CN115270264A - Intelligent Design Method of Auxiliary Houses in Sewage Treatment Plant - Google Patents

Abstract

The invention provides an intelligent design method of an auxiliary room of a sewage treatment plant, which aims to solve the problems of long time consumption, low accuracy and non-intuition of the traditional design mode of the auxiliary room, and belongs to the technical field of engineering design. The method comprises the following steps: analyzing the structure of auxiliary rooms designed by each specialty of the sewage treatment plant, and splitting each auxiliary room into a plurality of components from the structural composition; establishing an auxiliary room standard calculation book, and writing various components into the auxiliary room standard calculation book in a parameter form; and executing auxiliary room design at a revit end, capturing parameters corresponding to components in an auxiliary room standard calculation book, and automatically generating a three-dimensional model. According to the invention, the auxiliary room standard calculation book is established, and data transmission is completed by the auxiliary room standard calculation book, so that the entity three-dimensional model is generated, the design process is simplified, the design accuracy and the design efficiency are improved, and the intuition is strong.

Description

Intelligent Design Method of Auxiliary Building in Sewage Treatment Plant

technical field

The invention relates to the technical field of engineering design, in particular to an intelligent design method for an auxiliary room of a sewage treatment plant.

Background technique

The auxiliary room is an indispensable part of the sewage treatment plant. It divides the main operating space of the sewage treatment plant into sludge, dosing, blast, backwash, power distribution, ventilation and other systems. The auxiliary room traditionally adopts two-dimensional design (CAD), and the system designers calculate and select the equipment in the auxiliary room, and consult the equipment manufacturer for the corresponding equipment size, and then arrange the room, and return it to the general manager after obtaining the room size. The plan designer and general plan designer then search for the location of the room according to the room size, room requirements, column network form and other information, determine its elevation and final size and return it to the individual designer, and finally the individual designer will carry out the in-depth design. Since the auxiliary room system involves various professional information, the modification of the general drawing or the column network will lead to a large number of professional rework; at the same time, the consulting work of the equipment size in the early stage of design is quite complicated, and a slight modification of the equipment calculation will lead to re-selection of equipment, Re-consult the size of the equipment with the manufacturer, which may even affect the size of the room. Therefore, the traditional traditional design method of auxiliary housing has the following defects:

1. There are many types of auxiliary rooms, and all majors must participate in the calculation and layout, which makes it difficult to interact with each other. Accuracy cannot be guaranteed for a long time.

2. Designers and equipment manufacturers transmit information through QQ, WeChat or email, and need to urge manufacturers to raise funds at any time, and the communication efficiency is low.

3. For auxiliary buildings with complex structures, the two-dimensional design results are not intuitive and cannot clearly reflect their spatial relationships.

Contents of the invention

In order to solve the problems of long time consumption, low accuracy and invisibility in the traditional design method of the auxiliary room, the invention provides an intelligent design method for the auxiliary room of the sewage treatment plant. Establish the corresponding auxiliary room standard calculation book for the auxiliary room involved in the professional design of the sewage treatment plant, and write the components into the auxiliary room standard calculation book in a parametric way, and the auxiliary room standard calculation book completes the data transfer , simplifies the design process, improves design accuracy and design efficiency. At the same time, the spatial relationship can be viewed through the automatically generated solid 3D model, which is intuitive.

The technical scheme adopted in the present invention is:

An intelligent design method for an auxiliary room of a sewage treatment plant, the method comprising the following steps:

Step S1, analyzing the structure of the auxiliary buildings involved in the professional design of the sewage treatment plant, and splitting each auxiliary building into various components in terms of structural composition;

Step S2, establishing a standard calculation book for the auxiliary room, and writing various components into the standard calculation book for the auxiliary room in the form of parameters;

In step S3, the auxiliary building design is performed on the revit side, and the parameters corresponding to the components in the auxiliary building standard calculation book are captured through the back-end program of the water treatment engineering design system to automatically generate a three-dimensional model.

Further, in the step S1, the specific process of splitting each auxiliary room into various components in terms of structural composition is as follows:

For each auxiliary room, it is divided into walls, panels, doors, windows, equipment and pipes in terms of structural composition.

Further, in the step S2, the specific process of establishing the standard calculation book for the auxiliary room includes:

Step S21, establishing the calculation pages of the standard calculation book for auxiliary buildings, constructing the parameter transmission rules corresponding to the calculation pages between each auxiliary room, and constructing the parameter transmission rules when the calculation pages are sent to the revit terminal to generate the model;

Step S22, establish the equipment table page of the equipment library and auxiliary room standard calculation book, build the selection matching rules between the equipment in the equipment table page and the equipment library, and the transfer rules for the unit price of the corresponding equipment and the basic size of the equipment.

