1.1 Operating Temperature. A hopper scale must not display or print any usable weight values until the operating temperature necessary for accurate weighing and a stable zero-balance condition have been attained.

3.2.4.2 Power Supply. A hopper scale must comply with the performance and technical requirements when operated within −15 percent to + 10 percent of the power supply specified on the scale's descriptive markings.

3.3 Technical Requirements.

3.3.1 Indicators and Printers.

3.3.1.1 General. a. A hopper scale must be equipped with an indicator and printer that indicates and prints the weight of each load and a no-load reference value; and a printer that prints the total weight of fish in each haul or set and the total cumulative weight of all fish and other material weighed on the scale between annual inspections (“the cumulative weight”). The indications and printed information must be clear, definite, accurate, and easily read under all conditions of normal operation of the hopper scale.

b. A no-load reference value may be a positive or negative value in terms of scale divisions or zero. When the no-load reference value is zero, the scale must return to a zero indication (within ±0.5 scale division) when the load receptor (hopper) is empty following the discharge of all loads, without the intervention of either automatic or manual means.

3.3.1.2 Values Defined. If indications or printed representations are intended to have specific values, these must be defined by a sufficient number of figures, words, or symbols, uniformly placed with reference to the indications or printed representations and as close as practicable to the indications or printed representations but not so positioned as to interfere with the accuracy of reading.

3.3.1.3 Units. The weight of each haul or set must be indicated in kilograms, and the cumulative weight must be indicated in either kilograms or metric tons and decimal subdivisions.

3.3.1.4 Value of the Scale Division. The value of the scale division (d) expressed in a unit of weight must be equal to 1, 2, or 5, or a decimal multiple or sub-multiple of 1, 2, or 5.

3.3.1.5 Weighing Sequence. For hopper scales used to receive (weigh in), the no-load reference value must be determined and printed only at the beginning of each weighing cycle. For hopper scales used to deliver (weigh out), the no-load reference value must be determined and printed only after the gross-load weight value for each weighing cycle has been indicated and printed.

3.3.1.6 Printing Sequence. Provision must be made so that all weight values are indicated until the completion of the printing of the indicated values.

3.3.1.7 Printed Information. The information printed must include—

a. For catch weight:

i. The vessel name;

ii. The Federal fisheries or processor permit number of the vessel;

iii. The haul or set number;

iv. The total weight of catch in each haul or set;

v. The total cumulative weight of all fish or other material weighed on the scale; and

vi. The date and time the information is printed.

b. For the audit trail:

i. The vessel name;

ii. The Federal fisheries or processor permit number of the vessel;

iii. The date and time (to the nearest minute) of the change;

iv. The name or type of adjustment being made; and

v. The initial and final values of the parameter being changed.

3.3.1.8 Permanence of Markings. All required indications, markings, and instructions must be distinct and easily readable and must be of such character that they will not tend to become obliterated or illegible.

3.3.1.9 Range of Indication. The range of the weight indications and printed values for each haul or set must be from 0 kg to 999,999 kg and for the cumulative weight must be from 0 to 99,999 metric tons.

3.3.1.10 Non-Resettable Values. The cumulative weight must not be resettable to zero without breaking a security means and must be reset only upon direction by NMFS or by an authorized scale inspector.

3.3.1.11 Power Loss. In the event of a power failure, means must be provided to retain in a memory the weight of fish in each haul or set for which a printed record has not yet been made, the cumulative weight, and the information on the audit trail described in 3.3.1.13.

3.3.1.12 Adjustable Components. An adjustable component that, when adjusted, affects the performance or accuracy of the scale must not be capable of adjustment without breaking a security means, unless a record of the adjustment is made on the audit trail described in 3.3.1.13.

3.3.1.13 Audit Trail. An audit trail in the form of an event logger must be provided to document changes made using adjustable components. The following information must be provided in an electronic form that cannot be changed or erased by the scale operator, can be printed at any time, and can be cleared by the scale manufacturer's representative upon direction of NMFS or by an authorized scale inspector:

a. The date and time (to the nearest minute) of the change;

b. The name or type of adjustment being made; and

c. The initial and final values of the parameter being changed.

3.3.1.14 Zero-Load Adjustment. A hopper scale must be equipped with a manual or semi-automatic means that can be used to adjust the zero-load balance or no-load reference value.

3.3.1.14.1 Manual. A manual means must be operable or accessible only by a tool outside of, or entirely separate from, this mechanism or enclosed in a cabinet.

3.3.1.14.2 Semi-Automatic. A semi-automatic means must be operable only when the indication is stable within ±1 scale division and cannot be operated during a weighing cycle (operation).

3.3.1.15 Damping Means. A hopper scale must be equipped with effective automatic means to bring the indications quickly to a readable stable equilibrium. Effective automatic means must also be provided to permit the recording of weight values only when the indication is stable within plus or minus one scale division.

3.3.1.16 Adjustments to Scale Weights. The indicators and printer must be designed so that the scale operator cannot change or adjust the indicated and printed weight values.

3.3.2 Interlocks and Gate Control. A hopper scale must have operating interlocks so that—

a. Product cannot be weighed if the printer is disconnected or subject to a power loss;

b. The printer cannot print a weight if either of the gates leading to or from the weigh hopper is open;

c. The low paper sensor of the printer is activated;

d. The system will operate only in the sequence intended; and

e. If the overfill sensor is activated, this condition is indicated to the operator and is printed.

3.3.3 Overfill Sensor. The weigh hopper must be equipped with an overfill sensor that will cause the feed gate to close, activate an alarm, and stop the weighing operation until the overfill condition has been corrected.

3.3.4 Weighing Elements.

3.3.4.1 Overload Protection. The weigh hopper must be equipped with means so that an overload of 150 percent or more of the capacity of the hopper does not affect the metrological characteristics of the scale.

3.3.4.2 Adjustable Components. An adjustable component that can affect the performance of the hopper scale must be held securely in position and must not be capable of adjustment without breaking a security means.

3.3.4.3 Motion Compensation. A hopper scale must be equipped with automatic means to compensate for the motion of a vessel at sea so that the weight values indicated are within the MPEs. Such means shall be a reference load cell and a reference mass weight or other equally effective means. When equivalent means are utilized, the manufacturer must provide NMFS with information demonstrating that the scale can weigh accurately at sea.

3.3.5 Installation Conditions. A hopper scale must be rigidly installed in a level condition.

3.3.6 Marking. A hopper scale must be marked with the following:

a. Name, initials, or trademark of the manufacturer or distributer;

b. Model designation;

c. Non-repetitive serial number;

d. Maximum capacity (Max);

e. Minimum capacity (min);

f. Minimum totalized load (Σmin);

g. Minimum weighment;

h. Value of the scale division (d);

i. Temperature range (if applicable); and

j. Mains voltage.

