Energy modernisation of Stahl Varianten Kft. (Q3924975): Difference between revisions
Jump to navigation
Jump to search
(Changed an Item: add summary) |
(Changed an Item: Adding English translations) |
||||||||||||||
Property / summary | |||||||||||||||
within the framework of the project, energy modernisation of the Company’s seat in Pásztó will be realised. We intend to implement the project between 01.09.2017 and 31.08.2018. The investment activity is not subject to authorisation, design drawings, architectural and technological technical specifications are available. The energy certificate of the building has been drawn up for both the existing and the planned condition. The structure of the building, the technical building equipment, the heating system were surveyed. In order to improve the energy properties of the building, the thermal insulation of the facade and external walls, the insulation of the plinth and the thermal insulation of the flat roof are realised. The old windows are replaced and a 9 kW solar panel system will be installed to reduce costs. 18 cm thick EPS insulation with polystyrene foam is required (heat conductivity factor min.: 0,04 W/mK) to achieve the optimised requirement level. All thermal insulation is made of 2 mm thick plaster covering the outer surface with glass fabric mesh embedded, on which traditional noble plaster is applied to 3 mm thickness. Thermal insulation of the plinth is carried up to a height of 30 cm above orderly terrain, while in the ground we drain the XPS thermal insulation plate to a depth of 30 cm in thickness. Thermal conductivity factor of the thermal insulation plate min.: 0,04 W/mK. It is fixed by glue per stain, and a plaster covering the outer surface of a glass fabric mesh is made in 2 mm thickness, on which a base plaster is applied in 2 cm thickness. The thermal insulation of the flat roof is carried out with a thermal insulation plate of mineral wool in a thickness of 24 cm, the thermal conductivity factor of the thermal insulation plate is min.: 0,04 W/mK. Full surface insulation reduces the negative effect of thermal bridges, thus limiting the formation of cold, inner wall surfaces, thereby eliminating condensation and dusting on the wall surface. External doors and windows are the weakest part of the building from a thermal point of view. Due to the ageing of the structures subject to increased stress, there is a severe deterioration of the condition, the window wings do not close properly, and the air tightness between the wall and the case has also been eliminated. In the case of doors and windows that have not yet been replaced, the required limit value cannot be achieved by repair, therefore it is appropriate to replace them. Thermal transmittance factor of structures: Plastic outdoor windows, windows: IS IT UW? 1.15 W/m2K steel bottom sectional garage door: IS IT UW? 1,80 W/m2K. The newly installed, three-layer glazed, LOW-E coated modern doors and windows are airtight, thus reducing the filtration loss. In order to avoid overheating in the summer, external shadings and cheesies are installed on the building’s foreheads exposed to sunlight, preferably by motor operation. In order to reduce energy costs, a 9 kW solar system will be installed. This will enable the building to increase its share of renewable energy consumption and to promote and promote an environmentally conscious approach. The total cost of the project is HUF 28.183.623, of which the in-house amount is HUF 2 818 363, the amount of the grant: HUF 12.654.446, the amount of the loan to be taken out: 12.710.814,-Ft. (English) | |||||||||||||||
Property / summary: within the framework of the project, energy modernisation of the Company’s seat in Pásztó will be realised. We intend to implement the project between 01.09.2017 and 31.08.2018. The investment activity is not subject to authorisation, design drawings, architectural and technological technical specifications are available. The energy certificate of the building has been drawn up for both the existing and the planned condition. The structure of the building, the technical building equipment, the heating system were surveyed. In order to improve the energy properties of the building, the thermal insulation of the facade and external walls, the insulation of the plinth and the thermal insulation of the flat roof are realised. The old windows are replaced and a 9 kW solar panel system will be installed to reduce costs. 