CN114580772A - Comprehensive method and system for energy-saving building design by adopting digital simulation - Google Patents

Abstract

The invention discloses a comprehensive method for energy-saving building design by adopting digital simulation, which comprises the following steps: establishing a meteorological information database; generating an environment model; generating a building model of single or multiple building components; embedding the building model into the environment model in a variable manner; calculating the energy consumption level of each part of the energy-saving building; optimizing the building parts with over-high energy consumption level aiming at the performance consumption, providing an alternative scheme or a custom optimization scheme and simulating the alternative scheme or the custom optimization scheme; and generating a simulated building energy consumption evaluation report. The system comprises a building information input module; an environment information calling module; a model generation module; an energy consumption analysis module; and optimizing the simulation module. The comprehensive method and the system for energy-saving building design by adopting digital simulation can obtain more accurate parameter information through shorter-time measurement, and have more comprehensive and specific analysis and higher working efficiency.

Description

Comprehensive method and system for energy-saving building design by adopting digital simulation

Technical Field

The invention relates to the technical field of building design, in particular to a comprehensive method and a system for energy-saving building design by adopting digital simulation.

Background

The energy-saving building refers to a low-energy-consumption building designed by researching building planning subareas, groups, monomers, building orientation, space, solar radiation, wind direction and external space environment according to a basic method for climate design and energy saving. The level of the conventional building energy-saving design standard on the specified index of the thermal performance of the building outer protective structure is lower, the requirement of realizing 50 percent of the target of energy saving at the present stage is only met, the requirement on comfortable buildings is far, and the difference from developed countries is large. Along with the development of economy in China, the building energy-saving design standard is modified in stages, and the thermal performance of the building external protective structure is gradually improved. Because the service life of the building is long, it is difficult to implement energy-saving reconstruction on the existing building according to a new standard when the service life is up, so that the advanced principle should be implemented, in particular to the summer hot areas, the thermal performance indexes of the building external protective structures (the roof, the external wall and the external door and window) should break through the minimum requirements specified by the energy-saving design standard, the building external protective structures are properly reinforced, and the summer internal surface calculation temperature of the roof and the external wall should be controlled.

However, when a digital simulation energy-saving building design is performed at present, data information such as sound, light, heat and the like in an environment is generally acquired on site to be analyzed, the environment data generally has large changes along with seasons, geographical conditions and the like, accurate simulation cannot be performed if a measurement period is short, and a project period and cost are increased if the measurement period is prolonged.

Therefore, in combination with the above-mentioned technical problems, there is a need to provide a new technical solution.

Disclosure of Invention

The invention aims to provide a comprehensive method and a system for energy-saving building design by adopting digital simulation, which have higher simulation efficiency, more comprehensive data and more visualized analysis.

In order to solve the technical problems, the invention provides a comprehensive method and a system for energy-saving building design by adopting digital simulation, and the specific technical scheme is as follows:

a comprehensive method for energy-saving building design by adopting digital simulation comprises the following steps:

s1, establishing a weather information database, wherein the weather information database is divided according to each region in the city and is connected with a database of a local weather information website;

s2, calling environmental information in a weather information database according to the position of the energy-saving building, and performing simulation analysis on the environment by combining with field detection data to generate an environmental model;

s3, inputting various design parameters of the energy-saving building, and generating a building model consisting of a single building or a plurality of buildings;

s4, embedding the building model into the environment model in a variable manner;

s5, analyzing the energy consumption of the energy-saving building by combining the building model and the environment model, and calculating the energy consumption level of each part of the energy-saving building;

s6, optimizing the energy consumption of the building part with the over-high energy consumption level aiming at the performance consumption, providing an alternative scheme or a custom optimization scheme and simulating the alternative scheme or the custom optimization scheme;

and S7, generating a simulated building energy consumption evaluation report.

Preferably, the environmental information includes one or more combinations of indoor and outdoor four-season temperatures of an area where the building is located, indoor and outdoor humidity of the building, an air quality value, an illumination angle and illumination duration of a corresponding height, a precipitation peak value, a wind speed and a wind pressure value.

