CN212506717U

CN212506717U - Passive low-energy-consumption building constructed based on overall process quality control system

Info

Publication number: CN212506717U
Application number: CN202020547957.9U
Authority: CN
Inventors: 马伊硕; 曹恒瑞
Original assignee: Beijing Kang Ju Certification Center
Current assignee: Beijing Kangju Certification Center Co ltd
Priority date: 2020-04-10
Filing date: 2020-04-10
Publication date: 2021-02-09
Anticipated expiration: 2030-04-10

Abstract

The utility model provides a passive form low energy consumption building based on overall process quality control system construction, belongs to the building energy conservation field, including the major structure wall body, the air tight layer, graphite polyphenyl board outer wall heat preservation, passive form external window, rock wool fire prevention median, waterproof ventilative membrane, waterproof vapour barrier, major structure roofing, high unit weight graphite polyphenyl board, major structure basement roof, first extruded polystyrene board, rock wool area, second extruded polystyrene board, the ground structure layer, third extruded polystyrene board, the wall pipeline that wears, the pipeline keeps warm, pre-compaction inflation sealing area, ventilation air conditioning all-in-one system, supply-air outlet, return air inlet, air outlet, circulation wind gap, supply-air duct, return air duct, exhaust duct, circulation air inlet duct. By adopting the technical scheme, the comfort of the indoor environment is effectively improved, the building energy consumption is reduced, and the building energy-saving target of more than 90 percent is realized.

Description

Passive low-energy-consumption building constructed based on overall process quality control system

Technical Field

The invention belongs to the field of building energy conservation, has an international IPC (International Industrial computer) classification number of E04H14/00 or E04B5/16, and particularly relates to a passive low-energy-consumption building constructed based on a whole-process quality control system.

Background

Under the background of global warming and energy shortage, building energy conservation with high energy efficiency and low emission as the core plays a crucial role in realizing energy safety and sustainable development of the country. The passive low-energy-consumption building is a building constructed by combining various passive energy-saving means such as natural ventilation, natural lighting, solar radiation, indoor non-heating heat source heating and the like with the external protective structure heat preservation, heat insulation and energy conservation technologies of the building by fully utilizing natural environment and resources. Two significant characteristics of passive low-energy-consumption buildings are that firstly, the comfort of indoor environment is significantly improved, including indoor thermal comfort (temperature, humidity and air flow rate), indoor air quality, indoor noise level, indoor lighting level and the like; secondly, the energy consumption of the building can be greatly reduced, and the aim of building energy conservation of more than 90 percent is achieved. The passive low-energy-consumption building is developed and popularized, the dependence on an active mechanical heating and refrigerating system is furthest eliminated by greatly reducing the heat/cold load of the building on the premise of ensuring the comfort of indoor environment, the heating and refrigerating energy consumption of the building is further reduced, and meanwhile, renewable energy sources are fully utilized so as to eliminate the dependence on the traditional fossil energy sources, so that the passive low-energy-consumption building becomes an important means leading the energy conservation and emission reduction of the state in the international building energy conservation technology.

The main key technologies for passive low-energy building applications include: 1. the outer heat preservation system of the outer envelope of efficient non-transparent: the heat transfer coefficient K of the roof, the outer wall, the ground or the top plate of the non-heating basement is less than or equal to 0.15W/(m)²K); 2. efficient outer door and window system: the total solar transmittance g of the glass is more than or equal to 0.35, the selectivity coefficient S of the glass is more than or equal to 1.25, and the heat transfer coefficient K of the whole window is less than or equal to 1.0W/(m)²K) glass heat transfer coefficient K is less than or equal to 0.8W/(m)²K) profile heat transfer coefficient K is less than or equal to 1.3W/(m)²K); 3. ventilation system with high efficiency heat recovery device: sensible heat recovery efficiency is more than or equal to 75 percent, total heat recovery efficiency is more than or equal to 70 percent, and ventilation power requirement is less than or equal to 0.45W/(m)³H), the internal air leakage rate is less than or equal to 2 percent, and the external air leakage rate is less than or equal to 2 percent; 4. good building air tightness measures: the method comprises the following steps of (1) setting a building integral air-tight layer, setting a window and wall sealing structure and setting sealing structures of various pipeline openings; 5. the design concept of no heat bridge and the construction mode of the building node are as follows: the anchoring technology of connecting the heat-insulating material with the thickness of more than or equal to 250mm to the bearing wall, the connection technology of the balcony and the main structure without a heat bridge, and the processing technology of the key node structure; 6. the external thermal insulation fireproof technology of the high-thickness external wall: the heat conductivity coefficient lambda of the fireproof material is less than or equal to 0.045W/(m.K), the fireproof material does not spread, does not drip or release toxic gas when meeting fire, and the fireproof isolation strip is arranged on the horizontal surrounding type fireproof isolation strip or three sides of the door and window opening; 7. moisture and water proofing; 8. and (4) noise protection measures.

However, the prior art cannot comprehensively and effectively solve all the problems.

Different from common buildings, the design, construction and operation of passive low-energy-consumption buildings take indoor environment indexes and building energy consumption indexes as constraint targets, and a design method with performance, a refined construction method and an intelligent operation mode are adopted for implementation, so that the refined design, the refined construction and the refined operation are realized.

The quality of passive low energy building projects relates to design quality, material/product quality, equipment quality, construction quality and operation quality at the same time. Therefore, for passive low-energy-consumption building projects, the dynamic management of the whole process is implemented by using a whole-process quality control system and taking an energy efficiency target (namely, a building energy-saving effect) and a comfort target (namely, a building operation effect) of a control building as a core, so that the realization of an expected target is ensured.

In the prior art, CN 104597884A discloses a building energy saving system, a data acquisition module is used for acquiring indoor and outdoor original data information, and transmitting the information to a data processing terminal through a data transmission module; the environment acquisition equipment is arranged in the building and used for acquiring environment parameters in the building; the data transmission module is used for transmitting the acquired data information, and the energy consumption equipment state acquisition module is connected with the data processing terminal.

However, such as the above prior art, only a single energy consumption monitoring system is involved, so as to achieve the effect of monitoring the building energy consumption or the indoor environment in the operation stage; the quality level of the construction project cannot be controlled in the whole process from the aspects of planning, designing, tendering, construction, detection, acceptance, delivery and operation, and even only aiming at the operation stage, the comprehensive control in multiple aspects cannot be realized from the aspects of long-term quality, long-term air tightness, user satisfaction and the like of the construction project.

The energy-saving mechanism of the passive low-energy-consumption building is as follows: the indoor and outdoor temperature difference heat transfer of the building is reduced through an external protective structure without a heat bridge and with excellent heat insulation performance, the solar radiation of the building is adjusted to obtain heat through the Low-E coating technology of external window glass and an effective external sunshade facility, the indoor and outdoor ventilation and permeation heat transfer of the building is reduced through good air tightness measures of the building and a fresh air system with efficient heat recovery, and meanwhile, the heat dissipation of non-heating heat sources of indoor personnel, illumination, equipment and the like is effectively utilized, so that the building can maintain proper indoor thermal comfort under extremely Low auxiliary heating and refrigerating load/energy consumption.

Among the energy-saving mechanisms, an external enclosure structure with superior thermal performance, an effective external sunshade facility and good air tightness measure belong to the energy-saving technology of building enclosures, and a fresh air system with a high-efficiency heat recovery function belongs to the energy-saving technology of equipment. It follows that the energy efficient operation of passive low energy buildings is a result of the co-operation of the building envelope and the ventilation equipment. Under the operation mechanism, the annual heating demand of the passive low-energy-consumption building does not exceed 15 kWh/(m)²A), one tenth to one fourth of the ordinary energy-saving buildings, the annual total primary energy demand (including the primary energy demand of heating, refrigeration, ventilation, domestic hot water, lighting and household appliances) not exceeding 120 kWh/(m)²A). On the basis of the passive low-energy-consumption building, the building with zero energy consumption and even an energy production room can be built by further utilizing renewable energy sources.

