KR20200140049A - System and method for producing and providing pipe for one-touch modular systems, pipes for one-touch modular systems, order servers for one-touch modular systems and methods of operation thereof - Google Patents

Abstract

The present invention relates to a system and a method for producing and providing a pipe for a one-touch modular system, a pipe for a one-touch modular system, an ordering server for a one-touch modular system, and a method for operating the ordering server. According to the present invention, the system provides the pipe used for a specific space in one pack while the pipe is preliminarily cut so as to reduce processing time and remove surplus material wastes, so that waste processing costs can be reduced. Moreover, the system secures high quality of a product due to precise cutting to prevent poor construction and simplifies processes to improve safety.

Description

System and method for producing and providing pipes for one-touch modular systems, pipes for one-touch modular systems, order servers for one-touch modular systems, and operation methods thereof (System and method for producing and providing pipe for one-touch modular systems, pipes for one-touch modular) systems, order servers for one-touch modular systems and methods of operation thereof}

The present invention relates to a pipe production system for a one-touch modularization system and a one-touch modularization system using the same, which provides a single pack in a cut state by marking a construction confirmation line on a pipe used in a specific space.

In general, safety management, process management, and eco-friendly construction methods are emerging as very important factors in construction sites. If process management is done well, the construction period can be shortened and safety and productivity can be improved, and the importance of process management is emerging.

For example, when constructing a pipe, if a pipe for work is supplied to the site, the operator sees the drawing and cuts it at the site to fit the dimensions. In other words, the material is piled up in a specific space, and as many pipes as required by the operator are moved to the place where the cutter is located and cut. Then, after moving the cut pipe to the place for construction, the pipe installation work is carried out.

According to the above-described working method, time wasted due to frequent transportation, and if a pipe is loaded on the floor, there may be a risk of damage and defects of the pipe. Defects in the pipe may reduce watertightness and cause leakage. In addition, when cutting the product at the site, dimension errors of the product may occur depending on the skill level of the operator, which may lead to construction defects.

In addition, excess material waste is generated at the site, and costs for waste treatment are incurred. If the work site is narrow, there is a problem that work efficiency is lowered and productivity is lowered accordingly.

An object of the present invention is a construction confirmation line that automatically calculates the number and dimensions of pipes through design drawings, provides them as a modularized pack, and then produces pipes so that pipes can be easily constructed along the construction confirmation line at the site. This is to provide a pipe production system.

In addition, it is an object of the present invention to provide a one-touch modular system for providing a pipe produced by using the pipe production system having the above-described construction confirmation line to a consumer.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention that are not mentioned can be understood by the following description, and will be more clearly understood by examples of the present invention. In addition, it will be easily understood that the objects and advantages of the present invention can be realized by the means shown in the claims and combinations thereof.

The present invention is a frame assembly in which raw material pipes before cutting are loaded and transferred and a plurality of frames are combined; A pipe uploading module installed on the frame assembly and supplying the raw material pipe to a feeding position which is a transfer position of one side of the frame assembly; A pipe transfer module installed on the frame assembly and transferring the raw material pipe supplied from the pipe uploading module to a cutting position, but rotatably clamping one side of the raw material pipe in a longitudinal direction; A pipe push module installed on the frame assembly, rotatably clamping the other side of the raw material pipe transported from the pipe transport module in a longitudinal direction, and pushing the raw material pipe in a direction opposite to the pipe uploading module; A pipe lining module installed on the frame assembly and marking a construction confirmation line on the outer circumferential surface of the raw material pipe with a laser while the other side of the raw material pipe in the longitudinal direction is clamped by the pipe push module; Pipe cutting that is installed on the frame assembly and includes a cutter for cutting the raw material pipe while the other side of the raw material pipe in the longitudinal direction is clamped by the pipe push module to generate a plurality of good-quality pipes having a preset length module; And a pipe sorting module for separately loading the good pipe and the non-standard pipe by classifying the good pipe and the non-standard pipe remaining after the production of the good pipe, wherein the cutting length of the raw material pipe is an architectural design drawing Depending on the result of calculating the length and number of pipes for a one-touch modular system constructed in a specific space in the pipe calculation unit using the shop drawing drawings created in the shop drawing drawing creation unit based on the architectural design drawings for construction work prepared by the provider department. It provides a pipe production system for a one-touch modular system, characterized in that determined.

