CN106845934B - Electric power engineering design exploitable report generation system and working method thereof - Google Patents

Electric power engineering design exploitable report generation system and working method thereof Download PDF

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CN106845934B
CN106845934B CN201710012507.2A CN201710012507A CN106845934B CN 106845934 B CN106845934 B CN 106845934B CN 201710012507 A CN201710012507 A CN 201710012507A CN 106845934 B CN106845934 B CN 106845934B
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CN106845934A (en
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艾璐博
王振洋
王秋翠
张凯
牛晓丹
雒亚芳
刘冉
桑洋
刘霄
马增强
张言攀
赵素梅
张顺生
黄兰芝
韩硕
苑嗣亮
朱银生
田贵民
李连海
徐珂
张军
宫联星
刘通
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Heze Tianrun Electric Power Survey And Design Co ltd
Hongfujin Precision Industry Wuhan Co Ltd
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Hongfujin Precision Industry Wuhan Co Ltd
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Abstract

The invention relates to a power engineering design exploratable report generating system and a working method thereof, wherein the power engineering design exploratable report generating system comprises: the data acquisition units are used for collecting construction component data used in the construction of each electric power engineering project so as to establish a design model corresponding to the electric power engineering project; the server is used for matching and obtaining a design model from each data acquisition unit according to the input corresponding configuration parameters so as to generate an electric power engineering design research report; the electric power engineering design exploitable report generation system and the working method thereof integrate the cases of the existing electric power engineering project, improve the design efficiency of the project to be built, and enable designers to more intuitively and accurately reference the similar design cases by establishing and decomposing the design model and fully utilizing the three-dimensional model to fill the primary three-dimensional design model, thereby providing necessary technical support for the electric power engineering project to be built and generating a more valuable and accurate electric power engineering design exploitable report.

Description

Electric power engineering design exploitable report generation system and working method thereof
Technical Field
The invention relates to a system for power engineering, in particular to a system for generating a power engineering design exploitable report and a working method thereof.
Background
The electric power engineering project needs capital construction business due to complex investment environment, high technical content, wide related range and large fund amount.
At present, aiming at the electric power engineering project, the electric power engineering project is still basically in a manual design stage, the design period is long, and the subjectivity is large, so that the feasibility report is not strict enough.
Therefore, on the basis, a set of electric power engineering design exploitable report generation system and a working method thereof need to be designed to overcome the technical problems.
Disclosure of Invention
The invention aims to provide a power engineering design exploitable report generation system and a working method thereof, which aim to solve the technical problems that the existing power engineering design generation period is long and the exploitable report excessively depends on manpower.
In order to solve the above technical problem, the present invention provides a design report generation system, including:
the data acquisition units are distributed in each electric power engineering project and used for collecting construction component data used in the construction of the electric power engineering project so as to establish a design model corresponding to the electric power engineering project;
and the server is used for matching and obtaining a design model from each data acquisition unit according to the input corresponding configuration parameters so as to generate an electric power engineering design research report.
Further, the data acquisition unit includes:
the positioning module is used for acquiring the geographical position information of the electric power project;
the environmental parameter acquisition module is used for acquiring meteorological and environmental data information of the location of the electric power engineering project;
the construction component recording module is used for acquiring data of each construction component of the construction power engineering project;
the design parameter recording module is used for recording electric power engineering design parameters, characteristic parameters of each construction component and an assembly position corresponding to each construction component;
and the model establishing module is used for establishing a three-dimensional design model of the electric power engineering project according to the data of each construction part.
Further, when designing the electric power engineering project, the server generates a primary three-dimensional design model corresponding to the electric power engineering project to be built according to the corresponding configuration parameters, wherein the primary three-dimensional model comprises a filling area of a three-dimensional model of a part to be constructed;
then screening out the best matched three-dimensional design model in each data acquisition unit according to the corresponding configuration parameters;
and decomposing the best matched three-dimensional design model to obtain three-dimensional models corresponding to the construction parts, and filling the three-dimensional models into the primary three-dimensional design model.
