Components
6
Twig Components
15
Render Count
37
ms
Render Time
146.0
MiB
Memory Usage
Components
| Name | Metadata | Render Count | Render Time |
|---|---|---|---|
| ProductCard |
"App\Twig\Components\ProductCard"components/ProductCard.html.twig |
4 | 30.59ms |
| ProductState |
"App\Twig\Components\ProductState"components/ProductState.html.twig |
4 | 0.82ms |
| ProductMostRecent |
"App\Twig\Components\ProductMostRecent"components/ProductMostRecent.html.twig |
4 | 2.88ms |
| PageBanner |
"App\Twig\Components\PageBanner"components/PageBanner.html.twig |
1 | 5.65ms |
| BackButton |
"App\Twig\Components\BackButton"components/BackButton.html.twig |
1 | 0.27ms |
| ResponsiveCollapsibleGrid |
"App\Twig\Components\ResponsiveCollapsibleGrid"components/ResponsiveCollapsibleGrid.html.twig |
1 | 0.93ms |
Render calls
| PageBanner | App\Twig\Components\PageBanner | 146.0 MiB | 5.65 ms | |
|---|---|---|---|---|
| Input props | [ "backLabel" => "29 : Electrical engineering" "backUrl" => "/taxons/main/ics-2277/29-electrical-engineering-4357" "paddingClasses" => "p-2 px-lg-5 py-lg-0" "searchPlaceholder" => "sylius.ui.search" "showSearch" => "true" "title" => "29.220 : Galvanic cells and batteries" ] |
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| Attributes | [] |
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| Component | App\Twig\Components\PageBanner {#94336 +supTitle: null +title: "29.220 : Galvanic cells and batteries" +subTitle: null +backUrl: "/taxons/main/ics-2277/29-electrical-engineering-4357" +backLabel: "29 : Electrical engineering" +customClasses: null +backgroundType: null +centered: true +showSearch: true +searchPlaceholder: "sylius.ui.search" +searchValue: null +paddingClasses: "p-2 px-lg-5 py-lg-0" } |
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| BackButton | App\Twig\Components\BackButton | 146.0 MiB | 0.27 ms | |
|---|---|---|---|---|
| Input props | [ "url" => "/taxons/main/ics-2277/29-electrical-engineering-4357" "label" => "29 : Electrical engineering" ] |
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| Attributes | [] |
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| Component | App\Twig\Components\BackButton {#94427 +label: "29 : Electrical engineering" +url: "/taxons/main/ics-2277/29-electrical-engineering-4357" } |
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| ResponsiveCollapsibleGrid | App\Twig\Components\ResponsiveCollapsibleGrid | 146.0 MiB | 0.93 ms | |
|---|---|---|---|---|
| Input props | [ "items" => Doctrine\ORM\PersistentCollection {#8717 #collection: Doctrine\Common\Collections\ArrayCollection {#8663 …} #initialized: true -snapshot: [ …5] -owner: App\Entity\Taxonomy\Taxon {#8646 …} -association: [ …16] -em: ContainerHAOxQ06\EntityManagerGhostEbeb667 {#773 …} -backRefFieldName: "parent" -typeClass: Symfony\Component\VarDumper\Caster\CutStub {#178079 …} -isDirty: false } "responsiveItemsPerRow" => [ "mobile" => 2 "tablet" => 4 "desktop" => 6 ] "responsiveVisibleRows" => [ "mobile" => 50 "tablet" => 25 "desktop" => 17 ] "containerClass" => "taxon-grid-subcategories-listing mb-4 px-4 px-sm-0" "itemTemplate" => "@BitBagSyliusElasticsearchPlugin/Shop/Product/Index/DisplayStyle/_grid_subcategory_item.html.twig" "showMoreText" => "app.ui.collapsible_choices.show_more" "showLessText" => "app.ui.collapsible_choices.show_less" ] |
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| Attributes | [] |
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| Component | App\Twig\Components\ResponsiveCollapsibleGrid {#94614 +items: Doctrine\ORM\PersistentCollection {#8717 #collection: Doctrine\Common\Collections\ArrayCollection {#8663 …} #initialized: true -snapshot: [ …5] -owner: App\Entity\Taxonomy\Taxon {#8646 …} -association: [ …16] -em: ContainerHAOxQ06\EntityManagerGhostEbeb667 {#773 …} -backRefFieldName: "parent" -typeClass: Symfony\Component\VarDumper\Caster\CutStub {#178079 …} -isDirty: false } +responsiveItemsPerRow: [ "mobile" => 2 "tablet" => 4 "desktop" => 6 ] +responsiveVisibleRows: [ "mobile" => 50 "tablet" => 25 "desktop" => 17 ] +containerClass: "taxon-grid-subcategories-listing mb-4 px-4 px-sm-0" +buttonClass: "" +itemTemplate: "@BitBagSyliusElasticsearchPlugin/Shop/Product/Index/DisplayStyle/_grid_subcategory_item.html.twig" +showMoreText: "app.ui.collapsible_choices.show_more" +showLessText: "app.ui.collapsible_choices.show_less" +gridItemsIdentifierClass: "responsive-collapsible-grid-item-400741" } |
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| ProductCard | App\Twig\Components\ProductCard | 146.0 MiB | 11.67 ms | |
|---|---|---|---|---|
| Input props | [ "product" => App\Entity\Product\Product {#95056 #id: 12447 #code: "IEEE00007706" #attributes: Doctrine\ORM\PersistentCollection {#95124 …} #variants: Doctrine\ORM\PersistentCollection {#95122 …} #options: Doctrine\ORM\PersistentCollection {#95118 …} #associations: Doctrine\ORM\PersistentCollection {#95120 …} #createdAt: DateTime @1751040438 {#95060 : 2025-06-27 18:07:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95068 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95134 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95324 #locale: "en_US" #translatable: App\Entity\Product\Product {#95056} #id: 44797 #name: "IEEE 535:2022" #slug: "ieee-535-2022-ieee00007706-244101" #description: """ Revision Standard - Active.<br />\n Qualification methods for Class 1E vented lead acid batteries and racks to be used in nuclear power generating stations outside primary containment are described in this standard. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEEE Std 323. The application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. A process to demonstrate qualifications for both applications is provided in this standard<br />\n \t\t\t\t<br />\n This standard describes qualification methods for Class 1E vented lead-acid batteries and racks to be used in nuclear power generating stations outside primary containment. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEC/IEEE 60780-323. Application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. This standard provides a process to demonstrate qualification for both applications. This standard is based on the user demonstrating that the predominant failure mechanism is positive plate grid corrosion. The following technologies have been demonstrated to meet this criterion for full float service: a) Lead-calcium b) Lead-antimony c) Lead-selenium (low-antimony) To apply this standard to vented lead-acid technologies other than those listed above, the user is required to demonstrate the following for full float service: a) The predominant failure mechanism is positive plate grid corrosion using either natural aging or accelerated aging using aging factors specific to the technology. Battery sizing, maintenance, capacity testing, installation, charging equipment, and consideration of other battery technologies are beyond the scope of this standard. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Standard for Qualification of Class 1E Vented Lead Acid Storage Batteries for Nuclear Power Generating Stations" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95132 …} #channels: Doctrine\ORM\PersistentCollection {#95126 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95130 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95128 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95140 …} -apiLastModifiedAt: DateTime @1743289200 {#95073 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1677452400 {#95076 : 2023-02-27 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1675638000 {#95074 : 2023-02-06 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "535" -bookCollection: "" -pageCount: 27 -documents: Doctrine\ORM\PersistentCollection {#95138 …} -favorites: Doctrine\ORM\PersistentCollection {#95136 …} } "layout" => "vertical" "showPrice" => true "showStatusBadges" => true "imageFilter" => "product_listing_thumbnail" "additionalClasses" => "h-100 border-0" "hasStretchedLink" => true "backgroundColor" => "white" "hoverType" => "border-black" ] |
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| Attributes | [] |