Further, in the step S2, the specific process of writing various components in the form of parameters into the standard calculation book for auxiliary buildings includes:

Step S23, write the main parameters of each component of the auxiliary room into the calculation page, the main parameters of the components include the surrounding wall thickness, plate thickness, door width, door height, door position, window width, window height, window position, Equipment name and the size and location information of the corresponding equipment base;

Step S24, preset a commonly used room layout form in the calculation page, and set the acquisition method for obtaining room size information;

Step S25, setting optional other parameter information in the calculation page to meet special requirements;

Step S26, determining the equipment parameter information used for calculation and equipment selection in the calculation page;

Step S27, write the equipment parameter information required by the corresponding room into the equipment table page, the equipment parameter information includes equipment name, equipment tag, type, specification, quantity and unit price.

Further, in the step S24, the specific process of setting the way of obtaining room size information is as follows:

Step S241, through the back-end program of the water treatment engineering design system, the initial length and width dimension information of the room composed of the equipment foundation is read;

Step S242, the back-end program of the water treatment engineering design system identifies the location of the room, and reads the space height under the specific location of the room to obtain height information;

Step S243, return the height information to the calculation page.

Further, in the step S3, the auxiliary room design is executed on the revit side, and the parameters corresponding to the components in the auxiliary room standard calculation book are captured through the back-end program of the water treatment engineering design system, and the specific process of automatically generating a three-dimensional model is as follows: :

Step S31, grab and calculate the initial length and width information of the room in the page through the back-end program of the water treatment engineering design system, and automatically generate surrounding walls; the height of the wall is identified by the back-end program of the water treatment engineering design system The height of the space between the upper and lower nearest two floors in the view is obtained;

Step S32, using the built-in family library model in the water treatment engineering design system and the surrounding walls that have been generated as positioning, grabbing and calculating the position and size information of the corresponding components in the page through the back-end program of the water treatment engineering design system, and automatically Generate walls, panels, doors, windows and equipment foundations;

Step S33, read and calculate the height information of the room in the book page through the back-end program of the water treatment engineering design system, generate a solid three-dimensional model, and display it on the revit side.

Further, in the step S3, the design of the auxiliary room is executed on the revit side, and the specific process of automatically generating the three-dimensional model is to capture the parameters corresponding to the components in the standard calculation book of the auxiliary room through the back-end program of the water treatment engineering design system. include:

Step S34, if the solid three-dimensional model displayed on the revit terminal meets the design requirements, then use the preset automatic drawing plug-in on the revit terminal to export drawings that meet the predetermined requirements;

Step S35, if the solid 3D model displayed on the revit terminal does not meet the design requirements, modify the model on the revit terminal; after modification, use the preset automatic drawing plug-in on the revit terminal to export drawings that meet the predetermined requirements.

Further, in the step S35, if the solid three-dimensional model displayed on the revit terminal does not meet the design requirements, the specific process of modifying the model on the revit terminal includes:

Step S351, establishing the component to be modified, selecting the component on the Revit terminal and moving it to a predetermined position to generate a new room arrangement form;

Step S352, based on the new room layout form, identify the room size information in the new room layout form through the back-end program of the water treatment engineering design system, and return the new room size information to the calculation page.

The beneficial effects of the present invention are:

In order to solve the problems of long time consumption, low accuracy and invisibility in the traditional design method of the auxiliary room, the invention provides an intelligent design method for the auxiliary room of the sewage treatment plant. The method includes the following steps: step S1, analyzing the structure of auxiliary buildings involved in the professional design of the sewage treatment plant, and splitting each auxiliary building into various components in terms of structural composition; step S2, establishing auxiliary buildings and write various components into the auxiliary room standard calculation book in the form of parameters; step S3, execute the auxiliary room design on the revit side, and grab the auxiliary room through the back-end program of the water treatment engineering design system. According to the parameters corresponding to the components in the room standard calculation book, the 3D model is automatically generated. In the present invention, a corresponding auxiliary room standard calculation book is established for the auxiliary room involved in the professional design of the sewage treatment plant, and the components are written into the auxiliary room standard calculation book in a parameterized manner, and the auxiliary room standard calculation is carried out. The book completes the data transfer, simplifies the design process, and improves the accuracy and efficiency of the design. At the same time, the spatial relationship can be viewed through the automatically generated solid 3D model, which is intuitive.