Preferably, the field detection data includes one or more of the distance between the building location and the surrounding building, the field hydrological condition of the building, the pedestrian and vehicle flow rate around the building, the noise value of the building location, and the field condition of the building location.

Preferably, the design parameters include one or more of the building structure, the number of buildings and the floor space, the height and the floor number of the buildings, the requirement of the buildings for long time of illumination, the window opening area of the buildings, the energy type of the buildings and the energy use system.

Preferably, the energy consumption analysis includes one or more of a combination of a cold and heat load calculation for heating or cooling of the building, an electric load calculation for illumination, an indoor humidity average value calculation, a pedestrian and vehicle flow calculation for ensuring convenience in traveling, and a building facade sound field distribution calculation for ensuring noise reduction effect.

Preferably, the energy consumption optimization comprises the steps of carrying out heat preservation operation on indoor and outdoor wall bodies according to the cold and heat load value, adjusting the distance between buildings and/or the size and the position of a window according to the lighting electric load value, calculating and setting a fresh air conveying system according to the average value of indoor humidity, calculating the positions and the number of entrances and exits of the building according to the flow of people and vehicles, and carrying out noise reduction treatment on specific parts according to sound field distribution of the vertical surface of the building.

A system for energy efficient architectural design using digital simulation, comprising:

the building information input module is used for inputting various parameters into the system according to the actual requirements of the building;

the environment information calling module is connected with a database of a local weather information website and used for importing environment information of the region to which the building belongs;

the model generation module is connected with the building information input module and the environment information calling module and is used for generating a building model and an environment model which are embedded;

the energy consumption analysis module is connected with the model generation module to analyze the energy consumption of the building model;

and the optimization simulation module is used for optimizing the building according to the data provided by the energy consumption analysis module and adjusting various parameters of the building so as to meet the aim of energy conservation.

Preferably, the energy-saving system further comprises an energy consumption evaluation report generation module, wherein the energy consumption evaluation report generation module generates an evaluation report according to the building parameters optimized by the optimization simulation module, and fills the simulation result into the energy-saving report template.

Preferably, the model generation module includes a building model generation module, an environment model generation module and a scene embedding module, the building model generation module receives parameters input in the building information input module and constructs a building model, the environment model generation module receives parameters input in the environment information calling module and constructs an environment model, and the scene embedding module embeds the building model in the environment model to be matched with each other.

The comprehensive method and the system for designing the energy-saving building by adopting the digital simulation have the following beneficial effects that:

according to the comprehensive method and the system for energy-saving building design by adopting digital simulation, by adopting a mode of combining the construction environment information database with the construction model, the construction model and the environment model are combined and analyzed for energy consumption, the optimization and adjustment are carried out by the optimization and simulation module, multiple optimization and analysis can be carried out only by setting one group of parameters, more accurate parameter information can be obtained by measuring in a shorter time, the analysis is more comprehensive and specific, and the working efficiency is higher;

additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings needed for the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic block diagram of a system for energy efficient architectural design using digital simulation;

fig. 2 is a schematic structural diagram of a model generation module in fig. 1.

Wherein, 1-building information input module; 2-an environment information calling module; 3-a model generation module; 31-a building model generation module; 32-an environmental model generation module; 33-scene embedding module; 4-an energy consumption analysis module; 5-optimizing a simulation module; 6-energy consumption evaluation report generation module.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

Examples

Referring to fig. 1 to 2, a comprehensive method for energy-saving architectural design using digital simulation is characterized in that: the method comprises the following steps:

s1, establishing a weather information database, wherein the weather information database is divided according to each region in the city and is connected with a database of a local weather information website;

s2, calling environmental information in a weather information database according to the position of the energy-saving building, and performing simulation analysis on the environment by combining with field detection data to generate an environmental model;

s3, inputting various design parameters of the energy-saving building, and generating a building model consisting of a single building or a plurality of buildings;

s4, embedding the building model into the environment model in a variable manner;

s5, analyzing the energy consumption of the energy-saving building by combining the building model and the environment model, and calculating the energy consumption level of each part of the energy-saving building;

s6, optimizing the energy consumption of the building part with the over-high energy consumption level aiming at the performance consumption, providing an alternative scheme or a custom optimization scheme and simulating the alternative scheme or the custom optimization scheme;

and S7, generating a simulated building energy consumption evaluation report.