3.3.6.1 Presentation. Descriptive markings must be reasonably permanent and grouped together in a place visible to the operator.

3.4 Tests.

3.4.1 Standards. The error of the standards used must not exceed 25 percent of the MPE to be applied.

3.4.2 Laboratory Tests.

3.4.2.1 Influence Quantity and Disturbance Tests. Tests must be conducted according to annex A and the results of these tests must be within the values specified in section 3.2.1.1.

3.4.2.2 Performance Tests. Performance tests must be conducted as follows:

a. Increasing load test. At least five increasing load tests must be conducted with test loads at the minimum load, at a load near capacity, and at 2 or more critical points in between; and

b. Decreasing load test. A decreasing load test must be conducted with a test load approximately equal to one-half capacity when removing the test loads of an increasing load test.

3.4.3 Annual Inspections.

At least two increasing load tests and two decreasing load tests must be conducted as specified in 3.4.2.2. Additionally, tests must be conducted with test loads approximately equal to the weight of loads at which the scale is normally used.

4. Platform Scales and Hanging Scales

4.1 Applicability. The requirements in this section apply to platform and hanging scales used to weigh total catch. Platform scales used only as observer sampling scales or to determine the known weight of fish for a material test of another scale are not required to have a printer under sections 4.3.1 and 4.3.1.5 or an audit trail under section 4.3.1.8.

4.2 Performance Requirements.

4.2.1 Maximum Permissible Errors. For laboratory tests of a scale and initial inspection and annual reinspections of an installed scale while the vessel is tied up at a dock and is not under power at sea, the following MPEs are specified:

4.2.1.1 Laboratory Tests. See annex A to this appendix A for procedures for disturbance tests and influence factors.

a. Disturbances. Significant fault (±1 scale division); and

b. Influence Factors. See Table 1 in section 4.2.1.2.

4.2.1.2 Increasing and Decreasing Load and Shift Tests. Increasing and decreasing load and shift tests conducted in a laboratory or on a scale installed on a vessel while the vessel is tied up at a dock and is not under power at sea, see Table 1 as follows:

4.2.2 Accuracy Classes. Scales are divided into two accuracy classes, class III and class IIII. The accuracy class of a scale is designated by the manufacturer. The design of each accuracy class with respect to number of scale divisions (n) and the value of the scale division (d) is specified according to table 2:

4.2.3 Minimum Load: For a Class III scale, 20d; for a Class IIII scale, 10d.

4.2.4 Influence Quantities. The following requirements apply to influence factor tests conducted in the laboratory.

4.2.4.1 Temperature. A scale must comply with the performance and technical requirements at temperatures from −10 °C to + 40 °C. However, for special applications the temperature range may be different, but the range must not be less than 30 °C and must be so specified on the descriptive markings.

4.2.4.1.1 Operating Temperature. A scale must not display or print any usable weight values until the operating temperature necessary for accurate weighing and a stable zero-balance condition have been attained.

4.2.4.2 Power Supply. A scale must comply with the performance and technical requirements when operated within −15 percent to + 10 percent of the power supply specified on the scale's descriptive markings.

4.3 Technical Requirements.

4.3.1 Indicators and Printers.

4.3.1.1 General. A scale must be equipped with an indicator and a printer. The indications and printed information must be clear, definite, accurate, and easily read under all conditions of normal operation of the scale.

4.3.1.2 Values Defined. If indications or printed representations are intended to have specific values, these must be defined by a sufficient number of figures, words, or symbols, uniformly placed with reference to the indications or printed representations and as close as practicable to the indications or printed representations but not so positioned as to interfere with the accuracy of reading.

4.3.1.3 Units. The weight units indicated must be in terms of kilograms and decimal subdivisions.

4.3.1.4 Value of the Scale Division. The value of the scale division (d) expressed in a unit of weight must be equal to 1, 2, or 5, or a decimal multiple or sub-multiple of 1, 2, or 5.

4.3.1.5 Printed Information. The information printed must include—

a. For catch weight:

i. The vessel name;

ii. The Federal fisheries or processor permit number of the vessel;

iii. The haul or set number;

iv. Net weight of the fish.

b. For the audit trail:

i. The vessel name;

ii. The Federal fisheries or processor permit number of the vessel;

iii. The date and time (to the nearest minute) of the change;

iv. The name or type of adjustment being made; and

v. The initial and final values of the parameter being changed.

4.3.1.6 Permanence of Markings. All required indications, markings, and instructions must be distinct and easily readable and must be of such character that they will not tend to become obliterated or illegible.

4.3.1.7 Power Loss. In the event of a power failure, means must be provided to retain in a memory the weight of the last weighment if it is a non-repeatable weighment.

4.3.1.8 Adjustable Components.

a. An adjustable component that, when adjusted, affects the performance or accuracy of the scale must be held securely in position and must not be capable of adjustment without breaking a security means.

b. An audit trail in the form of an event logger must be provided to document changes made using adjustable components. The following information must be provided in an electronic form that cannot be changed or erased by the scale operator, can be printed at any time, and can be cleared by the scale manufacturer's representative upon direction of NMFS or an authorized scale inspector:

i. The date and time (to the nearest minute) of the change;

ii. The name or type of adjustment being made; and

iii. The initial and final values of the parameter being changed.

4.3.1.9 Zero-Load Adjustment. A scale must be equipped with a manual or semi-automatic means that can be used to adjust the zero-load balance or no-load reference value.

4.3.1.9.1 Manual. A manual means must be operable or accessible only by a tool outside of or entirely separate from this mechanism or enclosed in a cabinet.

4.3.1.9.2 Semi-automatic. A semi-automatic means must meet the provisions of 4.3.1.8 or must be operable only when the indication is stable within ±1 scale division and cannot be operated during a weighing cycle (operation).

4.3.1.10 Damping Means. A scale must be equipped with effective automatic means to bring the indications quickly to a readable stable equilibrium. Effective automatic means must also be provided to permit the recording of weight values only when the indication is stable within plus or minus one scale division.

4.3.2 Weighing Elements.

4.3.2.1 Overload Protection. The scale must be so designed that an overload of 150 percent or more of the capacity does not affect the metrological characteristics of the scale.

4.3.2.2 Adjustable Components. An adjustable component that can affect the performance of the scale must be held securely in position and must not be capable of adjustment without breaking a security means.