Disclosure of Invention

The invention provides a passive low-energy-consumption building constructed based on a whole-process quality control system, which is mainly used for solving the problems of external heat preservation of an enclosure structure, efficiency of an external door and window system, efficiency of a ventilation system, building air tightness and the like on the basis of the defects in the prior art,

it comprises a main structure wall body, an airtight layer, a graphite polystyrene board outer wall heat preservation layer, a passive outer window, a rock wool fireproof isolation belt, a waterproof vapor permeable membrane, a waterproof vapor barrier membrane, a main structure roof, a high volume weight graphite polystyrene board, a main structure basement roof, a first extruded polystyrene board, a rock wool belt, a second extruded polystyrene board, a ground structure layer, a third extruded polystyrene board, a wall penetrating pipeline, a pipeline heat preservation layer, a prepressing expansion sealing belt, a ventilation and air conditioning all-in-one machine system, an air supply opening, an air return opening, an air inlet opening, an air outlet opening, a circulating air opening, an air supply pipeline, an air return pipeline, an air inlet pipeline, an air exhaust pipeline and a circulating air pipeline,

the airtight layer is arranged on the inner side of the main structure wall body, the graphite polystyrene board outer wall heat insulation layer is arranged on the outer side of the main structure wall body, the passive outer window is arranged on the main structure wall body,

rock wool fire prevention median adopt the level to encircle the mode and lay major structure wall body on, rock wool fire prevention median's thickness be 240mm, rock wool fire prevention median's width be 300mm, rock wool fire prevention median's comprehensive heat transfer coefficient be 0.15W/(m²K), the rock wool fireproof isolation belt is laid in a double-layer staggered joint mode, the height of a double-layer lap joint part is more than or equal to 300mm, the height of the lower edge of the double-layer lap joint part from the upper edge of a door/window opening is less than or equal to 500mm,

the main structure basement roof is connected with the main structure wall in a pouring mode, the first extruded polystyrene board is laid on the upper side of the main structure basement roof, the thickness of the first extruded polystyrene board is 70mm, and the dry density is larger than or equal to 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁A stage; the lower side of the main body structure is paved with a rock wool belt, the thickness of the rock wool belt is 50mm, and the heat transfer coefficient is 0.27W/(m)²K) dry density of not less than 100kg/m³The heat conductivity coefficient is less than or equal to 0.045W/(m.K), the acidity coefficient is more than or equal to 1.8, and the combustion performance grade is A grade; the rock wool belt extends from the top plate of the basement to the inner side of the outer wall of the basement, and the extension length is 1 m;

a second extruded polystyrene board is laid on the outer side of the part, below the soil, of the main structure wall, wherein the thickness of the second extruded polystyrene board is 240mm, the laying range of the second extruded polystyrene board is 1m from the outdoor terrace, and the laying range of the second extruded polystyrene board is 500mm from the outdoor terrace; the second extruded polystyrene board has a heat transfer coefficient of 0.13W/(m)²K) is adhered by adopting a heat-insulating material with double-layer staggered joints, and the dry density is more than or equal to 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁A stage;

the outer windowsill is also included, and one layer of the ground structure layer is in contact with soilA third extruded polystyrene board is laid on the lower side of the soil part; the third extruded polystyrene plate has a thickness of 200mm and a heat transfer coefficient of 0.15W/(m)²K) dry density of not less than 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁A stage;

the three-glass two-cavity hollow argon-filled fire-resistant glass window further comprises an outer door and window system, wherein the outer door and window system comprises an aluminum-wood composite profile outer window, a three-glass two-cavity hollow argon-filled fire-resistant glass and a warm edge spacing strip; the heat transfer coefficient K of the whole outer window of the outer door and window system is less than or equal to 1.0W/(m)²K) profile heat transfer coefficient K is less than or equal to 1.3W/(m)²K) glass heat transfer coefficient K is less than or equal to 0.8W/(m)²K), the total solar transmittance g of the glass is 0.35, the glass selectivity coefficient LSG is more than or equal to 1.25, the air tightness of an outer window of the outer door and window system is 8 grades, the water tightness is 6 grades, the air sound insulation performance is 3 grades, and the fire resistance integrity is more than or equal to 0.50 h;

the outer door and window is installed in a manner of being tightly attached to the outer side of the structural wall body, a joint between the outer door and window frame and the structural wall body is sealed by a door and window opening sealing system, and the door and window opening sealing system comprises a waterproof vapor-barrier film, a waterproof vapor-permeable film and an adhesive; the waterproof vapor-barrier film is arranged on one indoor side, and the waterproof vapor-permeable film is arranged on one outdoor side; one side of each of the waterproof vapor-barrier film and the waterproof vapor-permeable film is effectively adhered to the side surface of the door and window frame or the attached frame, the other side of each of the waterproof vapor-barrier film and the waterproof vapor-permeable film is adhered to the structural wall, and the overlapping width of the waterproof vapor-barrier film or the waterproof vapor-permeable film is not less than 100 mm; the external wall is covered with a door and window frame in a heat-insulating way, and the width of the exposed part of the door and window frame is reserved for 15 mm; the outer windowsill is provided with a metal windowsill plate, the metal windowsill plate is structurally connected with the lower opening of the window frame and is embedded into the lower opening of the window frame by 10-15 mm; the lower edge of the metal window board is provided with a water dripping line; sealing the joint between the lower side of the metal window board and the outer wall heat-insulating layer by adopting a pre-pressed expansion sealing tape; the end heads at the two sides of the metal window board are turned upwards and embedded into the outer wall heat insulation layer of the window side opening by 20-30 mm; sealing joints between the upturned ends on the two sides of the metal window board and the outer wall heat insulation layer by adopting a prepressing expansion sealing tape;

also comprises a ventilation and air conditioning integrated machine with a heat recovery deviceThe system is characterized in that the heat recovery device adopts a total heat recovery machine core, the total heat recovery efficiency is more than or equal to 70 percent, the sensible heat recovery efficiency is more than or equal to 75 percent, and the unit air volume fan power of the heat recovery device is not more than 0.45Wh/m³The fresh air inlet and the return air inlet are provided with filters, the grade of the fresh air inlet filter is not less than G4+ F8 grade, the grade of the return air inlet filter is not less than G4 grade, the internal air leakage rate of the fresh air system is less than 2 percent, and the external air leakage rate is less than 2 percent; the fresh air pipeline leading to the outdoor is coated with a rubber-plastic heat-insulating layer with the thickness of 80mm, the exhaust pipeline leading to the outdoor is coated with a rubber-plastic heat-insulating layer with the thickness of 60mm, and the indoor air supply pipeline is coated with a phenolic aldehyde heat-insulating layer with the thickness of 20 mm; the indoor unit and the outdoor unit are respectively provided with an independent condensate vertical pipe, and the condensate vertical pipe adopts a rubber-plastic heat-insulating sleeve with the thickness of 20 mm;

the ventilation and air-conditioning integrated machine system also comprises a compressor, a fresh air fan, an indoor temperature controller and a carbon dioxide monitoring point, wherein the compressor adopts a frequency conversion technology, the fresh air fan adopts a stepless speed regulation EC fan, and the indoor temperature controller and the carbon dioxide monitoring point are arranged in a living room;

the graphite polyphenyl board outer wall heat insulation layer is formed by paving a plurality of graphite polyphenyl board heat insulation boards, the width of each graphite polyphenyl board heat insulation board is 600mm, the length of each graphite polyphenyl board heat insulation board is 1200mm, the graphite polyphenyl boards are paved in a double-layer staggered joint mode, and the dry density of each graphite polyphenyl board is more than or equal to 20kg/m³The heat conductivity coefficient of the graphite polystyrene board is less than or equal to 0.032W/(m.K), and the combustion performance grade B of the graphite polystyrene board₁A stage;

the main structure roof is arranged on the main structure wall, the high volume weight graphite polyphenyl board is laid on the main structure roof, the thickness of the high volume weight graphite polyphenyl board is 250mm, and the heat transfer coefficient is 0.14W/(m)²K) is paved by adopting a two-layer staggered joint mode, the dry density is more than or equal to 30kg/m3, the compressive strength is more than or equal to 200kPa, the heat conductivity coefficient is less than or equal to 0.033W/(m.K), and the combustion performance grade is B₁A stage;

