Building energy development using renewable energy at VILKOR Kft. (Q3935571): Difference between revisions
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The technical preparation of the project is reflected by the fact that the energetic designer prepared the building design documentation and the energy certificates (existing, planned) following the on-site survey and determined the quantifiable results and indicators of the project accordingly. The investment is not subject to authorisation, so the acquisition of these contributions is not relevant. In addition to the above-mentioned engineering tasks, requests from technical inspectors have been made, the name and the eligibility number of the inspector to be used during the implementation of the project are indicated in the detailed description of the project data sheet. The responsibility of project management is the correct implementation of the project by the deadline. For this task, a broad-minded (external) company with significant background experience and expertise will be selected, with sufficient references for the implementation of EU projects of similar scale and development, as the company does not have sufficient experience in the implementation of EU projects. In addition, the information package under the provisions of the Széchenyi 2020 JTI will be implemented. Short technical content of the construction: 1. Architecture Façade and plinth: Dryvit thermal insulation is made on the facade of the building. The thickness of the Austrotherm AT-H80 thermal insulation tiles on the façade is 150 mm, which is attached exactly to the wall structure. The plinth receives a 150 mm thick EPS thermal insulation (Austrotherm Expert Fix) on which resin plaster is applied in anthracite color. Slab insulation: A 2 x 100 mm Austrotherm AT-N100 EPS thermal insulation plate is installed on the top plane of the ceiling structure, on which we place a MIKROLITH glass veil separator layer, on which the rainwater insulation is made on the top plane. SIKAPLAN 15G PVC insulation is made by mechanical fastening. Doors and windows, lights: We want to replace the facade doors. The new doors and windows are constructed in the sizes shown on the design sheet, plastic-structured doors and windows with heat insulated glazing, in white, with a heat transfer factor U=1,15 W/m2K. 2. Solar system: The conditions for the deployment of the system are met. 23 modules are placed on the roof of the building. 60 cell monocrystalline modules in alu frame with 3.2 mm iron-free hardened solar glass, EVA filling, IP65 connector box, solar wire, solar connectors. Designed panel: Risen RSM60-6-310M. Support structure: Stainless steel and aluminium lightweight duct system with connecting elements, for fitting to the PV-generator arrangement, partly with scaffolding and partly parallel to the roof plane. Inverter: 1 (FRONIUS SYMO 7.0-3-M) three-phase 400/3x230V, 50 Hz network synchronous inverter with wifi module 3. Construction of a complete heating system, i.e. installing boilers in the engine room of the building (2pcs Condital Antea wall boiler (IPX4D), each of which is e=1.0; Q=24.9 kW,q= 2.51 m³/h. Based on the heating requirement of the building, 2 boilers are required with Kaskád step, via hydraulic transmission, with expansion tanks installed. In addition to the installation of boilers, complete upgrading of fittings, heating pipes and heaters will take place, which is in line with point 3.1.1(B) II(a) of the Call. (English) | |||||||||||||||
| Property / summary: The technical preparation of the project is reflected by the fact that the energetic designer prepared the building design documentation and the energy certificates (existing, planned) following the on-site survey and determined the quantifiable results and indicators of the project accordingly. The investment is not subject to authorisation, so the acquisition of these contributions is not relevant. In addition to the above-mentioned engineering tasks, requests from technical inspectors have been made, the name and the eligibility number of the inspector to be used during the implementation of the project are indicated in the detailed description of the project data sheet. The responsibility of project management is the correct implementation of the project by the deadline. For this task, a broad-minded (external) company with significant background experience and expertise will be selected, with sufficient references for the implementation of EU projects of similar scale and