{"id":19023,"date":"2025-10-17T14:24:26","date_gmt":"2025-10-17T12:24:26","guid":{"rendered":"https:\/\/www.darda.de\/carbon-footprint"},"modified":"2026-03-30T13:16:02","modified_gmt":"2026-03-30T11:16:02","slug":"carbon-footprint","status":"publish","type":"page","link":"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint","title":{"rendered":"Carbon footprint"},"content":{"rendered":"<div class=\"wissen-inhaltsbereich\">\n<p>The carbon footprint describes the greenhouse-gas impact of processes, products, and projects-across the construction and deconstruction sectors from manufacturing to end of use. In concrete demolition, specialized deconstruction, rock demolition, and natural stone extraction, energy use, transport, tool wear, material separation, and recycling significantly influence the climate impact. Tools such as <a href=\"https:\/\/www.darda.de\/en\/product-overview\/concrete-crushers\">concrete crushers<\/a>, <a href=\"https:\/\/www.darda.de\/en\/product-overview\/hydraulic-rock-and-concrete-splitters\">rock and concrete splitters<\/a>, hydraulic power packs, combination shears, multi cutters, steel shears, concrete crushers, stone splitting cylinders, and tank cutters from Darda GmbH are frequently used in these applications. Proper selection and the right workflow can markedly improve the carbon footprint of construction sites without compromising safety, quality, or schedule. Transparent measurement and documentation further enable verifiable tendering and compliance with reporting requirements.<\/p>\n<h2>Definition: What is meant by the carbon footprint?<\/h2>\n<p>The carbon footprint (also greenhouse-gas balance, CO\u2082 footprint, or climate balance) is the sum of all relevant greenhouse-gas emissions of a system, expressed in CO\u2082 equivalents (CO\u2082e). It includes direct emissions from the combustion of fuels and indirect emissions from purchased energy, upstream products, transport, and disposal. In practice, system boundaries are defined (e.g., from raw material extraction to disposal) and a functional unit is specified (e.g., <em>1 m\u00b3 of reinforced concrete deconstructed<\/em> or <em>1 t of natural stone extracted<\/em>). The result is a traceable indicator that supports decisions-for example, when choosing between different deconstruction methods or when sizing hydraulic power packs. In line with established standards such as ISO 14067 and EN 15804 for construction products, results are typically reported as Global Warming Potential (GWP) per functional unit.<\/p>\n<ul>\n<li><strong>System boundaries:<\/strong> From cradle-to-gate, gate-to-gate, or cradle-to-grave depending on the question at hand.<\/li>\n<li><strong>Emission scopes:<\/strong> Scope 1 (direct), Scope 2 (purchased energy), and relevant Scope 3 (supply chain and end of life) for comprehensive accounting.<\/li>\n<li><strong>Functional unit:<\/strong> Clearly defined output enables fair comparison across methods and tools.<\/li>\n<\/ul>\n<h2>Methodology of the carbon footprint in deconstruction and natural stone extraction<\/h2>\n<p>The carbon footprint in demolition, specialized deconstruction, strip-out, cutting, as well as rock and tunnel construction follows life-cycle logic: manufacturing (materials, fabrication), provision (transport, storage), use (energy, wear parts, maintenance), end of life or recycling. Key metrics include energy consumption (kWh, liters, kg), material flows (t), transport distances (km), and emission factors (e.g., kg CO\u2082e per kWh of electricity or per liter of diesel). Typical system boundaries range from <em>cradle-to-gate<\/em> (to the factory gate) and <em>gate-to-gate<\/em> (site operation) to <em>cradle-to-grave<\/em> (including disposal). Environmental Product Declarations serve as data sources for construction products; for site processes, measurements and robust experience are central. The functional unit is decisive: whether concrete crushers or stone and concrete splitters-comparisons should always be based on the same output (e.g., identical volume or tonnage). This enables fair evaluation of methods and reveals optimization potential.