by adopting the technical scheme, the comfort of the indoor environment is effectively improved, and the comfort comprises indoor thermal comfort (temperature, humidity and air flow rate), indoor air quality, indoor noise level, indoor lighting level and the like; meanwhile, the energy consumption of the building is reduced, and the aim of building energy conservation of more than 90% is achieved. Besides, the design concept without a heat bridge and the construction mode of the building node, the anchoring technology of connecting the heat-insulating material with the thickness of more than or equal to 250mm to the bearing wall, the connection technology of the balcony and the main structure without the heat bridge, and the processing technology of the key node structure; the external thermal insulation fireproof technology of the high-thickness external wall: the heat conductivity coefficient lambda of the fireproof material is less than or equal to 0.045W/(m.K), the fireproof material does not spread, drip or release toxic gas when meeting fire, and the arrangement technology of the horizontal surrounding type fireproof isolation strip or the fireproof isolation strips at three sides of the door and window opening can obtain better effects of moisture resistance, water resistance and noise protection.

In addition, aiming at the problems, the invention also provides a passive construction overall process quality control system based on a construction engineering dynamic management method, which is used for carrying out quality control on the overall process of decision planning, reconnaissance design, bid procurement, construction installation, detection and inspection, completion acceptance and delivery operation of the passive low-energy-consumption construction.

The passive building overall process quality control system based on the construction engineering dynamic management method comprises an index system database, a support platform, a platform layer, a network layer and a sensing layer;

the index system database comprises building energy efficiency level index system databases of different climate zones in the country, building indoor comfort level index system databases of different climate zones in the country, building outer enclosure structure index system databases of different climate zones in the country, equipment parameter index system databases of different climate zones in the country, building air tightness index system databases of different climate zones in the country, a passive low-energy-consumption building standard building node structure design database and a building material index system database suitable for passive low-energy-consumption buildings;

the support platform comprises an overall process quality control online management support platform and an operation data monitoring platform;

the platform layer comprises a computer and a mobile phone;

the network layer comprises a mobile network, the Internet and an internal wireless network;

the sensing layer comprises a camera, a blast door device, a thermal infrared imager, a temperature sensor, a humidity sensor, a carbon dioxide concentration sensor, a PM2.5 concentration sensor, a PM10 concentration sensor, a formaldehyde concentration sensor, a VOC concentration sensor, an ozone concentration sensor, a noise sensor and an energy metering device;

the index system database is used for storing building energy efficiency level index system data of different climate zones in the country, building indoor comfort level index system data of different climate zones in the country, building outer enclosure structure index system data of different climate zones in the country, equipment parameter index system data of different climate zones in the country, building air tightness index system data of different climate zones in the country, passive low-energy-consumption building standard building node structure design data and building material index system data suitable for passive low-energy-consumption buildings;

the camera is arranged on an observation point set at the periphery of the passive low-energy-consumption building, or on a field handheld camera device, or on a safety helmet;

the air blowing door equipment is used for acquiring wind speed and pressure test data in the building air tightness test process;

the thermal infrared imager is used for shooting an infrared thermal imaging photo of the building envelope, and displaying and analyzing the thermal performance and the thermal defects of each position and node of the building envelope;

the temperature sensor, the humidity sensor, the carbon dioxide concentration sensor, the PM2.5 concentration sensor, the PM10 concentration sensor, the formaldehyde concentration sensor, the VOC concentration sensor, the ozone concentration sensor, the noise sensor and the energy metering device are used for collecting indoor environment data and building energy consumption data, and the indoor environment data and the building energy consumption data are transmitted back to the system platform layer through a mobile network, the Internet and an internal wireless network;

the passive low-energy-consumption building overall process quality control system based on the construction engineering dynamic management method comprises the following steps of:

step 1: establishing an index system database so as to evaluate the energy efficiency level, the technical scheme and the operation condition of the target building based on the database;

step 1.1: building an index system database of building energy efficiency levels of different climate areas in the country and an index system database of building indoor comfort levels of different climate areas in the country;

step 1.2: establishing index system databases of building outer enclosing structures in different climatic regions in the country, wherein the index system databases comprise a non-transparent outer enclosing structure thermal performance index system database and a transparent outer enclosing structure thermal performance index system database;

step 1.3: establishing equipment parameter index system databases of different climate zones in the country, wherein the equipment parameter index system databases comprise a fresh air system, a heating system and a refrigerating system;

step 1.4: building a database of building air tightness index systems of different climatic regions in the country;

step 1.5: establishing a passive low-energy-consumption building standard building node structure design database;

step 1.6: building a building material index system database suitable for passive low-energy-consumption buildings;

step 2: arranging an online design training module on a system platform;

and step 3: generating a preliminary design drawing;

step 3.1: generating a design task book by a system platform;

step 3.2: finishing a primary design drawing and uploading the primary design drawing to a system platform;

and 4, step 4: performing energy efficiency analysis and drawing verification on the building, and optimizing a construction drawing design;

step 4.1: based on a preliminary design drawing of a building, a system platform carries out building energy efficiency analysis, searches sensitivity analysis and optimized parameters of key parameters of the building and equipment, and generates a technical scheme;

step 4.2: the system platform checks the preliminary design drawing;

step 4.3: generating a construction drawing design drawing based on the technical scheme and the preliminary design drawing auditing result;

step 4.4: designing a drawing based on a construction drawing of a building, and carrying out building energy efficiency analysis by a system platform to determine a building energy efficiency index;

step 4.5: the system platform carries out construction drawing verification, carries out optimization design on the wall body and the node structure of the building, and carries out optimization design on heating, refrigerating, ventilating, domestic hot water, lighting, electrical and renewable energy systems;

step 4.6: judging whether the passive low-energy-consumption building requirements are met or not based on a passive low-energy-consumption building energy efficiency level index system database, a building peripheral protective structure index system database, an equipment parameter index system database and a standard building node construction design database; when the requirements are not met, modifying the construction drawing design drawing, regenerating the construction drawing design drawing, and carrying out building energy efficiency analysis and drawing verification again until the requirements of the passive low-energy-consumption building are met;

and 5: the system platform carries out construction training, broadcasts videos of sample boards or construction method walls, explains construction methods of an external heat insulation system, a roof heat insulation waterproof system, a door and window system and an air tightness system of a passive low-energy-consumption building, and broadcasts construction operation methods of building nodes;

step 6: based on a thermal performance index system database, an equipment parameter index system database and a building material index system database of the transparent outer enclosing structure, the controllability index threshold of key materials, products and systems of a target building is determined, a construction site camera is adopted to randomly sample, seal and check the materials, products and systems entering a field, a detection report is input to a system platform, and the selected materials, products and systems are compared and controlled to meet the requirement of the technical index threshold;

and 7: a construction site camera or a sensor collects construction site pictures or videos, and the construction site pictures or videos are transmitted back to a system platform through a mobile network or the internet to control the quality of key nodes in the construction process of the building;

step 7.1: a construction site camera or a sensor collects construction site pictures or videos, the construction site pictures or videos are transmitted back to a system platform through a mobile network or the internet, the working procedures and the construction methods related to the key construction building of the passive low-energy-consumption building are monitored in real time, and whether the requirements of the passive low-energy-consumption building are met is judged;

step 7.2: when the requirements are not met, the system platform generates a site construction quality monitoring and checking report and outputs a problem and a rectification mode;

step 7.3: the construction site camera or the sensor is used for acquiring construction site pictures or videos and monitoring the rectification process and the effect of the building in real time until the requirements of the passive low-energy-consumption building are met;

and 8: building detection is carried out, and the system platform controls the building detection;

step 8.1: the construction site camera or the sensor and the blast door equipment are used for collecting construction detection site pictures, videos and wind speed and pressure test data of the blast door equipment, and the data are transmitted back to a system platform through a mobile network or the internet to monitor the implementation process of the construction air tightness test in real time;