4.3.2.3 Motion Compensation. A platform scale must be equipped with automatic means to compensate for the motion of a vessel at sea so that the weight values indicated are within the MPEs. Such means shall be a reference load cell and a reference mass weight or other equally effective means. When equivalent means are utilized, the manufacturer must provide NMFS with information demonstrating that the scale can weigh accurately at sea.

4.3.3 Installation Conditions. A platform scale must be rigidly installed in a level condition. When in use, a hanging scale must be freely suspended from a fixed support or a crane.

4.3.4 Marking. A scale must be marked with the following:

a. Name, initials, or trademark of the manufacturer or distributor;

b. Model designation;

c. Non-repetitive serial number;

d. Accuracy class (III or IIII);

e. Maximum capacity (Max);

f. Minimum capacity (min);

g. Value of a scale division (d);

h. Temperature range (if applicable); and

i. Mains voltage.

4.3.4.1 Presentation. Descriptive markings must be reasonably permanent and grouped together in a place visible to the operator.

4.4 Tests.

4.4.1 Standards. The error of the standards used must not exceed 25 percent of the MPE applied.

4.4.2 Laboratory Tests.

4.4.2.1 Influence Quantities and Disturbance Tests. Tests must be conducted according to annex A to this appendix A, and the results of these tests must be within the values specified in section 4.2.1.1.

4.4.2.2 Performance Tests. Performance tests must be conducted as follows:

a. Increasing load test. At least five increasing load tests must be conducted with test loads at the minimum load, at a load near capacity, and at 2 or more critical points in between.

b. Shift test (platform scales only). A shift test must be conducted during the increasing load test at one-third capacity test load centered in each quadrant of the platform.

c. Decreasing load test. A decreasing load test must be conducted with a test load approximately equal to one-half capacity when removing the test loads of an increasing load test.

4.4.3 Annual Scale Inspections.

At least two increasing load tests, shift tests, and decreasing load tests must be conducted as specified in section 4.4.2.2. Additionally tests must be conducted with test loads approximately equal to the weight of loads at which the scale is normally used. The results of all tests must be as specified in Table 1 in section 4.2.1.2.

5. Definitions

Adjustable component—Any component that, when adjusted, affects the performance or accuracy of the scale, e.g., span adjustment or automatic zero-setting means. Manual or semi-automatic zero-setting means are not considered adjustable components.

Audit trail—An electronic count and/or information record of the changes to the values of the calibration or configuration parameters of a scale.

Automatic hopper scale—A hopper scale adapted to the automatic weighing of a bulk commodity (fish) in predetermined amounts. Capacities vary from 20 kg to 50 mt. It is generally equipped with a control panel, with functions to be set by an operator, including the start of an automatic operation. (See definition of hopper scale).

Belt scale—A scale that employs a conveyor belt in contact with a weighing element to determine the weight of a bulk commodity being conveyed. It is generally a part of a system consisting of an input conveyor, the flow scale, and an output conveyor. The conveyor belt may be constructed of various materials, including vulcanized rubber, canvas, and plastic. The capacity is generally specified in terms of the amount of weight that can be determined in a specified time, and can vary from, for example, 1 ton per hour to 100 or more tons per hour. An operator generally directs the flow of product onto the input conveyor.

Calibration mode—A means by which the span of a scale can be adjusted by placing a known “test weight” on the scale and manually operating a key on a key board.

Disturbances—An influence that may occur during the use of a scale but is not within the rated operating conditions of the scale.

Event logger—A form of audit trail containing a series of records where each record contains the identification of the parameter that was changed, the time and date when the parameter was changed, and the new value of the parameter.

Final weighment—The last partial load weighed on a hopper scale that is part of the weight of many loads.

Hanging scale—A scale that is designed to weigh a load that is freely suspended from an overhead crane or it may be permanently installed in an overhead position. The load receiver may be a part of the scale such as a pan suspended on chains, or simply a hook that is used to “pick-up” the container of the commodity to be weighed. The technology employed may be mechanical, electro-mechanical, or electronic. The loads can be applied either manually or by such means as a crane.

Hopper scale—A scale designed for weighing individual loads of a bulk commodity (fish). The load receiver is a cylindrical or rectangular container mounted on a weighing element. The weighing element may be mechanical levers, a combination of levers and a load cell, or all load cells. The capacity can vary from less than 20 kg to greater than 50 mt. The loads are applied from a bulk source by such means as a conveyor or storage hopper. Each step of the weighing process, that is the loading and unloading of the weigh hopper, is controlled by an operator.

Indicator—That part of a scale that indicates the quantity that is being weighed.

Influence factor—A value of an influence quantity, e.g., 10°, that specifies the limits of the rated operating conditions of the scale.

Influence quantity—A quantity that is not the subject of the measurement but which influences the measurement obtained within the rated operating conditions of the scale.

Influence quantity and disturbance tests—Tests conducted in a laboratory to determine the capability of the scale under test to perform correctly in the environmental influences in which they are used and when subjected to certain disturbances that may occur during the use of the scale.

Initial verification—The first evaluation (inspection and test) of a production model of a weighing instrument that has been type evaluated to determine that the production model is consistent with the model that had been submitted for type evaluation.

Known weight test—A test in which the load applied is a test weight with a known value simulating the weight of the material that is usually weighed.

Load receiver—That part of the scale in which the quantity is placed when being weighed.

Material test—A test using a material that is the same or similar to the material that is usually weighed, the weight of which has been determined by a scale other than the scale under test.

Maximum flow-rate—The maximum flow-rate of material specified by the manufacturer at which a belt scale can perform correctly.

Minimum flow-rate—The minimum flow-rate specified by the manufacturer at which a belt scale can perform correctly.

Minimum load—The smallest weight load that can be determined by the scale that is considered to be metrologically acceptable.

Minimum totalized load—The smallest weight load that can be determined by a belt scale that is considered to be metrologically acceptable.

Minimum weighment—The smallest weight that can be determined by a hopper scale that is considered to be metrologically acceptable.

Motion compensation—The means used to compensate for the motion of the vessel at sea.

No-load reference value—A weight value obtained by a hopper scale when the load receiver (hopper) is empty of the product that was or is to be weighed.

Non-repeatable weighment—A process where the product after being weighed is disposed of in such a manner that it cannot be retrieved to be reweighed.

Number of scale divisions (n)—The number of scale divisions of a scale in normal operation. It is the quotient of the scale capacity divided by the value of the scale division. n = Max/d

Performance requirements—A part of the regulations or standards that applies to the weighing performance of a scale, e.g., MPEs.