Description of drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application or in the prior art, the following will briefly introduce the accompanying drawings that need to be used in the description of the embodiments or existing technologies. Obviously, the accompanying drawings in the following description are only These are some embodiments of the present application. Those skilled in the art can also obtain other drawings based on these drawings without creative work.

Fig. 1 is a schematic flowchart of an intelligent design method for an auxiliary building of a sewage treatment plant in an embodiment.

Detailed ways

In the following, only some exemplary embodiments are briefly described. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Accordingly, the drawings and descriptions are to be regarded as illustrative in nature and not restrictive.

The following disclosure provides many different embodiments or examples for implementing different structures of the present invention. To simplify the disclosure of the present invention, components and arrangements of specific examples are described below. Of course, they are merely examples and are not intended to limit the invention.

Embodiments of the invention will be described in detail below in conjunction with the accompanying drawings.

In order to solve the problems of long time-consuming, low accuracy and unintuitive problems in the traditional design of auxiliary rooms, the present invention provides an intelligent design method for auxiliary rooms of sewage treatment plants, the process of which is shown in Figure 1.

An intelligent design method for an auxiliary room of a sewage treatment plant, the method comprising the following steps:

Step S1, analyzing the structure of the auxiliary buildings involved in the professional design of the sewage treatment plant, and splitting each auxiliary building into various components in terms of structural composition;

Step S2, establishing a standard calculation book for the auxiliary room, and writing various components into the standard calculation book for the auxiliary room in the form of parameters;

In step S3, the auxiliary building design is performed on the revit side, and the parameters corresponding to the components in the auxiliary building standard calculation book are captured through the back-end program of the water treatment engineering design system to automatically generate a three-dimensional model.

For the structure and functions of the water treatment engineering design system in this embodiment, refer to the published patent application, titled "Water Treatment Engineering Design System", publication number CN112528374A, publication date 2021-03-19.

The technical effect of the above technical scheme is: to establish the corresponding auxiliary room standard calculation book for each specialty in the design of the sewage treatment plant, and write the components into the auxiliary room standard calculation book in a parameterized manner, and calculate by the auxiliary room standard The book completes the data transfer, simplifies the design process, and improves the accuracy and efficiency of the design. At the same time, the spatial relationship can be viewed through the automatically generated solid 3D model, which is intuitive.

Further, in the step S1, the specific process of splitting each auxiliary room into various components in terms of structural composition is as follows:

For each auxiliary room, it is divided into walls, panels, doors, windows, equipment and pipes in terms of structural composition.

Further, in the step S2, the specific process of establishing the standard calculation book for the auxiliary room includes:

Step S21, establishing the calculation pages of the standard calculation book for auxiliary buildings, constructing the parameter transmission rules corresponding to the calculation pages between each auxiliary room, and constructing the parameter transmission rules when the calculation pages are sent to the revit terminal to generate the model;

Step S22, establish the equipment table page of the equipment library and auxiliary room standard calculation book, build the selection matching rules between the equipment in the equipment table page and the equipment library, and the transfer rules for the unit price of the corresponding equipment and the basic size of the equipment.

The parameter transmission rules of the corresponding calculation pages between various auxiliary rooms are realized based on the reference function of the data table. Through the parameter transfer rules of the corresponding calculation pages between various auxiliary rooms, the data interaction between auxiliary rooms involved in different specialties can be realized, the efficiency of design can be improved, and the accuracy of design results can be guaranteed at the same time.

Similarly, the equipment table page selection and matching rules of the equipment library and the auxiliary room standard calculation book are also implemented in a similar form index, so that the corresponding equipment can be selected from the equipment library. At the same time, the basic size of the equipment is transmitted by the equipment library, which saves the time for raising capital from the manufacturer and greatly improves the design efficiency.

Further, in the step S2, the specific process of writing various components in the form of parameters into the standard calculation book for auxiliary buildings includes:

Step S23, write the main parameters of each component of the auxiliary room into the calculation page, the main parameters of the components include the surrounding wall thickness, plate thickness, door width, door height, door position, window width, window height, window position, Equipment name and the size and location information of the corresponding equipment foundation;

Step S24, preset a commonly used room layout form in the calculation book page, and set the acquisition method for obtaining room size information; each major prepares a commonly used layout form in the standard calculation books corresponding to the system, and the auxiliary room The size calculation is carried out by the background program, avoiding the problem of calculation errors;

Step S25, set optional other parameter information in the calculation page to meet special needs; for example, if the dosing room needs to add a weir wall around the medicine storage tank, you need to name the wall separately and write its name Relative location information;

Step S26, determining the equipment parameter information used for calculation and equipment selection in the calculation page;

Step S27, write the equipment parameter information required by the corresponding room into the equipment table page, the equipment parameter information includes equipment name, equipment tag, type, specification, quantity and unit price.