<\/p>\n<ul>\n<li><strong>Data quality:<\/strong> Prefer primary measurements on site over generic factors; ensure temporal and geographic representativeness.<\/li>\n<li><strong>Utilization and load profiles:<\/strong> Emissions per unit depend on duty cycles, idling shares, and peak loads of hydraulic power packs.<\/li>\n<li><strong>Allocation and cut-offs:<\/strong> Define handling of shared equipment and minor inputs transparently to maintain comparability.<\/li>\n<\/ul>\n<h2>Influencing factors on the carbon footprint of site processes<\/h2>\n<p>The climate impact of a deconstruction or extraction process is shaped by several key levers. Addressing these specifically often cuts emissions significantly-frequently without additional cost and with positive side effects on schedule, noise, and dust. <em>Well-planned sequences frequently reduce both downtime and transport masses.<\/em><\/p>\n<h3>Energy source and efficiency<\/h3>\n<p><a href=\"https:\/\/www.darda.de\/en\/product-overview\/hydraulic-power-units\">Hydraulic power packs<\/a> account for the largest share of energy consumption. Electrically driven power-pack solutions can-depending on the electricity mix-show lower emissions per kWh than diesel-powered units. Further levers include demand-based pressure and flow control, load management, avoidance of idling, and maintenance (filtration, oil condition, tightness). Where grid electricity features high renewable shares or is buffered via on-site storage, specific emissions decline further. In short: <strong>Every idling minute avoided saves CO\u2082<\/strong>.<\/p>\n<h3>Choice of method and process chain<\/h3>\n<p>The sequence of separating, splitting, crushing, and sorting influences energy demand and recycling rates. Selective deconstruction with concrete crushers or combination shears enables early material separation (e.g., removing reinforcing steel), which reduces transport masses and improves the quality of recycled material. Cleaner material streams also reduce downstream processing steps, cutting run times and wear.<\/p>\n<h3>Tool selection and wear<\/h3>\n<p>Correct sizing (e.g., jaw opening, splitting force), hardened cutting edges, and an appropriate hydraulic setup avoid inefficient cycles and extend service life. The <em>ecological backpack<\/em> of new wear parts (steel production, heat treatment) should be \u201clifted\u201d as rarely as possible through optimal utilization. Regular inspection of contact surfaces and timely regrinding or seal replacement preserve performance and lower energy per stroke.<\/p>\n<h3>Transport and logistics<\/h3>\n<p>Short travel distances, high utilization, and a smart sequence of sites reduce fuel demand. On-site downsizing with concrete crushers minimizes the number of heavy haul-offs. Additional levers include optimized routing, backhauls, appropriate payload management, and correct tire pressure on carriers and trucks.<\/p>\n<h3>Recycling and material recovery<\/h3>\n<p>Clean separation of concrete, reinforcing steel, cables, lines, and special substances facilitates reintroduction into secondary cycles. <strong>Every tonne of recovered reinforcement replaces primary steel<\/strong>-with a noticeable effect on the overall balance. Simple aids such as on-site magnets or sorting grids further increase recovery quality.<\/p>\n<h2>Equipment-specific view: concrete crushers and stone and concrete splitters<\/h2>\n<p>Concrete crushers and stone and concrete splitters are central levers for a better carbon footprint in many scenarios. The two approaches address different physical principles and complement each other in practice. Choosing the appropriate method depends on geometry, reinforcement density, access conditions, and permissible vibration or noise levels.<\/p>\n<h3>Concrete crushers: crushing and separating in one step<\/h3>\n<ul>\n<li><strong>Selective deconstruction:<\/strong> Local breakup of reinforced concrete, exposing reinforcement, direct detachment. Reduces rework with additional attachments.<\/li>\n<li><strong>Transport advantage:<\/strong> Crushed concrete requires fewer truck trips; steel can be hauled separately.