step 8.2: carrying out infrared thermal imaging test on the building, wherein the construction site camera collects construction site pictures and videos and infrared thermal imaging pictures, and transmits the pictures back to the system platform through a mobile network and the Internet to monitor the implementation process of the infrared thermal imaging test of the building in real time;

step 8.3: based on the building air tightness index system database and the standard building node construction design database, checking detection data, confirming detection quality and detection results, and judging whether the building meets the requirements of a passive low-energy-consumption building;

step 8.4: when the requirements are not met, generating leakage performance and thermal performance modification items of the building, and monitoring the modification process and effect of the building in real time until the requirements of the passive low-energy-consumption building are met;

and step 9: performing building acceptance, including on-line on-site acceptance and data acceptance;

step 9.1: a building site camera and a sensor are adopted to collect a building site picture or video, the picture or video is transmitted back to a system platform through a mobile network or the internet, the construction quality of the building site is checked and accepted, and a quality acceptance report is generated;

step 9.2: the system platform audits the construction process file, and if the construction process file is missing, the system platform performs additional entry until the audit of the verification data is completed;

step 10: after the step 1 to the step 9 are executed, the system platform generates a quality authentication certificate of the target building and transmits the quality authentication certificate to a receiving end through a mobile network or the internet;

step 11: generating a passive low-energy-consumption building use instruction manual suitable for a property management unit and a user on a system platform aiming at a target building, wherein the building use instruction manual is used for explaining building characteristics and use cautions;

step 12: a building site sensor and an energy metering device are adopted to collect 24-hour monitoring data of indoor environment and building energy consumption, and the 24-hour monitoring data are transmitted back to a system platform through a mobile network and the Internet to calculate the operation effect of the monitored building;

step 13: the method comprises the following steps of (1) acquiring photos and videos of the integrity of a peripheral protective structure, a building node structure and waterproof drainage measures of a building site by adopting a building site camera and a sensor, and transmitting the photos and videos back to a system platform through a mobile network or the Internet;

step 14: carrying out building air tightness test again after the building is operated for 1 year, collecting building detection site pictures, videos and wind speed and pressure test data of the air blowing door equipment by adopting a building site camera, a sensor and the air blowing door equipment, and transmitting the data back to a system platform through a mobile network and the Internet to carry out the air tightness test of the building in the operation process;

step 15: the system platform generates an actual experience questionnaire of a building user;

step 16: analyzing and evaluating the data collected in the steps 11 to 15 based on building energy efficiency level index system databases of different climate zones across the country, building indoor comfort level index system databases of different climate zones across the country and building air tightness index system databases of different climate zones across the country, and judging whether the passive low-energy-consumption building requirements are met; when the requirements are not met, the building and equipment system is subjected to iterative calculation and adjustment until the requirements of the passive low-energy-consumption building are met;

and step 17: and generating operation authentication of the building on the system platform aiming at the building which finishes executing the steps 11 to 16, and transmitting the operation authentication to a receiving end through a mobile network or the Internet.

Further, the database of the thermal performance index system of the non-transparent outer protective structure comprises an outer wall, a roof, the ground, a top plate of a non-heating basement, an overhead floor slab, an outer wall of the basement, a partition wall for separating heating space from non-heating space, a stair partition wall, a partition wall and a thermal performance index system database of the floor slab; the database of the thermal performance index system of the transparent outer enclosing structure comprises a door and window, a curtain wall and a glass thermal performance index body coefficient database; the design task comprises an indoor environment design index, a building energy efficiency design index and a building performance design requirement; the preliminary design drawing comprises an airtight layer material and position, a heat insulation layer material and position, a building design of a building envelope and a comprehensive energy scheme; the process files comprise qualification files, design files, technical files, inspection files of each stage, detection reports and acceptance files; the indoor environment comprises indoor temperature, relative humidity, carbon dioxide concentration, PM2.5 concentration, PM10 concentration, formaldehyde concentration, VOC concentration, ozone concentration and noise index; the building energy consumption comprises heating ventilation air conditioning, lighting, domestic hot water and the subentry energy consumption of electrical equipment;

furthermore, the receiving end is a client certificate receiving platform; the air tightness test is a blast door test.

By adopting the technical scheme, the following technical effects are realized: the building use instruction manual provides technical instructions for operation, maintenance and use of the building; auditing the energy efficiency measure results, and optimizing the non-ideal flow; monitoring the long-term quality level and maintenance level of the building in the operation process in real time; carrying out building air tightness test again after the building operates for 1 year, auditing detection data, confirming detection quality and detection results, and evaluating the long-term air tightness performance of the building; the practical experience questionnaire of the user pays attention to soft indexes of user experience, and gives questions aiming at the building body and the indoor environment of the building, and the mobile phone client of the system platform is utilized to implement comprehensive evaluation of the satisfaction degree of the user on the building. Therefore, overall quality control of high-energy-efficiency buildings with extremely high requirements on refinement levels, such as passive low-energy-consumption buildings, in the processes of decision planning, reconnaissance design, bid procurement, construction installation, detection inspection, completion acceptance inspection and delivery operation can be realized, the control targets of the energy efficiency and indoor comfort of projects are realized, and the improvement in the construction stage and the operation stage is realized.

Drawings

FIG. 1 is a schematic view of a passive low energy consumption building plan;

FIG. 2 is an enlarged view of a portion of FIG. 1;

FIG. 3 is a schematic view of passive low-energy-consumption building wall insulation;

FIG. 4 is a cross-sectional view of a passive low-energy building wall;

FIG. 5 is a cross-sectional view of a passive low-energy-consumption building roof and wall connection node;

FIG. 6 is a cross-sectional view of a passive low-energy-consumption building basement roof and wall connection node;

FIG. 7 is a sectional view of a connection node between the ground and the wall of the passive low-energy-consumption building;

FIG. 8 is a sectional view of a passive low energy consumption building exterior window installation node;

FIG. 9 is a cross-sectional view of a passive low-energy building pipe through-wall joint;

FIG. 10 is a plan view of a system layout of a passive low-energy-consumption integrated ventilation and air-conditioning system for a building;

FIG. 11 is a partially enlarged view of FIG. 10

FIG. 12 is a block diagram of a system for controlling the overall process quality of a passive building

FIG. 13 is a flow chart of a method of an embodiment of a passive building overall process quality control system

FIG. 14 is a schematic diagram of the overall process of the passive building overall process quality control system

FIG. 15 is a flow chart of the application of the passive building overall process quality control system

FIG. 16 is a flow chart of the application of the passive building overall process quality control system

1-main structure wall; 2-an air barrier; 3-graphite polyphenyl board outer wall heat insulation layer; 4-passive external window; 5-rock wool fire prevention isolation zone; 6-waterproof and vapor-permeable membrane; 7-waterproof vapor barrier film; 8-main structure roof; 9-high volume weight graphite polystyrene board; 10-main structure basement top plate; 11-first extruded polystyrene board; 12-rock wool band; 13-a second extruded polystyrene board; 14-a ground structure layer; 15-third extruded polystyrene board; 16-through-wall piping; 17-pipe insulation layer; 18-prepressing expansion sealing tape; 19-integrated ventilation and air conditioning system; 20-air supply outlet; 21-return air inlet; 22-air intake; 23-air outlet; 24-circulating tuyere; 25-air supply duct; 26-return air duct; 27-an air inlet pipeline; 28-non-wind duct; 29-circulating air pipeline.

Detailed Description

The description is illustrated by a passive low-energy consumption building with reference to the attached drawings 1-11, and the basic data are as follows: 18 layers above the ground and 2 layers below the ground, the building height is 55.35m, and the building area is 9497.92m²The structure is in a shear wall structure. The planned number of households is 72 households, the planned population is 3 persons/household, the body type coefficient is 0.32, and the area ratios of the east, south, west and north window walls are 0.30, 0.60, 0.30 and 0.38 respectively.

