TWM567445U - Integrated net zero energy building design and analysis system - Google Patents

Abstract

The present invention discloses an integrated design analysis system for a net zero-energy building, comprising a model building module, a model analysis module, a performance analysis module, and a solar module. This system integrates modeling and performance analysis of buildings and can be used to import renewable energy to provide an effective and convenient design tool for cycle design and analysis of green energy buildings.

Description

Integrated design analysis system for net zero-energy buildings

This creation is about an architectural integration design analysis system, especially an analysis system that integrates the design and analyzes the definition of a net zero-energy building.

With the warming of the earth, the global climate environment has undergone severe changes, causing extreme weather to occur frequently, seriously threatening the ecological environment on earth and human life. Therefore, in recent years, many countries and international organizations have formulated many environmental protection and energy conservation regulations. It is hoped that the effectiveness of these regulations will enable environmental protection to be implemented and alleviate global warming and extreme weather.

In view of this, in the field of architectural design, green energy building has become an emerging design concept. With low energy consumption, low emissions and low pollution, Green Energy Building can fulfill the demands of environmental protection and maintain the use of the earth. Development provides a big boost. Among them, Net Zero Energy Buildings (NZEB) is a higher standard design ideal, and has become the direction of many architects and scholars today.

However, existing architectural design tools do not have an analytical processing system that is sufficiently convenient. In known design tools, it is often impossible to integrate the three-dimensional rendering of architectural design details, the performance of buildings, and the analysis of energy use. Once architects design After the architecture of the building, additional analysis or simulation of the building is usually required. It is impossible to optimize the design of the green building by analyzing the cycle of simulation and design. Especially, today's architectural design tools cannot be energy-efficient. The use of management is even more difficult for the ideal implementation of Net Zero Energy Buildings (NZEB).

In order to solve the problems mentioned in the prior art, the present invention provides an integrated design analysis system for a net zero-energy building, comprising: a model construction module comprising: an input module comprising a plurality of first parameter input modes a plurality of second parameter input modules and a plurality of third parameter input modules; a receiving module connected to the input module, the receiving module receiving the plurality of first parameters generated by the plurality of first parameter input modules a plurality of second parameters generated by the plurality of second parameter input modules and a plurality of third parameters generated by the plurality of third parameter input modules; an operation module connected to the receiving module; a display module, and The computing module is connected, the display module comprises a visual display; and a first data transmission module is respectively connected with the computing module and the plurality of third parameter input modules; a model analysis module and a model construction module Connecting, the model analysis module comprises: a second data transmission module connected to the first data transmission module; a cloud processor connected to the second data transmission module; Energy analysis module, the module is connected to the model analysis, the performance analysis module comprises a predetermined value; and a solar module.

The above brief description of this creation aims to provide a basic explanation of several aspects of the creation and technical features of the creation. The creation brief is not a detailed description of the creation, so its purpose is not to specifically enumerate the key or important elements of the creation, nor to define the scope of the creation, but to present several concepts of the creation in a concise manner.

In order to understand the technical features and practical functions of the present invention, and to implement according to the contents of the specification, the following further describes the preferred embodiment as shown in the following figure:

Please refer to FIG. 1. FIG. 1 is an architectural diagram of an integrated design analysis system for a net zero-energy building in the present embodiment. As can be seen from FIG. 1, the integrated design analysis system of the net zero-energy building of the present invention comprises: a model construction module 100, comprising: an input module 200, comprising a plurality of first parameter input modules 201, and a plurality of The two parameter input module 202 and the plurality of third parameter input modules 203; a receiving module 300 connected to the input module 200, and the receiving module 300 receiving the plurality of first parameters generated by the plurality of first parameter input modules 201 a plurality of second parameters 302 generated by the plurality of second parameter input modules 202 and a plurality of third parameters 303 generated by the plurality of third parameter input modules 203; a computing module 400 and the receiving module 300 A display module 500 is connected to the computing module 400. The display module 500 includes a visual display 501, and a first data transmission module 600, respectively, and the computing module 400 and a plurality of third parameter input modules. The group analysis module 700 is connected to the model construction module 100. The model analysis module 700 includes: a second data transmission module 701 connected to the first data transmission module 600; a cloud processor 702 Connected to the second data transfer module 701; a performance analysis module 800, analysis module 700 is connected with the model, the performance analysis module 800 comprises a preset value 801; 900 and a solar module.