The pipe uploading module includes a belt in which a plurality of raw material pipes are loaded in a longitudinal direction, a plurality of guide rollers coupled to one side of the frame assembly to rotatably support the belt, and installed adjacent to one side of the belt A loading portion provided with a pipe rail for guiding the pipe to the feeding position; And a belt roller shaft rotatably installed on the frame assembly, a plurality of belt clamp rollers coupled on the belt roller shaft to fix one end of the belt so that the belt is wound when the belt roller shaft rotates. And an uploading drive unit having a loading motor that rotates the roller shaft, wherein when the belt is wound around the belt clamp roller, the raw material pipe is raised toward the pipe rail.

The frame assembly includes a main frame disposed on an installation surface in a horizontal direction to support the raw material pipe in a longitudinal direction, the pipe transfer module is installed on the main frame, and the raw material pipe is provided on the main frame. At least one pipe clamp having a clamping roller for rotatably clamping the raw material pipe after being uploaded to a position; At least one pipe rolling unit installed under the pipe clamp and having a first support roller rotatably supporting the raw material pipe from the lower side after the raw material pipe is uploaded to the feeding position on the main frame; And a second support roller installed under the pipe clamp and rotatably supporting the raw material pipe from the lower side after the raw material pipe is uploaded to the feeding position on the main frame, and rotating the second support roller. It includes; pipe feeding unit having a roller rotation motor.

The pipe transfer module is installed adjacent to the pipe rail, and when one raw material pipe moving along the pipe rail is supplied to the feeding position, it contacts one side of the outer peripheral surface of the remaining raw material pipe to block the movement of the raw material pipe. It further includes a first input stopper having a blocking rod and an air cylinder providing a driving force to move the blocking rod.

The pipe transfer module has the same configuration as the first input stopper, but further includes a second input stopper for blocking the movement of the raw material pipe by the blocking rod contacting the other side of the outer peripheral surface of the raw material pipe.

A pipe rotation roller installed on the main frame and installed adjacent to the pipe cutting module, the pipe rotation roller supporting the raw material pipe rotatably from the lower side during operation of the cutter and marking of the construction check line, and the pipe rotation roller. It further includes; a drive motor to rotate, and a pipe rotation lifting unit provided with a main air cylinder for lifting the rotation roller.

A clamping unit installed on the main frame, installed adjacent to the pipe lining module, rotatably clamping one end of the raw material pipe adjacent to the pipe cutting module, and a preset moving distance of the raw material pipe toward the cutter It further includes a pipe push module having a pipe push unit provided with a timing belt to be transferred by the amount and a push power unit for moving the timing belt.

The push power unit includes a stepping motor that rotates at an angle corresponding to the preset moving distance when marking of the construction confirmation line on the raw material pipe is completed.

The frame assembly is disposed adjacent to the pipe sorting module, and includes a good product loading part in which the good quality pipes are loaded, and a loss product loading part in which the non-standard pipe is loaded.

The pipe sorting module is installed on the frame assembly, a sorting frame that is obliquely disposed with a bottom surface on which the frame assembly is installed, a guide plate movably coupled to one end of the sorting frame, and installed on the sorting frame. And an air cylinder configured to move the guide plate by having a cylinder rod coupled to the guide plate, and a space between the good product loading part and the loss product loading part is blocked by the movement of the guide plate.

The pipe sorting module includes the guide plate extending from the sorting frame when the good pipe is generated and transferred to block the entrance of the loss product loading part, and when the non-standard pipe is transferred, the guide plate of the sorting frame It is fixed to the end, characterized in that to open the entrance of the loss product loading portion.