18 cm thick EPS insulation with polystyrene foam is required (heat conductivity factor min.: 0,04 W/mK) to achieve the optimised requirement level. All thermal insulation is made of 2 mm thick plaster covering the outer surface with glass fabric mesh embedded, on which traditional noble plaster is applied to 3 mm thickness. Thermal insulation of the plinth is carried up to a height of 30 cm above orderly terrain, while in the ground we drain the XPS thermal insulation plate to a depth of 30 cm in thickness. Thermal conductivity factor of the thermal insulation plate min.: 0,04 W/mK. It is fixed by glue per stain, and a plaster covering the outer surface of a glass fabric mesh is made in 2 mm thickness, on which a base plaster is applied in 2 cm thickness. The thermal insulation of the flat roof is carried out with a thermal insulation plate of mineral wool in a thickness of 24 cm, the thermal conductivity factor of the thermal insulation plate is min.: 0,04 W/mK. Full surface insulation reduces the negative effect of thermal bridges, thus limiting the formation of cold, inner wall surfaces, thereby eliminating condensation and dusting on the wall surface. External doors and windows are the weakest part of the building from a thermal point of view. Due to the ageing of the structures subject to increased stress, there is a severe deterioration of the condition, the window wings do not close properly, and the air tightness between the wall and the case has also been eliminated. In the case of doors and windows that have not yet been replaced, the required limit value cannot be achieved by repair, therefore it is appropriate to replace them. Thermal transmittance factor of structures: Plastic outdoor windows, windows: IS IT UW? 1.15 W/m2K steel bottom sectional garage door: IS IT UW? 1,80 W/m2K. The newly installed, three-layer glazed, LOW-E coated modern doors and windows are airtight, thus reducing the filtration loss. In order to avoid overheating in the summer, external shadings and cheesies are installed on the building’s foreheads exposed to sunlight, preferably by motor operation. In order to reduce energy costs, a 9 kW solar system will be installed. This will enable the building to increase its share of renewable energy consumption and to promote and promote an environmentally conscious approach. The total cost of the project is HUF 28.183.623, of which the in-house amount is HUF 2 818 363, the amount of the grant: HUF 12.654.446, the amount of the loan to be taken out: 12.710.814,-Ft. (English) / rank | |||||||||||||||
Normal rank | |||||||||||||||
Property / summary: within the framework of the project, energy modernisation of the Company’s seat in Pásztó will be realised. We intend to implement the project between 01.09.2017 and 31.08.2018. The investment activity is not subject to authorisation, design drawings, architectural and technological technical specifications are available. The energy certificate of the building has been drawn up for both the existing and the planned condition. The structure of the building, the technical building equipment, the heating system were surveyed. In order to improve the energy properties of the building, the thermal insulation of the facade and external walls, the insulation of the plinth and the thermal insulation of the flat roof are realised. The old windows are replaced and a 9 kW solar panel system will be installed to reduce costs. 18 cm thick EPS insulation with polystyrene foam is required (heat conductivity factor min.: 0,04 W/mK) to achieve the optimised requirement level. All thermal insulation is made of 2 mm thick plaster covering the outer surface with glass fabric mesh embedded, on which traditional noble plaster is applied to 3 mm thickness. Thermal insulation of the plinth is carried up to a height of 30 cm above orderly terrain, while in the ground we drain the XPS thermal insulation plate to a depth of 30 cm in thickness. Thermal conductivity factor of the thermal insulation plate min.: 0,04 W/mK. It is fixed by glue per stain, and a plaster covering the outer surface of a glass fabric mesh is made in 2 mm thickness, on which a base plaster is applied in 2 cm thickness. The thermal insulation of the flat roof is carried out with a thermal insulation plate of mineral wool in a thickness of 24 cm, the thermal conductivity factor of the thermal insulation plate is min.: 0,04 W/mK. Full surface insulation reduces the negative effect