CN110781536B - Building flat skylight node generation method, system, computer equipment and storage medium - Google Patents

Abstract

The application relates to a building flat skylight node generation method, a system, computer equipment and a storage medium. The method comprises the following steps: the method comprises the steps of obtaining a building flat skylight element and size information of the building flat skylight element, determining a generation position of a node according to the size information of the building flat skylight element, and determining a placement position of the node according to the size information and the generation position, so that the placement position of the node can be automatically determined.

Description

Building flat skylight node generation method, system, computer equipment and storage medium

Technical Field

The present disclosure relates to the field of computer aided design, and in particular, to a method, a system, a computer device, and a storage medium for generating a flat skylight node of a building.

Background

In the traditional building design, most of the building design is designed based on a building information model (Building Information Modeling, BIM), the BIM is a datamation tool applied to engineering design, construction and management, related information of various projects is integrated through a parameter model, the related information is shared and transmitted in the whole life cycle process of project planning, operation and maintenance, building data are continuously inserted, integrated and enriched by all links of a building industry chain together, and the related parties are extracted and used, so that the purposes of green low-carbon design, green construction, cost management and control, convenience in operation and maintenance and the like are achieved.

In engineering design construction management, a designer is required to design positioning nodes, and then building flat skylight nodes are generated one by one, so that the building flat skylight nodes cannot be automatically generated.

Disclosure of Invention

In view of the foregoing, it is desirable to provide a method, system, computer device, and storage medium for generating a flat skylight node that can automatically generate the flat skylight node.

A method of building flat roof node generation, the method comprising: acquiring the size information of a building flat skylight element; determining the generation position of the node according to the size information of the building flat skylight element; and determining the placement position of the node according to the size information and the generation position.

In one embodiment, the dimensional information of the architectural flat roof element includes a width of the architectural flat roof and a height of the architectural flat roof; the determining the generation position of the node according to the size information of the building flat skylight element comprises the following steps: acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; and determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes.

In one embodiment, the placement location of the node comprises a placement location of a cover seam panel; the determining the placement position of the node according to the size information and the generation position comprises the following steps: and carrying out coordinate conversion on the first original point and the second original point to obtain the coordinate information of the cover seam plate under the world coordinate system, and determining the coordinate information of the cover seam plate under the world coordinate system as the placement position of the cover seam plate.

In one embodiment, the dimensional information of the architectural flat roof element includes a thickness of the roof panel; the placement positions of the nodes comprise placement positions of the sealing paste in the positive direction, and the placement positions of the sealing paste in the positive direction are parallel to an X axis in the local coordinate system; the determining the placement position of the node according to the size information and the generation position comprises the following steps: translating the thickness of the cover seam plate along the negative direction of the Z axis in the local coordinate system by taking the first original point as a starting point to obtain a first moving point; translating the thickness of the cover seam plate along the negative direction of the Z axis in the local coordinate system by taking the second original point as a starting point to obtain a second moving point; and carrying out coordinate conversion on the first moving point and the second moving point to obtain the sealant coordinate information in the positive direction under the world coordinate system, and determining the sealant coordinate information in the positive direction under the world coordinate system as the placement position of the sealant in the positive direction.

In one embodiment, the dimensional information of the architectural flat roof element includes a width of a roof panel; the placement positions of the nodes comprise placement positions of cement mortar; the determining the placement position of the node according to the size information and the generation position comprises the following steps: moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the first original point as a starting point to obtain a third moving point; moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the second original point as a starting point to obtain a fourth moving point; and carrying out coordinate conversion on the third moving point and the fourth moving point to obtain cement mortar coordinate information under a world coordinate system, and determining the cement mortar coordinate information under the world coordinate system as the placement position of the cement mortar.

In one embodiment, the dimensional information of the architectural flat roof element includes a width of the architectural flat roof and a height of the architectural flat roof; the determining the generation position of the node according to the size information of the building flat skylight element comprises the following steps: acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; taking the insertion point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a third starting point; and determining the positions of the insertion point, the first original point, the second original point and the third original point as the generation positions of the nodes.