development, as the company does not have sufficient experience in the implementation of EU projects. In addition, the information package under the provisions of the Széchenyi 2020 JTI will be implemented. Short technical content of the construction: 1. Architecture Façade and plinth: Dryvit thermal insulation is made on the facade of the building. The thickness of the Austrotherm AT-H80 thermal insulation tiles on the façade is 150 mm, which is attached exactly to the wall structure. The plinth receives a 150 mm thick EPS thermal insulation (Austrotherm Expert Fix) on which resin plaster is applied in anthracite color. Slab insulation: A 2 x 100 mm Austrotherm AT-N100 EPS thermal insulation plate is installed on the top plane of the ceiling structure, on which we place a MIKROLITH glass veil separator layer, on which the rainwater insulation is made on the top plane. SIKAPLAN 15G PVC insulation is made by mechanical fastening. Doors and windows, lights: We want to replace the facade doors. The new doors and windows are constructed in the sizes shown on the design sheet, plastic-structured doors and windows with heat insulated glazing, in white, with a heat transfer factor U=1,15 W/m2K. 2. Solar system: The conditions for the deployment of the system are met. 23 modules are placed on the roof of the building. 60 cell monocrystalline modules in alu frame with 3.2 mm iron-free hardened solar glass, EVA filling, IP65 connector box, solar wire, solar connectors. Designed panel: Risen RSM60-6-310M. Support structure: Stainless steel and aluminium lightweight duct system with connecting elements, for fitting to the PV-generator arrangement, partly with scaffolding and partly parallel to the roof plane. Inverter: 1 (FRONIUS SYMO 7.0-3-M) three-phase 400/3x230V, 50 Hz network synchronous inverter with wifi module 3. Construction of a complete heating system, i.e. installing boilers in the engine room of the building (2pcs Condital Antea wall boiler (IPX4D), each of which is e=1.0; Q=24.9 kW,q= 2.51 m³/h. Based on the heating requirement of the building, 2 boilers are required with Kaskád step, via hydraulic transmission, with expansion tanks installed. In addition to the installation of boilers, complete upgrading of fittings, heating pipes and heaters will take place, which is in line with point 3.1.1(B) II(a) of the Call. (English) / rank | |||||||||||||||
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| Property / summary: The technical preparation of the project is reflected by the fact that the energetic designer prepared the building design documentation and the energy certificates (existing, planned) following the on-site survey and determined the quantifiable results and indicators of the project accordingly. The investment is not subject to authorisation, so the acquisition of these contributions is not relevant. In addition to the above-mentioned engineering tasks, requests from technical inspectors have been made, the name and the eligibility number of the inspector to be used during the implementation of the project are indicated in the detailed description of the project data sheet. The responsibility of project management is the correct implementation of the project by the deadline. For this task, a broad-minded (external) company with significant background experience and expertise will be selected, with sufficient references for the implementation of EU projects of similar scale and development, as the company does not have sufficient experience in the implementation of EU projects. In addition, the information package under the provisions of the Széchenyi 2020 JTI will be implemented. Short technical content of the construction: 1. Architecture Façade and plinth: Dryvit thermal insulation is made on the facade of the building. The thickness of the Austrotherm AT-H80 thermal insulation tiles on the façade is 150 mm, which is attached exactly to the wall structure. The plinth receives a 150 mm thick EPS thermal insulation (Austrotherm Expert Fix) on which resin plaster is applied in anthracite color. Slab insulation: A 2 x 100 mm Austrotherm AT-N100 EPS thermal insulation plate is installed on the top plane of the ceiling structure, on which we place a MIKROLITH glass veil separator layer, on which the rainwater insulation is made on the top plane. SIKAPLAN 15G PVC insulation is made by mechanical fastening. Doors and windows, lights: We want to replace the facade doors. The new doors and windows are constructed in the sizes shown on the design sheet, plastic-structured doors and windows with heat insulated glazing, in white, with a heat transfer factor U=1,15 W/m2K. 2. Solar system: The conditions for the deployment of the system are met. 23 modules are placed on the roof of the building. 