In addition, the present invention provides an architectural design drawing providing unit for providing an architectural design drawing for construction construction; A shop drawing drawing providing unit for creating a shop drawing drawing through the architectural design drawing; A pipe calculator configured to calculate at least one of a length, a type, and a number of pipes by using programming of preset conditions for the shop drawing drawing; And a pipe providing unit for a one-touch modularization system that cuts the pipe according to the information of the pipe calculated through the pipe calculation unit and provides a single pack according to the type and number of pipes required for a specific area, the pipe The calculation unit calculates the depth value of the straight pipe inserted into the joint pipe, calculates the inclination in the direction of gravity, calculates the length of the straight pipe, and uses the pipe production system for a one-touch modular system according to any one of paragraphs 1 to 11 above. It provides a pipe providing system for a one-touch modular system that provides information on the length of the straight pipe.

In addition, the present invention provides an architectural design drawing step of providing an architectural design drawing for construction in a construction company; A shop drawing drawing creation step of a facility company creating a shop drawing drawing through the architectural design drawing; A pipe calculation step of calculating at least one of a length, a type, and a number of pipes using programming of preset conditions for the shop drawing drawing; And cutting the pipe in the pipe production system for a one-touch modular system according to any one of claims 1 to 11 according to the information of the pipe calculated through the pipe calculation unit, and the type of pipe required for a specific area, and Including the step of providing a pipe for a one-touch modular system provided in one pack according to the number, and the pipe calculating step calculates the depth value at which the straight pipe is inserted into the joint pipe in which the straight pipe insert is formed in the X-axis, Y-axis and Z-axis directions. And, by calculating the inclination in the direction of gravity, the length of the straight pipe is calculated, and the step of providing the pipe for the one-touch modular system includes a method for providing a pipe for a one-touch modular system by displaying and providing the insertion depth of the straight pipe inserted into the joint pipe. to provide.

In the pipe calculation step, the length from the center of one end to the center of the other end of the pipe is calculated, and the upstream side is designated as “top” based on the flow of water, and the drain outlet side is designated as “bottom”. Calculate the cutting length.

In the pipe calculation step, a receiving height, which is the height of the pipe to be connected, is set, the vertical length of the pipe is calculated through the height difference between the pipes connected to the pipe, and the length in the horizontal direction and the length in the vertical direction. Calculate the length of the pipe.

In the pipe calculation step, the total length of the pipe is calculated by calculating the horizontal length of the pipe, calculating the additional length along the vertical direction of the pipe, and adding the horizontal length to the additional length along the vertical direction. .

In the pipe for a one-touch modular system provided by the method of providing a pipe for a one-touch modular system of claim 13, the pipe for the one-touch modular system includes at least one straight pipe. The pipe for the one-touch modular system further includes a joint pipe connected to the straight pipe.

A straight pipe insertion portion into which at least a portion of the straight pipe is inserted is formed in the joint pipe.

In addition, the present invention provides an architectural design drawing step of providing an architectural design drawing for construction in a construction company; A shop drawing drawing creation step of a facility company creating a shop drawing drawing through the architectural design drawing; A pipe calculation step of calculating at least one of a length, a type, and a number of pipes using programming of preset conditions for the shop drawing drawing; Cut the pipe in the pipe production system for a one-touch modular system according to any one of claims 1 to 11 according to the information of the pipe calculated through the pipe calculation unit, and the type and number of pipes required for a specific area In accordance with the step of providing a pipe for a sample generation one-touch modular system provided to the sample generation in one pack; An error correction step of actually constructing the pipe provided as one pack in the sample generation, checking the error according to the construction, and reflecting the error in the drawing; And a pipe providing step for a multi-generation one-touch modular system providing the pipe corrected through the error correction step as a single pack to a plurality of households, wherein the pipe calculation step is straightforward in the X-axis, Y-axis and Z-axis directions. Calculate the depth value at which the straight pipe is inserted into the joint pipe in which the insertion part is formed, and calculate the length of the straight pipe by calculating the slope in the direction of gravity, and the step of providing the pipe for the one-touch modularization system includes the insertion of the straight pipe inserted into the joint pipe Provides a method of providing a pipe for a one-touch modular system that displays and provides depth.

