Energy renovation of a warehouse building (Q3935261): Difference between revisions
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(Removed claim: summary (P836): The warehouse is currently functional, but its degraded condition, doors and windows, lighting systems and heating are outdated. The masonry material is B30 block brick, the slab is made of reinforced concrete panels without thermal insulation, the doors and windows are steel-structured with a layer of glazing. The existing industrial gates are not thermally insulated, and on the floor there are lighting strips along a steel structure, which a...) |
(Changed an Item: Adding English translations) |
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The warehouse is currently functional, but its degraded condition, doors and windows, lighting systems and heating are outdated. The masonry material is B30 block brick, the slab is made of reinforced concrete panels without thermal insulation, the doors and windows are steel-structured with a layer of glazing. The existing industrial gates are not thermally insulated, and on the floor there are lighting strips along a steel structure, which are unfavourable from a heat-technical point of view. The heating system of the building can be solved by means of an outdated and uneconomically operated oil boiler with ribbed radiator heat take-offs, cooling by an outdated compressor air cooler. Lighting is provided by traditional neon tube luminaires. Following the dismantling of uninsulated facade doors and industrial gates with steel structure, a new plastic door and window with a heat transfer factor in accordance with the regulations will be installed and a new sectional industrial gate will be installed. After dismantling the existing steel overlights along the line and removing the slab breakthroughs, we create point-like overlights, thereby reducing the amount of cooling surfaces, thereby improving the heat balance. On the facade we produce a 15 cm thick polystyrene thermal insulation system, the insulation of the flat roof is solved together with 25 cm thick polystyrene boards, PVC waterproofing and the necessary tinting, thus reducing the energy demand for heating and cooling. The front roof shielding structure running through the southwest facade was designed to reduce the solar effect of summer warming. After dismantling the elements of the current outdated, inefficient heating and cooling system, a thermo-entillator system will be installed with the installation of an air-to-water heat pump with a capacity of 44.5 kW, thus serving the heating and cooling needs. The electrical energy required for the operation of the system is provided by placing a 23.5 kW solar panel on the flat roof, making the operation of the system even more economical. The wiring of existing lighting circuits is outdated, so they need to be replaced with copper wires. As the current illumination values are far below the requirements, a new lamp layout is needed, so the entire lighting system will be rebuilt according to the current standard (new protective tubes, copper wires, switches, modern energy-saving luminaires) and a new distribution cabinet is made. The activities listed together are complex to improve the energy classification to an acceptable level and thus to reduce CO2 emissions significantly. (English) | |||||||||||||||
| Property / summary: The warehouse is currently functional, but its degraded condition, doors and windows, lighting systems and heating are outdated. The masonry material is B30 block brick, the slab is made of reinforced concrete panels without thermal insulation, the doors and windows are steel-structured with a layer of glazing. The existing industrial gates are not thermally insulated, and on the floor there are lighting strips along a steel structure, which are unfavourable from a heat-technical point of view. The heating system of the building can be solved by means of an outdated and uneconomically operated oil boiler with ribbed radiator heat take-offs, cooling by an outdated compressor air cooler. Lighting is provided by traditional neon tube luminaires. Following the dismantling of uninsulated facade doors and industrial gates with steel structure, a new plastic door and window with a heat transfer factor in accordance with the regulations will be installed and a new sectional industrial gate will be installed. After dismantling the existing steel overlights along the line and removing the slab breakthroughs, we create point-like overlights, thereby reducing the amount of cooling surfaces, thereby improving the heat balance. On the facade we produce a 15 cm thick polystyrene thermal insulation system, the insulation of the flat roof is solved together with 25 cm thick polystyrene boards, PVC waterproofing and the necessary tinting, thus reducing the energy demand for heating and cooling. The front roof shielding structure running through the southwest facade was designed to reduce the solar effect of summer warming. After dismantling the elements of the current