In one embodiment of the present invention, a user inputs a plurality of first parameters 301 and a plurality of second parameter inputs through a plurality of first parameter input modules 201 of the input module 200 through an input device, such as a personal computer. A plurality of second parameters 302 are input to the module 202, and a plurality of third parameters 303 are input to the plurality of third parameter input modules 203. In the embodiment, the first parameter input module 201 is used to input a plurality of buildings. The combination of parameters of the information, such as: configuration, shape, orientation, etc.; the second parameter input module 202 is used to input a combination of parameters of a plurality of architectural non-geometric information, such as: space type, wall structure, thermal conductivity The choice of active equipment (air conditioning equipment, lighting equipment, etc.), window opening rate, operation planning, etc.; the third parameter input module 203 is used to input regional data and meteorological data, such as: latitude and longitude, environmental characteristics, temperature, humidity , the path of the sun, the wind rose plot, etc.

The receiving module 300 receives a plurality of first parameters 301 generated by the plurality of first parameter input modules 201, a plurality of second parameters 302 generated by the plurality of second parameter input modules 202, and a plurality of third parameter input modes. After the plurality of third parameters 303 generated by the group 203, the computing module 400 will generate a three-dimensional building model that records the geometric spatial relationships of the building, geographic information, the number of building elements, and associated geometric or non-geometric properties. In the preferred embodiment of the present invention, the computing module 400 is composed of Building Information Modeling (BIM) Revit developed by Autodesk, Inc. and integrated into the green building work. The operation of the interface (Green Building Studio, GBS). In some embodiments, the model building module 100 includes a display module 500 coupled to the computing module 400. The display module 500 further includes a visual display 501 for displaying the three-dimensional building generated by the computing module 400. The model and the operation interface of the green building studio.

In this embodiment, the model construction module 100 further includes a first data transmission module 600, which is respectively connected to the operation module 400 and a plurality of third parameter input modules 203. The first data transmission module 600 has a function of externally transmitting the data generated by the operation module 400. Preferably, the first data transmission module 600 performs a conversion operation on the data generated by the operation module 400, and generates a gbXML. (Green Building Extensible Markup Language) format data, and the gbXML format data is transmitted externally.

In another embodiment of the present invention, the integrated design analysis system of the net zero-energy building includes a model analysis module 700 connected to the model construction module 100, and the model analysis module 700 includes a second data transmission module 701. The first data transmission module 600 is connected to the first data transmission module 600. After the first data transmission module 600 converts the data generated by the operation module 400 into the gbXML format, the data is transmitted to the second data transmission module 701 for model analysis. The module 700 is used. The model analysis module 700 also includes a cloud processor 702 connected to the second data transmission module 701. The cloud processor 702 performs various analysis operations on the data received by the second data transmission module 701, for example, energy consumption calculation, building heat dissipation performance calculation, building thermal load analysis, airflow characteristic analysis, acoustic characteristic analysis, architectural sunshine and lighting analysis, Visual perception analysis, building performance analysis, carbon emissions calculations, etc. In some embodiments, the cloud processor 702 further includes an energy consumption simulation operation module and a user interface. Preferably, the energy consumption simulation operation module includes a DOE-2 simulation engine, and the user interface is The Green Building Studio (GBS) interface developed by Autodesk, Inc., the cloud processor 702 converts the analysis results into a visual analysis graph and an analog numerical representation, wherein the visual analysis graph The presentation method can be simulated visual graphics, various numerical analysis tables, statistical charts, distribution maps, and the like.

In one embodiment of the present invention, the model analysis module 700 further includes a weather simulation module 703, which is connected to the second data transmission module 701 and a historical database 704 of a weather station, wherein the weather simulation module obtains historical data. The historical data of one of the libraries generates one of the plurality of third parameters 303, and the second data transmission module 701 transmits one of the plurality of third parameters 303 to the receiving module 300. After the user inputs the latitude and longitude of the building in the third parameter input module 203, the first data transmission module 600 transmits the regional information to the model analysis module 700 by using the second data transmission module 701. The weather simulation module 703 in the analysis module 700 searches and receives historical weather data of the Typical Meteorological Year (TMY) in the historical database 704 of the weather station based on the regional information, and records the historical data. Performing a simulation operation to generate a representative weather data as one of the third parameters 303. After the second data transmission module 701 transmits one of the third parameters 303 to the receiving module 300, the computing module 400 performs subsequent modeling. And the model analysis module 700 performs the analysis operation of the weather information again, and presents it in the form of a visual analysis graph (wind map, hot spot map, etc.).