of thermal bridges, thus limiting the formation of cold, inner wall surfaces, thereby eliminating condensation and dusting on the wall surface. External doors and windows are the weakest part of the building from a thermal point of view. Due to the ageing of the structures subject to increased stress, there is a severe deterioration of the condition, the window wings do not close properly, and the air tightness between the wall and the case has also been eliminated. In the case of doors and windows that have not yet been replaced, the required limit value cannot be achieved by repair, therefore it is appropriate to replace them. Thermal transmittance factor of structures: Plastic outdoor windows, windows: IS IT UW? 1.15 W/m2K steel bottom sectional garage door: IS IT UW? 1,80 W/m2K. The newly installed, three-layer glazed, LOW-E coated modern doors and windows are airtight, thus reducing the filtration loss. In order to avoid overheating in the summer, external shadings and cheesies are installed on the building’s foreheads exposed to sunlight, preferably by motor operation. In order to reduce energy costs, a 9 kW solar system will be installed. This will enable the building to increase its share of renewable energy consumption and to promote and promote an environmentally conscious approach. The total cost of the project is HUF 28.183.623, of which the in-house amount is HUF 2 818 363, the amount of the grant: HUF 12.654.446, the amount of the loan to be taken out: 12.710.814,-Ft. (English) / qualifier | |||||||||||||||
point in time: 8 February 2022
|
Revision as of 18:12, 8 February 2022
Project Q3924975 in Hungary
Language | Label | Description | Also known as |
---|---|---|---|
English | Energy modernisation of Stahl Varianten Kft. |
Project Q3924975 in Hungary |
Statements
28,163,623 forint
0 references
171,467.262 Euro
0.0027336256 Euro
15 December 2021
0 references
62,725,218.263 forint
0 references
44.899997 percent
0 references
19 July 2019
0 references
30 April 2021
0 references
STAHL - VARIANTEN Általános Gyártási és Külkereskedelmi Korlátolt Felelősségü Társaság
0 references
projekt keretében a Társaság pásztói székhelyének található energetikai korszerűsítése valósul meg. A beruházás kivitelezését 2017.09.01-2018.08.31 közötti időtartamban kívánjuk megvalósítani. A beruházási tevékenység nem engedélyköteles, a tervrajzok, az építészeti és technológiai műszaki leírás rendelkezésre áll. Elkészítésre került az épület energetikai tanúsítványa mind a meglévő, mind a tervezett állapotra vonatkozóan. Felmérésre került az épület szerkezete, az épületgépészeti berendezések, a fűtési rendszer. Az épület energetikai tulajdonságának fejlesztése érdekében megvalósul a homlokzati, külső falak hőszigetelése, a lábazat hőszigetelése, a lapostető hőszigetelése. Megtörténik a régi korszerűtlen nyílászárók cseréje, a költségek csökkentése érdekében pedig 9 kW teljesítményű napelemes rendszer kerül telepítésre. Az épületen 18 cm vastag EPS hőszigetelő polisztirolhab lemezzel történő szigetelés szükséges (hővezetési tényezője min.: 0,04 W/mK) az optimalizált követelményszint eléréséhez. Minden hőszigetelés dűbeles rögzítéssel, külső felületére üvegszövet háló beágyazással simító vakolat készül 2 mm vastagságban, melyre hagyományos nemesvakolat kerül felhordásra 3mm vastagságba. A lábazat hőszigetelése rendezett terepszint felett 30 cm magasságáig vezetjük fel, míg a talajban 30 cm mélységig vezetjük le az XPS hőszigetelő lemezt 18 cm vastagságban. A hőszigetelő lemez hővezetési tényezője min.: 0,04 W/mK. Rögzítése foltonként ragasztva történik, külső felületére üvegszövet háló beágyazással simító vakolat készül 2 mm vastagságban, melyre lábazati alapvakolat kerül felhordásra 2 cm vastagságban. A lapostető utólagos hőszigetelése ásványgyapot hőszigetelő lemezzel történik 24 cm-es vastagságban, hőszigetelő lemez hővezetési tényezője min.: 0,04 W/mK. A teljes felületű hőszigetelés csökkenti a hőhidak negatív hatását, a hideg, belső falfelületek kialakulása így korlátozhatóvá válik, ezáltal megszüntethető a párakicsapódás és a penészedés a falfelületen. Az épület leggyengébb pontját hőtechnikai szempontból a külső nyílászárók jelentik. A fokozott igénybevételnek kitett szerkezetek elöregedése során erős állapotromlás tapasztalható, az ablakszárnyak nem zárnak megfelelően, esetleg a fal és a tok között is megszűnt a légzárás. A még ki nem cserélt nyílászárók esetén javítással nem érhető el a kívánt határérték, ezért cseréjük indokolt. Szerkezetek hőátbocsátási tényezője: Műanyag kültéri nyílászáró, ablak: UW ? 