In one embodiment, the dimensional information of the architectural flat roof element includes a drain board width; the placement positions of the nodes comprise placement positions of the sealing paste in the lateral direction; the placement position of the sealant in the lateral direction is parallel to the Y axis in the local coordinate system; the determining the placement position of the node according to the size information and the generation position comprises the following steps: taking the insertion point as a starting point, and moving the width of the drain board along the negative direction of the X axis in the local coordinate system to obtain a fifth moving point; moving the width of the drain plate along the negative direction of the X axis in the local coordinate system by taking the first original point as a starting point to obtain a sixth moving point; moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the second original point as a starting point to obtain a seventh moving point; moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the third original point as a starting point to obtain an eighth moving point; performing coordinate conversion on the fifth moving point and the sixth moving point to obtain sealant coordinate information of one side under a world coordinate system, and determining the sealant coordinate information of one side under the world coordinate system as a placement position of one side of the sealant;

And carrying out coordinate conversion on the seventh moving point and the eighth moving point to obtain the coordinate information of the sealing paste on the other side under the world coordinate system, and determining the coordinate information of the sealing paste on the other side under the world coordinate system as the placement position of the sealing paste on the other side.

A method of building flat roof node generation, the method comprising: acquiring the size information of a building flat skylight element; the dimension information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight; acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes; and determining the placement position of the node according to the size information and the generation position.

A building flat skylight node generation system, the system comprising: the acquisition module is used for acquiring the dimension information of the building flat skylight element; the generation position determining module is used for determining the generation position of the node according to the size information of the building flat skylight element; and the placement position determining module is used for determining the placement position of the node according to the size information and the generation position.

A building flat skylight node generation system, the system comprising: the acquisition module is used for acquiring the dimension information of the building flat skylight element; the dimension information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight; the generation position determining module is used for acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes; and the placement position determining module is used for determining the placement position of the node according to the size information and the generation position.

A computer device comprising a memory and a processor, the memory having stored thereon a computer program executable on the processor, the processor performing the steps described in the embodiments above when the computer program is executed.

A computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps described in the above embodiments.

The method, the system, the computer equipment and the storage medium for generating the flat skylight node of the building acquire the flat skylight element of the building and the size information of the flat skylight element of the building, determine the generation position of the node according to the size information of the flat skylight element of the building, and determine the placement position of the node according to the size information and the generation position. According to the element size information of the flat skylight of the building and the node generation position, a designer is not required to design and position the nodes, and then the flat skylight of the building is generated one by one, so that the placement position of the nodes can be automatically determined.

Drawings

FIG. 1 is an application environment diagram of a method of generating a flat skylight node of a building in one embodiment;

FIG. 2 is a flow diagram of a method of generating a flat skylight node of a building in one embodiment;

FIG. 3 is a flow chart of the refinement step of step S21 in one embodiment;

FIG. 4 is a schematic diagram of axes and origin points of a local coordinate system in one embodiment;

FIG. 5 is a schematic diagram of nodes in one embodiment;

FIG. 6 is a flow chart of another refinement step of step S21 in one embodiment;

FIG. 7 is a schematic diagram of axes and origin points of a local coordinate system in one embodiment;

FIG. 8 is a flow diagram of a method of generating a flat skylight node of a building in one embodiment;

FIG. 9 is a block diagram of a construction of a flat skylight node generation system in one embodiment;

fig. 10 is an internal structural view of a computer device in one embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

The method for generating the building flat skylight node can be applied to an application environment shown in fig. 1. The terminal 100 may be, but is not limited to, various personal computers, notebook computers, tablet computers, etc. The terminal 100 includes a memory, a processor and a display. The processor may run building design software, which may be stored in the memory in the form of a computer program. The memory also provides an operating environment for the building design software, and the memory may store operating information for the building design software. Specifically, the display screen can display a design interface of the building design software, and a user can input information through the design interface to perform building design.

In one embodiment, as shown in fig. 2, a method for generating a flat skylight node of a building is provided, and the method is applied to fig. 1 for illustration, and includes the following steps:

step S20, acquiring size information of a flat skylight element of a building;

in the embodiment of the invention, the elements of the flat skylight of the building can be automatically identified by utilizing REVIT. Specifically, according to preset identification information, obtaining a flat skylight element of a building; wherein the identification information is set when the flat skylight of the building is generated. The method for obtaining the building flat skylight element by utilizing REVIT belongs to the prior art, and is not repeated here.