Further, aiming at unfilled positions in the primary three-dimensional design model, the server is suitable for screening out secondary matched three-dimensional design models from each data acquisition unit according to unfilled construction components, decomposing the three-dimensional design models, and filling unfilled positions in the primary three-dimensional design models with the three-dimensional models of the corresponding construction components obtained through decomposition;
if the primary three-dimensional design model has unfilled positions, the process is repeated until the matched three-dimensional design model can not be screened from each data acquisition unit, namely
Forming a quasi-complete three-dimensional design model; and
and manually filling and/or adjusting the construction part model on the basis of the quasi-complete three-dimensional design model to obtain a final three-dimensional design model and generate a power engineering design exploitable report.
In another aspect, the invention further provides a design report generation method.
The design report generation method comprises the following steps: for each electric power engineering project, collecting construction component data used in construction of the electric power engineering project to establish a design model corresponding to the electric power engineering project;
and matching and obtaining design models from the design models according to the input corresponding configuration parameters to generate the power engineering design exploitable report.
Further, the method for collecting the construction component data used in the construction process to establish the design model corresponding to the electric power engineering project comprises the following steps:
acquiring geographical position information of a power project and meteorological and environmental data information of a place;
building data of each construction component of the electric power engineering project; and is
Recording electric power engineering design parameters, characteristic parameters of each construction component and assembly positions corresponding to each construction component; and
and constructing a three-dimensional design model of the electric power engineering project according to the data of each construction part.
Further, the method for calling the best matching power engineering design model from the corresponding data acquisition unit according to the input corresponding configuration parameters comprises the following steps:
when designing an electric power engineering project, firstly generating a primary three-dimensional design model corresponding to the electric power engineering project to be built according to corresponding configuration parameters, wherein the primary three-dimensional model comprises a filling area of a three-dimensional model of a part to be constructed;
then screening out the best matched three-dimensional design model in each data acquisition unit according to the corresponding configuration parameters;
and decomposing the best matched three-dimensional design model to obtain three-dimensional models corresponding to the construction parts, and filling the three-dimensional models into the primary three-dimensional design model.
Further, aiming at unfilled positions in the primary three-dimensional design model, screening secondary matched three-dimensional design models from each data acquisition unit according to unfilled construction components, decomposing the three-dimensional design models, and filling unfilled positions in the primary three-dimensional design models with the three-dimensional models of the corresponding construction components obtained through decomposition;
if the primary three-dimensional design model has unfilled positions, the process is repeated until the matched three-dimensional design model can not be screened from each data acquisition unit, namely
And forming a quasi-complete three-dimensional design model.
Further, the construction component model is manually filled and/or adjusted on the basis of the quasi-complete three-dimensional design model, so that a final three-dimensional design model is obtained to generate a power engineering design exploitable report.
The power engineering design exploitable report generation system and the working method thereof have the advantages that the existing cases of the power engineering project are integrated, the design efficiency of the project to be built is improved, the primary three-dimensional design model is filled by fully utilizing the three-dimensional model through the establishment and the decomposition of the design model, so that a designer can more intuitively and accurately refer to the similar design cases, necessary technical support is provided for the power engineering project to be built, and a more valuable and accurate power engineering design exploitable report is generated.
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The invention is further illustrated with reference to the following figures and examples.
FIG. 1 is a functional block diagram of a design report generation system of the present invention;
FIG. 2 is a flow chart of the steps of the design report generation method of the present invention.
Detailed Description
The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.
Example 1
As shown in FIG. 1, the present invention provides a design report generating system, comprising:
the data acquisition units are distributed in each electric power engineering project and used for collecting construction component data used in the construction of the electric power engineering project so as to establish a design model corresponding to the electric power engineering project;
and the server is used for matching and obtaining a design model from each data acquisition unit according to the input corresponding configuration parameters so as to generate an electric power engineering design research report.