Performance test—A test conducted to determine that the scale is performing within the MPE applicable.

Periodic verification—A verification of a weighing instrument at an interval that is specified by regulation or administrative ruling.

Platform scale—A scale by the nature of its physical size, arrangement of parts, and relatively small capacity (generally 220 kg or less) that is adapted for use on a bench or counter or on the floor. A platform scale can be self contained, that is, the indicator and load receiver and weighing elements are all comprised of a single unit, or the indicator can be connected by cable to a separate load receiver and weighing element. The technology used may be mechanical, electro-mechanical, or electronic. Loads are applied manually.

Rated capacity—The maximum flow-rate in terms of weight per unit time specified by the manufacturer at which a belt scale can perform correctly.

Scale division (d)—The smallest digital subdivision in units of mass that is indicated by the weighing instrument in normal operation.

Sealing—A method used to prevent the adjustment of certain operational characteristics or to indicate that adjustments have been made to those operational characteristics.

Security seals or means—A physical seal such as a lead and wire seal that must be broken in order to change the operating or performance characteristics of the scale, or a number generated by the scale whenever a change is made to an adjustable component. The number must be sequential and it must not be possible for the scale operator to alter it. The number must be displayed whenever the scale is turned on.

Significant fault—An error greater than the value specified for a particular scale. For a belt scale: A fault greater than 0.18 percent of the weight value equal to the minimum totalized load. For all other scales: 1 scale division (d). A significant fault does not include faults that result from simultaneous and mutually independent causes in the belt scale; faults that imply the impossibility of performing any measurement; transitory faults that are momentary variations in the indications that cannot be interpreted, memorized, or transmitted as a measurement result; faults so serious that they will inevitably be noticed by those interested in the measurement.

Simulated material test—A test in which the load applied is test material simulating the weight of the material that is usually weighed.

Simulated test—A test in which the weight indications are developed by means other than weight, e.g., a load cell simulator.

Stationary installation—An installation of a scale in a facility on land or a vessel that is tied-up to a dock or in dry dock.

Subsequent verification—Any evaluation of a weighing instrument following the initial verification.

Suitability for use—A judgement that must be made that certain scales by nature of their design are appropriate for given weighing applications.

Technical requirements—A part of the regulations or standards that applies to the operational functions and characteristics of a scale, e.g., capacity, scale division, tare.

Testing laboratory—A facility for conducting type evaluation examinations of a scale that can establish its competency and proficiency by such means as ISO Guide 25, ISO 9000, EN 45011, NVLAP, NTEP.

Type evaluation—A process for evaluating the compliance of a weighing instrument with the appropriate standard or regulation.

User requirements—A part of the regulations or standards that applies to the operator/owner of the scale.

Weighment—A single complete weighing operation.

Annex A of Appendix A to Part 679—Influence Quantity and Disturbance Tests

A.1 General—Included in this annex are tests that are intended to ensure that electronic scales can perform and function as intended in the environment and under the conditions specified. Each test indicates, where appropriate, the reference condition under which the intrinsic error is determined.

A.2 Test Considerations

A.2.1 All electronic scales of the same category must be subjected to the same performance test program.

A.2.2 Tests must be carried out on fully operational equipment in its normal operational state. When equipment is connected in other than a normal configuration, the procedure must be mutually agreed to by NMFS and the applicant.

A.2.3 When the effect of one factor is being evaluated, all other factors must be held relatively constant, at a value close to normal. The temperature is deemed to be relatively constant when the difference between the extreme temperatures noted during the test does not exceed 5 °C and the variation over time does not exceed 5 °C per hour.

A.2.4 Before the start of a test, the equipment under test (EUT) must be energized for a period of time at least equal to the warm-up time specified by the manufacturer. The EUT must remain energized throughout the duration of the test.

A.3 Tests

A.3 Tests

A.3.1 Static Temperatures

Test method: Dry heat (non condensing) and cold.

Object of the test: To verify compliance with the applicable MPE under conditions of high and low temperature.

Reference to standard: See Bibliography (1).

Test procedure in brief: The test consists of exposure of the EUT to the high and low temperatures specified in section 2.2.4.1 for belt scales, section 3.2.4.1 for automatic hopper scales, and section 4.2.3.1 for platform scales and hanging scales, under “free air” condition for a 2-hour period after the EUT has reached temperature stability. The EUT must be tested during a weighing operation consisting of:

For belt scales—the totalization of the Σmin, 2 times each at approximately the minimum flow rate, an intermediate flow rate, and the maximum flow rate.

For platform, hanging, and automatic hopper scales—tested with at least five different test loads or simulated loads under the following conditions:

a. At a reference temperature of 20 °C following conditioning.

b. At the specified high temperature, 2 hours after achieving temperature stabilization.

c. At the specified low temperature, 2 hours after achieving temperature stabilization.

d. At a temperature of 5 °C, 2 hours after achieving temperature stabilization.

e. After recovery of the EUT at the reference temperature of 20 °C.

Test severities: Duration: 2 hours.

Number of test cycles: At least one cycle.

Maximum allowable variations:

a. All functions must operate as designed.

b. All indications must be within the applicable MPEs.

Conduct of test: Refer to the International Electrotechnical Commission (IEC) Publications mentioned in section A.4 Bibliography (a) for detailed test procedures.

Supplementary information to the IEC test procedures.

Preconditioning: 16 hours.

Condition of EUT: Normal power supplied and “on” for a time period equal to or greater than the warm-up time specified by the manufacturer. Power is to be “on” for the duration of the test. Adjust the EUT as close to a zero indication as practicable prior to the test.

Test Sequence:

a. Stabilize the EUT in the chamber at a reference temperature of 20 °C. Conduct the tests as specified in the test procedure in brief and record the following data:

i. Date and time,

ii. Temperature,

iii. Relative humidity,

iv. Test load,

v. Indication,

vi. Errors, and

vii. Functions performance.

b. Increase the temperature in the chamber to the high temperature specified. Check by measurement that the EUT has reached temperature stability and maintain the temperature for 2 hours. Following the 2 hours, repeat the tests and record the test data indicated in this A.3.1 Test Sequence section.

c. Reduce the temperature in the chamber as per the IEC procedures to the specified low temperature. After temperature stabilization, allow the EUT to soak for 2 hours. Following the 2 hours, repeat the tests and record the test data as indicated in this A.3.1 Test Sequence section.

d. Raise the temperature in the chamber as per the IEC procedures to 5 °C. After temperature stabilization, allow the EUT to soak for 2 hours. Following the 2 hours, repeat the tests and record the test data as indicated in this A.3.1 Test Sequence section.