outdated, inefficient heating and cooling system, a thermo-entillator system will be installed with the installation of an air-to-water heat pump with a capacity of 44.5 kW, thus serving the heating and cooling needs. The electrical energy required for the operation of the system is provided by placing a 23.5 kW solar panel on the flat roof, making the operation of the system even more economical. The wiring of existing lighting circuits is outdated, so they need to be replaced with copper wires. As the current illumination values are far below the requirements, a new lamp layout is needed, so the entire lighting system will be rebuilt according to the current standard (new protective tubes, copper wires, switches, modern energy-saving luminaires) and a new distribution cabinet is made. The activities listed together are complex to improve the energy classification to an acceptable level and thus to reduce CO2 emissions significantly. (English) / rank | |||||||||||||||
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| Property / summary: The warehouse is currently functional, but its degraded condition, doors and windows, lighting systems and heating are outdated. The masonry material is B30 block brick, the slab is made of reinforced concrete panels without thermal insulation, the doors and windows are steel-structured with a layer of glazing. The existing industrial gates are not thermally insulated, and on the floor there are lighting strips along a steel structure, which are unfavourable from a heat-technical point of view. The heating system of the building can be solved by means of an outdated and uneconomically operated oil boiler with ribbed radiator heat take-offs, cooling by an outdated compressor air cooler. Lighting is provided by traditional neon tube luminaires. Following the dismantling of uninsulated facade doors and industrial gates with steel structure, a new plastic door and window with a heat transfer factor in accordance with the regulations will be installed and a new sectional industrial gate will be installed. After dismantling the existing steel overlights along the line and removing the slab breakthroughs, we create point-like overlights, thereby reducing the amount of cooling surfaces, thereby improving the heat balance. On the facade we produce a 15 cm thick polystyrene thermal insulation system, the insulation of the flat roof is solved together with 25 cm thick polystyrene boards, PVC waterproofing and the necessary tinting, thus reducing the energy demand for heating and cooling. The front roof shielding structure running through the southwest facade was designed to reduce the solar effect of summer warming. After dismantling the elements of the current outdated, inefficient heating and cooling system, a thermo-entillator system will be installed with the installation of an air-to-water heat pump with a capacity of 44.5 kW, thus serving the heating and cooling needs. The electrical energy required for the operation of the system is provided by placing a 23.5 kW solar panel on the flat roof, making the operation of the system even more economical. The wiring of existing lighting circuits is outdated, so they need to be replaced with copper wires. As the current illumination values are far below the requirements, a new lamp layout is needed, so the entire lighting system will be rebuilt according to the current standard (new protective tubes, copper wires, switches, modern energy-saving luminaires) and a new distribution cabinet is made. The activities listed together are complex to improve the energy classification to an acceptable level and thus to reduce CO2 emissions significantly. (English) / qualifier | |||||||||||||||
point in time: 8 February 2022
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Revision as of 22:03, 8 February 2022
Project Q3935261 in Hungary
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Energy renovation of a warehouse building |
Project Q3935261 in Hungary |
Statements
85,299,384 forint
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423,957.418 Euro
0.0027336256 Euro
15 December 2021
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155,089,789.091 forint
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54.999999 percent
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1 July 2020
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30 June 2022
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Bácska Mérnöki Szolgáltató Korlátolt Felelősségű Társaság
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46°25'40.26"N, 19°28'59.92"E