In the embodiment of the present invention, REVIT is the name of a set of software of Autodesk company. The REVIT series software is built for a Building Information Model (BIM), and can help building designers to design, build and maintain buildings with better quality and higher energy efficiency. The REVIT has an application program interface API which is fully open, the REVIT API can access graphic data of a model, access parameter data of the model, create, modify and delete model elements, create plugins to complete the enhancement of UI, create plugins to complete the automation of repeated work, integrate third party applications to complete the connection to an external database, convert data to an analysis application and the like, execute BIM analysis of all kinds, automatically create project documents and the like.

The method for obtaining the building flat skylight element by utilizing REVIT belongs to the prior art, and is not repeated here.

Step S21, determining the generation position of the node according to the size information of the building flat skylight element;

in the embodiment of the invention, the REVIT can be utilized to automatically acquire the size information of the flat skylight element of the building, wherein the size information comprises the following components: the height of the flat roof window, the width of the flat roof window, the height of the drain board, the width of the drain board, the thickness of the window frame, the width of the drain board guide lead skirt, the thickness of the cover seam board, the width of the cover seam board, and the like are not exemplified herein.

In the embodiment of the invention, the generation position of the node is a position in a local coordinate system in the REVIT.

And S22, determining the placement position of the node according to the size information and the generation position.

In the embodiment of the invention, at the generation position, the mobile node is moved according to the size information, and the coordinate conversion from the local coordinate system to the world coordinate system is carried out on the node, so that the placement position of the node is determined.

According to the method for generating the flat skylight node of the building, the flat skylight element of the building and the size information of the flat skylight element of the building are obtained, the generation position of the node is determined according to the size information of the flat skylight element of the building, and the placement position of the node is determined according to the size information and the generation position. According to the size information of the building flat skylight elements and the generation positions of the nodes, a designer is not required to design and position the nodes, and then the building flat skylight nodes are generated one by one, so that the placement positions of the nodes can be automatically determined.

As an alternative embodiment, the dimensional information of the architectural flat roof element includes a width of the architectural flat roof and a height of the architectural flat roof; as shown in fig. 3, a flow chart of a refinement step of step S21 is shown, and step S21 determines a generation position of a node according to size information of the flat skylight element of the building specifically includes:

step S210, obtaining an insertion point in a local coordinate system in REVIT;

in the embodiment of the present invention, as shown in fig. 4, the insertion point is an origin O (0, 0) in a local coordinate system, where the local coordinate system is briefly described, the local coordinate system is a three-axis coordinate system in a REVIT, and an X axis, a Y axis, a Z axis, a positive direction of the X axis is (1, 0), a negative direction of the X axis is (-1, 0), a positive direction of the Y axis is (0, 1, 0), a negative direction of the Y axis is (0, -1, 0), a positive direction of the Z axis is (0, 1), and a negative direction of the Z axis is (0, -1) are provided in the coordinate system. Here, since the local coordinate system in the REVIT belongs to the prior art, the description thereof will not be repeated here.

Step S211, taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point;

Step S212, taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point;

in the embodiment of the present invention, as shown in fig. 4, the system may automatically acquire the positive and negative directions of the insertion point and each axis, and then start moving from the insertion point O, so as to obtain a first origin a and a second origin B.

And step S213, determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes.

Optionally, in one embodiment, the placement position of the node includes a placement position of a cover seam plate; wherein the stitched-over panel is shown in fig. 5. Step S22, determining a placement position of the node according to the size information and the generation position, specifically includes: and carrying out coordinate conversion on the first original point and the second original point to obtain the coordinate information of the cover seam plate under the world coordinate system, and determining the coordinate information of the cover seam plate under the world coordinate system as the placement position of the cover seam plate.

In the embodiment of the invention, since the coordinate information is information of two points, a placement range can be determined according to the coordinate information, that is, the placement range determined by taking a point after one coordinate conversion as a starting point and taking another point after the other coordinate conversion as an ending point is used as a placement position of the cover seam plate.