In addition, the present invention receives the pipe material order information transmitted from the customer terminal, the definition document generation module for generating a pipe material type definition defining a pipe material specification based on the pipe material order information; And pipe material production information including specifications and installation drawings for each pipe material package according to the pipe material type definition, so that a pipe package including at least one of a plurality of pipes and joint pipes and a pipe installation diagram is produced. It provides an order server for a one-touch modular system including an information generation module for transmitting the pipe material production information to a material production plant server.

The pipe material order information may include a specification for each package of at least one of the plurality of pipes and joint pipes, a center length for each package of at least one of the plurality of pipes and joint pipes, and at least one of the plurality of pipes and joint pipes. It includes at least one of an installation type and a design diagram for each package of at least one of the plurality of pipes and joint pipes, and information on the site where at least one of the plurality of pipes and joint pipes is installed.

The pipe material order information includes a center length for each package for at least one of the plurality of pipes and joint pipes, and the definition statement generation module includes a pipe specification for a pipe and the pipe specification based on the center length for each package. Based on, the pipe material type definition including the specification of the joint pipe for the joint pipe is generated.

The pipe material order information includes at least one installation type of the plurality of pipes and joint pipes, and the definition generating module includes a pipe specification for a pipe set according to the installation type and a joint pipe specification for a joint pipe. Generate the pipe material type definition to include.

The pipe material order information includes a design drawing for each package of at least one of the plurality of pipes and joint pipes, and the definition statement generation module creates a shop drawing drawing through the design drawing for each package, and through the shop drawing drawing The pipe material type definition statement including the calculated straight pipe specification for the pipe and the joint pipe specification for the joint pipe is generated.

The pipe material type definition document defines the pipe material specification including the pipe specification including the name, specification, length, and number of the pipe and the connection pipe specification including the name, specification, and number of the joint pipe. .

The pipe material type definition document defines the pipe material specification including at least one of a pipe specification and a joint pipe specification for at least one of the plurality of pipes and joint pipes, and the information generation module includes the pipe specification and the The pipe material package specification and the pipe material package including at least one of a package pipe specification and a package fitting pipe specification for each of a package pipe and a package fitting pipe, respectively, based on at least one of the joint pipe specifications The pipe production information including the installation diagram for installing at least one of the package pipe and the package joint pipe included separately is generated.

The installation diagram is indicated as'up' on the upstream side of the first package pipe based on the flow of water, indicated as'bottom' on the downstream side of the first package pipe, and on the downstream side of the first package pipe. It is indicated as'up' on the upstream side of the connected package fitting pipe, and'down' on the downstream side of the package fitting pipe connected to the upstream side of the second package pipe different from the first package pipe.

In the installation diagram, when the package fitting pipe is of the LT type, it is marked as'up' on the upstream side of the package fitting pipe based on the flow of water, and marked as'bottom' on the downstream side of the package fitting pipe, The middle side between the upstream side and the downstream side of the package joint pipe is marked as'medium'.

In addition, the present invention comprises the steps of receiving pipe material order information transmitted from a customer terminal; Generating a pipe material type definition that defines a pipe material specification based on the pipe material order information; And pipe material production information including specifications and installation drawings for each pipe material package according to the pipe material type definition, so that a pipe package including at least one of a plurality of pipes and joint pipes and a pipe installation diagram is produced. It provides a method of operating an order server for a one-touch modular system comprising the step of transmitting the pipe material production information to a material production plant server.

The pipe material order information may include a specification for each package of at least one of the plurality of pipes and joint pipes, a center length for each package of at least one of the plurality of pipes and joint pipes, and installation of at least one of the plurality of pipes and joint pipes It includes at least one of a type and a design diagram for each package of at least one of the plurality of pipes and joint pipes, and field information of at least one of the plurality of pipes and joint pipes.