The environmental information comprises one or more combinations of indoor and outdoor four-season temperature of the area where the building is located, indoor and outdoor humidity of the building, air quality value, illumination angle and illumination duration of corresponding height, precipitation peak value, wind speed and wind pressure value.

The on-site detection data comprises one or more of the distance between the position of the building and the surrounding building, the on-site hydrologic condition of the building, the pedestrian and vehicle flow rate around the building, the noise value of the position of the building and the actual land condition of the position of the building.

The design parameters comprise one or more of the combination of the building structure of the building, the number and the floor area of the building, the height and the floor number of the building, the requirement of the building for long time of illumination, the window opening area of the building, the energy type of the building and the energy use system.

The energy consumption analysis comprises one or more of the combination of the calculation of cold and heat loads of the building for heating or cooling, the calculation of electric loads of the building for illumination, the calculation of the average indoor humidity, the calculation of pedestrian and vehicle flow for ensuring the convenience of travel and the calculation of sound field distribution of the building facade for ensuring the noise reduction effect.

The energy consumption optimization comprises the steps of carrying out heat preservation operation on indoor and outdoor wall bodies according to the cold and heat load value, adjusting the distance between buildings and/or the size and the position of a window according to the lighting electric load value, calculating and setting a fresh air conveying system according to the average value of indoor humidity, calculating the positions and the number of entrances and exits of the building according to the flow of people and vehicles, and carrying out noise reduction treatment on specific parts according to sound field distribution of the vertical surface of the building.

A system for energy-saving architectural design by digital simulation is characterized in that: the method comprises the following steps:

the building information input module 1 is used for inputting various parameters into the system according to the actual requirements of the building;

the environment information calling module 2 is connected with a database of a local weather information website and used for importing the environment information of the area to which the building belongs;

the model generation module 3 is connected with the building information input module 1 and the environment information calling module 2 and is used for generating a building model and an environment model which are embedded;

the energy consumption analysis module 4 is connected with the model generation module 3 to analyze the energy consumption of the building model;

and the optimization simulation module 5 is used for optimizing the building according to the data provided by the energy consumption analysis module and adjusting various parameters of the building so as to meet the aim of energy conservation.

The energy consumption evaluation report generation module 6 is used for generating an evaluation report according to the building parameters optimized by the optimization simulation module and filling the simulation result into an energy-saving report template.

The model generation module 3 comprises a building model generation module 31, an environment model generation module 32 and a scene embedding module 33, the building model generation module 31 receives parameters input in the building information input module 1 and constructs a building model, the environment model generation module 32 receives parameters input in the environment information calling module 2 and constructs an environment model, and the scene embedding module 33 embeds the building model in the environment model to be matched with each other.

The system for energy-saving building design by adopting digital simulation of the invention inputs parameter information into the building information input module 1 to construct a building model according to the actual requirements of the building when in work, meanwhile, the environmental information in the meteorological information database is called to cooperate with the monitoring data collected on the spot, and the environmental information is input into the environmental information calling module 2 to construct an environmental model, the building model is combined with the environment model by the scene embedding module 33 in the model generating module 3, and then analyzed by the energy consumption analyzing module, and the model is optimized and simulated according to the analysis data and improvement opinions are given, so that designers can supplement and improve the high-energy consumption part according to the improvement method recommended by the system or by combining with the actual situation, and the optimized building model and the optimized environment model are more visually presented through the optimization simulation module, and an energy consumption evaluation report is generated.

The invention has the beneficial effects that: through adopting the mode that the environment information database of structure combines together with the building model, combine the analysis energy consumption after building out building model and environment model to optimize the adjustment through optimizing simulation module to it, only need set up a set of parameter and can carry out a lot of optimization analysis, can obtain more accurate parameter information through the measurement of short time, the analysis is more comprehensive concrete moreover, and its work efficiency is also higher.