Further, in the step S24, the specific process of setting the way of obtaining room size information is as follows:

Step S241, through the back-end program of the water treatment engineering design system, the initial length and width dimension information of the room composed of the equipment foundation is read;

Step S242, the back-end program of the water treatment engineering design system identifies the location of the room, and reads the space height under the specific location of the room to obtain height information;

Step S243, return the height information to the calculation page.

Further, in the step S3, the auxiliary room design is executed on the revit end, that is, click the "auxiliary room" option on the revit end, and the back-end program of the water treatment engineering design system grabs the corresponding components in the auxiliary room standard calculation book. parameters, the specific process of automatically generating a 3D model is:

Step S31, grab and calculate the initial length and width information of the room in the page through the back-end program of the water treatment engineering design system, and automatically generate surrounding walls; the height of the wall is identified by the back-end program of the water treatment engineering design system The height of the space between the upper and lower nearest two floors in the view is obtained;

Step S32, using the built-in family library model in the water treatment engineering design system and the generated surrounding walls as positioning, grabbing and calculating the position and size information of the corresponding components in the page through the back-end program of the water treatment engineering design system, and automatically generating Walls, panels, doors, windows and equipment foundations;

Step S33, read and calculate the height information of the room in the book page through the back-end program of the water treatment engineering design system, generate a solid three-dimensional model, and display it on the revit side.

Further, in the step S3, the auxiliary room design is executed on the revit end, that is, click the "auxiliary room" option on the revit end, and the back-end program of the water treatment engineering design system grabs the corresponding components in the auxiliary room standard calculation book. parameters, the specific process of automatically generating a 3D model also includes:

Step S34, if the solid three-dimensional model displayed on the revit terminal meets the design requirements, then use the preset automatic drawing plug-in on the revit terminal to export drawings that meet the predetermined requirements;

Step S35, if the solid 3D model displayed on the revit terminal does not meet the design requirements, modify the model on the revit terminal; after modification, use the preset automatic drawing plug-in on the revit terminal to export drawings that meet the predetermined requirements.

Further, in the step S35, if the solid three-dimensional model displayed on the revit terminal does not meet the design requirements, the specific process of modifying the model on the revit terminal includes:

Step S351, establish the component that needs to be modified, select the component on the revit terminal and move it to the predetermined position to generate a new room layout form; for example, the room wall and the basic position of the equipment can be moved and rearranged, which is convenient for model modification The flexibility allows the general plan designer to modify the room size by himself;

Step S352, based on the new room layout form, identify the room size information in the new room layout form through the back-end program of the water treatment engineering design system, and return the new room size information to the calculation page.

In this embodiment, in order to solve the problems of long time-consuming, low accuracy and unintuitive problems in the traditional design method of auxiliary rooms, an intelligent design method for auxiliary rooms of sewage treatment plants is provided. The method includes the following steps: step S1, analyzing the structure of auxiliary buildings involved in the professional design of the sewage treatment plant, and splitting each auxiliary building into various components in terms of structural composition; step S2, establishing auxiliary buildings and write various components into the auxiliary room standard calculation book in the form of parameters; step S3, execute the auxiliary room design on the revit side, and grab the auxiliary room through the back-end program of the water treatment engineering design system. According to the parameters corresponding to the components in the room standard calculation book, the 3D model is automatically generated. In the present invention, a corresponding auxiliary room standard calculation book is established for the auxiliary room involved in the professional design of the sewage treatment plant, and the components are written into the auxiliary room standard calculation book in a parameterized manner, and the auxiliary room standard calculation is carried out. The book completes the data transfer, simplifies the design process, and improves the accuracy and efficiency of the design. At the same time, the spatial relationship can be viewed through the automatically generated solid 3D model, which is intuitive.