<\/li>\n<li><strong>Energy input:<\/strong> Continuous, controlled force application-often more efficient than prolonged impact mechanisms with unfavorable geometry.<\/li>\n<li><strong>Recycling-ready fragmentation:<\/strong> Adjustable grain size improves downstream screening and reuse options.<\/li>\n<li><strong>Noise profile:<\/strong> Typically lower peak sound pressure than impact-intensive methods in comparable use cases.<\/li>\n<\/ul>\n<h3>Stone and concrete splitters: crack propagation instead of material removal<\/h3>\n<ul>\n<li><strong>Low peripheral impact:<\/strong> In rock demolition, tunnel construction, and sensitive environments, only minimal vibrations occur-often decisive for permits and process stability.<\/li>\n<li><strong>Targeted geometry:<\/strong> Splitting boreholes and controlled crack patterns enable large blocks with little energy, which are then further processed with concrete crushers or multi cutters.<\/li>\n<li><strong>Indirect effects:<\/strong> Fewer secondary damages mean fewer repairs and extra work-this also positively affects the carbon footprint.<\/li>\n<li><strong>Non-sparking approach:<\/strong> Beneficial in confined spaces and near sensitive media where hot work is restricted.<\/li>\n<\/ul>\n<h2>Application areas and their climate-relevant specifics<\/h2>\n<h3>Concrete demolition and specialized deconstruction<\/h3>\n<p>Concrete crushers accelerate selective deconstruction and increase steel recovery. In combination with hydraulic power packs featuring demand-oriented control, energy consumption and emissions per tonne of deconstructed material decrease. Coordinated attachment changes and staged separation further stabilize cycle times and reduce idle fractions.<\/p>\n<h3>Strip-out and cutting<\/h3>\n<p>When removing lines, beams, and installations, multi cutters, combination shears, and steel shears support clean sorting. Tank cutters can outperform hot cutting methods when they avoid sparks and fuel gases-often with advantages for occupational safety and the carbon footprint. Pre-marking cut lines, setting safe supports, and bundling material classes reduce rework and transport volume.<\/p>\n<h3>Rock demolition and tunnel construction<\/h3>\n<p>Stone and concrete splitters as well as stone splitting cylinders enable low-vibration work. Pinpoint crack guidance reduces energy demand and lowers rework in the fit-out-shortening machine run times and transports. Controlled sequencing of boreholes and pressure ramps enhances both stability and energy efficiency.<\/p>\n<h3>Natural stone extraction<\/h3>\n<p>Controlled splitting produces high-quality blocks with minimal waste. The higher the yield, the better the carbon footprint per tonne of saleable material. Strategic orientation of cracks relative to natural bedding further boosts output and reduces downstream cutting effort.<\/p>\n<h3>Special applications<\/h3>\n<p>With sensitive infrastructure or in city centers, low-emission drives of the hydraulic power packs, low vibrations, and less dust support the permitting environment. Scheduled shifts instead of night work can additionally reduce logistics emissions. Defined access routes and staging areas cut shunting movements and waiting times.<\/p>\n<h2>Lifecycle of the tools: manufacturing, use, maintenance, end of life<\/h2>\n<p>Tools themselves carry a CO\u2082 backpack from steel, machining, and heat treatment. Durability, regrinding, component overhaul, and recycling of steels reduce lifecycle emissions per operating hour. In use, correct contact pressure, suitable hydraulic pressures, and timely maintenance (e.g., seal replacement) lower energy demand. At end of life, high-alloy steels can be returned to the materials cycle. Where feasible, remanufacturing of cores and availability of spare parts extend service life and reduce embodied carbon.<\/p>\n<h2>Data sources and footprint accounting in practice<\/h2>\n<p>For a robust carbon footprint, project-specific consumption data are collected and combined with recognized emission factors. Typical data foundations are electricity and fuel consumption, operating hours of hydraulic power packs, replacement intervals of tools, transport masses and distances, as well as weigh tickets and recycling evidence. Environmental Product Declarations for building materials provide GWP values per tonne or m\u00b3. Clear assumptions on electricity mix, utilization, and yield are important-along with transparent documentation.