Increasing energy efficiency using renewable energy sources at the headquarters of MI Park Kft. (Q3924947): Difference between revisions
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During the preparation of the project, an energy audit was carried out. During the on-site survey, the dimensions and strata of the building boundaries were recorded and the U values of each structure were accurately determined using the building energy programme used. The energy demand was based on the consumption of electricity, gas and other energy in the last year. Development is not an activity subject to authorisation. The project management members are all experienced in the field of tender and construction projects, as well as technical inspectors to ensure the compliance of the implementation. — New doors and windows are aluminium housing, 3-layer, argon gas-filled, heat insulated glazed structures with a heat transmittance (u) factor of 0,8 W/m2K. The windows are roll-open and fixed glazed. The windowsills on the outside are sheet metal and plastic structures on the inner side. — Rearward 15 cm thick facade thermal insulation, glued on the entire surface, mechanically fixed on the wall surface made even with the airtight plaster. Above the windows, instead of the polystyrene facade thermal insulation, we use rock wool in the same thickness. For the plinth, 10 cm vtg XPS thermal insulation shall be fixed after equalisation to the current red sandstone plinth. The pedestal thermal insulation should be lowered into the ground up to a depth of 50 cm. The thermal insulation to be placed in the posterior shall be attached to the plinth by gluing and doweling over the entire surface. The wall insulation should be folded to the plinth at a height of 50 cm, on which the thermal insulation is placed. A plinth ornamental plaster is made on the glued glass fabric. A sliding layer shall be placed between the plinth surface and the concrete of the pavement, because the different movement of the two structures may lead to the separation of the pedestal insulation from the base surface. — Facade formation: The plinth is thermally insulated with a plinth ornamental plaster. The thermal insulation, rolling-grained thin blind is surface-formed, matching the coverings and coloring of existing buildings. — As the basement has an open side surface in part, the slab must be insulated with 15 cm thick mineral wool. — To be placed on the roof with 22 cm thick rock wool material thermal insulation with mechanical attachment, vapor-proofing under it, above it, PVC sheet waterproofing. — During the modernisation of the building, a new and modern low-temperature heat pump heating and cooling system will be installed on the roof with 1 pcs Midea MV5-X615 W/V2GN1 MDV V5 X and 1 Pcs Midea MV5-X560 W/V2GN1 MDV V5 X heat pump outdoor unit. In the basement, the energy storage element of the system, the divider-collector element, and the additional fixtures required for the system are created. The system will be equipped with a modern, insulated, new pipe network that ensures efficient energy transmission with controlled speed circulating pumps and central temperature control per room. Indoor heat dischargers (41 MI-28G/DHN1-M and 9 MI-36Q4/DHN1-A3) and wall remote controls (50 KJR-29B1/BK-E) provide the appropriate temperature in winter and summer in the building as well as domestic hot water. — On the roof of the building, a 50 kW solar system will be installed, which generates a significant part of the electricity costs used. The system consists of 186 pcs IBC Solar IBC PolySol 270Wp solar panels, 2 FRONIUS Eco 25.0-3 network inverters, and the necessary support structure and safety components. (English) | |||||||||||||||
| Property / summary: During the preparation of the project, an energy audit was carried out. During the on-site survey, the dimensions and strata of the building boundaries were recorded and the U values of each structure were accurately determined using the building energy programme used. The energy demand was based on the consumption of electricity, gas and other energy in the last year. Development is not an activity subject to authorisation. The project management members are all experienced in the field of tender and construction projects, as well as technical inspectors to ensure the compliance of the implementation. — New doors and windows are aluminium housing, 3-layer, argon gas-filled, heat insulated glazed structures with a heat transmittance (u) factor of 0,8 W/m2K. The windows are roll-open and fixed glazed. The windowsills on the outside are sheet metal and plastic structures on the inner side. — Rearward 15 cm thick facade thermal insulation, glued on the entire surface, mechanically fixed on the wall