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| Component | App\Twig\Components\ProductCard {#95211 +product: App\Entity\Product\Product {#95056 #id: 12447 #code: "IEEE00007706" #attributes: Doctrine\ORM\PersistentCollection {#95124 …} #variants: Doctrine\ORM\PersistentCollection {#95122 …} #options: Doctrine\ORM\PersistentCollection {#95118 …} #associations: Doctrine\ORM\PersistentCollection {#95120 …} #createdAt: DateTime @1751040438 {#95060 : 2025-06-27 18:07:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95068 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95134 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95324 #locale: "en_US" #translatable: App\Entity\Product\Product {#95056} #id: 44797 #name: "IEEE 535:2022" #slug: "ieee-535-2022-ieee00007706-244101" #description: """ Revision Standard - Active.<br />\n Qualification methods for Class 1E vented lead acid batteries and racks to be used in nuclear power generating stations outside primary containment are described in this standard. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEEE Std 323. The application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. A process to demonstrate qualifications for both applications is provided in this standard<br />\n \t\t\t\t<br />\n This standard describes qualification methods for Class 1E vented lead-acid batteries and racks to be used in nuclear power generating stations outside primary containment. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEC/IEEE 60780-323. Application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. This standard provides a process to demonstrate qualification for both applications. This standard is based on the user demonstrating that the predominant failure mechanism is positive plate grid corrosion. The following technologies have been demonstrated to meet this criterion for full float service: a) Lead-calcium b) Lead-antimony c) Lead-selenium (low-antimony) To apply this standard to vented lead-acid technologies other than those listed above, the user is required to demonstrate the following for full float service: a) The predominant failure mechanism is positive plate grid corrosion using either natural aging or accelerated aging using aging factors specific to the technology. Battery sizing, maintenance, capacity testing, installation, charging equipment, and consideration of other battery technologies are beyond the scope of this standard. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Standard for Qualification of Class 1E Vented Lead Acid Storage Batteries for Nuclear Power Generating Stations" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95132 …} #channels: Doctrine\ORM\PersistentCollection {#95126 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95130 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95128 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95140 …} -apiLastModifiedAt: DateTime @1743289200 {#95073 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1677452400 {#95076 : 2023-02-27 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1675638000 {#95074 : 2023-02-06 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "535" -bookCollection: "" -pageCount: 27 -documents: Doctrine\ORM\PersistentCollection {#95138 …} -favorites: Doctrine\ORM\PersistentCollection {#95136 …} } +layout: "vertical" +showPrice: true +showStatusBadges: true +additionalClasses: "h-100 border-0" +linkLabel: "" +imageFilter: "product_listing_thumbnail" +hasStretchedLink: true +backgroundColor: "white" +hoverType: "border-black" } |
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| ProductState | App\Twig\Components\ProductState | 146.0 MiB | 0.26 ms | |
|---|---|---|---|---|
| Input props | [ "product" => App\Entity\Product\Product {#95056 #id: 12447 #code: "IEEE00007706" #attributes: Doctrine\ORM\PersistentCollection {#95124 …} #variants: Doctrine\ORM\PersistentCollection {#95122 …} #options: Doctrine\ORM\PersistentCollection {#95118 …} #associations: Doctrine\ORM\PersistentCollection {#95120 …} #createdAt: DateTime @1751040438 {#95060 : 2025-06-27 18:07:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95068 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95134 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95324 #locale: "en_US" #translatable: App\Entity\Product\Product {#95056} #id: 44797 #name: "IEEE 535:2022" #slug: "ieee-535-2022-ieee00007706-244101" #description: """ Revision Standard - Active.<br />\n Qualification methods for Class 1E vented lead acid batteries and racks to be used in nuclear power generating stations outside primary containment are described in this standard. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEEE Std 323. The application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. A process to demonstrate qualifications for both applications is provided in this standard<br />\n \t\t\t\t<br />\n This standard describes qualification methods for Class 1E vented lead-acid batteries and racks to be used in nuclear power generating stations outside primary containment. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEC/IEEE 60780-323. Application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. This standard provides a process to demonstrate qualification for both applications. This standard is based on the user demonstrating that the predominant failure mechanism is positive plate grid corrosion. The following technologies have been demonstrated to meet this criterion for full float service: a) Lead-calcium b) Lead-antimony c) Lead-selenium (low-antimony) To apply this standard to vented lead-acid technologies other than those listed above, the user is required to demonstrate the following for full float service: a) The predominant failure mechanism is positive plate grid corrosion using either natural aging or accelerated aging using aging factors specific to the technology. Battery sizing, maintenance, capacity testing, installation, charging equipment, and consideration of other battery technologies are beyond the scope of this standard. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Standard for Qualification of Class 1E Vented Lead Acid Storage Batteries for Nuclear Power Generating Stations" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95132 …} #channels: Doctrine\ORM\PersistentCollection {#95126 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95130 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95128 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95140 …} -apiLastModifiedAt: DateTime @1743289200 {#95073 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1677452400 {#95076 : 2023-02-27 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1675638000 {#95074 : 2023-02-06 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "535" -bookCollection: "" -pageCount: 27 -documents: Doctrine\ORM\PersistentCollection {#95138 …} -favorites: Doctrine\ORM\PersistentCollection {#95136 …} } ] |
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| Attributes | [ "showFullLabel" => false ] |
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| Component | App\Twig\Components\ProductState {#95331 +product: App\Entity\Product\Product {#95056 #id: 12447 #code: "IEEE00007706" #attributes: Doctrine\ORM\PersistentCollection {#95124 …} #variants: Doctrine\ORM\PersistentCollection {#95122 …} #options: Doctrine\ORM\PersistentCollection {#95118 …} #associations: Doctrine\ORM\PersistentCollection {#95120 …} #createdAt: DateTime @1751040438 {#95060 : 2025-06-27 18:07:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95068 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95134 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95324 #locale: "en_US" #translatable: App\Entity\Product\Product {#95056} #id: 44797 #name: "IEEE 535:2022" #slug: "ieee-535-2022-ieee00007706-244101" #description: """ Revision Standard - Active.<br />\n Qualification methods for Class 1E vented lead acid batteries and racks to be used in nuclear power generating stations outside primary containment are described in this standard. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEEE Std 323. The application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. A process to demonstrate qualifications for both applications is provided in this standard<br />\n \t\t\t\t<br />\n This standard describes qualification methods for Class 1E vented lead-acid batteries and racks to be used in nuclear power generating stations outside primary containment. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEC/IEEE 60780-323. Application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. This standard provides a process to demonstrate qualification for both applications. This standard is based on the user demonstrating that the predominant failure mechanism is positive plate grid corrosion. The following technologies have been demonstrated to meet this criterion for full float service: a) Lead-calcium b) Lead-antimony c) Lead-selenium (low-antimony) To apply this standard to vented lead-acid technologies other than those listed above, the user is required to demonstrate the following for full float service: a) The predominant failure mechanism is positive plate grid corrosion using either natural aging or accelerated aging using aging factors specific to the technology. Battery sizing, maintenance, capacity testing, installation, charging equipment, and consideration of other battery technologies are beyond the scope of this standard. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Standard for Qualification of Class 1E Vented Lead Acid Storage Batteries for Nuclear Power Generating Stations" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95132 …} #channels: Doctrine\ORM\PersistentCollection {#95126 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95130 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95128 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95140 …} -apiLastModifiedAt: DateTime @1743289200 {#95073 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1677452400 {#95076 : 2023-02-27 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1675638000 {#95074 : 2023-02-06 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "535" -bookCollection: "" -pageCount: 27 -documents: Doctrine\ORM\PersistentCollection {#95138 …} -favorites: Doctrine\ORM\PersistentCollection {#95136 …} } +appearance: "state-active" +labels: [ "Active" ] -stateAttributeCode: "state" -localeContext: Sylius\Component\Locale\Context\CompositeLocaleContext {#1831 …} } |