The passive low-energy-consumption building has the following passive low-energy-consumption processing region ranges: 1-18 floors above ground, the elevator car on the roof floor, and the underground portion of the elevator car on the north side floor.

The passive low-energy-consumption building is characterized in that: (1) the air tightness of the building is ensured, unnecessary ventilation heat loss caused by unexpected air flow permeation is avoided, and meanwhile, the situations that the living quality and the comfort degree are influenced due to the fact that the indoor local temperature is reduced and the relative humidity is insufficient due to cold air permeation are avoided; (2) an efficient outer heat insulation system of the non-transparent outer enclosure structure is adopted, so that the outer enclosure structure is ensured to have balanced heat insulation, heat inertia, heat storage, vapor permeability, air tightness and other performances, and meanwhile, the systematicness, compatibility and durability are considered; (3) the high-performance external door and window system is adopted, the door and window system integrates multiple visual angle design requirements such as sanitation, energy efficiency, comfort and the like, and meanwhile, the thermal performance of an installation mode is emphasized; (4) executing a design concept without a heat bridge and a building node construction mode, thereby ensuring the balance of indoor temperature, avoiding the phenomena of condensation and too low local temperature, and realizing that heat dissipation of indoor personnel, illumination, household appliances and the like can be considered as a stable heat source of a building through refined energy throttling management; (5) have high-efficient heat recovery unit's ventilation air conditioner all-in-one system, become the ventilation of organizing with artificial ventilation, ensure indoor air quality through intelligent control, retrieve heat and moisture content in the exhaust air, cyclic utilization has refrigeration, heating function simultaneously concurrently.

The building air tightness area is that the whole building is provided with a continuous and complete air tight layer surrounding the whole heating volume. The masonry wall part on the boundary of the airtight area range adopts a plastering layer with the thickness of more than or equal to 15mm on the inner surface of the masonry wall as an airtight layer; the concrete structure part on the boundary of the airtight area range, the concrete wall, the beam column, the floor slab and the roof can be used as an airtight layer. The plastering layer on the inner surface of the masonry wall body as the airtight layer is connected with a reinforced concrete roof panel, a floor slab or the ground to form a complete closed airtight area. The doors and windows on the boundary of the airtight range are passive windows and passive doors which meet the passive requirements; the door and window opening executes an air tightness installation mode, and a gap between the outer door and the outer window and the structural wall is sealed by a waterproof steam-insulating film (indoor side) and a waterproof steam-permeable film (outdoor side) with good durability. The wall-through pipeline opening on the boundary of the air tightness range is constructed according to an air tightness processing method, one end of a waterproof steam-isolating membrane (indoor side) and one end of a waterproof steam-permeable membrane (outdoor side) are pasted on a wall body, the other end of the waterproof steam-permeable membrane (outdoor side) is pasted on a pipeline, and the pasting width is more than or equal to 40 mm.

The efficient outer heat insulation system of the non-transparent outer enclosure structure is characterized in that a graphite polyphenyl plate with the thickness of 240mm is laid on a main structure wall body, and a horizontal surrounding type rock wool fireproof isolation belt with the thickness of 240mm and the width of 300mm is matched with the graphite polyphenyl plateIs arranged on a main structure wall body, and the comprehensive heat transfer coefficient reaches 0.15W/(m)²K); the graphite polystyrene board is laid by double-layer staggered joints, and the dry density is more than or equal to 20kg/m³Thermal conductivity coefficient is less than or equal to 0.032W/(m.K), and combustion performance grade B₁A stage; the rock wool fireproof isolation belt is paved in a double-layer staggered joint mode, the height of a double-layer lap joint part is more than or equal to 300mm, and the height of the lower edge of the double-layer lap joint part from the upper edge of a door and window opening is less than or equal to 500 mm; the outer wall external heat insulation system adopts systematized accessories, and the durability of the system is ensured.

The high-efficiency outer heat insulation system of the non-transparent outer enclosure structure adopts a high-volume-weight graphite polyphenyl plate with the thickness of 250mm to be laid on the roof of the main structure, and the heat transfer coefficient reaches 0.14W/(m)²K); the high volume weight graphite polyphenyl plate is laid by two layers of staggered joints, the dry density is more than or equal to 30kg/m3, the compressive strength is more than or equal to 200kPa, the heat conductivity coefficient is less than or equal to 0.033W/(m.K), and the combustion performance grade B₁And (4) stages.

The efficient outer heat preservation system of the non-transparent outer enclosure structure adopts a first extruded polystyrene board with the thickness of 70mm to be laid on the upper side of the top plate of the basement of the main structure, adopts a rock wool belt with the thickness of 50mm to be laid on the lower side of the top plate of the basement of the main structure, and the heat transfer coefficient reaches 0.27W/(m)²K). The dry density of the first extruded polystyrene board is more than or equal to 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁And (4) stages. The dry density of the rock wool belt is more than or equal to 100kg/m³The heat conduction coefficient is less than or equal to 0.045W/(m.K), the acidity coefficient is more than or equal to 1.8, and the combustion performance grade is A grade. The 50mm thick rock wool area of basement roof downside extends to basement outer wall inboard from the basement roof, and extension length is 1 m.

The efficient non-transparent outer envelope structure outer heat insulation system is characterized in that a second extruded polystyrene board with the thickness of 240mm is paved on the outer side of a main structure wall body buried under soil, the paving range is 1m from an outdoor terrace to extend upwards for 500mm from the outdoor terrace. The heat transfer coefficient reaches 0.13W/(m)²K); the heat insulating material is adhered in double-layer staggered joint with dry density not less than 30kg/m³The heat conductivity coefficient is less than or equal to 0.030W/(m.K), and the combustion performance grade is B1 grade.

The high-efficiency non-transparent outer enclosure structure outer heat insulation system adopts a third extruded polystyrene board with the thickness of 200mm to be pavedIs arranged at the lower side of a ground structure layer contacting with soil, and the heat transfer coefficient reaches 0.15W/(m)²K); the dry density of the third extruded polystyrene board is more than or equal to 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁And (4) stages.

The high-performance outer door and window system adopts an aluminum-wood composite profile outer window, argon refractory glass is filled in a hollow cavity of two cavities of three glass layers, and a warm edge spacing strip with good durability is adopted. The heat transfer coefficient K of the whole outer window is less than or equal to 1.0W/(m)²K) profile heat transfer coefficient K is less than or equal to 1.3W/(m)²K) glass heat transfer coefficient K is less than or equal to 0.8W/(m)²K), the total solar transmittance g of the glass is 0.35, and the glass selectivity coefficient LSG is more than or equal to 1.25. The air tightness of the outer window is 8 grades, the water tightness is 6 grades, the sound and sound insulation performance of the air is 3 grades, the test of repeatedly opening and closing the outer window for 1 ten thousand times has no abnormity, and the use is free of obstacles. The fire resistance integrity is not less than 0.50 h.

The design idea of no heat bridge and building node construction mode, outer door and window should hug closely the installation of structure wall body outside, the seam between outer door and window frame and the structure wall body should adopt the good door and window entrance to a cave sealing system that comprises waterproof vapour barrier film, waterproof ventilative membrane and special adhesive of durability to seal. The waterproof vapor-barrier film is used on one indoor side, and the waterproof vapor-permeable film is used on one outdoor side. The waterproof vapor-barrier film and the waterproof vapor-permeable film are adhered to the side surface (vertical surface of the wall) of the door and window frame or the auxiliary frame on one side and the structural wall on the other side, and are covered on the structural wall and the door and window frame or the auxiliary frame in a loose (non-tight) state. The lapping width of the waterproof vapor-barrier film or the waterproof vapor-permeable film is not less than 100 mm. The external wall heat preservation covers the door and window frame as far as possible, and the width of the exposed part of the door and window frame is reserved for 15 mm. The outer windowsill should set up the good metal window board of durability, avoids the rainwater to corrode the destruction that causes the heat preservation, and outdoor metal window board should have structural connection with the window frame end opening to the embedding advances window frame end opening 10 ~ 15 mm. The lower edge of the metal window board is provided with a water dripping line. The joint between the lower side of the metal window board and the outer wall heat-insulating layer is sealed by a prepressing expansion sealing tape. The end heads of the two sides of the metal window board are turned upwards and embedded into the outer wall heat insulation layer of the window side opening by 20-30 mm. The joints of the upturned ends at the two sides of the metal window board and the outer wall heat-insulating layer are sealed by adopting a prepressing expansion sealing strip.