Optionally, in one embodiment, the dimensional information of the architectural flat roof element includes a thickness of the roof panel; the placement positions of the nodes comprise placement positions of the sealing paste in the positive direction, and the placement positions of the sealing paste in the positive direction are parallel to an X axis in a local coordinate system; the positive direction sealant is shown in fig. 5. Step S22, determining the placement position of the node according to the size information and the generation position, specifically comprising the following steps: translating the thickness of the cover slit plate along the negative direction of the Z axis in the local coordinate system by taking the first original point as a starting point to obtain a first moving point; translating the thickness of the cover slit plate along the negative direction of the Z axis in the local coordinate system by taking the second original point as a starting point to obtain a second moving point; and carrying out coordinate conversion on the first moving point and the second moving point to obtain the sealant coordinate information in the positive direction under the world coordinate system, and determining the sealant coordinate information in the positive direction under the world coordinate system as the placement position of the sealant in the positive direction.

In the embodiment of the invention, since the coordinate information is information of two points, a placement range can be determined according to the coordinate information, that is, a placement range determined by taking a point after one coordinate conversion as a starting point and taking another point after the other coordinate conversion as an end point is taken as a placement position of the sealant in the positive direction.

Optionally, in one embodiment, the dimensional information of the architectural flat roof element includes a width of a roof panel; the placement positions of the nodes comprise placement positions of cement mortar; the cement mortar is shown in fig. 5. Step S22, determining a placement position of the node according to the size information and the generation position, specifically includes: moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the first original point as a starting point to obtain a third moving point; moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the second original point as a starting point to obtain a fourth moving point; and carrying out coordinate conversion on the third moving point and the fourth moving point to obtain cement mortar coordinate information under a world coordinate system, and determining the cement mortar coordinate information under the world coordinate system as the placement position of the cement mortar.

In the embodiment of the invention, since the coordinate information is information of two points, a placement range can be determined according to the coordinate information, that is, the placement range determined by taking a point after one coordinate conversion as a starting point and taking another point after the other coordinate conversion as an ending point is used as a placement position of cement mortar.

As an alternative embodiment, the dimensional information of the architectural flat roof element includes a width of the architectural flat roof and a height of the architectural flat roof; as shown in fig. 6, a flowchart of another refinement step of step S21 is shown, and step S21 determines a generation position of a node according to the size information of the flat skylight element of the building specifically includes:

step S214, obtaining an insertion point in a local coordinate system in REVIT; step S215, taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; step S216, taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; step S217, taking the insertion point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a third starting point; and step S218, determining the positions of the insertion point, the first origin, the second origin and the third origin as the generation positions of the nodes.

In the embodiment of the present invention, as shown in fig. 7, the system may automatically acquire the positive and negative directions of the insertion point and each axis, and then start moving from the insertion point O, so as to obtain a first origin a, a second origin B, and a third origin C.

In the embodiment of the present invention, the descriptions of the steps S214 to S218 are substantially identical to the descriptions of the steps S210 to S213, and are not repeated here.

Optionally, in one embodiment, the dimensional information of the architectural flat roof element includes a drain board width; the placement positions of the nodes comprise placement positions of the sealing paste in the lateral direction; the placement position of the sealant in the lateral direction is parallel to the Y axis in the local coordinate system; the sealing paste in the lateral direction is shown in fig. 5. Step S22, determining a placement position of the node according to the size information and the generation position, specifically includes: taking the insertion point as a starting point, and moving the width of the drain board along the negative direction of the X axis in the local coordinate system to obtain a fifth moving point; moving the width of the drain plate along the negative direction of the X axis in the local coordinate system by taking the first original point as a starting point to obtain a sixth moving point; moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the second original point as a starting point to obtain a seventh moving point; moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the third original point as a starting point to obtain an eighth moving point; performing coordinate conversion on the fifth moving point and the sixth moving point to obtain sealant coordinate information of one side under a world coordinate system, and determining the sealant coordinate information of one side under the world coordinate system as a placement position of one side of the sealant; and carrying out coordinate conversion on the seventh moving point and the eighth moving point to obtain the coordinate information of the sealing paste on the other side under the world coordinate system, and determining the coordinate information of the sealing paste on the other side under the world coordinate system as the placement position of the sealing paste on the other side.