The integrated design analysis system of the net zero-energy building of the present embodiment further includes a performance analysis module 800 connected to the model analysis module 700, the performance analysis module 800 further includes a preset value 801; and a solar module 900 is connected to the model analysis module 700. In addition, the analog value generated by the cloud processor 702 includes an Energy Usage Intensity (EII), and the performance analysis module 800 calculates an optimized performance percentage value of the energy usage intensity value relative to the preset value 801. Among them, the energy use intensity value is defined as the annual energy consumption of the building divided by the floor area of the building's gross floor, and only counts the electricity consumption for one year in the operation phase. The unit is kWh/m ² *y, kWh is the power unit. Kilowatt, m ² is the unit of length in square centimeters, and y is the year. The default value of the creation 801 is the energy use intensity value of the initial plan selected by the building in the preliminary design stage. The selection of the preset value 801 is compared with the average value and the extreme value of the same type of building. The most reasonable value chosen is used as a basis for comparison of the percentage of optimized performance designed and optimized for subsequent cycles.

In one embodiment of the present invention, the solar module 900 further includes an external solar energy source database and an Autodesk Solar Analysis for Revit, which can be considered in the building. The energy output after adding solar panels with different coverage rates can also find suitable solar energy sources in the adjacent solar energy source database according to the latitude and longitude information of the location of the building, and then return to the model analysis module 700. Perform Energy Usage Intensity (EUI) and optimize performance percentage values.

Please refer to FIG. 2. FIG. 2 is a flow chart of the operation method of the integrated design analysis system of the net zero energy-consuming building in the embodiment of the present invention. It can be seen from Fig. 2 that the step S1 of the operation method of the integrated design and analysis system of the net zero-energy building of the present invention "using a model construction module to construct a building model" includes: inputting a plurality of building parameters, and inputting a plurality of users The parameters of the building information and the parameters of the building non-combination information, and input a geographic location parameter to obtain a meteorological simulation data; then generate one of the building model building model data and display one of the architectural models of the three-dimensional building model Then, step S2 is performed.

As can be seen from Fig. 2, step S2 of the operation method of the integrated design analysis system of the net zero-energy building of the present invention "analyze the building model using a model analysis module" includes: uploading the building model data generated in step S1 to A cloud processor 702 generates an energy consumption analysis data for the building model data, including an energy usage intensity value; and generates an energy consumption analysis map for the building model data, and then performs step S3. The step S3 of the operation method of the integrated design and analysis system of the net zero-energy building of the present invention comprises: using a performance analysis module 800 to analyze the building model generated in S1, and calculating the energy use intensity value and a preset value to generate An optimized performance percentage value. Finally, the step S4 of the operation method of the integrated design and analysis system of the net zero-energy building of the present invention comprises: after performing step S3, using a solar module 900, generating a solar energy data for the building model data, and performing step S3 again. .

Next, please refer to FIG. 3. FIG. 3 is a flowchart of a method for operating an integrated design analysis system for a net zero-energy building in another embodiment of the present invention. In this embodiment, after performing step S3, a design strategy is further executed, including: adjusting a plurality of building parameters in the step m1 (for example, wall construction parameters, window opening rate, active device selection, etc.) and performing the steps again. m3-S3, the construction model construction and analysis of the design parameters of this time, when the analysis of the optimization performance percentage value does not reach the expected value, repeat step D1 "adjust the plurality of building parameters in step m1 and repeat the steps S2-S3, the construction model construction and analysis of the design parameters of this time, until the analysis of the optimization performance percentage value is greater than or equal to the expected value, the best design of the net zero energy-consuming building is completed. Among them, the expected value is the energy-saving optimization target set in the energy-saving analysis. In one embodiment of the present creation, the expected performance percentage value of 21% is set in the preliminary design stage (Schematic Design, SD). The value of the optimized performance percentage set by the expected value of 30% in the Design Development (DD).