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| ProductMostRecent | App\Twig\Components\ProductMostRecent | 146.0 MiB | 0.77 ms | |
|---|---|---|---|---|
| Input props | [ "product" => App\Entity\Product\Product {#95056 #id: 12447 #code: "IEEE00007706" #attributes: Doctrine\ORM\PersistentCollection {#95124 …} #variants: Doctrine\ORM\PersistentCollection {#95122 …} #options: Doctrine\ORM\PersistentCollection {#95118 …} #associations: Doctrine\ORM\PersistentCollection {#95120 …} #createdAt: DateTime @1751040438 {#95060 : 2025-06-27 18:07:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95068 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95134 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95324 #locale: "en_US" #translatable: App\Entity\Product\Product {#95056} #id: 44797 #name: "IEEE 535:2022" #slug: "ieee-535-2022-ieee00007706-244101" #description: """ Revision Standard - Active.<br />\n Qualification methods for Class 1E vented lead acid batteries and racks to be used in nuclear power generating stations outside primary containment are described in this standard. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEEE Std 323. The application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. A process to demonstrate qualifications for both applications is provided in this standard<br />\n \t\t\t\t<br />\n This standard describes qualification methods for Class 1E vented lead-acid batteries and racks to be used in nuclear power generating stations outside primary containment. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEC/IEEE 60780-323. Application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. This standard provides a process to demonstrate qualification for both applications. This standard is based on the user demonstrating that the predominant failure mechanism is positive plate grid corrosion. The following technologies have been demonstrated to meet this criterion for full float service: a) Lead-calcium b) Lead-antimony c) Lead-selenium (low-antimony) To apply this standard to vented lead-acid technologies other than those listed above, the user is required to demonstrate the following for full float service: a) The predominant failure mechanism is positive plate grid corrosion using either natural aging or accelerated aging using aging factors specific to the technology. Battery sizing, maintenance, capacity testing, installation, charging equipment, and consideration of other battery technologies are beyond the scope of this standard. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Standard for Qualification of Class 1E Vented Lead Acid Storage Batteries for Nuclear Power Generating Stations" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95132 …} #channels: Doctrine\ORM\PersistentCollection {#95126 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95130 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95128 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95140 …} -apiLastModifiedAt: DateTime @1743289200 {#95073 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1677452400 {#95076 : 2023-02-27 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1675638000 {#95074 : 2023-02-06 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "535" -bookCollection: "" -pageCount: 27 -documents: Doctrine\ORM\PersistentCollection {#95138 …} -favorites: Doctrine\ORM\PersistentCollection {#95136 …} } ] |
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| Attributes | [] |
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| Component | App\Twig\Components\ProductMostRecent {#95425 +product: App\Entity\Product\Product {#95056 #id: 12447 #code: "IEEE00007706" #attributes: Doctrine\ORM\PersistentCollection {#95124 …} #variants: Doctrine\ORM\PersistentCollection {#95122 …} #options: Doctrine\ORM\PersistentCollection {#95118 …} #associations: Doctrine\ORM\PersistentCollection {#95120 …} #createdAt: DateTime @1751040438 {#95060 : 2025-06-27 18:07:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95068 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95134 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95324 #locale: "en_US" #translatable: App\Entity\Product\Product {#95056} #id: 44797 #name: "IEEE 535:2022" #slug: "ieee-535-2022-ieee00007706-244101" #description: """ Revision Standard - Active.<br />\n Qualification methods for Class 1E vented lead acid batteries and racks to be used in nuclear power generating stations outside primary containment are described in this standard. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEEE Std 323. The application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. A process to demonstrate qualifications for both applications is provided in this standard<br />\n \t\t\t\t<br />\n This standard describes qualification methods for Class 1E vented lead-acid batteries and racks to be used in nuclear power generating stations outside primary containment. Qualifications required by IEEE Std 308 can be demonstrated by using the procedures in this standard in accordance with IEC/IEEE 60780-323. Application of batteries in nuclear power generating stations can be divided into two sections: duty cycles equal to or less than 8 h and duty cycles greater than 8 h. This standard provides a process to demonstrate qualification for both applications. This standard is based on the user demonstrating that the predominant failure mechanism is positive plate grid corrosion. The following technologies have been demonstrated to meet this criterion for full float service: a) Lead-calcium b) Lead-antimony c) Lead-selenium (low-antimony) To apply this standard to vented lead-acid technologies other than those listed above, the user is required to demonstrate the following for full float service: a) The predominant failure mechanism is positive plate grid corrosion using either natural aging or accelerated aging using aging factors specific to the technology. Battery sizing, maintenance, capacity testing, installation, charging equipment, and consideration of other battery technologies are beyond the scope of this standard. """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Standard for Qualification of Class 1E Vented Lead Acid Storage Batteries for Nuclear Power Generating Stations" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95132 …} #channels: Doctrine\ORM\PersistentCollection {#95126 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95130 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95128 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95140 …} -apiLastModifiedAt: DateTime @1743289200 {#95073 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1677452400 {#95076 : 2023-02-27 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1675638000 {#95074 : 2023-02-06 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "535" -bookCollection: "" -pageCount: 27 -documents: Doctrine\ORM\PersistentCollection {#95138 …} -favorites: Doctrine\ORM\PersistentCollection {#95136 …} } +label: "Most Recent" +icon: "check-xs" -mostRecentAttributeCode: "most_recent" -localeContext: Sylius\Component\Locale\Context\CompositeLocaleContext {#1831 …} } |
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| ProductCard | App\Twig\Components\ProductCard | 146.0 MiB | 7.12 ms | |