The pipe material order information includes a specification for each package of at least one of the plurality of pipes and joint pipes, and the step of generating the pipe material type definition may include a pipe specification and a joint for a pipe corresponding to the package specification. The pipe material type definition document including the joint pipe specification for the pipe is created.

The pipe material order information includes a center length for each package of at least one of the plurality of pipes and joint pipes, and the step of generating the pipe material type definition may include a pipe specification for a pipe based on the center length for each package. And generating the pipe material type definition document including the joint pipe specification for the joint pipe based on the pipe specification.

The pipe material order information includes at least one installation type of the plurality of pipes and joint pipes, and generating the pipe material type definition,

The pipe material type definition statement including a pipe specification for a pipe set according to the installation type and a joint pipe specification for a joint pipe is generated.

The pipe material order information includes a design drawing for each package of at least one of the plurality of pipes and joint pipes, and the step of generating the pipe material type definition may include creating a shop drawing drawing through the design drawing for each package, and the The pipe material type definition statement including the pipe specification for the pipe calculated through the shop drawing drawing and the joint pipe specification for the joint pipe is generated.

The pipe material type definition includes a pipe specification including a name, a standard, a length, and a number of the pipe, and a joint pipe specification including a name, standard, and number of the joint pipe.

The pipe material type definition document defines the pipe material specification including a pipe specification and a joint pipe specification for at least one of the plurality of pipes and joint pipes, and transmitting the pipe material production information includes the pipe specification And the pipe material package specification and the pipe material including at least one of a package straight pipe specification and a package joint pipe specification for each of a package pipe and a package joint pipe included for each pipe package, based on at least one of the joint pipe specifications. The pipe material production information including the installation diagram for installing the package pipe included for each package and the package joint pipe is generated.

The installation diagram is indicated as'up' on the upstream side of the first package straight pipe based on the flow of water, indicated as'down' on the downstream side of the first package pipe, and on the downstream side of the first package pipe. It is indicated as'up' on the upstream side of the connected package fitting pipe, and'down' on the downstream side of the package fitting pipe connected to the upstream side of the second package pipe different from the first package pipe.

In the installation diagram, when the package fitting pipe is of the LT type, it is marked as'up' on the upstream side of the package fitting pipe based on the flow of water, and marked as'bottom' on the downstream side of the package fitting pipe, The middle side between the upstream side and the downstream side of the package joint pipe is marked as'medium'.

According to the present invention, since a construction confirmation line is marked with a laser on a pipe for a one-touch modular system, cut to a required size at the site, and provided as one pack, there is an effect of simplifying construction at the site and improving workability.

In addition, since the construction confirmation line is provided on the pipe, there is an effect of reducing construction errors.

According to the present invention, processing time is shortened as pipes used in a specific space are provided in one pack in a pre-cut state, and waste disposal costs are reduced because excess material waste is not generated. In addition, the high quality of the product is secured by accurate dimensional cutting, thereby preventing unimplemented work, and improving safety through process simplification.

In addition, according to the present invention, by providing at least one of the pipes and joint pipes ordered by the customer and a pipe installation diagram, there is an advantage that the site manager or site supervisor who supervises the site can easily supervise the installation of piping materials. .

According to the present invention, by simplifying unnecessary processes and drawings-related processes between loading-shop-generation at a construction site, small transportation at the construction site is greatly reduced, and there is no on-site cutting, so the difficulty of work is lowered, and workers can be easily obtained at low wages. As a result, the rate of safety accidents also decreases.

In addition, by providing a single piping package, construction companies can organize and organize on-site, safe site management, equipment companies can achieve low labor costs, safe construction, shortened construction period, easy and safe work for workers, and efficient physical fitness management. As a result, it is possible to simplify the process of the construction site, reduce small transportation, safe construction, and expenditure of low labor costs, thereby maximizing the overall order system efficiency.