Note:

This test relates to a −10 °C to + 40 °C range. For special ranges, it may not be necessary.

e. Raise the temperature in the chamber as per the IEC procedures and to the 20 °C reference temperature. After recovery, repeat the tests and record the test data as indicated in this A.3.1 Test Sequence section.

A.3.2 Damp Heat, Steady State

Test method: Damp heat, steady state.

Object of the test: To verify compliance with the applicable MPE under conditions of high humidity and constant temperature.

Reference to standard: See section A.4 Bibliography (b)

Test procedure in brief: The test consists of exposure of the EUT to a constant temperature at the upper limit of the temperature range and of a constant relative humidity of 85 percent for a 2-day period. The EUT must be tested during a weighing operation consisting of the following:

For belt scales—the totalization of the Σmin, 2 times each at approximately the minimum flow rate, an intermediate flow rate, and the maximum flow rate.

For platform, hanging, and automatic hopper scales—tested with at least five different test loads or simulated loads at a reference temperature of 20 °C and a relative humidity of 50 percent following conditioning, and at the upper limit temperature and a relative humidity of 85 percent 2 days following temperature and humidity stabilization.

Test severities:

Temperature: upper limit.

Humidity: 85 percent (non-condensing).

Duration: 2 days.

Number of test cycles: At least one test.

Maximum Allowable Variations:

a. All functions must operate as designed.

b. All indications must be within the applicable MPE.

Conduct of the test: Refer to the IEC Publications mentioned in section A.4 Bibliography (b) for detailed test procedures.

Supplementary information to the IEC test procedures.

Preconditioning: None required.

Condition of EUT:

a. Normal power supplied and “on” for a time period equal to or greater than the warm-up time specified by the manufacturer. Power is to be “on” for the duration of the test.

b. The handling of the EUT must be such that no condensation of water occurs on the EUT.

c. Adjust the EUT as close to a zero indication as practicable prior to the test.

Test Sequence:

a. Allow 3 hours for stabilization of the EUT at a reference temperature of 20 °C and a relative humidity of 50 percent. Following stabilization, conduct the tests as specified in the test procedures in brief and record the following data:

i. Date and time,

ii. Temperature,

iii. Relative humidity,

iv. Test load,

v. Indication,

vi. Errors, and

vii. Functions performance.

b. Increase the temperature in the chamber to the specified high temperature and a relative humidity of 85 percent. Maintain the EUT at no load for a period of 2 days. Following the 2 days, repeat the tests and record the test data as indicated in this A.3.2 Test Sequence section.

c. Allow full recovery of the EUT before any other tests are performed.

A.3.3 Power Voltage Variation

A.3.3.1 AC Power Supply

Test method: Variation in AC mains power supply (single phase).

Object of the test: To verify compliance with the applicable MPEs under conditions of varying AC mains power supply.

Reference to standard: See section A.4 Bibliography (c).

Test procedure in brief: The test consists of subjecting the EUT to AC mains power during a weighing operation consisting of the following:

For belt scales—while totalizing the Σmin at the maximum flow rate.

For platform, hanging, and automatic hopper scales—at no load and a test load between 50 percent and 100 percent of weighing capacity.

Test severities: Mains voltage:

Upper limit U (nom) + 10 percent.

Lower limit U (nom) −15 percent.

Number of test cycles: At least one cycle.

Maximum allowable variations:

a. All functions must operate correctly.

b. All indications must be within MPEs specified in sections 2, 3, or 4 of this appendix to part 679.

Conduct of the test:

Preconditioning: None required.

Test equipment:

a. Variable power source,

b. Calibrated voltmeter, and

c. Load cell simulator, if applicable.

Condition of EUT:

a. Normal power supplied and “on” for a time period equal to or greater than the warm-up time specified by the manufacturer.

b. Adjust the EUT as close to a zero indication as practicable prior to the test.

Test sequence:

a. Stabilize the power supply at nominal voltage ±2 percent.

b. Conduct the tests specified in the test procedure in brief and record the following data:

i. Date and time,

ii. Temperature,

iii. Relative humidity,

iv. Power supply voltage,

v. Test load,

vi. Indications,

vii. Errors, and

viii. Functions performance.

c. Reduce the power supply to −15 percent nominal.

d. Repeat the test and record the test data as indicated in this A.3.3 Test Sequence section.

e. Increase the power supply to + 10 percent nominal.

f. Repeat the test and record the test data as indicated in this A.3.3 Test Sequence section.

g. Unload the EUT and decrease the power supply to nominal power ±2 percent.

h. Repeat the test and record the test data as indicated in this A.3.3 Test Sequence section.

Note:

In case of three-phase power supply, the voltage variation must apply for each phase successively. Frequency variation applies to all phases simultaneously.

A.3.3.2 DC Power Supply

Under consideration.

A.3.4 Short Time Power Reduction

Test method: Short time interruptions and reductions in mains voltage.

Object of the test: To verify compliance with the applicable significant fault under conditions of short time mains voltage interruptions and reductions.

Reference to standard: See section A.4 Bibliography (d) IEC Publication 1000-4-11 (1994).

Test procedure in brief: The test consists of subjecting the EUT to voltage interruptions from nominal voltage to zero voltage for a period equal to 8-10 ms, and from nominal voltage to 50 percent of nominal for a period equal to 16-20 ms. The mains voltage interruptions and reductions must be repeated ten times with a time interval of at least 10 seconds. This test is conducted during a weighing operation consisting of the following:

For belt scales—while totalizing at the maximum flow rate at least the Σmin (or a time sufficient to complete the test).

For platform, hanging, and automatic hopper scales—tested with one small test load or simulated load.

Test severities: One hundred percent voltage interruption for a period equal to 8-10 ms. Fifty percent voltage reduction for a period equal to 16-20 ms.

Number of test cycles: Ten tests with a minimum of 10 seconds between tests.

Maximum allowable variations: The difference between the weight indication due to the disturbance and the indication without the disturbance either must not exceed 1d or the EUT must detect and act upon a significant fault.

Conduct of the Test:

Preconditioning: None required.

Test equipment:

a. A test generator suitable to reduce the amplitude of the AC voltage from the mains. The test generator must be adjusted before connecting the EUT.

b. Load cell simulator, if applicable.

Condition of EUT:

a. Normal power supplied and “on” for a time period equal to or greater than the warm-up time specified by the manufacturer.

b. Adjust the EUT as close to zero indication as practicable prior to the test.