In the embodiment of the invention, since the coordinate information is information of two points, a placement range can be determined according to the coordinate information, that is, a placement range determined by taking a point after one coordinate conversion as a starting point and taking a point after another coordinate conversion as an end point is taken as a placement position of the sealant.

In one embodiment, as shown in fig. 8, a method for generating a flat skylight node of a building is provided, and the method is applied to fig. 1 for illustration, and includes the following steps: step S80, acquiring size information of a flat skylight element of a building; the dimension information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight; step S81, obtaining an insertion point in a local coordinate system in REVIT; step S82, taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; step S83, taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; step S84, determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes; and step S85, determining the placement position of the node according to the size information and the generation position.

In the embodiment of the present invention, the descriptions of the steps S80 to S85 are identical to those of the embodiments, and are not repeated here.

It should be understood that, although the steps in the flowcharts of fig. 2-3 and fig. 6 and 8 are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited to the order of execution unless explicitly recited herein, and the steps may be executed in other orders. Moreover, at least some of the steps of fig. 2-3 and 6, 8 may include multiple sub-steps or stages that are not necessarily performed at the same time, but may be performed at different times, nor does the order in which the sub-steps or stages are performed necessarily occur sequentially, but may be performed alternately or alternately with at least some of the other steps or stages.

In one embodiment, as shown in fig. 9, there is provided a building flat skylight node generation system, the system comprising: an acquisition module 90, a generation position determination module 91, and a placement position determination module 92, wherein: an acquisition module 90, configured to acquire a flat skylight element of a building and size information of the flat skylight element of the building; a generation position determining module 91, configured to determine a generation position of a node according to size information of the flat skylight element of the building; a placement location determining module 92, configured to determine a placement location of the node according to the size information and the generated location.

As an alternative embodiment, the dimensional information of the architectural flat roof element includes a width of the architectural flat roof and a height of the architectural flat roof; the generation position determining module 91 is configured to: acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; and determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes.

As an alternative embodiment, the placement location of the node includes a placement location of a cover seam plate; the placement location determination module 92 is configured to: and carrying out coordinate conversion on the first original point and the second original point to obtain the coordinate information of the cover seam plate under the world coordinate system, and determining the coordinate information of the cover seam plate under the world coordinate system as the placement position of the cover seam plate.

As an alternative embodiment, the dimensional information of the architectural flat roof element includes a thickness of the roof panel; the placement positions of the nodes comprise placement positions of the sealing paste in the positive direction, and the placement positions of the sealing paste in the positive direction are parallel to an X axis in the local coordinate system; the placement location determination module 92 is configured to: translating the thickness of the cover seam plate along the negative direction of the Z axis in the local coordinate system by taking the first original point as a starting point to obtain a first moving point; translating the thickness of the cover seam plate along the negative direction of the Z axis in the local coordinate system by taking the second original point as a starting point to obtain a second moving point; and carrying out coordinate conversion on the first moving point and the second moving point to obtain the sealant coordinate information in the positive direction under the world coordinate system, and determining the sealant coordinate information in the positive direction under the world coordinate system as the placement position of the sealant in the positive direction.

As an alternative embodiment, the dimensional information of the architectural flat roof element includes the width of the roof panel; the placement positions of the nodes comprise placement positions of cement mortar; the placement location determination module 92 is configured to: moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the first original point as a starting point to obtain a third moving point; moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the second original point as a starting point to obtain a fourth moving point; and carrying out coordinate conversion on the third moving point and the fourth moving point to obtain cement mortar coordinate information under a world coordinate system, and determining the cement mortar coordinate information under the world coordinate system as the placement position of the cement mortar.

As an alternative embodiment, the dimensional information of the architectural flat roof element includes a width of the architectural flat roof and a height of the architectural flat roof; the generation position determination module 91 is configured to: acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; taking the insertion point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a third starting point; and determining the positions of the insertion point, the first original point, the second original point and the third original point as the generation positions of the nodes.