surface made even with the airtight plaster. Above the windows, instead of the polystyrene facade thermal insulation, we use rock wool in the same thickness. For the plinth, 10 cm vtg XPS thermal insulation shall be fixed after equalisation to the current red sandstone plinth. The pedestal thermal insulation should be lowered into the ground up to a depth of 50 cm. The thermal insulation to be placed in the posterior shall be attached to the plinth by gluing and doweling over the entire surface. The wall insulation should be folded to the plinth at a height of 50 cm, on which the thermal insulation is placed. A plinth ornamental plaster is made on the glued glass fabric. A sliding layer shall be placed between the plinth surface and the concrete of the pavement, because the different movement of the two structures may lead to the separation of the pedestal insulation from the base surface. — Facade formation: The plinth is thermally insulated with a plinth ornamental plaster. The thermal insulation, rolling-grained thin blind is surface-formed, matching the coverings and coloring of existing buildings. — As the basement has an open side surface in part, the slab must be insulated with 15 cm thick mineral wool. — To be placed on the roof with 22 cm thick rock wool material thermal insulation with mechanical attachment, vapor-proofing under it, above it, PVC sheet waterproofing. — During the modernisation of the building, a new and modern low-temperature heat pump heating and cooling system will be installed on the roof with 1 pcs Midea MV5-X615 W/V2GN1 MDV V5 X and 1 Pcs Midea MV5-X560 W/V2GN1 MDV V5 X heat pump outdoor unit. In the basement, the energy storage element of the system, the divider-collector element, and the additional fixtures required for the system are created. The system will be equipped with a modern, insulated, new pipe network that ensures efficient energy transmission with controlled speed circulating pumps and central temperature control per room. Indoor heat dischargers (41 MI-28G/DHN1-M and 9 MI-36Q4/DHN1-A3) and wall remote controls (50 KJR-29B1/BK-E) provide the appropriate temperature in winter and summer in the building as well as domestic hot water. — On the roof of the building, a 50 kW solar system will be installed, which generates a significant part of the electricity costs used. The system consists of 186 pcs IBC Solar IBC PolySol 270Wp solar panels, 2 FRONIUS Eco 25.0-3 network inverters, and the necessary support structure and safety components. (English) / rank | |||||||||||||||
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| Property / summary: During the preparation of the project, an energy audit was carried out. During the on-site survey, the dimensions and strata of the building boundaries were recorded and the U values of each structure were accurately determined using the building energy programme used. The energy demand was based on the consumption of electricity, gas and other energy in the last year. Development is not an activity subject to authorisation. The project management members are all experienced in the field of tender and construction projects, as well as technical inspectors to ensure the compliance of the implementation. — New doors and windows are aluminium housing, 3-layer, argon gas-filled, heat insulated glazed structures with a heat transmittance (u) factor of 0,8 W/m2K. The windows are roll-open and fixed glazed. The windowsills on the outside are sheet metal and plastic structures on the inner side. — Rearward 15 cm thick facade thermal insulation, glued on the entire surface, mechanically fixed on the wall surface made even with the airtight plaster. Above the windows, instead of the polystyrene facade thermal insulation, we use rock wool in the same thickness. For the plinth, 10 cm vtg XPS thermal insulation shall be fixed after equalisation to the current red sandstone plinth. The pedestal thermal insulation should be lowered into the ground up to a depth of 50 cm. The thermal insulation to be placed in the posterior shall be attached to the plinth by gluing and doweling over the entire surface. The wall insulation should be folded to the plinth at a height of 50 cm, on which the thermal insulation is placed. A plinth ornamental plaster is made on the glued glass fabric. A sliding layer shall be placed between the plinth surface and the concrete of the pavement, because the different movement of the two structures may lead to the separation of the pedestal insulation from the base surface. — Facade formation: The plinth is thermally insulated with a plinth ornamental plaster. The thermal insulation, rolling-grained thin blind is surface-formed, matching the coverings and coloring of existing buildings. — As the basement has