60 cell monocrystalline modules in alu frame with 3.2 mm iron-free hardened solar glass, EVA filling, IP65 connector box, solar wire, solar connectors. Designed panel: Risen RSM60-6-310M. Support structure: Stainless steel and aluminium lightweight duct system with connecting elements, for fitting to the PV-generator arrangement, partly with scaffolding and partly parallel to the roof plane. Inverter: 1 (FRONIUS SYMO 7.0-3-M) three-phase 400/3x230V, 50 Hz network synchronous inverter with wifi module 3. Construction of a complete heating system, i.e. installing boilers in the engine room of the building (2pcs Condital Antea wall boiler (IPX4D), each of which is e=1.0; Q=24.9 kW,q= 2.51 m³/h. Based on the heating requirement of the building, 2 boilers are required with Kaskád step, via hydraulic transmission, with expansion tanks installed. In addition to the installation of boilers, complete upgrading of fittings, heating pipes and heaters will take place, which is in line with point 3.1.1(B) II(a) of the Call. (English) / qualifier | |||||||||||||||
point in time: 8 February 2022
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Revision as of 21:53, 8 February 2022
Project Q3935571 in Hungary
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Building energy development using renewable energy at VILKOR Kft. |
Project Q3935571 in Hungary |
Statements
20,098,870 forint
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36,543,400.0 forint
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54.999998 percent
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1 October 2020
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30 September 2022
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VILKOR Ipari, Kereskedelmi és Szolgáltató Korlátolt Felelősségű Társaság
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46°15'59.08"N, 17°5'34.58"E
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A projekt kellő műszaki előkészítettségét tükrözi, hogy az energetikus, tervező a helyszíni felmérést követően elkészítette az építési tervdokumentációt és az energetikai tanúsítványokat (meglévő, tervezett), s ennek megfelelően meghatározta a projekt számszerűsíthető eredményeit, indikátorait. A beruházás nem minősül engedélykötelesnek, így ezen hozzájárulások beszerzése nem releváns. A fent említett mérnöki feladatokon túl műszaki ellenőri ajánlatkérések megtörténtek, a projekt megvalósítás során igénybe veendő műellenőr nevét és jogosultsági számát a projekt részletes bemutatása adatlapon feltüntettük. A projektmenedment felelőssége a projekt határidőre történő hibátlan végrehajtása, így erre a feladatra széles látókörű, jelentős háttértapasztalatokkal és szakértelemmel rendelkező – külső – vállalkozás kerül kiválasztásra, akik kellő referenciákkal rendelkeznek a hasonló volumenű és fejlesztésű célú uniós projektek lebonyolítása terén, mivel a társaság nem rendelkezik uniós projektek lebonyolítása terén kellő tapasztattal. Az előzőeken túl, a Széchenyi 2020 KTK rendelkezései szerinti tájékoztatási csomag kerül megvalósításra. A kivitelezés rövid műszaki tartalma: 1. Építészet Homlokzat és lábazat: Az épület homlokzatán dryvit rendszerű hőszigetelés készül. Az AUSTROTHERM AT-H80 hőszigetelő lapok vastagsága a homlokzaton 150 mm, melyet pontszerűen rögzítünk a falszerkezethez. A lábazat 150 mm vastagságú formahabosított EPS hőszigetelést (AUSTROTHERM Expert Fix) kap, melyre műgyanta lábazatvakolatot hordunk fel, antracit színben. Födémszigetelés: A födémszerkezet felső síkján 2 x 100 mm AUSTROTHERM AT-N100 EPS hőszigetelő lemezt építünk be, melyre MIKROLITH üvegfátyol elválasztó réteget helyezünk, melynek felső síkján készül a csapadékvíz elleni szigetelés. A SIKAPLAN 15 G PVC szigetelést mechanikai rögzítéssel készítjük. Nyílászárók, bevilágítók: A homlokzati nyílászárók cseréjét el kívánjuk végezni. Az új nyílászárók a tervlapon szereplő méretekben készülnek, műanyag szerkezetű, hőszigetelt üvegezéssel ellátott nyílászárók, fehér színben, U=1,15 W/m2K hőátbocsátási tényezővel. 2. Napelemes rendszer: A rendszer kiépítésének feltételei adottak. Az épület tetejére 23 db, modul kerül elhelyezésre. 