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| Input props | [ "product" => App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. Measurements of impedance to remote earth, step and touch potentials, and current distributions are covered for grounding systems ranging in complexity from small grids (less than 900m 2), with only a few connected overhead or direct burial bare concentric (2) neutrals, to large grids (greater than 20 000m 2), with many connected neutrals, overhead ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Measurement of Impedance and Safety Characteristics of Large, Extended or Interconnected Grounding Systems" -notes: "Inactive-Withdrawn" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#7292 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @709423200 {#7318 : 1992-06-25 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1326150000 {#7316 : 2012-01-10 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "81.2" -bookCollection: "" -pageCount: 112 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } "showFullLabel" => "true" ] |
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| Component | App\Twig\Components\ProductState {#93008 +product: App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. Measurements of impedance to remote earth, step and touch potentials, and current distributions are covered for grounding systems ranging in complexity from small grids (less than 900m 2), with only a few connected overhead or direct burial bare concentric (2) neutrals, to large grids (greater than 20 000m 2), with many connected neutrals, overhead ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. 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| Input props | [ "product" => App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. Measurements of impedance to remote earth, step and touch potentials, and current distributions are covered for grounding systems ranging in complexity from small grids (less than 900m 2), with only a few connected overhead or direct burial bare concentric (2) neutrals, to large grids (greater than 20 000m 2), with many connected neutrals, overhead ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Measurement of Impedance and Safety Characteristics of Large, Extended or Interconnected Grounding Systems" -notes: "Inactive-Withdrawn" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#7292 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @709423200 {#7318 : 1992-06-25 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1326150000 {#7316 : 2012-01-10 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "81.2" -bookCollection: "" -pageCount: 112 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } ] |
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| Component | App\Twig\Components\ProductType {#93188 +product: App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. 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This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. 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| Input props | [ "product" => App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. Measurements of impedance to remote earth, step and touch potentials, and current distributions are covered for grounding systems ranging in complexity from small grids (less than 900m 2), with only a few connected overhead or direct burial bare concentric (2) neutrals, to large grids (greater than 20 000m 2), with many connected neutrals, overhead ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Measurement of Impedance and Safety Characteristics of Large, Extended or Interconnected Grounding Systems" -notes: "Inactive-Withdrawn" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#7292 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @709423200 {#7318 : 1992-06-25 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1326150000 {#7316 : 2012-01-10 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "81.2" -bookCollection: "" -pageCount: 112 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } ] |
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| Component | App\Twig\Components\ProductMostRecent {#93263 +product: App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. Measurements of impedance to remote earth, step and touch potentials, and current distributions are covered for grounding systems ranging in complexity from small grids (less than 900m 2), with only a few connected overhead or direct burial bare concentric (2) neutrals, to large grids (greater than 20 000m 2), with many connected neutrals, overhead ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Measurement of Impedance and Safety Characteristics of Large, Extended or Interconnected Grounding Systems" -notes: "Inactive-Withdrawn" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#7292 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @709423200 {#7318 : 1992-06-25 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1326150000 {#7316 : 2012-01-10 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "81.2" -bookCollection: "" -pageCount: 112 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } +label: "Most Recent" +icon: "check-xs" -mostRecentAttributeCode: "most_recent" -localeContext: Sylius\Component\Locale\Context\CompositeLocaleContext {#1833 …} } |