Test sequence:

a. Stabilize all factors at nominal reference conditions.

b. Totalize as indicated in this A.3.4 Test Sequence section and record the—

i. Date and time,

ii. Temperature,

iii. Relative humidity,

iv. Power supply voltage,

v. Test load,

vi. Indications,

vii. Errors, and

viii. Functions performance.

c. Interrupt the power supply to zero voltage for a period equal to 8-10 ms. During interruption observe the effect on the EUT and record, as appropriate.

d. Repeat the steps four times in this A.3.4 Test Sequence section, making sure that there is a 10 second interval between repetitions. Observe the effect on the EUT.

e. Reduce the power supply to 50 percent of nominal voltage for a period equal to 16-20 ms. During reduction observe the effect on the EUT and record, as appropriate.

f. Repeat the steps four times in this A.3.4 Test Sequence section, making sure that there is a 10 second interval between repetitions. Observe the effect on the EUT.

A.3.5 Bursts

Test method: Electrical bursts.

Object of the test: To verify compliance with the provisions in this manual under conditions where electrical bursts are superimposed on the mains voltage.

Reference to standard: See section A.4 Bibliography (e)

Test Procedure in brief:

The test consists of subjecting the EUT to bursts of double exponential wave-form transient voltages. Each spike must have a rise in time of 5 ns and a half amplitude duration of 50 ns. The burst length must be 15 ms, the burst period (repetition time interval) must be 300 ms. This test is conducted during a weighing operation consisting of the following:

For belt scales—while totalizing at the maximum flow rate at least the Σmin (or a time sufficient to complete the test).

For platform, hanging, and automatic hopper scales—tested with one small test load or simulated load.

Test severities: Amplitude (peak value) 1000 V.

Number of test cycles: At least 10 positive and 10 negative randomly phased bursts must be applied at 1000 V.

Maximum allowable variations: The difference between the indication due to the disturbance and the indication without the disturbance either must not exceed the values given in sections 2.2.1.1b., 3.2.1.1b., and 4.2.1.1b, of this appendix, or the EUT must detect and act upon a significant fault.

Conduct of the test: Refer to the IEC Publication referenced in section A.4 Bibliography (e) for detailed test procedures.

Supplementary information to the IEC test procedures:

Test equipment:

A burst generator having an output impedance of 50 ohms.

Test conditions:

The burst generator must be adjusted before connecting the EUT. The bursts must be coupled to the EUT both on common mode and differential mode interference.

Condition of EUT:

a. Normal power supplied and “on” for a time period equal to or greater than the warm-up time specified by the manufacturer.

b. Adjust the EUT as close to a zero indication as practicable prior to the test.

Test Sequence:

a. Stabilize all factors at nominal reference conditions.

b. Conduct the test as indicated in this A.3.5 Test Sequence section and record the—

i. Date and time,

ii. Temperature,

iii. Relative humidity,

iv. Test load,

v. Indication,

vi. Errors, and

vii. Functions performance.

c. Subject the EUT to at least 10 positive and 10 negative randomly phased bursts at the 1000 V mode. Observe the effect on the EUT and record, as appropriate.

d. Stabilize all factors at nominal reference conditions.

e. Repeat the test and record the test data as indicated in this A.3.5 Test Sequence section.

A.3.6 Electrostatic Discharge

Test method: Electrostatic discharge (ESD).

Object of the test: To verify compliance with the provisions of this manual under conditions of electrostatic discharges.

Reference to standard: See section A.4 Bibliography (f)

Test procedure in brief:

A capacitor of 150 pF is charged by a suitable DC voltage source. The capacitor is then discharged through the EUT by connecting one terminal to ground (chassis) and the other via 150 ohms to surfaces which are normally accessible to the operator. This test is conducted during a weighing operation consisting of the following:

For belt scales—while totalizing at the maximum flow rate at least the Σmin (or a time sufficient to complete the test).

For platform, hanging, and automatic hopper scales—test with one small test load or simulated load.

Test severities

Air Discharge: up to and including 8 kV.

Contact Discharge: up to and including 6 kV.

Number of test cycles: At least 10 discharges must be applied at intervals of at least 10 seconds between discharges.

Maximum allowable variations:

The difference between the indication due to the disturbance and the indication without the disturbance either must not exceed the values indicated in sections 2.2.1.1 b., 3.2.1.1 b., and 4.2.1.1 b. of this appendix, or the EUT must detect and act upon a significant fault.

Conduct of the test: Refer to the IEC Publication mentioned in section A.4 Bibliography (d) for detailed test procedures.

Supplementary information to the IEC test procedures.

Preconditioning: None required.

Condition of EUT:

a. The EUT without a ground terminal must be placed on a grounded plate which projects beyond the EUT by at least 0.1 m on all sides. The ground connection to the capacitor must be as short as possible.

b. Normal power supplied and “on” for a time period equal to or greater than the warm-up time specified by the manufacturer. Power is to be “on” for the duration of the test.

c. The EUT must be operating under standard atmospheric conditions for testing.

d. Adjust the EUT as close to a zero indication as practicable prior to the test.

Test sequence:

a. Stabilize all factors at nominal reference conditions.

b. Conduct test as indicated in this A.3.6 Test Sequence section and record the—

i. Date and time,

ii. Temperature,

iii. Relative humidity,

iv. Power supply voltage,

v. Test load,

vi. Indication,

vii. Errors, and

viii. Functions performance.

c. Approach the EUT with the discharge electrode until discharge occurs and then remove it before the next discharge. Observe the effect of the discharge on the EUT and record, as appropriate.

d. Repeat the above step at least nine times, making sure to wait at least 10 seconds between successive discharges. Observe the effect on the EUT and record as appropriate.

e. Stabilize all factors at nominal reference conditions.

f. Repeat the test and record the test data as indicated in this A.3.6 Test Sequence section.

A.3.7 Electromagnetic Susceptibility

Test method: Electromagnetic fields (radiated).

Object of the Test:

To verify compliance with the provisions in this manual under conditions of electromagnetic fields.

Reference to standard: See section A.4 Bibliography (g).

Test procedure in brief:

a. The EUT is placed in an EMI chamber and tested under normal atmospheric conditions. This test is first conducted at one load in a static mode, and the frequencies at which susceptibility is evident are noted. Then tests are conducted at the problem frequencies, if any, during a weighing operation consisting of the following:

For belt scales—while totalizing at the maximum flow rate at least the Σmin (or a time sufficient to complete the test). It is then exposed to electromagnetic field strengths as specified in the Test severities in this section A.3.7 of this annex to appendix A of this part.