an open side surface in part, the slab must be insulated with 15 cm thick mineral wool. — To be placed on the roof with 22 cm thick rock wool material thermal insulation with mechanical attachment, vapor-proofing under it, above it, PVC sheet waterproofing. — During the modernisation of the building, a new and modern low-temperature heat pump heating and cooling system will be installed on the roof with 1 pcs Midea MV5-X615 W/V2GN1 MDV V5 X and 1 Pcs Midea MV5-X560 W/V2GN1 MDV V5 X heat pump outdoor unit. In the basement, the energy storage element of the system, the divider-collector element, and the additional fixtures required for the system are created. The system will be equipped with a modern, insulated, new pipe network that ensures efficient energy transmission with controlled speed circulating pumps and central temperature control per room. Indoor heat dischargers (41 MI-28G/DHN1-M and 9 MI-36Q4/DHN1-A3) and wall remote controls (50 KJR-29B1/BK-E) provide the appropriate temperature in winter and summer in the building as well as domestic hot water. — On the roof of the building, a 50 kW solar system will be installed, which generates a significant part of the electricity costs used. The system consists of 186 pcs IBC Solar IBC PolySol 270Wp solar panels, 2 FRONIUS Eco 25.0-3 network inverters, and the necessary support structure and safety components. (English) / qualifier | |||||||||||||||
point in time: 8 February 2022
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Revision as of 18:11, 8 February 2022
Project Q3924947 in Hungary
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Increasing energy efficiency using renewable energy sources at the headquarters of MI Park Kft. |
Project Q3924947 in Hungary |
Statements
97,136,216 forint
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220,764,127.273 forint
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44.0 percent
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1 December 2017
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30 November 2018
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MI Park Korlátolt Felelősségű Társaság
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46°58'18.30"N, 18°8'21.34"E
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A projekt előkészítés során energia audit végzésére került sor. A helyszíni felmérés során rögzítették az épület határoló szerkezeteinek méreteit és rétegrendjét, és az alkalmazott épületenergetikai program segítségével pontosan meghatároztak az egyes szerkezetek U értékeit. Az energiaigényt az elmúlt év villamos, fölgáz és egyéb energia fogyasztására alapoztuk. A fejlesztés nem engedélyköteles tevékenység. A projektmenedzsment tagjai mind pályázati és építési projektek területén tapasztalattal rendelkező személyek, továbbá műszaki ellenőr is biztosítja a kivitelezés megfelelőségét. - Az új nyílászárók alumínium tokszerkezetű, 3 rétegű, argon gázzal töltött, hőszigetelt üvegezésű szerkezetek, melyeknek hőátbocsátási (u) tényezője 0,8 W/m2K. Az ablakok bukó-nyíló rendszerűek, illetve fix üvegezésűek. Az ablakpárkányok külső oldalon fémlemez, belső oldalon műanyag szerkezetek. - Utólagos 15 cm vastag homlokzati hőszigetelés, teljes felületen ragasztással, mechanikus rögzítéssel a légzáró vakolattal egyenletessé tett falfelületen. A nyílászárók felett, a polisztirol anyagú homlokzati hőszigetelés helyett kőzetgyapotot alkalmazunk, azonos vastagságban. A lábazat esetében a jelenlegi vörös homokkő lábazatra kiegyenlítés után 10 cm vtg XPS hőszigetelés rögzítendő. A lábazati hőszigetelést le kell engedni a talajba 50 cm mélységig. Az utólagosan elhelyezésre kerülő hőszigetelés a lábazatra teljes felületen ragasztással és dübellel rögzítendő. A falszigetelés 50 cm magasan felhajtandó a lábazatra, melyre a hőszigetelés kerül. A felragasztott üvegszövetre lábazati díszvakolat készül. A lábazati felület és a járda betonja közé csúsztató réteget kell elhelyezni, mert a két szerkezet eltérő mozgása révén a lábazati hőszigetelés leszakadhat az alapfelületről. - Homlokzatképzés: A lábazat hőszigetelést kap, melyre lábazati díszvakolat létesül. A hőszigetelés, gördülőszemcsés vékonyvakolat felületképzést kap, illeszkedve a meglévő épületek burkolataihoz és színezéséhez. - Mivel a pince részben nyitott oldalfelülettel rendelkezik, ezért a födémet 15 cm vastag, ásványgyapot szigeteléssel kell ellátni. - A tetőre 22 cm vastag kőzetgyapot anyagú hőszigetelés helyezendő, mechanikus rögzítéssel, alatta párazáró fóliával, felette, PVC lemez vízszigeteléssel. - A korszerűsítés során az épület, új és korszerű, alacsony hőmérsékletű hőszivattyús fűtési, hűtési rendszer kerül kialakításra. a tetőn kerül elhelyezésre 1 db MIDEA MV5-X615W / V2GN1 MDV V5 X, és 1 db MIDEA MV5-X560W / V2GN1 MDV V5 X típusú hőszivattyú kültéri egység. A pincében kerül kialakításra a rendszer energia tároló eleme, az osztó-gyűjtő eleme, és a rendszerhez szükséges további berendezési tárgyak. A rendszer modern, szigetelt, új csőhálózattal lesz szerelve, mely biztosítja a hatékony energia továbbítást, szabályozott fordulatszámú keringtető szivattyúkkal, helyiségenként központi hőmérséklet szabályzással. A beltéri hőleadók (41 db MI-28G / DHN1-M, és 9 db MI-36Q4 / DHN1-A3), és a fali távvezérlők (50 db KJR-29B1/BK-E) biztosítják télen, és nyáron az épületben a megfelelő hőmérsékletet, valamint a használati melegvizet. - Az épület tetején, egy 50kW-os napelemes rendszer kerül kiépítésre, mely a felhasznált elektromos energia költségek jelentős részét megtermeli. Rendszert 186 db IBC Solar IBC PolySol 270Wp napelem, 2 db FRONIUS Eco 25.0-3 hálózati inverter, és a hozzá szükséges tartószerkezet, biztonsági elemek alkotják. (Hungarian)
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During the preparation of the project, an energy audit was carried out. During the on-site survey, the dimensions and strata of the building boundaries were recorded and the U values of each structure were accurately determined using the building energy programme used. The energy demand was based on the consumption of electricity, gas and other energy in the last year. Development is not an activity subject to authorisation. The project management members are all experienced in the field of tender and construction projects, as well as technical inspectors to ensure the compliance of the implementation. — New doors and windows are aluminium housing, 3-layer, argon gas-filled, heat insulated glazed structures with a heat transmittance (u) factor of 0,8 W/m2K. The windows are roll-open and fixed glazed. The windowsills on the outside are sheet metal and plastic structures on the inner side. — Rearward 15 cm thick facade thermal insulation, glued on the entire surface, mechanically fixed on the wall surface made even with the airtight plaster. Above the windows, instead of the polystyrene facade thermal insulation, we use rock wool in the same thickness. For the plinth, 10 cm vtg XPS thermal insulation shall be fixed after equalisation to the current red sandstone plinth. The pedestal thermal insulation should be lowered into the ground up to a depth of 50 cm. The thermal insulation to be placed in the posterior shall be attached to the plinth by gluing and doweling over the entire surface. The wall insulation should be folded to the plinth at a height of 50 cm, on which the thermal insulation is placed. A plinth ornamental plaster is made on the glued glass fabric. A sliding layer shall be placed between the plinth surface and the concrete of the pavement, because the different movement of the two structures may lead to the separation of the pedestal insulation from the base surface. — Facade formation: The plinth is thermally insulated with a plinth ornamental plaster. The thermal insulation, rolling-grained thin blind is surface-formed, matching the coverings and coloring of existing buildings. — As the basement has an open side surface in part, the slab must be insulated with 15 cm thick mineral wool. — To be placed on the roof with 22 cm thick rock wool material thermal insulation with mechanical attachment, vapor-proofing under it, above it, PVC sheet waterproofing. — During the modernisation of the building, a new and modern low-temperature heat pump heating and cooling system will be installed on the roof with 1 pcs Midea MV5-X615 W/V2GN1 MDV V5 X and 1 Pcs Midea MV5-X560 W/V2GN1 MDV V5 X heat pump outdoor unit. In the basement, the energy storage element of the system, the divider-collector element, and the additional fixtures required for the system are created. The system will be equipped with a modern, insulated, new pipe network that ensures efficient energy transmission with controlled speed circulating pumps and central temperature control per room. Indoor heat dischargers (41 MI-28G/DHN1-M and 9 MI-36Q4/DHN1-A3) and wall remote controls (50 KJR-29B1/BK-E) provide the appropriate temperature in winter and summer in the building as well as domestic hot water. — On the roof of the building, a 50 kW solar system will be installed, which generates a significant part of the electricity costs used. The system consists of 186 pcs IBC Solar IBC PolySol 270Wp solar panels, 2 FRONIUS Eco 25.0-3 network inverters, and the necessary support structure and safety components. (English)
8 February 2022
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Balatonvilágos, Somogy
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Identifiers
GINOP-4.1.1-8-4-4-16-2017-00161
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