Specifically, the data acquisition unit includes:
the positioning module is used for acquiring the geographical position information of the electric power project;
the environmental parameter acquisition module is used for acquiring meteorological and environmental data information of the location of the electric power engineering project;
the construction component recording module is used for acquiring data of each construction component of the construction power engineering project;
the design parameter recording module is used for recording electric power engineering design parameters, characteristic parameters of each construction component and an assembly position corresponding to each construction component;
and the model establishing module is used for establishing a three-dimensional design model of the electric power engineering project according to the data of each construction part.
The data acquisition unit is an industrial personal computer, wherein the data acquisition unit is connected with the GPS module or the Beidou positioning module through a serial port, or the longitude and latitude where the electric power engineering project is located can be known in advance, and the data acquisition unit can also be input into the industrial personal computer.
The environmental parameter acquisition module includes, for example but not limited to: the device comprises a temperature data acquisition unit, a humidity data acquisition unit, an inhalable particle data acquisition unit, an ultraviolet data acquisition unit and a wind speed data acquisition unit; the weather data collected by the environmental parameter collecting module include, but are not limited to, weather information, precipitation, sunshine intensity, wind power and the like, the environmental data information includes, but is not limited to, air pollution degree, air quality AQI data and the like, and the weather data collecting module can be connected with a Chinese weather database to obtain corresponding weather data information and official air quality AQI data.
Each construction component data includes, but is not limited to, a three-dimensional model library, a discrete component code subset, a discrete component attribute subset, and a discrete component three-dimensional coordinate subset for each construction component; the characteristic parameters of the construction components correspond to the discrete element attribute subsets, and the assembly positions corresponding to the construction components correspond to the discrete element three-dimensional coordinate subsets.
The electrical engineering design parameters include, for example but are not limited to: generating capacity, generating mode, power plant area, and sub-area within the power plant area; wherein the generating capacity is 300MW unit or 600MW unit; examples of power generation include, but are not limited to: hydroelectric power generation, thermal power generation, nuclear power generation, wind power generation, solar power generation, tidal power generation and the like. Such power plant areas include, for example and without limitation: a main plant area, a furnace rear area and an ash removal area; sub-areas within a power plant area include, for example and without limitation: a steam turbine room area in the main plant and a coal bunker bay area in the main plant.
When designing an electric power engineering project, the server firstly generates a primary three-dimensional design model corresponding to the electric power engineering project to be built according to corresponding configuration parameters; then screening out the best matched three-dimensional design model in each data acquisition unit according to the corresponding configuration parameters (the best matched three-dimensional design model is suitable for first decomposition and filling); and decomposing the best matched three-dimensional design model to obtain three-dimensional models corresponding to the construction parts, and filling the three-dimensional models into the primary three-dimensional design model.
Aiming at unfilled positions in the primary three-dimensional design model, the server is suitable for screening secondary matched three-dimensional design models from each data acquisition unit according to unfilled construction components (the secondary matched three-dimensional design models are suitable for secondary decomposition and filling), decomposing the three-dimensional design models, and filling unfilled positions in the primary three-dimensional design models with three-dimensional models of corresponding construction components obtained through decomposition; if the primary three-dimensional design model has unfilled positions, repeating the process until the matched three-dimensional design model can not be screened out from each data acquisition unit, namely forming a quasi-complete three-dimensional design model; and manually filling and/or adjusting the construction component model on the basis of the quasi-complete three-dimensional design model to obtain a final three-dimensional design model and generate a power engineering design exploitable report.
For example, the power engineering project to be built is a solar power station, a primary three-dimensional design model of the solar power station is built firstly, primary three-dimensional models of various power generation capacities can be prestored in a database of a server, and after parameters such as the power generation capacities are configured, the primary three-dimensional models matched with the power generation capacities are called from the database, wherein the primary three-dimensional models comprise filling areas of three-dimensional models of required construction parts; and then obtaining the illumination intensity at the similar latitude through a data acquisition unit, retrieving a three-dimensional design model (a best-matched three-dimensional design model) of a solar power station project with or without similar capacity at the similar latitude, if the three-dimensional design model is obtained by searching, taking the three-dimensional design model as a decomposition model, and filling the three-dimensional design model corresponding to each construction part after decomposition into the primary three-dimensional design model, wherein each three-dimensional model comprises but not limited to three-dimensional models of a solar cell matrix, a storage battery pack, a charge and discharge controller, an inverter, an alternating current power distribution cabinet, a solar tracking control system and other equipment, and also comprises the data of the number, the type, the conversion efficiency, manufacturers and the like of the equipment.