The ventilation and air conditioning integrated machine system with the efficient heat recovery device provides fresh air quantity which meets the requirement that each person is 30m per hour³The air quantity adjusting device has the air quantity adjusting function, can automatically adjust the air quantity according to indoor conditions, and can also realize the manual adjusting function. Can realize automatic start-stop according to indoor carbon dioxide concentration. The fresh air heat recovery system adopts a total heat recovery machine core, the total heat recovery efficiency is more than or equal to 70 percent, and the sensible heat recovery efficiency is more than or equal to 75 percent. The unit air volume fan power of the heat recovery device is not more than 0.45Wh/m³. The outdoor fresh air and air outlet are provided with a primary filter screen capable of filtering large granular substances, winged insects and the like, the fresh air inlet and the return air inlet are provided with filters, the grade of the filter of the fresh air inlet is not less than G4+ F8 grade, the grade of the filter of the return air inlet is not less than G4 grade, and the outdoor fresh air and air outlet have a replacement prompting function. The air leakage rate in the fresh air system is less than 2%, and the air leakage rate in the fresh air system is less than 2%. The fresh air pipeline leading to the outdoor is coated with rubber and plastic with the thickness of 80mm for heat preservation, the exhaust pipeline leading to the outdoor is coated with rubber and plastic with the thickness of 60mm for heat preservation, and identification is carried out on site for distinguishing; the indoor air supply pipeline is coated with phenolic aldehyde with the thickness of 20mm for heat preservation. The indoor unit and the outdoor unit are respectively provided with an independent condensate water vertical pipe for collecting and discharging condensate water generated by the unit. The condensate pipe adopts a 20mm thick rubber and plastic heat-insulating sleeve.

The ventilation and air conditioning integrated machine system with the efficient heat recovery device is characterized in that each apartment is provided with one set, and air supply openings are arranged in bedrooms, living rooms and dining rooms and are connected with equipment through air supply pipelines; each toilet is provided with an air return port which is connected with the equipment through an air return pipeline; a circulating air port is arranged in a restaurant or a corridor and is connected with equipment through a circulating air pipeline; holes are formed in the outer wall of each household to serve as an air inlet and an air outlet, and fresh air is obtained from the outside or dirty air after heat recovery is exhausted from the outside. The air inlet pipeline and the air outlet pipeline are provided with heat-insulating closed electric valves which are interlocked with the fan to ensure the air tightness of the building. Outdoor fresh air enters the equipment through an air inlet pipeline, the fresh air after treatment (heat exchange, haze removal, cooling, temperature rise, dehumidification and the like) is sent into each room through an air supply pipeline, is responsible for treating cold and heat loads of each room, dilutes indoor carbon dioxide, overflows to a toilet through a room door gap or an air guide groove, enters a heat exchange core of the equipment through an air return port of the toilet, performs heat exchange with the outdoor fresh air, and is discharged outdoors through an exhaust pipeline. When the indoor cold (heat) load is large, the circulating air is started, the indoor cold and heat load can be quickly reduced by the circulating air, and the minimum fresh air quantity required in the room is also included when the circulating air is started. The wind speed of the indoor main wind pipe is 3-4 m/s; the wind speed of the branch wind pipe is not more than 2 m/s; the air speed of the air supply outlet is 1.5-3 m/s; the air speed of the return air inlet is not more than 4 m/s; the air speed of an outdoor air inlet is 2-4 m/s; the air speed of an outdoor air outlet is 3-5 m/s; the indoor air flow rate is not more than 0.15 m/s.

The ventilation and air conditioning integrated machine system with the efficient heat recovery device is characterized in that the compressor adopts a frequency conversion technology, the fresh air fan adopts a stepless speed regulation EC fan, and the control system supports multiple partitions and multiple indexes (temperature, humidity, carbon dioxide and PM)_2.5) And (4) independently controlling. The system carries out regional and variable air volume intelligent control according to indoor real-time cold and heat load, fresh air volume demand, cleanliness and the like. The indoor temperature controller and the carbon dioxide monitoring point are arranged in the living room.

The ventilation and air-conditioning integrated machine system with the efficient heat recovery device operates according to the following modes:

(1) a comfort mode. The comfort control is carried out on the indoor environment according to the highest sanitary and health standard. In the aspect of air source use, outdoor fresh air is used as far as possible to bear the requirements of indoor cooling and heating and pollutant concentration reduction. The air flow is organized such that fresh air first enters the bedroom, then flows to the living room, and finally is discharged from the bathroom to the outside. The use of circulating air is avoided as much as possible, and cross contamination caused by wind cross among bedrooms is reduced to the maximum extent.

Under normal working conditions, when the temperature is within a set range of +/-2 ℃, or PM_2.5The concentration is 50-115 mu g/m³Floating, or the relative humidity is more than 70 percent, or the carbon dioxide concentration is more than 1000PPM, and the system only uses fresh air with adjusted temperature (when needed) to optimize the indoor air quality.

In the following cases, where comfort and health are seriously affected, the circulating wind is turned on,increase total amount of wind to improve indoor air quality fast: when PM in room_2.5The concentration exceeds the national third-level standard, namely 115 mu g/m³When the current is over; when the indoor temperature exceeds the set value +/-2 ℃; when the indoor relative humidity exceeds 80%.

(2) And (4) an energy-saving mode. The energy consumption is reduced as much as possible while meeting the basic hygienic and health needs. In the aspect of air source use, indoor circulating air can be used to bear the requirements of indoor cooling and heating and pollutant concentration reduction. And only when the concentration of the carbon dioxide exceeds the standard or the minimum ventilation volume per day needs to be met, fresh air is conveyed indoors. The air flow of the circulating air is organized in such a way that the circulating air is taken from the living room, is filtered and temperature-regulated, then is sent to the bedroom, and then flows back to the living room. In this mode, the pollutants in each area are mixed together and diluted together in the apartment complex, with the risk of cross-contamination. But as the circulating air is also filtered, the basic hygienic requirements can be met.

Under normal working conditions, when the temperature is within a set range of +/-2 ℃, or PM_2.5When the concentration exceeds the standard, or the relative humidity is more than 70%, the system utilizes the circulating air as an air source to improve the indoor air quality, and whether the fresh air is mixed depends on the concentration of carbon dioxide. When the indoor temperature exceeds the set value +/-2 ℃, or the relative humidity is more than 80%, the unit adopts the maximum cooling heat, namely fresh air and circulating air, so as to quickly adjust the temperature and the humidity.

The energy consumption test of the heating period and the refrigerating period is carried out on the building test sample, and the test comparison result is as follows:

terminal energy consumption analysis

The energy source used in the sample chamber (two-layer east chamber, 132m 2; two-layer west chamber, 134m2) was only electric energy. Three electric meters are used for respectively metering the electricity consumption of an air-conditioning fresh air unit (comprising heating, refrigerating and ventilating electricity consumption), a lamp (comprising lighting electricity consumption), a socket (comprising household appliances, cooking and domestic hot water electricity consumption), and the actual electricity consumption in each test period is shown in table 1.

TABLE 1 statistics of electricity consumption

And on the basis of the data of the second heating period and the refrigerating period, the daily average power consumption of the air-conditioning fresh air unit is about 13 degrees/day in the heating period in winter, and the daily average power consumption of the air-conditioning fresh air unit is about 6 degrees/day in the refrigerating period in summer.

Energy use cost analysis

According to the result of the electricity consumption metering, the electricity consumption cost of heating and refrigeration (including fresh air) in the whole heating period or the refrigeration period is calculated and compared with the energy consumption cost of heating and refrigeration of common residential buildings, and the comparison result is shown in table 2. The electricity charge in the meter is calculated according to 0.52 yuan/degree, and the municipal central heating charge of the common residential building is calculated according to 0.24 yuan/m²The heating area is calculated according to 70% of the building area, and the refrigeration cost is calculated according to the electricity charge of 5 hours of the air conditioner which consumes 0.8 degree/hour of electricity.