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| Input props | [ "product" => App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. Measurements of impedance to remote earth, step and touch potentials, and current distributions are covered for grounding systems ranging in complexity from small grids (less than 900m 2), with only a few connected overhead or direct burial bare concentric (2) neutrals, to large grids (greater than 20 000m 2), with many connected neutrals, overhead ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Measurement of Impedance and Safety Characteristics of Large, Extended or Interconnected Grounding Systems" -notes: "Inactive-Withdrawn" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#7292 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @709423200 {#7318 : 1992-06-25 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1326150000 {#7316 : 2012-01-10 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "81.2" -bookCollection: "" -pageCount: 112 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } "showFullLabel" => "true" ] |
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| Component | App\Twig\Components\ProductState {#100216 +product: App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. 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Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. 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| Input props | [ "product" => App\Entity\Product\Product {#7311 #id: 8297 #code: "IEEE00000227" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751037298 {#7274 : 2025-06-27 17:14:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#7322 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 28197 #name: "IEEE 81.2:1991" #slug: "ieee-81-2-1991-ieee00000227-239949" #description: """ New IEEE Standard - Inactive-Withdrawn.\n Practical instrumentation methods are presented for measuring the ac characteristics of large, extended or interconnected grounding systems. Measurements of impedance to remote earth, step and touch potentials, and current distributions are covered for grounding systems ranging in complexity from small grids (less than 900m 2), with only a few connected overhead or direct burial bare concentric (2) neutrals, to large grids (greater than 20 000m 2), with many connected neutrals, overhead ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . Even if a large grid has an impedance phase angle of 18 ° the resistance component will be only 5% lower than its impedance. However, for large grounding grids in low-resistive earth (<75 W -m) and for grounding systems that have numerous extended grounding conductors, the impedance could be signiÞcantly greater than the resistive component measured with the conventional test sets of IEEE Std 81-1983\n The purpose of this guide is to present practical instrumentation methods that may be used for the measurement of\n impedance to remote earth, step and touch potentials, and current distributions of large extended or interconnected\n grounding systems ranging in complexity from small grids (less than 900 m\n 2\n ), with only a few connected overhead or\n direct burial bare concentric neutrals, to large grids (greater than 20 000 m\n ), with many connected neutrals, overhead\n ground wires (sky wires), counterpoises, grid tie conductors, cable shields, and metallic pipes. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Measurement of Impedance and Safety Characteristics of Large, Extended or Interconnected Grounding Systems" -notes: "Inactive-Withdrawn" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#7292 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @709423200 {#7318 : 1992-06-25 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1326150000 {#7316 : 2012-01-10 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "81.2" -bookCollection: "" -pageCount: 112 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } ] |
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This standard addresses measurement safety; earth-return mutual errors; low-current measurements; power-system staged faults; communication and control cable transfer impedance; current distribution (current splits) in the grounding system; step, touch, mesh, and profile measurements; the foot-equivalent electrode earth resistance; and instrumentation characteristics and limitations.\n \t\t\t\t\n Test methods and instrumentation techniques used to measure the ac characteristics of large grounding systems include the following topics: 1) Measurement safety 2) Earth-return mutual errors 3) Low-current measurements 4) Power-system staged faults 5) Communication and control cable transfer impedance 6) Current distribution (current splits) in the grounding system 7) Step, touch, mesh, and proÞle measurements 8) The foot-equivalent electrode earth resistance 9) Instrumentation characteristics and limitations Grounding electrodes consisting of a single ground rod, arrays of ground rods, tower footings, and many grids (if no external grounding is connected) can be measured, interference voltages permitting, with methods outlined in IEEE Std 81-1983 [2] 1 . 