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| Input props | [ "product" => App\Entity\Product\Product {#95111 #id: 12599 #code: "IEEE00010255" #attributes: Doctrine\ORM\PersistentCollection {#95105 …} #variants: Doctrine\ORM\PersistentCollection {#95107 …} #options: Doctrine\ORM\PersistentCollection {#95142 …} #associations: Doctrine\ORM\PersistentCollection {#95109 …} #createdAt: DateTime @1751040538 {#95116 : 2025-06-27 18:08:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95115 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95082 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95655 #locale: "en_US" #translatable: App\Entity\Product\Product {#95111} #id: 45405 #name: "IEEE/ASHRAE 1635:2022" #slug: "ieee-ashrae-1635-2022-ieee00010255-244254" #description: """ Revision Standard - Active.<br />\n Vented lead-acid (VLA), valve-regulated lead-acid (VRLA), nickel-cadmium (Ni-Cd - both fully vented and partially-recombinant types), and Li-ion stationary battery installations are discussed in this guide, written to serve as a bridge between the electrical designer and the heating, ventilation, and air-conditioning (HVAC) designer. Ventilation of stationary battery installations is critical to improving battery life while reducing the hazards associated with hydrogen production (hydrogen production is not a concern with Li-ion under normal operating conditions [it is under thermal runaway conditions]). This guide describes battery operating modes and the hazards associated with each. It provides the HVAC designer with the information to provide a cost effective ventilation solution.<br />\n \t\t\t\t<br />\n This guide discusses the ventilation and thermal management of stationary battery systems as applied to the following: -- Vented (flooded) lead-acid (VLA) -- Valve-regulated lead-acid (VRLA) -- Nickel-cadmium (Ni-Cd) -- Partially recombinant nickel-cadmium. -- Lithium ion (Li-ion) For each category, both the technology and the design of the battery are described in order to facilitate user understanding of the environmental issues associated with each type of technology. The scope of this document includes only stationary batteries under conditions of expected use. Multiple operating modes are identified. The ventilation practices described in this guide represent the "best practice" based on the information available at the time this document was developed. The user should evaluate these practices against their operating experience, operating conditions, number and size of battery systems, manufacturer's recommendations, resources, and needs in developing an environment that is conducive to safety and optimum operation of the equipment. These recommendations were developed without consideration of economics, availability of equipment and personnel, or relative importance of the application. Design of a ventilation system for a specific battery installation requires consideration of all issues, not just the technical issues considered in this document.<br />\n The purpose of this document is to provide heating, ventilation, and air conditioning (HVAC) and battery system designers and users with information and recommendations concerning the ventilation and thermal management of stationary battery installations """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE/ASHRAE Guide for the Ventilation and Thermal Management of Batteries for Stationary Applications" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95099 …} #channels: Doctrine\ORM\PersistentCollection {#95103 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95098 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95101 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95086 …} -apiLastModifiedAt: DateTime @1743289200 {#95114 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1739919600 {#95113 : 2025-02-19 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1669762800 {#95112 : 2022-11-30 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "1635" -bookCollection: "" -pageCount: 140 -documents: Doctrine\ORM\PersistentCollection {#95089 …} -favorites: Doctrine\ORM\PersistentCollection {#95084 …} } "layout" => "vertical" "showPrice" => true "showStatusBadges" => true "imageFilter" => "product_listing_thumbnail" "additionalClasses" => "h-100 border-0" "hasStretchedLink" => true "backgroundColor" => "secondary-lighter" "hoverType" => "border-black" ] |
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| Component | App\Twig\Components\ProductCard {#95633 +product: App\Entity\Product\Product {#95111 #id: 12599 #code: "IEEE00010255" #attributes: Doctrine\ORM\PersistentCollection {#95105 …} #variants: Doctrine\ORM\PersistentCollection {#95107 …} #options: Doctrine\ORM\PersistentCollection {#95142 …} #associations: Doctrine\ORM\PersistentCollection {#95109 …} #createdAt: DateTime @1751040538 {#95116 : 2025-06-27 18:08:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95115 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95082 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95655 #locale: "en_US" #translatable: App\Entity\Product\Product {#95111} #id: 45405 #name: "IEEE/ASHRAE 1635:2022" #slug: "ieee-ashrae-1635-2022-ieee00010255-244254" #description: """ Revision Standard - Active.<br />\n Vented lead-acid (VLA), valve-regulated lead-acid (VRLA), nickel-cadmium (Ni-Cd - both fully vented and partially-recombinant types), and Li-ion stationary battery installations are discussed in this guide, written to serve as a bridge between the electrical designer and the heating, ventilation, and air-conditioning (HVAC) designer. Ventilation of stationary battery installations is critical to improving battery life while reducing the hazards associated with hydrogen production (hydrogen production is not a concern with Li-ion under normal operating conditions [it is under thermal runaway conditions]). This guide describes battery operating modes and the hazards associated with each. It provides the HVAC designer with the information to provide a cost effective ventilation solution.<br />\n \t\t\t\t<br />\n This guide discusses the ventilation and thermal management of stationary battery systems as applied to the following: -- Vented (flooded) lead-acid (VLA) -- Valve-regulated lead-acid (VRLA) -- Nickel-cadmium (Ni-Cd) -- Partially recombinant nickel-cadmium. -- Lithium ion (Li-ion) For each category, both the technology and the design of the battery are described in order to facilitate user understanding of the environmental issues associated with each type of technology. The scope of this document includes only stationary batteries under conditions of expected use. Multiple operating modes are identified. The ventilation practices described in this guide represent the "best practice" based on the information available at the time this document was developed. The user should evaluate these practices against their operating experience, operating conditions, number and size of battery systems, manufacturer's recommendations, resources, and needs in developing an environment that is conducive to safety and optimum operation of the equipment. These recommendations were developed without consideration of economics, availability of equipment and personnel, or relative importance of the application. Design of a ventilation system for a specific battery installation requires consideration of all issues, not just the technical issues considered in this document.<br />\n The purpose of this document is to provide heating, ventilation, and air conditioning (HVAC) and battery system designers and users with information and recommendations concerning the ventilation and thermal management of stationary battery installations """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE/ASHRAE Guide for the Ventilation and Thermal Management of Batteries for Stationary Applications" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95099 …} #channels: Doctrine\ORM\PersistentCollection {#95103 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95098 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95101 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95086 …} -apiLastModifiedAt: DateTime @1743289200 {#95114 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1739919600 {#95113 : 2025-02-19 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1669762800 {#95112 : 2022-11-30 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "1635" -bookCollection: "" -pageCount: 140 -documents: Doctrine\ORM\PersistentCollection {#95089 …} -favorites: Doctrine\ORM\PersistentCollection {#95084 …} } +layout: "vertical" +showPrice: true +showStatusBadges: true +additionalClasses: "h-100 border-0" +linkLabel: "" +imageFilter: "product_listing_thumbnail" +hasStretchedLink: true +backgroundColor: "secondary-lighter" +hoverType: "border-black" } |
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| ProductState | App\Twig\Components\ProductState | 146.0 MiB | 0.18 ms | |