60 cellás, monokristályos modulok alu keretben, 3,2 mm vasmentes edzett szolárüveggel, EVA kitöltéssel, IP65-ös csatlakozó dobozzal, szolár vezetékkel, szolár csatlakozókkal.. Tervezett panel: Risen RSM60-6-310M. Tartószerkezet: Rozsdamentes acél és alumíniumból készült könnyűszerkezetű alépítmény rendszer csatlakozó elemekkel, a PV-generátor elrendezéséhez illesztett, részben állványos, részben tetősíkkal párhuzamos szereléshez. Inverter: 1 db (FRONIUS SYMO 7.0-3-M) háromfázisú 400/3x230V, 50Hz hálózattal szinkron üzemben működő, wifi modullal rendelkező inverter 3. Gépészet Komplett fűtési rendszer feljlesztése, azaz az épület gépházában helyezük el a kazánokat (2db Fonditál Antea fali kazán (IPX4D), melyek egyenként e=1,0; Q=24,9 kW,q= 2,51 m3/h. Az épület fűtési igénye alapján 2 db kazán szükséges Kaskád léptetéssel, hidraulikus váltón keresztül, tágulási tartályok beépítésével. A kazánok beépítése mellett a szerelvények, fűtéscsövek, fűtőtestek komplett korszerűsítésére sor kerül, amely összhangban van a Felhívás 3.1.1 B) II. a) pontjával.l. (Hungarian)
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The technical preparation of the project is reflected by the fact that the energetic designer prepared the building design documentation and the energy certificates (existing, planned) following the on-site survey and determined the quantifiable results and indicators of the project accordingly. The investment is not subject to authorisation, so the acquisition of these contributions is not relevant. In addition to the above-mentioned engineering tasks, requests from technical inspectors have been made, the name and the eligibility number of the inspector to be used during the implementation of the project are indicated in the detailed description of the project data sheet. The responsibility of project management is the correct implementation of the project by the deadline. For this task, a broad-minded (external) company with significant background experience and expertise will be selected, with sufficient references for the implementation of EU projects of similar scale and development, as the company does not have sufficient experience in the implementation of EU projects. In addition, the information package under the provisions of the Széchenyi 2020 JTI will be implemented. Short technical content of the construction: 1. Architecture Façade and plinth: Dryvit thermal insulation is made on the facade of the building. The thickness of the Austrotherm AT-H80 thermal insulation tiles on the façade is 150 mm, which is attached exactly to the wall structure. The plinth receives a 150 mm thick EPS thermal insulation (Austrotherm Expert Fix) on which resin plaster is applied in anthracite color. Slab insulation: A 2 x 100 mm Austrotherm AT-N100 EPS thermal insulation plate is installed on the top plane of the ceiling structure, on which we place a MIKROLITH glass veil separator layer, on which the rainwater insulation is made on the top plane. SIKAPLAN 15G PVC insulation is made by mechanical fastening. Doors and windows, lights: We want to replace the facade doors. The new doors and windows are constructed in the sizes shown on the design sheet, plastic-structured doors and windows with heat insulated glazing, in white, with a heat transfer factor U=1,15 W/m2K. 2. Solar system: The conditions for the deployment of the system are met. 23 modules are placed on the roof of the building. 60 cell monocrystalline modules in alu frame with 3.2 mm iron-free hardened solar glass, EVA filling, IP65 connector box, solar wire, solar connectors. Designed panel: Risen RSM60-6-310M. Support structure: Stainless steel and aluminium lightweight duct system with connecting elements, for fitting to the PV-generator arrangement, partly with scaffolding and partly parallel to the roof plane. Inverter: 1 (FRONIUS SYMO 7.0-3-M) three-phase 400/3x230V, 50 Hz network synchronous inverter with wifi module 3. Construction of a complete heating system, i.e. installing boilers in the engine room of the building (2pcs Condital Antea wall boiler (IPX4D), each of which is e=1.0; Q=24.9 kW,q= 2.51 m³/h. Based on the heating requirement of the building, 2 boilers are required with Kaskád step, via hydraulic transmission, with expansion tanks installed. In addition to the installation of boilers, complete upgrading of fittings, heating pipes and heaters will take place, which is in line with point 3.1.1(B) II(a) of the Call. (English)
8 February 2022
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Csurgó, Somogy
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Identifiers
GINOP-4.1.4-19-2020-02706
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