As an alternative embodiment, the dimensional information of the architectural flat roof element includes a drain board width; the placement positions of the nodes comprise placement positions of the sealing paste in the lateral direction; the placement position of the sealant in the lateral direction is parallel to the Y axis in the local coordinate system; the placement location determination module 92 is configured to:

taking the insertion point as a starting point, and moving the width of the drain board along the negative direction of the X axis in the local coordinate system to obtain a fifth moving point; moving the width of the drain plate along the negative direction of the X axis in the local coordinate system by taking the first original point as a starting point to obtain a sixth moving point; moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the second original point as a starting point to obtain a seventh moving point; moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the third original point as a starting point to obtain an eighth moving point; performing coordinate conversion on the fifth moving point and the sixth moving point to obtain sealant coordinate information of one side under a world coordinate system, and determining the sealant coordinate information of one side under the world coordinate system as a placement position of one side of the sealant; and carrying out coordinate conversion on the seventh moving point and the eighth moving point to obtain the coordinate information of the sealing paste on the other side under the world coordinate system, and determining the coordinate information of the sealing paste on the other side under the world coordinate system as the placement position of the sealing paste on the other side.

In one embodiment, a building flat skylight node generation system is provided, the system comprising: the device comprises an acquisition module, a generation position determination module and a placement position determination module, wherein: the acquisition module is used for acquiring the dimension information of the building flat skylight element; the dimension information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight; the generation position determining module is used for acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes; and the placement position determining module is used for determining the placement position of the node according to the size information and the generation position.

Specific limitations regarding the building flat skylight node generation system may be found in the above limitations regarding the building flat skylight node generation method, and will not be described in detail herein. The modules in the building flat skylight node generation system can be fully or partially realized by software, hardware and a combination thereof. The above modules may be embedded in hardware or may be independent of a processor in the computer device, or may be stored in software in a memory in the computer device, so that the processor may call and execute operations corresponding to the above modules.

In one embodiment, a computer device is provided, which may be a server, and the internal structure of which may be as shown in fig. 10. The computer device includes a processor, a memory, a network interface, and a database connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of the computer device is used for storing size information and the like. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a method of building flat skylight node generation.

It will be appreciated by those skilled in the art that the structure shown in fig. 10 is merely a block diagram of some of the structures associated with the present application and is not limiting of the computer device to which the present application may be applied, and that a particular computer device may include more or fewer components than shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, a computer device is provided that includes a memory and a processor, where the memory stores a computer program executable on the processor, and where the processor implements the steps described in the embodiments above when the computer program is executed.

In one embodiment, a computer readable storage medium is provided, on which a computer program is stored which, when executed by a processor, implements the steps described in the above embodiments.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the various embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples merely represent a few embodiments of the present application, which are described in more detail and are not to be construed as limiting the scope of the invention. It should be noted that it would be apparent to those skilled in the art that various modifications and improvements could be made without departing from the spirit of the present application, which would be within the scope of the present application. Accordingly, the scope of protection of the present application is to be determined by the claims appended hereto.

Claims (10)

1. A method of generating a flat skylight node for a building, the method comprising:

acquiring the size information of a building flat skylight element; the size information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight;

acquiring an insertion point in a local coordinate system in REVIT;

taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point;

Taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point;

determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes;

determining the placement position of the node according to the size information and the generation position;

wherein the node comprises one or more of a joint compound plate, a sealant and cement mortar.

2. The method of claim 1, wherein the placement of the nodes comprises placement of a caulk sheet;

the determining the placement position of the node according to the size information and the generation position comprises the following steps:

and carrying out coordinate conversion on the first original point and the second original point to obtain the coordinate information of the cover seam plate under the world coordinate system, and determining the coordinate information of the cover seam plate under the world coordinate system as the placement position of the cover seam plate.

3. The method of claim 1, wherein the dimensional information of the architectural flat roof element includes a thickness of a roof panel; the placement positions of the nodes comprise placement positions of the sealing paste in the positive direction, and the placement positions of the sealing paste in the positive direction are parallel to an X axis in the local coordinate system;

The determining the placement position of the node according to the size information and the generation position comprises the following steps:

translating the thickness of the cover seam plate along the negative direction of the Z axis in the local coordinate system by taking the first original point as a starting point to obtain a first moving point;

translating the thickness of the cover seam plate along the negative direction of the Z axis in the local coordinate system by taking the second original point as a starting point to obtain a second moving point;

and carrying out coordinate conversion on the first moving point and the second moving point to obtain the sealant coordinate information in the positive direction under the world coordinate system, and determining the sealant coordinate information in the positive direction under the world coordinate system as the placement position of the sealant in the positive direction.