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| Input props | [ "product" => App\Entity\Product\Product {#95111 #id: 12599 #code: "IEEE00010255" #attributes: Doctrine\ORM\PersistentCollection {#95105 …} #variants: Doctrine\ORM\PersistentCollection {#95107 …} #options: Doctrine\ORM\PersistentCollection {#95142 …} #associations: Doctrine\ORM\PersistentCollection {#95109 …} #createdAt: DateTime @1751040538 {#95116 : 2025-06-27 18:08:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95115 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95082 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95655 #locale: "en_US" #translatable: App\Entity\Product\Product {#95111} #id: 45405 #name: "IEEE/ASHRAE 1635:2022" #slug: "ieee-ashrae-1635-2022-ieee00010255-244254" #description: """ Revision Standard - Active.<br />\n Vented lead-acid (VLA), valve-regulated lead-acid (VRLA), nickel-cadmium (Ni-Cd - both fully vented and partially-recombinant types), and Li-ion stationary battery installations are discussed in this guide, written to serve as a bridge between the electrical designer and the heating, ventilation, and air-conditioning (HVAC) designer. Ventilation of stationary battery installations is critical to improving battery life while reducing the hazards associated with hydrogen production (hydrogen production is not a concern with Li-ion under normal operating conditions [it is under thermal runaway conditions]). This guide describes battery operating modes and the hazards associated with each. It provides the HVAC designer with the information to provide a cost effective ventilation solution.<br />\n \t\t\t\t<br />\n This guide discusses the ventilation and thermal management of stationary battery systems as applied to the following: -- Vented (flooded) lead-acid (VLA) -- Valve-regulated lead-acid (VRLA) -- Nickel-cadmium (Ni-Cd) -- Partially recombinant nickel-cadmium. -- Lithium ion (Li-ion) For each category, both the technology and the design of the battery are described in order to facilitate user understanding of the environmental issues associated with each type of technology. The scope of this document includes only stationary batteries under conditions of expected use. Multiple operating modes are identified. The ventilation practices described in this guide represent the "best practice" based on the information available at the time this document was developed. The user should evaluate these practices against their operating experience, operating conditions, number and size of battery systems, manufacturer's recommendations, resources, and needs in developing an environment that is conducive to safety and optimum operation of the equipment. These recommendations were developed without consideration of economics, availability of equipment and personnel, or relative importance of the application. Design of a ventilation system for a specific battery installation requires consideration of all issues, not just the technical issues considered in this document.<br />\n The purpose of this document is to provide heating, ventilation, and air conditioning (HVAC) and battery system designers and users with information and recommendations concerning the ventilation and thermal management of stationary battery installations """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE/ASHRAE Guide for the Ventilation and Thermal Management of Batteries for Stationary Applications" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95099 …} #channels: Doctrine\ORM\PersistentCollection {#95103 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95098 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95101 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95086 …} -apiLastModifiedAt: DateTime @1743289200 {#95114 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1739919600 {#95113 : 2025-02-19 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1669762800 {#95112 : 2022-11-30 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "1635" -bookCollection: "" -pageCount: 140 -documents: Doctrine\ORM\PersistentCollection {#95089 …} -favorites: Doctrine\ORM\PersistentCollection {#95084 …} } ] |
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| Component | App\Twig\Components\ProductState {#95673 +product: App\Entity\Product\Product {#95111 #id: 12599 #code: "IEEE00010255" #attributes: Doctrine\ORM\PersistentCollection {#95105 …} #variants: Doctrine\ORM\PersistentCollection {#95107 …} #options: Doctrine\ORM\PersistentCollection {#95142 …} #associations: Doctrine\ORM\PersistentCollection {#95109 …} #createdAt: DateTime @1751040538 {#95116 : 2025-06-27 18:08:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95115 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95082 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95655 #locale: "en_US" #translatable: App\Entity\Product\Product {#95111} #id: 45405 #name: "IEEE/ASHRAE 1635:2022" #slug: "ieee-ashrae-1635-2022-ieee00010255-244254" #description: """ Revision Standard - Active.<br />\n Vented lead-acid (VLA), valve-regulated lead-acid (VRLA), nickel-cadmium (Ni-Cd - both fully vented and partially-recombinant types), and Li-ion stationary battery installations are discussed in this guide, written to serve as a bridge between the electrical designer and the heating, ventilation, and air-conditioning (HVAC) designer. Ventilation of stationary battery installations is critical to improving battery life while reducing the hazards associated with hydrogen production (hydrogen production is not a concern with Li-ion under normal operating conditions [it is under thermal runaway conditions]). This guide describes battery operating modes and the hazards associated with each. It provides the HVAC designer with the information to provide a cost effective ventilation solution.<br />\n \t\t\t\t<br />\n This guide discusses the ventilation and thermal management of stationary battery systems as applied to the following: -- Vented (flooded) lead-acid (VLA) -- Valve-regulated lead-acid (VRLA) -- Nickel-cadmium (Ni-Cd) -- Partially recombinant nickel-cadmium. -- Lithium ion (Li-ion) For each category, both the technology and the design of the battery are described in order to facilitate user understanding of the environmental issues associated with each type of technology. The scope of this document includes only stationary batteries under conditions of expected use. Multiple operating modes are identified. The ventilation practices described in this guide represent the "best practice" based on the information available at the time this document was developed. The user should evaluate these practices against their operating experience, operating conditions, number and size of battery systems, manufacturer's recommendations, resources, and needs in developing an environment that is conducive to safety and optimum operation of the equipment. These recommendations were developed without consideration of economics, availability of equipment and personnel, or relative importance of the application. Design of a ventilation system for a specific battery installation requires consideration of all issues, not just the technical issues considered in this document.<br />\n The purpose of this document is to provide heating, ventilation, and air conditioning (HVAC) and battery system designers and users with information and recommendations concerning the ventilation and thermal management of stationary battery installations """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE/ASHRAE Guide for the Ventilation and Thermal Management of Batteries for Stationary Applications" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95099 …} #channels: Doctrine\ORM\PersistentCollection {#95103 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95098 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95101 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95086 …} -apiLastModifiedAt: DateTime @1743289200 {#95114 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1739919600 {#95113 : 2025-02-19 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1669762800 {#95112 : 2022-11-30 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "1635" -bookCollection: "" -pageCount: 140 -documents: Doctrine\ORM\PersistentCollection {#95089 …} -favorites: Doctrine\ORM\PersistentCollection {#95084 …} } +appearance: "state-active" +labels: [ "Active" ] -stateAttributeCode: "state" -localeContext: Sylius\Component\Locale\Context\CompositeLocaleContext {#1831 …} } |
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| ProductMostRecent | App\Twig\Components\ProductMostRecent | 146.0 MiB | 0.70 ms | |