Claims (8)

1. The intelligent design method of auxiliary building of sewage treatment plant, it is characterized in that, described method comprises the following steps: Step S1, analyzing the structure of the auxiliary buildings involved in the professional design of the sewage treatment plant, and splitting each auxiliary building into various components in terms of structural composition; Step S2, establishing a standard calculation book for the auxiliary room, and writing various components into the standard calculation book for the auxiliary room in the form of parameters; In step S3, the auxiliary building design is performed on the revit side, and the parameters corresponding to the components in the auxiliary building standard calculation book are captured through the back-end program of the water treatment engineering design system to automatically generate a three-dimensional model. 2. The intelligent design method for the auxiliary room of sewage treatment plant according to claim 1, characterized in that, in the step S1, each auxiliary room is split into various components from the structural composition The process is: For each auxiliary room, it is divided into walls, panels, doors, windows, equipment and pipes in terms of structural composition. 3. The intelligent design method of the auxiliary room of the sewage treatment plant according to claim 2, characterized in that, in the step S2, the specific process of establishing the standard calculation book of the auxiliary room includes: Step S21, establishing the calculation pages of the standard calculation book for auxiliary buildings, constructing the parameter transmission rules corresponding to the calculation pages between each auxiliary room, and constructing the parameter transmission rules when the calculation pages are sent to the revit terminal to generate the model; Step S22, establish the equipment table page of the equipment library and the auxiliary room standard calculation book, build the selection matching rules between the equipment in the equipment table page and the equipment library, and the transfer rules for the unit price of the corresponding equipment and the basic size of the equipment. 4. The intelligent design method for the auxiliary room of the sewage treatment plant according to claim 3, characterized in that, in the step S2, the specific process of writing various components into the standard calculation book of the auxiliary room in the form of parameters include: Step S23, write the main parameters of each component of the auxiliary room into the calculation page, the main parameters of the components include the surrounding wall thickness, plate thickness, door width, door height, door position, window width, window height, window position, Equipment name and the size and location information of the corresponding equipment foundation; Step S24, preset a commonly used room layout form in the calculation page, and set the acquisition method for obtaining room size information; Step S25, setting optional other parameter information in the calculation page to meet special needs; Step S26, determining the equipment parameter information used for calculation and equipment selection in the calculation page; Step S27, write the equipment parameter information required by the corresponding room into the equipment table page, the equipment parameter information includes equipment name, equipment tag, type, specification, quantity and unit price. 5. The intelligent design method of the auxiliary room of sewage treatment plant according to claim 4, characterized in that, in the step S24, the specific process of setting and obtaining the acquisition method of room size information is: Step S241, through the back-end program of the water treatment engineering design system, the initial length and width dimension information of the room composed of the equipment foundation is read; Step S242, the back-end program of the water treatment engineering design system identifies the location of the room, and reads the space height under the specific location of the room to obtain height information; Step S243, return the height information to the calculation page. 6. The intelligent design method for the auxiliary room of a sewage treatment plant according to claim 5, characterized in that, in the step S3, the design of the auxiliary room is executed at the revit end, and the back-end program of the water treatment engineering design system captures The specific process of automatically generating a 3D model by taking the parameters corresponding to the components in the standard calculation book for auxiliary buildings is as follows: Step S31, grab and calculate the initial length and width information of the room in the page through the back-end program of the water treatment engineering design system, and automatically generate surrounding walls; the height of the wall is identified by the back-end program of the water treatment engineering design system The height of the space between the upper and lower nearest two floors in the view is obtained; Step S32, using the built-in family library model in the water treatment engineering design system and the surrounding walls that have been generated as positioning, grabbing and calculating the position and size information of the corresponding components in the page through the back-end program of the water treatment engineering design system, and automatically Generate walls, panels, doors, windows and equipment foundations; Step S33, read and calculate the height information of the room in the book page through the back-end program of the water treatment engineering design system, generate a solid three-dimensional model, and display it on the revit terminal. 7. The intelligent design method for the auxiliary room of sewage treatment plant according to claim 6, characterized in that, in the step S3, the design of the auxiliary room is carried out at the revit end, and the back-end program of the water treatment engineering design system grasps The specific process of automatically generating a 3D model by taking the parameters corresponding to the components in the standard calculation book for auxiliary buildings also includes: Step S34, if the solid three-dimensional model displayed on the revit terminal meets the design requirements, then use the preset automatic drawing plug-in on the revit terminal to export drawings that meet the predetermined requirements; Step S35, if the solid 3D model displayed on the revit terminal does not meet the design requirements, modify the model on the revit terminal; after modification, use the preset automatic drawing plug-in on the revit terminal to export drawings that meet the predetermined requirements. 8. The intelligent design method for the auxiliary building of sewage treatment plant according to claim 7, characterized in that, in the step S35, if the solid three-dimensional model displayed on the revit end does not meet the design requirements, then the model is carried out on the revit end The specific process of modification includes: Step S351, establishing the component to be modified, selecting the component on the Revit terminal and moving it to a predetermined position to generate a new room arrangement form; Step S352, based on the new room layout form, identify the room size information in the new room layout form through the back-end program of the water treatment engineering design system, and return the new room size information to the calculation page.

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