<\/p>\n<ul>\n<li><strong>Emission factors:<\/strong> EPDs per EN 15804, national electricity grid factors, and well-to-tank plus combustion values for fuels.<\/li>\n<li><strong>Measurement:<\/strong> Calibrated meters for electricity and fuel, logged operating hours, and mass balances via certified scales.<\/li>\n<li><strong>Verification:<\/strong> Documented methodologies and sensitivity checks for key parameters such as electricity mix and transport distances.<\/li>\n<\/ul>\n<h2>Practical measures to reduce the carbon footprint<\/h2>\n<ol>\n<li><strong>Optimize the drive:<\/strong> Use electric hydraulic power packs where available; minimize idling; adjust pressure\/flow to the task.<\/li>\n<li><strong>Plan the process chain:<\/strong> Choose a sequence so that concrete crushers separate early and reduce mass; split where vibrations are undesirable.<\/li>\n<li><strong>Standardize maintenance:<\/strong> Clean hydraulic oil, tight lines, intact cutting edges and teeth-less energy per work stroke.<\/li>\n<li><strong>Save trips:<\/strong> Downsize and sort on site; bundle transports; avoid empty runs.<\/li>\n<li><strong>Increase the recycling rate:<\/strong> Extract steel cleanly, separate concrete; document material streams.<\/li>\n<li><strong>Dimension tools appropriately:<\/strong> Match jaw opening, splitting force, and geometry to component thickness to avoid inefficient strokes.<\/li>\n<li><strong>Train operators and monitor KPIs:<\/strong> Cycle time, idling share, and energy per tonne guide continuous improvement.<\/li>\n<li><strong>Measure and verify:<\/strong> Use simple logs or data loggers to track consumption and close the loop to planning assumptions.<\/li>\n<\/ol>\n<h2>Illustrative comparison of two deconstruction options<\/h2>\n<p>Initial situation: deconstruction of 1 m\u00b3 of reinforced concrete (approx. 2.4 t). Variant A uses an impact-intensive method and a diesel-powered power pack; Variant B combines stone and concrete splitters for pre-separation with concrete crushers for downsizing, powered by an electric hydraulic power pack. Under typical assumptions, practice often shows the following tendencies: Variant B requires less energy per tonne, generates fewer secondary damages, and increases steel recovery. With a higher recycling rate, primary raw materials are displaced, which can reduce the overall accounted climate impact. Specific values depend on site logistics, electricity mix, component geometry, and operating practice; sensitivity checks should vary these inputs to test robustness.<\/p>\n<h2>Safety, dust, and noise: indirect climate effects<\/h2>\n<p>Dust and noise reduction may not seem climate-relevant at first. Indirectly, however, they affect the carbon footprint: where work is quieter and less dusty, longer working windows are possible, decoupling processes and reducing idle time. Splitting techniques and the targeted use of concrete crushers also reduce consequential damage to adjacent components-less rework means less energy and fewer transports. More predictable schedules lower standby times for equipment and logistics, stabilizing emissions per functional unit.<\/p>\n<\/div>\n","protected":false},"excerpt":{"rendered":"<p>The carbon footprint describes the greenhouse-gas impact of processes, products, and projects-across the construction and deconstruction sectors from manufacturing to end of use. In concrete demolition, specialized deconstruction, rock demolition, and natural stone extraction, energy use, transport, tool wear, material separation, and recycling significantly influence the climate impact. Tools such <a class=\"moretag\" href=\"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint\">read more&#8230;<\/a><\/p>\n","protected":false},"author":9,"featured_media":0,"parent":14846,"menu_order":0,"comment_status":"open","ping_status":"open","template":"tmpl\/template-wissen.php","meta":{"_acf_changed":false,"footnotes":""},"class_list":["post-19023","page","type-page","status-publish","hentry"],"acf":[],"yoast_head":"<!