If the construction part of the best matched three-dimensional design model can completely fill the filling area of the primary three-dimensional model after being decomposed, the condition is an ideal condition; if the filling cannot be finished, for example, in the filling process, the most matched three-dimensional design model is not provided with the solar tracking control system, and the primary three-dimensional model needs to be added into the solar tracking control system, an unfilled position appears, at the moment, the server searches whether the three-dimensional design model provided with the solar tracking control system exists again at a close latitude position from each data acquisition unit, and if the three-dimensional design model is found, the three-dimensional model of the solar tracking control system is filled into the primary three-dimensional model to form a quasi-complete three-dimensional design model; further, individual adjustment may be performed manually in order to better match each construction member.
Example 2
As shown in fig. 2, this embodiment 2 provides a design report generation method based on embodiment 1.
The design report generation method comprises the following steps:
step S1, establishing a design model of each power engineering project; namely, it is
For each electric power engineering project, collecting construction component data used in construction of the electric power engineering project to establish a design model corresponding to the electric power engineering project;
and step S2, matching and obtaining design models from the design models according to the input corresponding configuration parameters to generate the power engineering design exploitable report.
Specifically, the method for collecting the construction component data used in the construction process to establish the design model corresponding to the electric power engineering project comprises the following steps: acquiring geographical position information of a power project and meteorological and environmental data information of a place; building data of each construction component of the electric power engineering project; recording electric power engineering design parameters, characteristic parameters of each construction component and assembly positions corresponding to each construction component; and constructing a three-dimensional design model of the electric power engineering project according to the data of each construction component.
Specifically, the method for calling the best matching power engineering design model from the corresponding data acquisition unit according to the input corresponding configuration parameters comprises the following steps: when designing an electric power engineering project, firstly generating a primary three-dimensional design model corresponding to the electric power engineering project to be built according to corresponding configuration parameters, wherein the primary three-dimensional model comprises a filling area of a three-dimensional model of a part to be constructed; then screening out the best matched three-dimensional design model in each data acquisition unit according to the corresponding configuration parameters; and decomposing the best matched three-dimensional design model to obtain three-dimensional models corresponding to the construction parts, and filling the three-dimensional models into the primary three-dimensional design model.
Specifically, aiming at unfilled positions in the primary three-dimensional design model, screening secondary matched three-dimensional design models from each data acquisition unit according to unfilled construction components, decomposing the three-dimensional design models, and filling unfilled positions in the primary three-dimensional design models with three-dimensional models of corresponding construction components obtained through decomposition; if the primary three-dimensional design model has unfilled positions, the process is repeated until the matched three-dimensional design model can not be screened out from each data acquisition unit, and the quasi-complete three-dimensional design model is formed.
And manually filling and/or adjusting the construction part model on the basis of the quasi-complete three-dimensional design model to obtain a final three-dimensional design model and generate a power engineering design exploitable report.
For the case that the project to be built is a solar power station, reference may be made to example 1 for discussion.
In addition, the design report generation method is also suitable for adding the air quality AQI into a report, for example, in the area where the existing electric power engineering project is located, the influence of the current air pollution degree on photovoltaic power generation is caused, namely the reduction of the generated energy relative to the air quality when the generated energy is excellent due to haze in a sunny day.
Therefore, according to the descriptions of the above embodiment 1 and embodiment 2, the present invention can integrate the cases of the existing power engineering project, improve the design efficiency of the project to be built, and enable the designer to more intuitively and accurately refer to the similar design cases by establishing and decomposing the design model and fully utilizing the three-dimensional model to fill the primary three-dimensional design model, thereby providing necessary technical support for the power engineering project to be built, and generating a more valuable and accurate power engineering design exploitable report.