1 is a block diagram schematically showing a one-touch modular system according to an embodiment of the present invention.
2 is a flowchart schematically illustrating a method of providing a one-touch modular system according to an embodiment of the present invention.
3 is a flowchart schematically illustrating a method of providing a one-touch modular system according to another embodiment of the present invention.
4 is a flowchart illustrating a detailed process of an error correction step according to FIG. 3 by way of example.
FIG. 5 is a diagram schematically illustrating an example of a pipe calculation step of FIG. 2 in use.
6 is a side view schematically showing a pipe production system for a one-touch modular system according to an embodiment of the present invention.
7 is an enlarged side view of a main part of FIG. 6.
8 is a one-way front view showing some major configurations according to FIG. 6.
9 and 10 are side views illustrating a part of the pipe uploading module according to FIG. 6.
11 is a front view showing the pipe transfer module according to FIG. 6.
12 is a front view showing another part of the pipe transfer module according to FIG. 6.
13 is a diagram showing a detailed shape of a second input stopper according to FIGS. 11 and 12.
14 is a front view showing a part of the pipe rotation lifting unit and the pipe transfer module according to FIG. 6.
15 is a side view illustrating a part of the pipe rotation lifting unit and the pipe transfer module according to FIG. 14.
16 is a front view illustrating the pipe cutting module according to FIG. 6.
17 is a side view illustrating the pipe cutting module according to FIG. 16.
18 is a side view illustrating the pipe lining module according to FIG. 6.
19 is a plan view illustrating the pipe lining module according to FIG. 18.
20 is a plan view illustrating a pipe push module according to FIG. 6.
21 is a side view illustrating the pipe push module according to FIG. 20.
22 is a side view illustrating a clamping part of the pipe push module according to FIG. 20.
23 is a front view showing an installation state of the pipe splitting module according to FIG. 6.
24 is a side view showing the pipe classification module according to FIG. 23.
25 is a plan view showing the pipe classification module according to FIG. 23.
26 is a system block diagram schematically showing an order system for a one-touch modular system including an order server of the one-touch modular system according to the present invention.
FIG. 27 is an exemplary diagram for calculating the center length described in the pipe material type definition when the pipe material order information shown in FIG. 26 is the center length for each package.
28 is an exemplary view showing an embodiment of a pipe material type definition generated based on the pipe material order information shown in FIG.
29 is an exemplary view showing an embodiment of an installation drawing generated based on the pipe material type definition document shown in FIG. 28.
30 is a flow chart showing a method of operating an order server for a one-touch modular system according to the present invention.

The above-described objects, features, and advantages will be described later in detail with reference to the accompanying drawings, and accordingly, one of ordinary skill in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of known technologies related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description will be omitted. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar elements.

Hereinafter, it means that an arbitrary component is disposed on the "top (or lower)" of the component or the "top (or lower)" of the component, the arbitrary component is arranged in contact with the top (or bottom) of the component. In addition, it may mean that other components may be interposed between the component and any component disposed on (or under) the component.

In addition, when a component is described as being "connected", "coupled" or "connected" to another component, the components may be directly connected or connected to each other, but other components are "interposed" between each component. It is to be understood that "or, each component may be "connected", "coupled" or "connected" through other components.

The present invention relates to a'one-touch modular system'. The one-touch modular system includes a method of providing a one-touch modular system including a method of providing a pipe for a one-touch modular system, a pipe production system with a construction check line for a one-touch modular system, an order server for a one-touch modular system, and an operation method of the order server for a one-touch modular system. It means a system that includes all. In the present invention,'pipe' is used as a term that comprehensively means a hollow tube shape. In the present invention, the term'pipe' is used as a term to mean a state in which pipes are installed alone or connected to a plurality of pipes in an unprocessed or processed state.

In the present invention, the pipe for the one-touch modular system will be provided in the form of a package (pack) in which various pipes having a plurality of shapes, a plurality of lengths, and a plurality of diameters required for construction in a specific place or space are all contained in one package. I can.

Accordingly, the'one-touch modular system' of the present invention may be expressed as a'one-pack system'. That is, in this specification, the'one-touch modular system' refers to the same system as the'one-pack system'.

Hereinafter, the one-touch modular system will be described in the order of a pipe providing system and a method for a one-touch modular system, a pipe production system with a construction confirmation line, and an operation method of an order server for a one-touch modular system.