While embodiments of the present invention have been shown and described above, it is to be understood that the above embodiments are exemplary and not to be construed as limiting the present invention, and that changes, modifications and variations may be made therein by those of ordinary skill in the art within the scope of the present invention.

Claims (9)

1. A comprehensive method for energy-saving building design by adopting digital simulation is characterized by comprising the following steps: the method comprises the following steps:

s1, establishing a weather information database, wherein the weather information database is divided according to each region in a city and is connected with a database of a local weather information website;

s2, calling environmental information in a weather information database according to the position of the energy-saving building, and performing simulation analysis on the environment by combining with field detection data to generate an environmental model;

s3, inputting various design parameters of the energy-saving building, and generating a building model consisting of a single building or a plurality of buildings;

s4, embedding the building model into the environment model in a variable manner;

s5, analyzing the energy consumption of the energy-saving building by combining the building model and the environment model, and calculating the energy consumption level of each part of the energy-saving building;

s6, optimizing the energy consumption of the building part with the over-high energy consumption level, providing an alternative scheme or a custom optimization scheme and simulating the alternative scheme or the custom optimization scheme;

and S7, generating a simulated building energy consumption evaluation report.

2. The integrated method for energy efficient architectural design using digital simulation of claim 1, wherein: the environment information comprises one or more combinations of indoor and outdoor four-season temperature of the area where the building is located, indoor and outdoor humidity of the building, an air quality value, an illumination angle and illumination duration of corresponding height, a precipitation peak value, a wind speed and a wind pressure value.

3. A comprehensive method for energy efficient building design using digital simulation according to claim 2, characterized by: the on-site detection data comprises one or more of the distance between the position of the building and the surrounding building, the on-site hydrological condition of the building, the pedestrian and vehicle flow rate around the building, the noise value of the position of the building and the actual land condition of the position of the building.

4. A comprehensive method of energy efficient building design using digital simulation according to claim 3, characterized by: the design parameters comprise one or more of building structure, building number and floor area, building height and floor number, building illumination time requirement, building window opening area, building energy type and energy use system.

5. The integrated method for energy efficient architectural design using digital simulation of claim 4, wherein: the energy consumption analysis comprises one or more of the combination of the cold and heat load calculation for heating or cooling of the building, the electric load calculation for illumination, the indoor humidity mean value calculation, the pedestrian and vehicle flow calculation for ensuring the convenience of travel and the building facade sound field distribution calculation for ensuring the noise reduction effect.

6. The integrated method for energy efficient architectural design using digital simulation according to claim 5, wherein: the energy consumption optimization comprises the steps of carrying out heat preservation operation on indoor and outdoor wall bodies according to the cold and heat load value, adjusting the distance between buildings and/or the size and the position of a window according to the lighting electric load value, calculating and setting a fresh air conveying system according to the average value of indoor humidity, calculating the positions and the number of entrances and exits of the building according to the flow of people and vehicles, and carrying out noise reduction treatment on specific parts according to sound field distribution of the vertical surface of the building.

7. A system for energy-saving architectural design by digital simulation is characterized in that: the method comprises the following steps:

the building information input module is used for inputting various parameters into the system according to the actual requirements of the building;

the environment information calling module is connected with a database of a local meteorological information website and used for importing environment information of the area to which the building belongs;

the model generation module is connected with the building information input module and the environment information calling module and is used for generating a building model and an environment model which are embedded;

the energy consumption analysis module is connected with the model generation module to analyze the energy consumption of the building model;

and the optimization simulation module is used for optimizing the building according to the data provided by the energy consumption analysis module and adjusting various parameters of the building so as to meet the aim of energy conservation.

8. The system for energy efficient architectural design according to claim 7, wherein: the energy consumption evaluation report generation module generates an evaluation report according to the building parameters optimized by the optimization simulation module, and fills the simulation result into an energy-saving report template.

9. The system for energy efficient architectural design according to claim 7, wherein: the model generation module comprises a building model generation module, an environment model generation module and a scene embedding module, the building model generation module receives parameters input in the building information input module and constructs a building model, the environment model generation module receives parameters input in the environment information calling module and constructs an environment model, and the scene embedding module embeds the building model into the environment model to enable the building model to be matched with the environment model.

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