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| Component | App\Twig\Components\ProductCard {#121763 +product: App\Entity\Product\Product {#121707 #id: 8294 #code: "IEEE00000224" #attributes: Doctrine\ORM\PersistentCollection {#121690 …} #variants: Doctrine\ORM\PersistentCollection {#121688 …} #options: Doctrine\ORM\PersistentCollection {#121683 …} #associations: Doctrine\ORM\PersistentCollection {#121685 …} #createdAt: DateTime @1751037295 {#121680 : 2025-06-27 17:14:55.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#121715 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#121701 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#121801 #locale: "en_US" #translatable: App\Entity\Product\Product {#121707} #id: 28185 #name: "IEEE 80:1986 (R1991)" #slug: "ieee-80-1986-r1991-ieee00000224-239946" #description: """ Revision Standard - Superseded.<br />\n Outdoor AC substations, either conventional or gas-insulated, are covered in this guide. Distribution, transmission, and generating plant substations are also included. With proper caution, the methods described herein are also applicable to indoor portions of such substations, or to substations that are wholly indoors. No attempt is made to cover the grounding problems peculiar to dc substations. A quantitative analysis of the effects of lightning surges is also beyond the scope of this guide.<br />\n \t\t\t\t """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Safety in AC Substation Grounding" -notes: "Superseded" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#121699 …} #channels: Doctrine\ORM\PersistentCollection {#121692 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#121696 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#121694 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#121709 …} -apiLastModifiedAt: DateTime @1754517600 {#121666 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#121714 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @523836000 {#121673 : 1986-08-08 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: DateTime @677973600 {#121686 : 1991-06-27 00:00:00.0 Europe/Paris (+02:00) } -canceledAt: null -edition: null -coreDocument: "80" -bookCollection: "" -pageCount: 370 -documents: Doctrine\ORM\PersistentCollection {#121705 …} -favorites: Doctrine\ORM\PersistentCollection {#121703 …} } +layout: "vertical" +showPrice: true +showStatusBadges: true +additionalClasses: "product__teaser--with-grey-border" +linkLabel: "See more" +imageFilter: "product_thumbnail_teaser" +hasStretchedLink: true +backgroundColor: "white" +hoverType: "shadow" } |
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| ProductState | App\Twig\Components\ProductState | 94.0 MiB | 0.19 ms | |
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| Input props | [ "product" => App\Entity\Product\Product {#121707 #id: 8294 #code: "IEEE00000224" #attributes: Doctrine\ORM\PersistentCollection {#121690 …} #variants: Doctrine\ORM\PersistentCollection {#121688 …} #options: Doctrine\ORM\PersistentCollection {#121683 …} #associations: Doctrine\ORM\PersistentCollection {#121685 …} #createdAt: DateTime @1751037295 {#121680 : 2025-06-27 17:14:55.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#121715 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#121701 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#121801 #locale: "en_US" #translatable: App\Entity\Product\Product {#121707} #id: 28185 #name: "IEEE 80:1986 (R1991)" #slug: "ieee-80-1986-r1991-ieee00000224-239946" #description: """ Revision Standard - Superseded.<br />\n Outdoor AC substations, either conventional or gas-insulated, are covered in this guide. Distribution, transmission, and generating plant substations are also included. With proper caution, the methods described herein are also applicable to indoor portions of such substations, or to substations that are wholly indoors. No attempt is made to cover the grounding problems peculiar to dc substations. A quantitative analysis of the effects of lightning surges is also beyond the scope of this guide.<br />\n \t\t\t\t """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Safety in AC Substation Grounding" -notes: "Superseded" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#121699 …} #channels: Doctrine\ORM\PersistentCollection {#121692 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#121696 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#121694 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#121709 …} -apiLastModifiedAt: DateTime @1754517600 {#121666 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#121714 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @523836000 {#121673 : 1986-08-08 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: DateTime @677973600 {#121686 : 1991-06-27 00:00:00.0 Europe/Paris (+02:00) } -canceledAt: null -edition: null -coreDocument: "80" -bookCollection: "" -pageCount: 370 -documents: Doctrine\ORM\PersistentCollection {#121705 …} -favorites: Doctrine\ORM\PersistentCollection {#121703 …} } ] |
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| Attributes | [ "showFullLabel" => false ] |