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A raktárépület jelenleg funkcionálisan működik, de leromlott állagú, nyílászárói, világítási rendszere és fűtése korszerűtlen. A falazat anyaga B30-as blokktégla, a födém hőszigetelés nélküli vasbeton panelekből készült, a nyílászárók acél szerkezetűek egy rétegű üvegezéssel. A meglévő ipari kapuk hőszigeteléssel nem rendelkeznek, a födémen pedig acél szerkezetű vonal menti bevilágító sávok találhatók, melyek hőtechnikai szempontból kedvezőtlenek. Az épület fűtési rendszere elavult és gazdaságtalan működtetésű olajkazán bordáscsöves radiátoros hőleadókkal, a hűtés egy elavult kompresszoros léghűtő berendezéssel oldható meg. A világítást hagyományos neoncsöves lámpatestek biztosítják. Az acélszerkezetű szigeteletlen homlokzati nyílászárók és ipari kapuk elbontása után az előírásoknak megfelelő hőátbocsájtási tényezővel rendelkező új műanyag ajtó és ablak kerül beépítésre, illetve új szekcionált ipari kapu. A meglévő vonal menti acél szerkezetű drótüveges felülvilágítók elbontása és a födém áttörések megszüntetése után pontszerű felülvilágítókat alakítunk ki, csökkentve ezáltal a lehülő felületek nagyságát, ezzel is javítva a hőháztartást. A homlokzaton 15 cm vastag polisztirol hőszigetelő rendszert készítünk, a lapostető szigetelését 25 cm vastag polisztirol táblákkal, PVC vízszigeteléssel, a szükséges bádogozásokkal együtt oldjuk meg, így csökkentve a fűtés-hűtés energiaszükségletét. A délnyugati homlokzaton végigfutó előtető árnyékoló szerkezetet terveztünk a nyári felmelegedés szoláris hatásának csökkentése érdekében. A jelenlegi elavult, gazdaságtalan fűtési és hűtési rendszer elemeinek elbontása után termoventillátoros rendszer kerül kiépítésre egy 44,5 kW teljesítményű levegő-víz rendszerű hőszivattyú telepítésével, mely így a fűtési és hűtési igényeket is kiszolgálja. A rendszer működéséhez szükséges elektromos energiát 23,5 kW teljesítményű napelem elhelyezésével biztosítjuk a lapostetőn, így téve még gazdaságosabbá a rendszer üzemeltetését. A meglévő világítási áramkörök vezetékei elavultak, így azokat réz vezetékre kell cserélni. Mivel a jelenlegi megvilágítási értékek messze elmaradnak az előírásoktól, új lámpakiosztás szükséges, ezért a teljes világítási rendszert az érvényben lévő szabvány előírásai szerint átépítjük (új védőcsövek, réz vezetékek, kapcsolók, korszerű energiatakarékos lámpatestek), valamint új elosztószekrény készül. A felsorolt tevékenységek együtt komplexen szükségesek az energetikai besorolás elfogadható szintre javításához, és ezáltal a CO2 kibocsájtás nagymértékű csökkentéséhez. (Hungarian)
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The warehouse is currently functional, but its degraded condition, doors and windows, lighting systems and heating are outdated. The masonry material is B30 block brick, the slab is made of reinforced concrete panels without thermal insulation, the doors and windows are steel-structured with a layer of glazing. The existing industrial gates are not thermally insulated, and on the floor there are lighting strips along a steel structure, which are unfavourable from a heat-technical point of view. The heating system of the building can be solved by means of an outdated and uneconomically operated oil boiler with ribbed radiator heat take-offs, cooling by an outdated compressor air cooler. Lighting is provided by traditional neon tube luminaires. Following the dismantling of uninsulated facade doors and industrial gates with steel structure, a new plastic door and window with a heat transfer factor in accordance with the regulations will be installed and a new sectional industrial gate will be installed. After dismantling the existing steel overlights along the line and removing the slab breakthroughs, we create point-like overlights, thereby reducing the amount of cooling surfaces, thereby improving the heat balance. On the facade we produce a 15 cm thick polystyrene thermal insulation system, the insulation of the flat roof is solved together with 25 cm thick polystyrene boards, PVC waterproofing and the necessary tinting, thus reducing the energy demand for heating and cooling. The front roof shielding structure running through the southwest facade was designed to reduce the solar effect of summer warming. After dismantling the elements of the current outdated, inefficient heating and cooling system, a thermo-entillator system will be installed with the installation of an air-to-water heat pump with a capacity of 44.5 kW, thus serving the heating and cooling needs. The electrical energy required for the operation of the system is provided by placing a 23.5 kW solar panel on the flat roof, making the operation of the system even more economical. The wiring of existing lighting circuits is outdated, so they need to be replaced with copper wires. As the current illumination values are far below the requirements, a new lamp layout is needed, so the entire lighting system will be rebuilt according to the current standard (new protective tubes, copper wires, switches, modern energy-saving luminaires) and a new distribution cabinet is made. The activities listed together are complex to improve the energy classification to an acceptable level and thus to reduce CO2 emissions significantly. (English)
8 February 2022
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Kiskunhalas, Bács-Kiskun
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Identifiers
GINOP-4.1.4-19-2020-02298
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