TABLE 2 energy cost analysis

Compared with the common residential building adopting a central heating mode, the passive low-energy-consumption building has the advantages that the heating cost can be reduced by 70-80%, and the refrigeration cost can be reduced by 50-60%. Taking the eastern room energy consumption cost of the second heating period and the second cooling period as an example for analysis, the heating and cooling (including fresh air) energy consumption cost of the passive low-energy consumption building is 1007 yuan and 189 yuan respectively, the corresponding common residential heating and cooling energy consumption cost is 3371 yuan and 374 yuan respectively, and the cost of 2364 yuan and 185 yuan is higher than that of the passive room in the single heating period and the single cooling period.

The heating and cooling costs saved by the passive low-energy-consumption building are respectively about 0.13 yuan/m according to the average level²Daily, 0.02 yuan/m²The day is.

As shown with reference to figure 12 of the drawings,

the invention provides a passive building overall process quality control system based on a construction engineering dynamic management method, which comprises an index system database, a support platform, a platform layer, a network layer and a perception layer;

the platform layer comprises a computer and a mobile phone;

the sensing layer comprises a camera, a blast door device, a thermal infrared imager, a temperature sensor, a humidity sensor, a CO2 concentration sensor, a PM2.5 concentration sensor, a PM10 concentration sensor, a formaldehyde concentration sensor, a VOC concentration sensor, an ozone concentration sensor, a noise sensor and an energy metering device;

temperature sensor, humidity transducer, CO2 concentration sensor, PM2.5 concentration sensor, PM10 concentration sensor, formaldehyde concentration sensor, VOC concentration sensor, ozone concentration sensor, noise sensor and energy metering device are used for gathering indoor environment data and building energy consumption data, pass back to system platform layer through mobile network, internet and inside wireless network.

As shown with reference to figure 13 of the drawings,

step 2: arranging an online design training module on a system platform;

and step 3: generating a preliminary design drawing;

step 3.1: generating a design task book by a system platform;

step 4.2: the system platform checks the preliminary design drawing;

step 6: based on a thermal performance index system database, an equipment parameter index system database and a building material index system database of the transparent outer enclosing structure, the controllability index threshold of key materials, products and systems of a target building is determined, a construction site camera is adopted to randomly sample, seal and check the materials, products and systems entering a field, a system platform generates a detection report, and the selected materials, products and systems are compared and controlled to meet the technical index threshold requirement;

step 8.4: when the requirements are not met, generating leakage performance and thermal performance modification items of the building, and carrying out real-time monitoring and iterative calculation on the modification process and effect of the building until the requirements of the passive low-energy-consumption building are met;

With reference to the accompanying drawings of the specification and fig. 14-16, a passive building overall process quality control system based on a construction engineering dynamic management method is described, and the core control target of the system is 1. the energy efficiency target of a building; 2. the comfort goal of the building.

TABLE 3 energy efficiency targets for buildings

Evaluation itemEyes of a user	Index requirement
		Primary energy demand of heating and refrigeration, kWh/(m)²·a)	≤30
Total primary energy requirement, kWh/(m)²·a)	≤120

As shown in table 3, the index requirements apply to each climate zone in our country. The sum of the heating and cooling primary energy requirements of the building and the total primary energy requirement of the building should meet the limit requirements at the same time, wherein the total primary energy requirement includes the primary energy requirements of heating, cooling, ventilation, lighting, domestic hot water, auxiliary electricity for equipment and electrical equipment. The standards apply to residential buildings as well as typical dormitories, hotels, offices and educational buildings. For buildings with other functions, the limit values of the primary energy demand for heating and refrigeration of the buildings are correspondingly adjusted due to the difference of the conditions of personnel, illumination and equipment heat dissipation in the buildings. The reasonable limit value is that when the technical scheme is further optimized, the change of the heating and refrigerating demands of the building does not exceed 1 kWh/(m)²A) heating and cooling load variation does not exceed 1W/m²And the indoor surface temperature of the outer wall in winter is not lower than 19.5 ℃, and the corresponding primary energy requirements of heating and cooling are met. For the high energy demand caused by special purpose lighting and equipment, the total primary energy demand limit value of the building can be adjusted correspondingly, but the high energy efficiency equipment is adopted. The index requirement correspondence area in the table is the building area of the passive low energy building processing area. The primary energy refers to energy resources existing in the original form in nature and not converted by processing, and is also called natural energy, such as raw coal, petroleum, natural gas and the like. When converting building energy into primary energy, the energy of the energy in the process of mining, transportation and processing conversion needs to be consideredAnd (4) loss. The primary energy demand of building heating (refrigeration) is primary energy required for enabling the indoor temperature of a building in winter to reach 20 ℃ (the indoor temperature in summer is lower than 26 ℃) under local climate conditions.

TABLE 4 comfort goals for buildings

Indoor CO, as shown in Table 4₂Should be below 1000 ppm; PM (particulate matter)_2.5Should be below 35. mu.g/m at a 24-hour average concentration³；PM₁₀Should be below 50. mu.g/m in 24 hours³(ii) a The maximum concentration of formaldehyde is less than 27 ppb; total Volatile Organic Compounds (VOCs) levels below 500 [ mu ] g/m³(ii) a The 8-hour average concentration of ozone is less than 100 mu g/m³。

The passive low-energy-consumption building overall Process quality Control system comprises Decision-making stage quality Control (namely Decision Control, DC), implementation stage quality Control (namely Process Control, PC) and Operation stage quality Control (namely Operation Control, OC); the main body for implementing quality control is a whole-process technical support party of a building project, a investor and a developer (a constructor) of the project, and all parties involved in the quality control comprise a designer, a constructor and a supplier of the building project and a manager of the project operation period.

The decision control of the passive low-energy-consumption building overall process quality control system comprises the steps of determining an energy efficiency target and an indoor comfort target of a building and demonstrating feasibility of target realization.

The process control of the passive low-energy-consumption building overall process quality control system is an implementation stage of a project, and comprises various stages of project investigation design, tender procurement, construction installation, detection inspection, completion acceptance and the like, and takes an energy efficiency target (namely a building energy-saving effect) and a comfort target (namely a building operation effect) of the control project as a core, and controls a dynamic control process of a series of activities, including planning, implementation, inspection, supervision, audit and the like, which are carried out by all parties participating in the project around the building energy efficiency and comfort target, and is the core control process of the passive low-energy-consumption building overall process quality control system.

The operation control of the passive low-energy-consumption building overall-process quality control system aims at the operation stages of projects, including the stages of project delivery, operation and the like, aims at building energy efficiency and comfort, utilizes digital infrastructure, tracks the operation effect of an energy system, optimizes the energy consumption of the building level, optimizes the two-way interaction of energy service between property management and users, and emphasizes the adaptation and continuous optimization between buildings and equipment systems.

In the process control and the operation control of the passive low-energy-consumption building overall process quality control system, the duties of all the participants of the project on the system platform are shown in tables 5 to 8 respectively.

TABLE 5 Producer responsibilities

TABLE 6 technical support Party responsibilities

TABLE 7 designer responsibilities

TABLE 8 job Party responsibilities

It should be understood that the above description of the preferred embodiments is given for clarity and not by way of limitation, and that alterations and modifications may be made by those skilled in the art without departing from the scope of the invention as hereinafter claimed.