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| Input props | [ "product" => App\Entity\Product\Product {#95111 #id: 12599 #code: "IEEE00010255" #attributes: Doctrine\ORM\PersistentCollection {#95105 …} #variants: Doctrine\ORM\PersistentCollection {#95107 …} #options: Doctrine\ORM\PersistentCollection {#95142 …} #associations: Doctrine\ORM\PersistentCollection {#95109 …} #createdAt: DateTime @1751040538 {#95116 : 2025-06-27 18:08:58.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1753970953 {#95115 : 2025-07-31 16:09:13.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95082 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95655 #locale: "en_US" #translatable: App\Entity\Product\Product {#95111} #id: 45405 #name: "IEEE/ASHRAE 1635:2022" #slug: "ieee-ashrae-1635-2022-ieee00010255-244254" #description: """ Revision Standard - Active.<br />\n Vented lead-acid (VLA), valve-regulated lead-acid (VRLA), nickel-cadmium (Ni-Cd - both fully vented and partially-recombinant types), and Li-ion stationary battery installations are discussed in this guide, written to serve as a bridge between the electrical designer and the heating, ventilation, and air-conditioning (HVAC) designer. Ventilation of stationary battery installations is critical to improving battery life while reducing the hazards associated with hydrogen production (hydrogen production is not a concern with Li-ion under normal operating conditions [it is under thermal runaway conditions]). This guide describes battery operating modes and the hazards associated with each. It provides the HVAC designer with the information to provide a cost effective ventilation solution.<br />\n \t\t\t\t<br />\n This guide discusses the ventilation and thermal management of stationary battery systems as applied to the following: -- Vented (flooded) lead-acid (VLA) -- Valve-regulated lead-acid (VRLA) -- Nickel-cadmium (Ni-Cd) -- Partially recombinant nickel-cadmium. -- Lithium ion (Li-ion) For each category, both the technology and the design of the battery are described in order to facilitate user understanding of the environmental issues associated with each type of technology. The scope of this document includes only stationary batteries under conditions of expected use. Multiple operating modes are identified. The ventilation practices described in this guide represent the "best practice" based on the information available at the time this document was developed. The user should evaluate these practices against their operating experience, operating conditions, number and size of battery systems, manufacturer's recommendations, resources, and needs in developing an environment that is conducive to safety and optimum operation of the equipment. These recommendations were developed without consideration of economics, availability of equipment and personnel, or relative importance of the application. Design of a ventilation system for a specific battery installation requires consideration of all issues, not just the technical issues considered in this document.<br />\n The purpose of this document is to provide heating, ventilation, and air conditioning (HVAC) and battery system designers and users with information and recommendations concerning the ventilation and thermal management of stationary battery installations """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE/ASHRAE Guide for the Ventilation and Thermal Management of Batteries for Stationary Applications" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95099 …} #channels: Doctrine\ORM\PersistentCollection {#95103 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95098 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95101 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95086 …} -apiLastModifiedAt: DateTime @1743289200 {#95114 : 2025-03-30 00:00:00.0 Europe/Paris (+01:00) } -lastUpdatedAt: DateTime @1739919600 {#95113 : 2025-02-19 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1669762800 {#95112 : 2022-11-30 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "1635" -bookCollection: "" -pageCount: 140 -documents: Doctrine\ORM\PersistentCollection {#95089 …} -favorites: Doctrine\ORM\PersistentCollection {#95084 …} } ] |
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IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications is to be used in conjunction with this document. Secondary (rechargeable) electro-chemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging are included in the category of lithium-based batteries for the purposes of this document. Lithium-ion, lithium-ion polymer, and lithium-sulfur batteries are examples of secondary lithium-based batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. A technology description, information on aging and failure modes, a discussion on safety issues, evaluation techniques, and regulatory issues are provided in this document. Sizing, installation, maintenance, and testing techniques are not covered, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n \t\t\t\t<br />\n This document provides guidance for an objective evaluation of lithium-based energy storage technologies by a potential user for any stationary application. This document is to be used in conjunction with IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications. For the purposes of this document, lithium-based batteries include those secondary (rechargeable) electrochemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging. Examples of secondary lithium-based batteries are lithium-ion, lithium-ion polymer, and lithium-sulfur batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. While this document does not cover lithium-based batteries used in mobile applications, the information provided is applicable to electric vehicle or similar batteries that are repurposed for use in stationary applications. This document also applies to batteries that are stationary when in operation but are intended to be relocated, for example, containerized or trailer-mounted systems. The outline of IEEE Std 1679-2020 is followed in this document, with tutorial information specific to lithium-based batteries provided as appropriate. Examples of tutorial information include technology descriptions, operating parameters, failure modes, safety information, battery architecture, and qualification and application considerations. This document does not cover sizing, installation, maintenance, and testing techniques, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n Lithium-based batteries have been used in various, non-stationary standby applications for many years, such as consumer electronics and military applications. They are now commonplace in stationary energy storage applications and are beginning to be more commonly used in stationary standby applications. and, as such, there is a need to provide appropriate information on safety and operating conditions related to these applications. End-users would benefit from having a guide to assist in evaluation of this technology for stationary applications.<br />\n Used with IEEE Std 1679-2020, this guide describes a format for the characterization of lithium-based battery technologies in terms of performance, service life, and safety attributes. 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Sizing, installation, maintenance, and testing techniques are not covered, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n \t\t\t\t<br />\n This document provides guidance for an objective evaluation of lithium-based energy storage technologies by a potential user for any stationary application. This document is to be used in conjunction with IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications. For the purposes of this document, lithium-based batteries include those secondary (rechargeable) electrochemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging. Examples of secondary lithium-based batteries are lithium-ion, lithium-ion polymer, and lithium-sulfur batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. While this document does not cover lithium-based batteries used in mobile applications, the information provided is applicable to electric vehicle or similar batteries that are repurposed for use in stationary applications. This document also applies to batteries that are stationary when in operation but are intended to be relocated, for example, containerized or trailer-mounted systems. The outline of IEEE Std 1679-2020 is followed in this document, with tutorial information specific to lithium-based batteries provided as appropriate. Examples of tutorial information include technology descriptions, operating parameters, failure modes, safety information, battery architecture, and qualification and application considerations. This document does not cover sizing, installation, maintenance, and testing techniques, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n Lithium-based batteries have been used in various, non-stationary standby applications for many years, such as consumer electronics and military applications. They are now commonplace in stationary energy storage applications and are beginning to be more commonly used in stationary standby applications. and, as such, there is a need to provide appropriate information on safety and operating conditions related to these applications. End-users would benefit from having a guide to assist in evaluation of this technology for stationary applications.