-- This site is optimized with the Yoast SEO plugin v27.4 - https:\/\/yoast.com\/product\/yoast-seo-wordpress\/ -->\n<title>Carbon Footprint in Construction &amp; Demolition<\/title>\n<meta name=\"description\" content=\"Reduce the carbon footprint in demolition, deconstruction &amp; extraction \u2713 with smart energy use, logistics &amp; recycling.\" \/>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"Carbon Footprint in Construction &amp; Demolition\" \/>\n<meta property=\"og:description\" content=\"Reduce the carbon footprint in demolition, deconstruction &amp; extraction \u2713 with smart energy use, logistics &amp; recycling.\" \/>\n<meta property=\"og:url\" content=\"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint\" \/>\n<meta property=\"og:site_name\" content=\"Darda GmbH\" \/>\n<meta property=\"article:publisher\" content=\"https:\/\/www.facebook.com\/DardaDemolition\" \/>\n<meta property=\"article:modified_time\" content=\"2026-03-30T11:16:02+00:00\" \/>\n<meta name=\"twitter:card\" content=\"summary_large_image\" \/>\n<meta name=\"twitter:label1\" content=\"Est. reading time\" \/>\n\t<meta name=\"twitter:data1\" content=\"9 minutes\" \/>\n<script type=\"application\/ld+json\" class=\"yoast-schema-graph\">{\"@context\":\"https:\\\/\\\/schema.org\",\"@graph\":[{\"@type\":\"WebPage\",\"@id\":\"https:\\\/\\\/www.darda.de\\\/en\\\/knowledge\\\/carbon-footprint\",\"url\":\"https:\\\/\\\/www.darda.de\\\/en\\\/knowledge\\\/carbon-footprint\",\"name\":\"Carbon Footprint in Construction & Demolition\",\"isPartOf\":{\"@id\":\"https:\\\/\\\/www.darda.de\\\/en#website\"},\"datePublished\":\"2025-10-17T12:24:26+00:00\",\"dateModified\":\"2026-03-30T11:16:02+00:00\",\"description\":\"Reduce the carbon footprint in demolition, deconstruction & extraction \u2713 with smart energy use, logistics & recycling.\",\"breadcrumb\":{\"@id\":\"https:\\\/\\\/www.darda.de\\\/en\\\/knowledge\\\/carbon-footprint#breadcrumb\"},\"inLanguage\":\"en-US\",\"potentialAction\":[{\"@type\":\"ReadAction\",\"target\":[\"https:\\\/\\\/www.darda.de\\\/en\\\/knowledge\\\/carbon-footprint\"]}]},{\"@type\":\"BreadcrumbList\",\"@id\":\"https:\\\/\\\/www.darda.de\\\/en\\\/knowledge\\\/carbon-footprint#breadcrumb\",\"itemListElement\":[{\"@type\":\"ListItem\",\"position\":1,\"name\":\"Home\",\"item\":\"https:\\\/\\\/www.darda.de\\\/en\"},{\"@type\":\"ListItem\",\"position\":2,\"name\":\"Knowledge\",\"item\":\"https:\\\/\\\/www.darda.de\\\/en\\\/knowledge\"},{\"@type\":\"ListItem\",\"position\":3,\"name\":\"Carbon footprint\"}]},{\"@type\":\"WebSite\",\"@id\":\"https:\\\/\\\/www.darda.de\\\/en#website\",\"url\":\"https:\\\/\\\/www.darda.de\\\/en\",\"name\":\"Darda GmbH\",\"description\":\"\",\"publisher\":{\"@id\":\"https:\\\/\\\/www.darda.de\\\/en#organization\"},\"alternateName\":\"Abbruchwerkzeuge\",\"potentialAction\":[{\"@type\":\"SearchAction\",\"target\":{\"@type\":\"EntryPoint\",\"urlTemplate\":\"https:\\\/\\\/www.darda.de\\\/en?s={search_term_string}\"},\"query-input\":{\"@type\":\"PropertyValueSpecification\",\"valueRequired\":true,\"valueName\":\"search_term_string\"}}],\"inLanguage\":\"en-US\"},{\"@type\":\"Organization\",\"@id\":\"https:\\\/\\\/www.darda.de\\\/en#organization\",\"name\":\"Darda GmbH\",\"url\":\"https:\\\/\\\/www.darda.de\\\/en\",\"logo\":{\"@type\":\"ImageObject\",\"inLanguage\":\"en-US\",\"@id\":\"https:\\\/\\\/www.darda.de\\\/en#\\\/schema\\\/logo\\\/image\\\/\",\"url\":\"https:\\\/\\\/www.darda.de\\\/wp-content\\\/uploads\\\/2017\\\/09\\\/android-icon-192x192-1.png\",\"contentUrl\":\"https:\\\/\\\/www.darda.de\\\/wp-content\\\/uploads\\\/2017\\\/09\\\/android-icon-192x192-1.png\",\"width\":192,\"height\":192,\"caption\":\"Darda GmbH\"},\"image\":{\"@id\":\"https:\\\/\\\/www.darda.de\\\/en#\\\/schema\\\/logo\\\/image\\\/\"},\"sameAs\":[\"https:\\\/\\\/www.facebook.com\\\/DardaDemolition\",\"https:\\\/\\\/www.instagram.com\\\/darda_demolition\",\"https:\\\/\\\/www.youtube.com\\\/user\\\/DardaGmbH\",\"https:\\\/\\\/www.xing.com\\\/pages\\\/darda-gmbh\",\"https:\\\/\\\/de.linkedin.com\\\/company\\\/darda-gmbh\"]}]}<\/script>\n<!