In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (3)

1. A design report generation system, comprising:
the data acquisition units are distributed in each electric power engineering project and used for collecting construction component data used in the construction of the electric power engineering project so as to establish a design model corresponding to the electric power engineering project;
the server is used for matching and obtaining a design model from each data acquisition unit according to the input corresponding configuration parameters so as to generate an electric power engineering design research report;
the data acquisition unit includes:
the positioning module is used for acquiring the geographical position information of the electric power project;
the environmental parameter acquisition module is used for acquiring meteorological and environmental data information of the location of the electric power engineering project;
the construction component recording module is used for acquiring data of each construction component of the construction power engineering project;
the design parameter recording module is used for recording electric power engineering design parameters, characteristic parameters of each construction component and an assembly position corresponding to each construction component;
the model building module is used for building a three-dimensional design model of the electric power engineering project according to the data of each construction part;
when designing an electric power engineering project, the server firstly generates a primary three-dimensional design model corresponding to the electric power engineering project to be built according to corresponding configuration parameters, wherein the primary three-dimensional model comprises a filling area of a three-dimensional model of a part to be constructed;
then screening out the best matched three-dimensional design model in each data acquisition unit according to the corresponding configuration parameters;
decomposing the best matched three-dimensional design model to obtain three-dimensional models corresponding to the construction parts, and filling the three-dimensional models into the primary three-dimensional design model;
aiming at unfilled positions in the primary three-dimensional design model, the server is suitable for screening out secondary matched three-dimensional design models from each data acquisition unit according to unfilled construction components, decomposing the three-dimensional design models, and filling unfilled positions in the primary three-dimensional design models with the three-dimensional models of the corresponding construction components obtained through decomposition;
if the primary three-dimensional design model has unfilled positions, the process is repeated until the matched three-dimensional design model can not be screened from each data acquisition unit, namely
Forming a quasi-complete three-dimensional design model; and
and manually filling and/or adjusting the construction part model on the basis of the quasi-complete three-dimensional design model to obtain a final three-dimensional design model and generate a power engineering design exploitable report.
2. A design report generation method is characterized in that,
for each electric power engineering project, collecting construction component data used in construction of the electric power engineering project to establish a design model corresponding to the electric power engineering project;
matching and obtaining design models from all the design models according to input corresponding configuration parameters so as to generate an electric power engineering design exploitable report;
the method for collecting the construction component data used in the construction process to establish the design model corresponding to the electric power engineering project comprises the following steps:
acquiring geographical position information of a power project and meteorological and environmental data information of a place;
building data of each construction component of the electric power engineering project; and is
Recording electric power engineering design parameters, characteristic parameters of each construction component and assembly positions corresponding to each construction component; and
constructing a three-dimensional design model of the electric power engineering project according to the data of each construction part;
the method for calling the best matching power engineering design model from the corresponding data acquisition unit according to the input corresponding configuration parameters comprises the following steps:
when designing an electric power engineering project, firstly generating a primary three-dimensional design model corresponding to the electric power engineering project to be built according to corresponding configuration parameters, wherein the primary three-dimensional model comprises a filling area of a three-dimensional model of a part to be constructed;
then screening out the best matched three-dimensional design model in each data acquisition unit according to the corresponding configuration parameters;
decomposing the best matched three-dimensional design model to obtain three-dimensional models corresponding to the construction parts, and filling the three-dimensional models into the primary three-dimensional design model;
aiming at unfilled positions in the primary three-dimensional design model, screening secondary matched three-dimensional design models from each data acquisition unit according to unfilled construction parts, decomposing the three-dimensional design models, and filling unfilled positions in the primary three-dimensional design models with the three-dimensional models of the corresponding construction parts obtained by decomposition;
if the primary three-dimensional design model has unfilled positions, the process is repeated until the matched three-dimensional design model can not be screened from each data acquisition unit, namely
And forming a quasi-complete three-dimensional design model.
3. The design report generation method according to claim 2,
and manually filling and/or adjusting the construction part model on the basis of the quasi-complete three-dimensional design model to obtain a final three-dimensional design model and generate a power engineering design exploitable report.
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