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| Component | App\Twig\Components\ProductState {#121803 +product: App\Entity\Product\Product {#121707 #id: 8294 #code: "IEEE00000224" #attributes: Doctrine\ORM\PersistentCollection {#121690 …} #variants: Doctrine\ORM\PersistentCollection {#121688 …} #options: Doctrine\ORM\PersistentCollection {#121683 …} #associations: Doctrine\ORM\PersistentCollection {#121685 …} #createdAt: DateTime @1751037295 {#121680 : 2025-06-27 17:14:55.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#121715 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#121701 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#121801 #locale: "en_US" #translatable: App\Entity\Product\Product {#121707} #id: 28185 #name: "IEEE 80:1986 (R1991)" #slug: "ieee-80-1986-r1991-ieee00000224-239946" #description: """ Revision Standard - Superseded.<br />\n Outdoor AC substations, either conventional or gas-insulated, are covered in this guide. Distribution, transmission, and generating plant substations are also included. With proper caution, the methods described herein are also applicable to indoor portions of such substations, or to substations that are wholly indoors. No attempt is made to cover the grounding problems peculiar to dc substations. A quantitative analysis of the effects of lightning surges is also beyond the scope of this guide.<br />\n \t\t\t\t """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Safety in AC Substation Grounding" -notes: "Superseded" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#121699 …} #channels: Doctrine\ORM\PersistentCollection {#121692 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#121696 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#121694 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#121709 …} -apiLastModifiedAt: DateTime @1754517600 {#121666 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#121714 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @523836000 {#121673 : 1986-08-08 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: DateTime @677973600 {#121686 : 1991-06-27 00:00:00.0 Europe/Paris (+02:00) } -canceledAt: null -edition: null -coreDocument: "80" -bookCollection: "" -pageCount: 370 -documents: Doctrine\ORM\PersistentCollection {#121705 …} -favorites: Doctrine\ORM\PersistentCollection {#121703 …} } +appearance: "state-suspended" +labels: [ "Superseded" ] -stateAttributeCode: "state" -localeContext: Sylius\Component\Locale\Context\CompositeLocaleContext {#1833 …} } |
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| ProductMostRecent | App\Twig\Components\ProductMostRecent | 94.0 MiB | 0.74 ms | |
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| Input props | [ "product" => App\Entity\Product\Product {#121707 #id: 8294 #code: "IEEE00000224" #attributes: Doctrine\ORM\PersistentCollection {#121690 …} #variants: Doctrine\ORM\PersistentCollection {#121688 …} #options: Doctrine\ORM\PersistentCollection {#121683 …} #associations: Doctrine\ORM\PersistentCollection {#121685 …} #createdAt: DateTime @1751037295 {#121680 : 2025-06-27 17:14:55.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754606304 {#121715 : 2025-08-08 00:38:24.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#121701 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#121801 #locale: "en_US" #translatable: App\Entity\Product\Product {#121707} #id: 28185 #name: "IEEE 80:1986 (R1991)" #slug: "ieee-80-1986-r1991-ieee00000224-239946" #description: """ Revision Standard - Superseded.<br />\n Outdoor AC substations, either conventional or gas-insulated, are covered in this guide. Distribution, transmission, and generating plant substations are also included. With proper caution, the methods described herein are also applicable to indoor portions of such substations, or to substations that are wholly indoors. No attempt is made to cover the grounding problems peculiar to dc substations. A quantitative analysis of the effects of lightning surges is also beyond the scope of this guide.<br />\n \t\t\t\t """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Safety in AC Substation Grounding" -notes: "Superseded" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#121699 …} #channels: Doctrine\ORM\PersistentCollection {#121692 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#121696 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#121694 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#121709 …} -apiLastModifiedAt: DateTime @1754517600 {#121666 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1704927600 {#121714 : 2024-01-11 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @523836000 {#121673 : 1986-08-08 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: DateTime @677973600 {#121686 : 1991-06-27 00:00:00.0 Europe/Paris (+02:00) } -canceledAt: null -edition: null -coreDocument: "80" -bookCollection: "" -pageCount: 370 -documents: Doctrine\ORM\PersistentCollection {#121705 …} -favorites: Doctrine\ORM\PersistentCollection {#121703 …} } ] |
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| Attributes | [] |
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