<br />\n Used with IEEE Std 1679-2020, this guide describes a format for the characterization of lithium-based battery technologies in terms of performance, service life, and safety attributes. 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IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications is to be used in conjunction with this document. Secondary (rechargeable) electro-chemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging are included in the category of lithium-based batteries for the purposes of this document. Lithium-ion, lithium-ion polymer, and lithium-sulfur batteries are examples of secondary lithium-based batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. A technology description, information on aging and failure modes, a discussion on safety issues, evaluation techniques, and regulatory issues are provided in this document. Sizing, installation, maintenance, and testing techniques are not covered, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n \t\t\t\t<br />\n This document provides guidance for an objective evaluation of lithium-based energy storage technologies by a potential user for any stationary application. This document is to be used in conjunction with IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications. For the purposes of this document, lithium-based batteries include those secondary (rechargeable) electrochemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging. Examples of secondary lithium-based batteries are lithium-ion, lithium-ion polymer, and lithium-sulfur batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. While this document does not cover lithium-based batteries used in mobile applications, the information provided is applicable to electric vehicle or similar batteries that are repurposed for use in stationary applications. This document also applies to batteries that are stationary when in operation but are intended to be relocated, for example, containerized or trailer-mounted systems. The outline of IEEE Std 1679-2020 is followed in this document, with tutorial information specific to lithium-based batteries provided as appropriate. Examples of tutorial information include technology descriptions, operating parameters, failure modes, safety information, battery architecture, and qualification and application considerations. This document does not cover sizing, installation, maintenance, and testing techniques, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n Lithium-based batteries have been used in various, non-stationary standby applications for many years, such as consumer electronics and military applications. They are now commonplace in stationary energy storage applications and are beginning to be more commonly used in stationary standby applications. and, as such, there is a need to provide appropriate information on safety and operating conditions related to these applications. End-users would benefit from having a guide to assist in evaluation of this technology for stationary applications.<br />\n Used with IEEE Std 1679-2020, this guide describes a format for the characterization of lithium-based battery technologies in terms of performance, service life, and safety attributes. 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IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications is to be used in conjunction with this document. Secondary (rechargeable) electro-chemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging are included in the category of lithium-based batteries for the purposes of this document. Lithium-ion, lithium-ion polymer, and lithium-sulfur batteries are examples of secondary lithium-based batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. A technology description, information on aging and failure modes, a discussion on safety issues, evaluation techniques, and regulatory issues are provided in this document. Sizing, installation, maintenance, and testing techniques are not covered, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n \t\t\t\t<br />\n This document provides guidance for an objective evaluation of lithium-based energy storage technologies by a potential user for any stationary application. This document is to be used in conjunction with IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications. For the purposes of this document, lithium-based batteries include those secondary (rechargeable) electrochemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging. Examples of secondary lithium-based batteries are lithium-ion, lithium-ion polymer, and lithium-sulfur batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. While this document does not cover lithium-based batteries used in mobile applications, the information provided is applicable to electric vehicle or similar batteries that are repurposed for use in stationary applications. This document also applies to batteries that are stationary when in operation but are intended to be relocated, for example, containerized or trailer-mounted systems. The outline of IEEE Std 1679-2020 is followed in this document, with tutorial information specific to lithium-based batteries provided as appropriate. Examples of tutorial information include technology descriptions, operating parameters, failure modes, safety information, battery architecture, and qualification and application considerations. 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| Input props | [ "product" => App\Entity\Product\Product {#95149 #id: 13094 #code: "IEEE00011048" #attributes: Doctrine\ORM\PersistentCollection {#95166 …} #variants: Doctrine\ORM\PersistentCollection {#95168 …} #options: Doctrine\ORM\PersistentCollection {#95172 …} #associations: Doctrine\ORM\PersistentCollection {#95170 …} #createdAt: DateTime @1751040858 {#95144 : 2025-06-27 18:14:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754608642 {#95145 : 2025-08-08 01:17:22.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95156 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#95914 #locale: "en_US" #translatable: App\Entity\Product\Product {#95149} #id: 47385 #name: "IEEE 1679.1:2025" #slug: "ieee-1679-1-2025-ieee00011048-272488" #description: """ Revision Standard - Active - Draft.<br />\n Guidance for an objective evaluation of lithium-based energy storage technologies by a potential user for any stationary application is provided in this document. IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications is to be used in conjunction with this document. Secondary (rechargeable) electro-chemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging are included in the category of lithium-based batteries for the purposes of this document. Lithium-ion, lithium-ion polymer, and lithium-sulfur batteries are examples of secondary lithium-based batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. A technology description, information on aging and failure modes, a discussion on safety issues, evaluation techniques, and regulatory issues are provided in this document. Sizing, installation, maintenance, and testing techniques are not covered, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n \t\t\t\t<br />\n This document provides guidance for an objective evaluation of lithium-based energy storage technologies by a potential user for any stationary application. This document is to be used in conjunction with IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications. For the purposes of this document, lithium-based batteries include those secondary (rechargeable) electrochemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging. Examples of secondary lithium-based batteries are lithium-ion, lithium-ion polymer, and lithium-sulfur batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. While this document does not cover lithium-based batteries used in mobile applications, the information provided is applicable to electric vehicle or similar batteries that are repurposed for use in stationary applications. This document also applies to batteries that are stationary when in operation but are intended to be relocated, for example, containerized or trailer-mounted systems. The outline of IEEE Std 1679-2020 is followed in this document, with tutorial information specific to lithium-based batteries provided as appropriate. Examples of tutorial information include technology descriptions, operating parameters, failure modes, safety information, battery architecture, and qualification and application considerations. This document does not cover sizing, installation, maintenance, and testing techniques, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n Lithium-based batteries have been used in various, non-stationary standby applications for many years, such as consumer electronics and military applications. They are now commonplace in stationary energy storage applications and are beginning to be more commonly used in stationary standby applications. and, as such, there is a need to provide appropriate information on safety and operating conditions related to these applications. End-users would benefit from having a guide to assist in evaluation of this technology for stationary applications.