The above-exemplified embodiments are only a brief description of the operation method of the integrated design analysis system for the net zero-energy-consumption building of the present creation, and the user can also arbitrarily arrange the steps of the above embodiments in a new arrangement. The operation of the integrated design analysis system for zero-energy buildings is not limited to this.

The integrated design analysis system and its operation method of the net zero-energy building of the creation provide a convenient analysis and processing system for the architect, which not only can display the design details of the building in three dimensions, but also directly upload the constructed model and Perform analysis of performance and energy usage to easily achieve a cycle of analytical simulation and design. Through the introduction of renewable energy and optimized parameters, this creation provides a more systematic and indicative decision-making method for green energy building design.

However, the above is only the preferred embodiment of the present invention. When it is not possible to limit the scope of the creative implementation, the simple equivalent changes and modifications made according to the scope and description of the patent application are still It is within the scope of this creation.

100‧‧‧Model Construction Module
200‧‧‧ input module
201‧‧‧First parameter input module
202‧‧‧Second parameter input module
203‧‧‧ third parameter input module
300‧‧‧ receiving module
301‧‧‧ first parameter
302‧‧‧ second parameter
303‧‧‧ third parameter
400‧‧‧ Computing Module
500‧‧‧ display module
501‧‧‧ visual display
600‧‧‧First Data Transmission Module
700‧‧‧Model Analysis Module
701‧‧‧Second data transmission module
702‧‧‧Cloud processor
703‧‧‧Weather Simulation Module
704‧‧‧Historical database
800‧‧‧Performance Analysis Module
801‧‧‧Preset value
900‧‧‧Solar modules
S1~S4‧‧‧ steps
M1~m4‧‧‧ steps
A1~a3‧‧‧ steps

(Fig. 1) Architecture diagram of the integrated design analysis system of the net zero-energy building in the present embodiment (Fig. 2) Flow chart of the operation method of the integrated design analysis system of the net zero-energy building in the present example (Fig. 3) Another embodiment of the present invention is a flow chart of the operation method of the integrated design analysis system for the net zero energy-consuming building

Claims (8)

An integrated design analysis system for a net zero-energy building includes: a model construction module comprising: an input module comprising a plurality of first parameter input modules, a plurality of second parameter input modules, and a plurality of third a parameter input module; a receiving module connected to the input module, the receiving module receiving a plurality of first parameters generated by the plurality of first parameter input modules, and the plurality of second parameter input modules a plurality of second parameters and a plurality of third parameters generated by the plurality of third parameter input modules; a computing module coupled to the receiving module; a display module coupled to the computing module, the display module The group includes a visual display; a first data transmission module, and the operation module and the plurality of third parameter input modes respectively a model analysis module, connected to the model construction module, the model analysis module comprises: a second data transmission module connected to the first data transmission module; a cloud processor, and the A data transmission module is connected; a performance analysis module is connected to the model analysis module, the performance analysis module includes a preset value; and a solar module. The integrated design and analysis system for a net zero-energy building according to claim 1, wherein the cloud processor further comprises an energy consumption simulation computing module and a user interface. An integrated design analysis system for a net zero energy consuming building as claimed in claim 1, wherein the visual display displays a three dimensional architectural model. The integrated design analysis system for a net zero-energy building according to claim 1, wherein the first data transmission module generates a gbXML format data, and transmits the gbXML format data to the second data transmission module. An integrated design analysis system for a net zero-energy building as described in claim 1, wherein the cloud processor further generates a visual analysis map and an analog value. The integrated design analysis system for a net zero-energy building according to claim 5, wherein the simulation value includes an Energy Usage Intensity (EII), and the performance analysis module calculates the energy use intensity value relative to the pre- Set one of the values to optimize the performance percentage value. The integrated design analysis system for a net zero-energy building according to claim 1, wherein the model analysis module further comprises a weather simulation module, and is connected to the second data transmission module and a historical database of a weather station. The weather simulation module acquires historical data of the historical database and generates one of the plurality of third parameters, and the second data transmission module transmits one of the plurality of third parameters to the receiving module. An integrated design analysis system for a net zero-energy building as described in claim 1, wherein the solar module further comprises an external solar energy source database and an Autodesk Solar Analysis for Revit.