For platform, hanging, and automatic hopper scales—tested with one small test load.

b. The field strength can be generated in various ways:

i. The strip line is used at low frequencies (below 30 MHz or in some cases 150 MHz) for small EUT's;

ii. The long wire is used at low frequencies (below 30 MHz) for larger EUT's;

iii. Dipole antennas or antennas with circular polarization placed 1 m from the EUT are used at high frequencies.

c. Under exposure to electromagnetic fields the EUT is again tested as indicated above.

Test severities: Frequency range: 26-1000 MHz.

Field strength: 3 V/m.

Modulation: 80 percent AM, 1 kHz sine wave.

Number of test cycles: Conduct test by continuously scanning the specified frequency range while maintaining the field strength.

Maximum allowable variations: The difference between the indication due to the disturbance and the indication without the disturbance either must not exceed the values given in this manual, or the EUT must detect and act upon a significant fault.

Conduct of the test: Refer to the IEC Publication referenced in section A.4 Bibliography (g) for detailed information on test procedures.

Supplementary information to the IEC test procedures.

Test conditions:

a. The specified field strength must be established prior to the actual testing (without the EUT in the field). At least 1 m of all external cables must be included in the exposure by stretching them horizontally from the EUT.

b. The field strength must be generated in two orthogonal polarizations and the frequency range scanned slowly. If antennas with circular polarization, i.e., log-spiral or helical antennas, are used to generate the electromagnetic field, a change in the position of the antennas is not required. When the test is carried out in a shielded enclosure to comply with international laws prohibiting interference to radio communications, care needs to be taken to handle reflections from the walls. Anechoic shielding might be necessary.

Condition of EUT:

a. Normal power supplied and “on” for a time period equal to or greater than the warm-up time specified by the manufacturer. Power is to be “on” for the duration of the test. The EUT must be operating under standard atmospheric conditions for testing.

b. Adjust the EUT as close to a zero indication as practicable prior to the test.

Test sequence:

a. Stabilize all factors at nominal reference conditions.

b. Conduct the test as indicated in this A.3.7 Test Sequence section and record the—

i. Date and time,

ii. Temperature,

iii. Relative humidity,

iv. Test load,

v. Indication,

vi. Errors, and

vii. Functions performance.

c. Following the IEC test procedures, expose the EUT at zero load to the specified field strengths while slowly scanning the three indicated frequency ranges.

d. Observe and record the effect on the EUT.

e. Repeat the test and observe and record the effect.

f. Stabilize all factors at nominal reference conditions.

g. Repeat the test and record the test data.

A.4 Bibliography

Below are references to Publications of the International Electrotechnical Commission (IEC), where mention is made in the tests in annex A to appendix A of this part.

a. IEC Publication 68-2-1 (1974): Basic environmental testing procedures. Part 2: Tests, Test Ad: Cold, for heat dissipating equipment under test (EUT), with gradual change of temperature.

IEC Publication 68-2-2 (1974): Basic environmental testing procedures, Part 2: Tests, Test Bd: Dry heat, for heat dissipating equipment under test (EUT) with gradual change of temperature.

IEC Publication 68-3-1 (1974): Background information, Section 1: Cold and dry heat tests.

b. IEC Publication 68-2-56 (1988): Environmental testing, Part 2: Tests, Test Cb: Damp heat, steady state. Primarily for equipment.

IEC Publication 68-2-28 (1980): Guidance for damp heat tests.

c. IEC Publication 1000-4-11 (1994): Electromagnetic compatibility (EMC) Part 4: Testing and measurement techniques, Section 11. Voltage dips, short interruptions and voltage variations immunity tests. Section 5.2 (Test levels—Voltage variation). Section 8.2.2 (Execution of the test-voltage variation).

d. IEC Publication 1000-4-11 (1994): Electromagnetic compatibility (EMC) Part 4: Testing and measurement techniques, Section 11: Voltage dips, short interruptions and voltage variations immunity tests. Section 5.1 (Test levels—Voltage dips and short interruptions. Section 8.2.1 (Execution of the test-voltage dips and short interruptions) of the maximum transit speed and the range of operating speeds.

e. IEC Publication 1000-4-4 (1995): Electromagnetic compatibility (EMC) Part 4: Testing and measurement techniques—Section 4: Electrical fast transient/burst immunity test. Basic EMC publication.

f. IEC Publication 1000-4-2 (1995): Electromagnetic compatibility (EMC) Part 4: Testing and measurement techniques—Section 2: Electrostatic discharge immunity test. Basic EMC Publication.

g. IEC Publication 1000-4-3 (1995): Electromagnetic compatibility (EMC) Part 4: Testing and measurement techniques—Section 3: Radiated, radio-frequency electromagnetic field immunity test.

[63 FR 5845, Feb. 4, 1998, as amended at 65 FR 33783, May 25, 2000]

b. Coordinates [64 FR 61983, Nov. 15, 1999; 65 FR 25290, May 1, 2000]

[64 FR 61985, Nov. 15, 1999]

b. Coordinates [64 FR 61987, Nov. 15, 1999; 65 FR 25291, May 1, 2000, as amended at 67 FR 4134, Jan. 28, 2002; 69 FR 21977, Apr. 23, 2004; 73 FR 76168, Dec. 15, 2008; 74 FR 18158, Apr. 21, 2009]

b. Coordinates [64 FR 61989, Nov. 15, 1999]

[79 FR 2801, Jan. 16, 2014]

[68 FR 23925, May 6, 2003]

[73 FR 76170, Dec. 15, 2008]

[75 FR 53069, Aug. 30, 2010]

b. Coordinates

The CSSA is an area defined as that portion of the Bering Sea Subarea described by straight lines connecting the following coordinates in the order listed:

56°00′ N. lat. 167°00′ W. long. 56°00′ N. lat. 165°00′ W. long. 55°30′ N. lat. 165°00′ W. long. 55°30′ N. lat. 164°00′ W. long. 55°00′ N. lat. 164°00′ W. long. 55°00′ N. lat. 167°00′ W. long. 56°00′ N. lat. 167°00′ W. long. [64 FR 61995, Nov. 15, 1999]

[79 FR 71348, Dec. 2, 2014]

[64 FR 61998, Nov. 15, 1999]

[74 FR 62509, Nov. 30, 2009]

b. Coordinates

The COBLZ is an area defined as that portion of the Bering Sea Subarea north of 56°30′ N. lat. that is west of a line connecting the following coordinates in the order listed:

56°30′ N. lat., 165°00′ W. long. 58°00′ N. lat., 165°00′ W. long. 59°30′ N. lat., 170°00′ W. long. and north along 170°00′ W. long. to its intersection with the U.S.-Russia Boundary. [64 FR 62000, Nov. 15, 2000]