<br />\n Used with IEEE Std 1679-2020, this guide describes a format for the characterization of lithium-based battery technologies in terms of performance, service life, and safety attributes. This format provides a framework for developers and manufacturers to describe their products. The resulting information will assist users, integrators, and servicing organizations in evaluating the possible use of these batteries in stationary applications and to provide objective criteria for comparative evaluation. 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IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications is to be used in conjunction with this document. Secondary (rechargeable) electro-chemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging are included in the category of lithium-based batteries for the purposes of this document. Lithium-ion, lithium-ion polymer, and lithium-sulfur batteries are examples of secondary lithium-based batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. A technology description, information on aging and failure modes, a discussion on safety issues, evaluation techniques, and regulatory issues are provided in this document. Sizing, installation, maintenance, and testing techniques are not covered, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n \t\t\t\t<br />\n This document provides guidance for an objective evaluation of lithium-based energy storage technologies by a potential user for any stationary application. This document is to be used in conjunction with IEEE Std 1679-2020, IEEE Recommended Practice for the Characterization and Evaluation of Energy Storage Technologies in Stationary Applications. For the purposes of this document, lithium-based batteries include those secondary (rechargeable) electrochemistries with lithium ions as the active species exchanged between the electrodes during charging and discharging. Examples of secondary lithium-based batteries are lithium-ion, lithium-ion polymer, and lithium-sulfur batteries. Emerging solid-state lithium technologies are also discussed. Primary (non-rechargeable) lithium batteries are beyond the scope of this document. While this document does not cover lithium-based batteries used in mobile applications, the information provided is applicable to electric vehicle or similar batteries that are repurposed for use in stationary applications. This document also applies to batteries that are stationary when in operation but are intended to be relocated, for example, containerized or trailer-mounted systems. The outline of IEEE Std 1679-2020 is followed in this document, with tutorial information specific to lithium-based batteries provided as appropriate. Examples of tutorial information include technology descriptions, operating parameters, failure modes, safety information, battery architecture, and qualification and application considerations. This document does not cover sizing, installation, maintenance, and testing techniques, except insofar as they may influence the evaluation of a lithium-based battery for its intended application.<br />\n Lithium-based batteries have been used in various, non-stationary standby applications for many years, such as consumer electronics and military applications. They are now commonplace in stationary energy storage applications and are beginning to be more commonly used in stationary standby applications. and, as such, there is a need to provide appropriate information on safety and operating conditions related to these applications. End-users would benefit from having a guide to assist in evaluation of this technology for stationary applications.<br />\n Used with IEEE Std 1679-2020, this guide describes a format for the characterization of lithium-based battery technologies in terms of performance, service life, and safety attributes. 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| Component | App\Twig\Components\ProductMostRecent {#96205 +product: App\Entity\Product\Product {#95179 #id: 13166 #code: "IEEE00010617" #attributes: Doctrine\ORM\PersistentCollection {#95196 …} #variants: Doctrine\ORM\PersistentCollection {#95198 …} #options: Doctrine\ORM\PersistentCollection {#95202 …} #associations: Doctrine\ORM\PersistentCollection {#95200 …} #createdAt: DateTime @1751040918 {#95174 : 2025-06-27 18:15:18.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754607611 {#95175 : 2025-08-08 01:00:11.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#95186 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#96122 #locale: "en_US" #translatable: App\Entity\Product\Product {#95179} #id: 47673 #name: "IEEE 2993:2025" #slug: "ieee-2993-2025-ieee00010617-496240" #description: """ New IEEE Standard - Active - Draft.<br />\n The selection and repurposing (including 1 design, operation and maintenance) of second-life electric vehicle batteries in energy storage systems with voltage levels of 10 kV and below is described in this recommended practice. Various technical indexes of batteries and equipment are assessed in different stages of engineering to evaluate the system's efficiency, safety, and economic aspects.<br />\n \t\t\t\t<br />\n This recommended practice describes the selection and repurposing (including design, operation and maintenance) of second-life electric vehicle batteries in energy storage systems with voltage levels of 10kV and below. Various technical indexes of batteries and equipment are assessed in different stages of engineering to evaluate the system efficiency, safety and economic aspects.<br />\n This recommended practice identifies the technical requirements for second-life electric vehicle batteries, including original design and data interaction in their service life in cars, to provide battery status assessment indicators and methods in the repurposing, system integration and technical essentials of key equipment, management requirements for operation, maintenance and monitoring, and overall technical consideration for system safety in an energy storage system. Availability of this information is intended to improve safety and promote efficient and economic applications of the energy storage technology using second-life electric vehicle batteries in scenarios such as backup power supply, peak-load shifting and stabilization of fluctuations in low-voltage power distribution systems. """ #metaKeywords: null #metaDescription: null #shortDescription: "Draft Recommended Practices for Energy Storage System Design using Second-life Electric Vehicle Batteries" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#95188 …} #channels: Doctrine\ORM\PersistentCollection {#95194 …} #mainTaxon: App\Entity\Taxonomy\Taxon {#8838 …} #reviews: Doctrine\ORM\PersistentCollection {#95190 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#95192 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#95141 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#95180 …} -apiLastModifiedAt: DateTime @1754517600 {#95176 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1753048800 {#95177 : 2025-07-21 00:00:00.0 Europe/Paris (+02:00) } -author: "" -publishedAt: DateTime @1749160800 {#95178 : 2025-06-06 00:00:00.0 Europe/Paris (+02:00) } -releasedAt: null -confirmedAt: null -canceledAt: null -edition: null -coreDocument: "2993" -bookCollection: "" -pageCount: 31 -documents: Doctrine\ORM\PersistentCollection {#95182 …} -favorites: Doctrine\ORM\PersistentCollection {#95184 …} } +label: "Most Recent" +icon: "check-xs" -mostRecentAttributeCode: "most_recent" -localeContext: Sylius\Component\Locale\Context\CompositeLocaleContext {#1831 …} } |
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