1,15 W/m2K Acéllamellás szekcionált garázskapu: UW ? 1,80 W/m2K. Az újonnan beépítendő, háromréteg üvegezésű, LOW-E bevonattal rendelkező korszerű nyílászárók légtömörek, így a filtrációs veszteség is lecsökken. A nyári túlmelegedés elkerülése érdekében külső árnyékolók, zsalúziák kerülnek felszerelésre az épület napsugárzásnak fokozottan kitett homlokzatain, lehetőleg motoros működtetéssel. Az energiaköltségek csökkentése érdekében 9 kW teljesítményű napelemes rendszer kerül telepítésre. Ennek segítségével az épület megújuló energiaforrásból származó energiafogyasztásának részarányát növelni tudja, valamint a környezettudatos szemléletet is képviseli és hirdeti. A projekt összköltsége nettó 28.183.623,-Ft, amelyből az önerő nagysága 2.818.363,- Ft, a vissza nem térítendő támogatás összege: 12.654.446,- Ft, a felvenni kívánt hitel összege: 12.710.814,-Ft. (Hungarian)
0 references
within the framework of the project, energy modernisation of the Company’s seat in Pásztó will be realised. We intend to implement the project between 01.09.2017 and 31.08.2018. The investment activity is not subject to authorisation, design drawings, architectural and technological technical specifications are available. The energy certificate of the building has been drawn up for both the existing and the planned condition. The structure of the building, the technical building equipment, the heating system were surveyed. In order to improve the energy properties of the building, the thermal insulation of the facade and external walls, the insulation of the plinth and the thermal insulation of the flat roof are realised. The old windows are replaced and a 9 kW solar panel system will be installed to reduce costs. 18 cm thick EPS insulation with polystyrene foam is required (heat conductivity factor min.: 0,04 W/mK) to achieve the optimised requirement level. All thermal insulation is made of 2 mm thick plaster covering the outer surface with glass fabric mesh embedded, on which traditional noble plaster is applied to 3 mm thickness. Thermal insulation of the plinth is carried up to a height of 30 cm above orderly terrain, while in the ground we drain the XPS thermal insulation plate to a depth of 30 cm in thickness. Thermal conductivity factor of the thermal insulation plate min.: 0,04 W/mK. It is fixed by glue per stain, and a plaster covering the outer surface of a glass fabric mesh is made in 2 mm thickness, on which a base plaster is applied in 2 cm thickness. The thermal insulation of the flat roof is carried out with a thermal insulation plate of mineral wool in a thickness of 24 cm, the thermal conductivity factor of the thermal insulation plate is min.: 0,04 W/mK. Full surface insulation reduces the negative effect of thermal bridges, thus limiting the formation of cold, inner wall surfaces, thereby eliminating condensation and dusting on the wall surface. External doors and windows are the weakest part of the building from a thermal point of view. Due to the ageing of the structures subject to increased stress, there is a severe deterioration of the condition, the window wings do not close properly, and the air tightness between the wall and the case has also been eliminated. In the case of doors and windows that have not yet been replaced, the required limit value cannot be achieved by repair, therefore it is appropriate to replace them. Thermal transmittance factor of structures: Plastic outdoor windows, windows: IS IT UW? 1.15 W/m2K steel bottom sectional garage door: IS IT UW? 1,80 W/m2K. The newly installed, three-layer glazed, LOW-E coated modern doors and windows are airtight, thus reducing the filtration loss. In order to avoid overheating in the summer, external shadings and cheesies are installed on the building’s foreheads exposed to sunlight, preferably by motor operation. In order to reduce energy costs, a 9 kW solar system will be installed. This will enable the building to increase its share of renewable energy consumption and to promote and promote an environmentally conscious approach. The total cost of the project is HUF 28.183.623, of which the in-house amount is HUF 2 818 363, the amount of the grant: HUF 12.654.446, the amount of the loan to be taken out: 12.710.814,-Ft. (English)
8 February 2022
0 references
Pásztó, Nógrád
0 references
Identifiers
GINOP-4.1.1-8-4-4-16-2017-00239
0 references