Claims

1. A passive form low energy consumption building based on overall process quality control system construction which characterized in that:

comprises a main structure wall body, an airtight layer, a graphite polystyrene board outer wall heat preservation layer, a passive outer window, a rock wool fireproof isolation belt, a waterproof vapor permeable membrane, a waterproof vapor barrier membrane, a main structure roof, a high volume weight graphite polystyrene board, a main structure basement roof, a first extruded polystyrene board, a rock wool belt, a second extruded polystyrene board, a ground structure layer, a third extruded polystyrene board, a wall penetrating pipeline, a pipeline heat preservation layer, a prepressing expansion sealing belt, a ventilation and air conditioning integrated machine system, an air supply opening, a return air opening, an air inlet, an air outlet, a circulating air opening, an air supply pipeline, a return air pipeline, an air inlet pipeline, an air outlet pipeline and a circulating air pipeline, the airtight layer is arranged on the inner side of the main structure wall body, the graphite polystyrene board outer wall heat insulation layer is arranged on the outer side of the main structure wall body, and the passive outer window is arranged on the main structure wall body.

2. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 1, wherein: rock wool fire prevention median adopt the level to encircle the mode and lay major structure wall body on, rock wool fire prevention median's thickness be 240mm, rock wool fire prevention keep apartThe width of the belt is 300mm, and the comprehensive heat transfer coefficient of the rock wool fireproof isolation belt is 0.15W/(m)²K), the rock wool fireproof isolation belt is laid in a double-layer staggered joint mode, the height of a double-layer lap joint part is more than or equal to 300mm, and the height of the lower edge of the double-layer lap joint part from the upper edge of the door and window opening is less than or equal to 500 mm.

3. A passive low energy building based on a full process quality control system construction according to claim 1 or 2, characterized in that: the main structure basement roof is connected with the main structure wall in a pouring mode, the first extruded polystyrene board is laid on the upper side of the main structure basement roof, the thickness of the first extruded polystyrene board is 70mm, and the dry density is larger than or equal to 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁A stage; the lower side of the main body structure is paved with a rock wool belt, the thickness of the rock wool belt is 50mm, and the heat transfer coefficient is 0.27W/(m)²K) dry density of not less than 100kg/m³The heat conductivity coefficient is less than or equal to 0.045W/(m.K), the acidity coefficient is more than or equal to 1.8, and the combustion performance grade is A grade; the rock wool area extends to basement outer wall inboard from basement roof, and extension length is 1 m.

4. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 3, wherein: a second extruded polystyrene board is laid on the outer side of the part, below the soil, of the main structure wall, wherein the thickness of the second extruded polystyrene board is 240mm, the laying range of the second extruded polystyrene board is 1m from the outdoor terrace, and the laying range of the second extruded polystyrene board is 500mm from the outdoor terrace; the second extruded polystyrene board has a heat transfer coefficient of 0.13W/(m)²K) is adhered by adopting a heat-insulating material with double-layer staggered joints, and the dry density is more than or equal to 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁And (4) stages.

5. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 4, wherein: one layer of said ground structure contacting the soilA third extruded polystyrene board is laid on the lower side; the third extruded polystyrene plate has a thickness of 200mm and a heat transfer coefficient of 0.15W/(m)²K) dry density of not less than 30kg/m³Thermal conductivity coefficient is less than or equal to 0.030W/(m.K), and combustion performance grade B₁And (4) stages.

6. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 5, wherein: the three-glass two-cavity hollow argon-filled fire-resistant glass window further comprises an outer door and window system, wherein the outer door and window system comprises an aluminum-wood composite profile outer window, and a three-glass two-cavity hollow argon-filled fire-resistant glass and a warm edge spacing strip; the heat transfer coefficient K of the whole outer window of the outer door and window system is less than or equal to 1.0W/(m)²K) profile heat transfer coefficient K is less than or equal to 1.3W/(m)²K) glass heat transfer coefficient K is less than or equal to 0.8W/(m)²K), the total solar transmittance g of the glass is 0.35, the glass selectivity coefficient LSG is more than or equal to 1.25, the air tightness of an outer window of the outer door and window system is 8 grades, the water tightness is 6 grades, the air sound insulation performance is 3 grades, and the fire resistance integrity is more than or equal to 0.50 h.

7. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 6, wherein: the outer windowsill is tightly attached to the outer side of the structural wall body, a joint between the outer door and window frame and the structural wall body is sealed by a door and window opening sealing system, and the door and window opening sealing system comprises a waterproof vapor-barrier film, a waterproof vapor-permeable film and an adhesive; the waterproof vapor-barrier film is arranged on one indoor side, and the waterproof vapor-permeable film is arranged on one outdoor side; one side of each of the waterproof vapor-barrier film and the waterproof vapor-permeable film is effectively adhered to the side surface of the door and window frame or the attached frame, the other side of each of the waterproof vapor-barrier film and the waterproof vapor-permeable film is adhered to the structural wall, and the overlapping width of the waterproof vapor-barrier film or the waterproof vapor-permeable film is not less than 100 mm; the external wall is covered with a door and window frame in a heat-insulating way, and the width of the exposed part of the door and window frame is reserved for 15 mm; the outer windowsill is provided with a metal windowsill plate, the metal windowsill plate is structurally connected with the lower opening of the window frame and is embedded into the lower opening of the window frame by 10-15 mm; the lower edge of the metal window board is provided with a water dripping line; sealing the joint between the lower side of the metal window board and the outer wall heat-insulating layer by adopting a pre-pressed expansion sealing tape; the end heads at the two sides of the metal window board are turned upwards and embedded into the outer wall heat insulation layer of the window side opening by 20-30 mm; and sealing joints between the upturned ends on the two sides of the metal window board and the outer wall heat-insulating layer by adopting a pre-pressed expansion sealing tape.

8. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 7, wherein: the air conditioner integrated machine system also comprises a ventilation and air conditioning integrated machine system with a heat recovery device, wherein the heat recovery device adopts a total heat recovery machine core, the total heat recovery efficiency is more than or equal to 70 percent, the sensible heat recovery efficiency is more than or equal to 75 percent, and the unit air volume fan power of the heat recovery device is not more than 0.45W/h/m³The fresh air inlet and the return air inlet are provided with filters, the grade of the fresh air inlet filter is not less than G4+ F8 grade, the grade of the return air inlet filter is not less than G4 grade, the internal air leakage rate of the fresh air system is less than 2 percent, and the external air leakage rate is less than 2 percent; the fresh air pipeline leading to the outdoor is coated with a rubber-plastic heat-insulating layer with the thickness of 80mm, the exhaust pipeline leading to the outdoor is coated with a rubber-plastic heat-insulating layer with the thickness of 60mm, and the indoor air supply pipeline is coated with a phenolic aldehyde heat-insulating layer with the thickness of 20 mm; the indoor unit and the outdoor unit are respectively provided with an independent condensate water vertical pipe, and the condensate water vertical pipe adopts a rubber-plastic heat-insulating sleeve with the thickness of 20 mm.

9. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 8, wherein: the ventilation and air-conditioning integrated machine system further comprises a compressor, a fresh air fan, an indoor temperature controller and a carbon dioxide monitoring point, wherein the compressor adopts a frequency conversion technology, the fresh air fan adopts a stepless speed regulation EC fan, and the indoor temperature controller and the carbon dioxide monitoring point are arranged in a living room.

10. The passive low-energy-consumption building constructed based on the overall process quality control system according to claim 8, wherein:

the graphite polystyrene board outer wall heat-insulating layer is formed by paving a plurality of graphite polystyrene board heat-insulating boardsThe width of the graphite polystyrene board insulation board is 600mm, the length of the graphite polystyrene board insulation board is 1200mm, the graphite polystyrene board is laid in a double-layer staggered joint mode, and the dry density of the graphite polystyrene board is more than or equal to 20kg/m³The heat conductivity coefficient of the graphite polystyrene board is less than or equal to 0.032W/(m.K), and the combustion performance grade B of the graphite polystyrene board₁The high-volume-weight graphite polyphenyl board is laid on the main structure roof, the thickness of the high-volume-weight graphite polyphenyl board is 250mm, and the heat transfer coefficient is 0.14W/(m)²K) is paved by adopting a two-layer staggered joint mode, and the dry density is more than or equal to 30kg/m³The compressive strength is more than or equal to 200kPa, the heat conductivity coefficient is less than or equal to 0.033W/(m.K), and the combustion performance grade is B₁And (4) stages.