-- \/ Yoast SEO plugin. -->","yoast_head_json":{"title":"Carbon Footprint in Construction & Demolition","description":"Reduce the carbon footprint in demolition, deconstruction & extraction \u2713 with smart energy use, logistics & recycling.","robots":{"index":"index","follow":"follow","max-snippet":"max-snippet:-1","max-image-preview":"max-image-preview:large","max-video-preview":"max-video-preview:-1"},"canonical":"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint","og_locale":"en_US","og_type":"article","og_title":"Carbon Footprint in Construction & Demolition","og_description":"Reduce the carbon footprint in demolition, deconstruction & extraction \u2713 with smart energy use, logistics & recycling.","og_url":"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint","og_site_name":"Darda GmbH","article_publisher":"https:\/\/www.facebook.com\/DardaDemolition","article_modified_time":"2026-03-30T11:16:02+00:00","twitter_card":"summary_large_image","twitter_misc":{"Est. reading time":"9 minutes"},"schema":{"@context":"https:\/\/schema.org","@graph":[{"@type":"WebPage","@id":"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint","url":"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint","name":"Carbon Footprint in Construction & Demolition","isPartOf":{"@id":"https:\/\/www.darda.de\/en#website"},"datePublished":"2025-10-17T12:24:26+00:00","dateModified":"2026-03-30T11:16:02+00:00","description":"Reduce the carbon footprint in demolition, deconstruction & extraction \u2713 with smart energy use, logistics & recycling.","breadcrumb":{"@id":"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint#breadcrumb"},"inLanguage":"en-US","potentialAction":[{"@type":"ReadAction","target":["https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint"]}]},{"@type":"BreadcrumbList","@id":"https:\/\/www.darda.de\/en\/knowledge\/carbon-footprint#breadcrumb","itemListElement":[{"@type":"ListItem","position":1,"name":"Home","item":"https:\/\/www.darda.de\/en"},{"@type":"ListItem","position":2,"name":"Knowledge","item":"https:\/\/www.darda.de\/en\/knowledge"},{"@type":"ListItem","position":3,"name":"Carbon footprint"}]},{"@type":"WebSite","@id":"https:\/\/www.darda.de\/en#website","url":"https:\/\/www.darda.de\/en","name":"Darda GmbH","description":"","publisher":{"@id":"https:\/\/www.darda.de\/en#organization"},"alternateName":"Abbruchwerkzeuge","potentialAction":[{"@type":"SearchAction","target":{"@type":"EntryPoint","urlTemplate":"https:\/\/www.darda.de\/en?s={search_term_string}"},"query-input":{"@type":"PropertyValueSpecification","valueRequired":true,"valueName":"search_term_string"}}],"inLanguage":"en-US"},{"@type":"Organization","@id":"https:\/\/www.darda.de\/en#organization","name":"Darda GmbH","url":"https:\/\/www.darda.de\/en","logo":{"@type":"ImageObject","inLanguage":"en-US","@id":"https:\/\/www.darda.de\/en#\/schema\/logo\/image\/","url":"https:\/\/www.darda.de\/wp-content\/uploads\/2017\/09\/android-icon-192x192-1.png","contentUrl":"https:\/\/www.darda.de\/wp-content\/uploads\/2017\/09\/android-icon-192x192-1.png","width":192,"height":192,"caption":"Darda GmbH"},"image":{"@id":"https:\/\/www.darda.de\/en#\/schema\/logo\/image\/"},"sameAs":["https:\/\/www.facebook.com\/DardaDemolition","https:\/\/www.instagram.com\/darda_demolition","https:\/\/www.youtube.com\/user\/DardaGmbH","https:\/\/www.xing.com\/pages\/darda-gmbh","https:\/\/de.linkedin.com\/company\/darda-gmbh"]}]}},"_links":{"self":[{"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/pages\/19023","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/users\/9"}],"replies":[{"embeddable":true,"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/comments?post=19023"}],"version-history":[{"count":1,"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/pages\/19023\/revisions"}],"predecessor-version":[{"id":25807,"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/pages\/19023\/revisions\/25807"}],"up":[{"embeddable":true,"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/pages\/14846"}],"wp:attachment":[{"href":"https:\/\/www.darda.de\/en\/wp-json\/wp\/v2\/media?parent=19023"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}