[64 FR 62002, Nov. 15, 2000]

b. Coordinates

Area 2A includes all waters off the states of California, Oregon, and Washington;

Area 2B includes all waters off British Columbia;

Area 2C includes all waters off Alaska that are east of a line running 340° true from Cape Spencer Light (58°11′57″ N. lat., 136°38′18″ W. long.) and south and east of a line running 205° true from said light;

Area 3A includes all waters between Area 2C and a line extending from the most northerly point on Cape Aklek (57°41′15″ N. lat., 155°35′00″ W. long.) to Cape Ikolik (57°17′17″ N. lat., 154°47′18″ W. long.), then along the Kodiak Island coastline to Cape Trinity (56°44′50″ N. lat., 154°08′44″ W. long.), then 140° true;

Area 3B includes all waters between Area 3A and a line extending 150° true from Cape Lutke (54°29′00″ N. lat., 164°20′00″ W. long.) and south of 54°49′00″ N. lat. in Isanotski Strait;

Area 4A includes all waters in the GOA west of Area 3B and in the Bering Sea west of the closed area defined below that are east of 172°00′00″ W. long. and south of 56°20′00″ N. lat.;

Area 4B includes all waters in the Bering Sea and the GOA west of Area 4A and south of 56°20′00″ N. lat.;

Area 4C includes all waters in the Bering Sea north of Area 4A and north of the closed area defined below which are east of 171°00′00″ W. long., south of 58°00′00″ N. lat., and west of 168°00′00″ W. long.;

Area 4D includes all waters in the Bering Sea north of Areas 4A and 4B, north and west of Area 4C, and west of 168°00′00″ W. long.;

Area 4E includes all waters in the Bering Sea north and east of the closed area defined below, east of 168°00′00″ W. long., and south of 65°34′00″ N. lat.

Closed areas

All waters in the Bering Sea north of 54°49′00″ N. lat. in Isanotski Strait that are enclosed by a line from Cape Sarichef Light (54°36′00″ N. lat., 164°55′42″ W. long.) to a point at 56°20′00″ N. lat., 168°30′00 W. long.; thence to a point at 58°21′25″ N. lat., 163°00′00″ W. long.; thence to Strogonof Point (56°53′18″ N. lat., 158°50′37″ W. long.); and then along the northern coasts of the Alaska Peninsula and Unimak Island to the point of origin at Cape Sarichef Light.

In Area 2A, all waters north of Point Chehalis, WA (46°53′18″ N. lat.).

[64 FR 62003, Nov. 15, 1999]

[73 FR 43371, July 25, 2008]

[75 FR 61648, Oct. 6, 2010]

b. Coordinates

An area totaling 2.5 square nm off Cape Edgecumbe, defined by straight lines connecting the following points in a counterclockwise manner:

56°55.5′ N lat., 135°54.0′ W long;

56°57.0′ N lat., 135°54.0′ W long;

56°57.0′ N lat., 135°57.0′ W long;

56°55.5′ N lat., 135°57.0′ W long.

[65 FR 67308, Nov. 9, 2000]

[74 FR 62511, Nov. 30, 2009]

[67 FR 4134, Jan. 28, 2002]

[73 FR 43372, July 25, 2008]

Figure 22 to Part 679—Cook Inlet EEZ Area [89 FR 34765, Apr. 30, 2024]

[86 FR 60587, Nov. 3, 2021]

[74 FR 56746, Nov. 3, 2009]

[75 FR 61649, Oct. 6, 2010]

This figure shows the location of elevating devices in the elevated section of modified nonpelagic trawl gear, as specified under § 679.24(f). The top image shows the location of the end elevating devices in the elevated section for gear with net bridles no greater than 185 feet in length. The bottom image shows the location of the beginning elevating devices near the doors and the end elevating devices near the net for gear with net bridles no greater than 185 feet in length.

[79 FR 2803, Jan. 16, 2014]

Note:

The location for measurement of maximum line material cross section does not include any devices or braided or doubled material used for section termination.

[75 FR 61651, Oct. 6, 2010]

[76 FR 40634, July 11, 2011]

[76 FR 40634, July 11, 2011, as amended at 81 FR 70607, Oct. 13, 2016]

[73 FR 76172, Dec. 15, 2008]

[85 FR 41431, July 10, 2020]

[73 FR 76172, Dec. 15, 2008]

[85 FR 41433, July 10, 2020]

[80 FR 11909, Mar. 5, 2015]

[80 FR 11910, Mar. 5, 2015]

[79 FR 70312, Nov. 25, 2014]

[79 FR 70322, Nov. 25, 2014]

[79 FR 70334, Nov. 25, 2014]

[77 FR 6502, Feb. 8, 2012]

[67 FR 4137, Jan. 28, 2002]

[78 FR 607, Jan. 6, 2014]

[86 FR 74387, Dec. 30, 2021]

[86 FR 74389, Dec. 30, 2021; 87 FR 412, Jan. 5, 2022]

[75 FR 81922, Dec. 29, 2010]

[81 FR 70606, Oct. 13, 2016]

[73 FR 76186, Dec. 15, 2008]

[73 FR 76186, Dec. 15, 2008]

[70 FR 10238, Mar. 2, 2005]

[73 FR 76187, Dec. 15, 2008, as amended at 81 FR 95457, Dec. 28, 2016; 89 FR 34766, Apr. 30, 2024]

[66 FR 55126, Nov. 1, 2001]

[66 FR 43527, Aug. 20, 2001]

[66 FR 55128, Nov. 1, 2001]

[74 FR 13358, Mar. 27, 2009]

[74 FR 13358, Mar. 27, 2009]

[79 FR 66332, Nov. 7, 2014]

[71 FR 36703, June 28, 2006]

[71 FR 36703, June 28, 2006]

[73 FR9037, Feb. 19, 2008]

[71 FR 36703, June 28, 2006]

[71 FR 36703, June 28, 2006]

[71 FR 36703, June 28, 2006]

[76 FR 81290, Dec. 27, 2011]

[76 FR 81290, Dec. 27, 2011]

[76 FR 81290, Dec. 27, 2011]

[76 FR 81290, Dec. 27, 2011]

[76 FR 81290, Dec. 27, 2011]

[76 FR 81292, Dec. 27, 2011]

[80 FR 80708, Dec. 28, 2015]

[72 FR 52739, Sept. 14, 2007]

[72 FR 52739, Sept. 14, 2007]

[72 FR 52739, Sept. 14, 2007; 72 FR 61214, Oct. 29, 2007]

[72 FR 52739, Sept. 14, 2007]