4. The method of claim 1, wherein the dimensional information of the architectural flat roof element includes a width of a roof panel; the placement positions of the nodes comprise placement positions of cement mortar;

the determining the placement position of the node according to the size information and the generation position comprises the following steps:

moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the first original point as a starting point to obtain a third moving point;

Moving the width of the cover seam plate along the positive direction of the Y axis in the local coordinate system by taking the second original point as a starting point to obtain a fourth moving point;

and carrying out coordinate conversion on the third moving point and the fourth moving point to obtain cement mortar coordinate information under a world coordinate system, and determining the cement mortar coordinate information under the world coordinate system as the placement position of the cement mortar.

5. A method of generating a flat skylight node for a building, the method comprising:

acquiring the size information of a building flat skylight element; the size information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight;

acquiring an insertion point in a local coordinate system in REVIT;

taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point;

taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point;

taking the insertion point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a third starting point;

Determining the positions of the insertion point, the first original point, the second original point and the third original point as the generation positions of the nodes;

determining the placement position of the node according to the size information and the generation position;

wherein the node comprises one or more of a joint compound plate, a sealant and cement mortar.

6. The method of claim 5, wherein the dimensional information of the architectural flat roof element includes a drain board width; the placement positions of the nodes comprise placement positions of the sealing paste in the lateral direction; the placement position of the sealant in the lateral direction is parallel to the Y axis in the local coordinate system;

the determining the placement position of the node according to the size information and the generation position comprises the following steps:

taking the insertion point as a starting point, and moving the width of the drain board along the negative direction of the X axis in the local coordinate system to obtain a fifth moving point;

moving the width of the drain plate along the negative direction of the X axis in the local coordinate system by taking the first original point as a starting point to obtain a sixth moving point;

moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the second original point as a starting point to obtain a seventh moving point;

Moving the width of the drain plate along the positive direction of the X axis in the local coordinate system by taking the third original point as a starting point to obtain an eighth moving point;

performing coordinate conversion on the fifth moving point and the sixth moving point to obtain sealant coordinate information of one side under a world coordinate system, and determining the sealant coordinate information of one side under the world coordinate system as a placement position of one side of the sealant;

and carrying out coordinate conversion on the seventh moving point and the eighth moving point to obtain the coordinate information of the sealing paste on the other side under the world coordinate system, and determining the coordinate information of the sealing paste on the other side under the world coordinate system as the placement position of the sealing paste on the other side.

7. A building flat skylight node generation system, the system comprising:

the acquisition module is used for acquiring the dimension information of the building flat skylight element; the dimension information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight;

the generation position determining module is used for acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; determining the positions of the insertion point, the first original point and the second original point as the generation positions of the nodes;

A placement position determining module, configured to determine a placement position of the node according to the size information and the generated position;

wherein the node comprises one or more of a joint compound plate, a sealant and cement mortar.

8. A building flat skylight node generation system, the system comprising:

the acquisition module is used for acquiring the dimension information of the building flat skylight element; the size information of the building flat skylight element comprises the width of the building flat skylight and the height of the building flat skylight;

the generation position determining module is used for acquiring an insertion point in a local coordinate system in REVIT; taking the insertion point as a starting point, and moving the width of the building flat skylight along the positive direction of the Y axis in the local coordinate system to obtain a first starting point; taking the first original point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a second original point; taking the insertion point as a starting point, and moving the height of the building flat skylight along the positive direction of the X axis in the local coordinate system to obtain a third starting point; determining the positions of the insertion point, the first original point, the second original point and the third original point as the generation positions of the nodes;

A placement position determining module, configured to determine a placement position of the node according to the size information and the generated position;

wherein the node comprises one or more of a joint compound plate, a sealant and cement mortar.

9. A computer device comprising a memory and a processor, the memory having stored thereon a computer program executable on the processor, characterized in that the processor, when executing the computer program, implements the steps of the method according to any of claims 1 to 4 or 5 to 6.

10. A computer readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the steps of the method of any of claims 1 to 4 or 5 to 6.