1 is a block diagram schematically showing a one-touch modular system according to an embodiment of the present invention. 2 is a flowchart schematically illustrating a method of providing a one-touch modular system according to an embodiment of the present invention. 3 is a flowchart schematically illustrating a method of providing a one-touch modular system according to another embodiment of the present invention. 4 is a flowchart illustrating a detailed process of an error correction step according to FIG. 3 by way of example. FIG. 5 is a diagram schematically illustrating an example of a pipe calculation step of FIG. 2 in use.

As shown in Fig. 1, the pipe providing system 1000 for a one-touch modular system includes an architectural design drawing providing unit 1100, a shop drawing drawing drawing unit 1200, a pipe calculating unit 1300, and a one-touch modular system pipe providing unit. (1400).

More specifically, the architectural design drawing providing unit 1100 creates architectural design drawings for construction work. The architectural design drawing providing unit 1100 provides the architectural design drawing to the shop drawing drawing drawing unit 1200. Architectural design drawings are generally prepared by construction companies.

Next, using the architectural design drawings provided from the architectural design drawing providing unit 1100, the shop drawing drawing drawing unit 1200 creates a shop drawing drawing that exactly matches the actual site. And shop drawing drawings are generally prepared by the facility company.

And, using the shop drawing drawing, the pipe calculation unit 1300 calculates at least one of the total length, type, and number of pipes installed on pipes in a specific space. For example, a specific space can be implemented as a bathroom. The pipe calculation unit 1300 calculates the type and number of pipes installed in the bathroom.

Further, the pipe is programmed through a preset condition and recognized in the shop drawing drawing, so that the pipe calculator 1300 may calculate the type and number of pipes.

To this end, the pipe calculation unit 1300 calculates the depth value of the straight pipe inserted into the joint pipe. Next, by calculating the inclination in the direction of gravity, the pipe calculation unit 1300 may calculate the length of the straight pipe.

In addition, according to the pipe information calculated by the pipe calculation unit 1300, the one-touch modularization system pipe providing unit 1400 cuts the straight pipe by an exact dimension. In addition, the one-touch modularized system pipe providing unit 1400 includes the number of joint pipes according to the type. The one-touch modular system pipe providing unit 1400 provides a straight pipe and a joint pipe in one pack (package, packaging).

As described above, according to the pipe providing system for a one-touch modular system according to an embodiment of the present invention, the pipe required for a specific space is cut in the field as a plurality of pipes are supplied in the correct dimensions and number through design drawings in advance. Efficient construction is possible without performing work or discarding remaining building materials.

Hereinafter, a method for providing a pipe for a one-touch modular system using a pipe providing system for a one-touch modular system will be described in more detail with reference to FIGS. 2 to 4.

As shown, the one-touch modular system pipe providing method (S1000) includes an architectural design drawing providing step (S1100), a shop drawing drawing providing step (S1200), a pipe calculating step (S1300), and a one-touch modular system pipe providing step (S1400). ).

More specifically, the step of providing architectural design drawings (S1100) is a step of creating and providing architectural design drawings for construction.

In addition, the shop drawing drawing providing step (S1200) is a step of creating and providing a shovel draw-in drawing that exactly matches the actual site using the architectural design drawing.

Next, using the shop drawing drawing, the pipe calculation step (S1300) calculates at least one of the total length, type, and number of pipes installed in a pipe in a specific space. For example, a specific space can be implemented as a toilet. At this time, the pipe calculation step (S1300) calculates the type and number of pipes installed in the toilet.

In order to calculate the cut length of the pipe, the pipe calculation step (S1300) obtains the length from the center to the center of the pipe on the shop drawing drawing. In addition, upper, middle, and lower are designated based on the opening of the straight pipe, and the pipe calculation step S1300 may automatically calculate the cut length of the pipe.

That is, since the depth value from the concentric circle center of the straight pipe to the straight pipe insertion part of the joint pipe may be different, the pipe calculation step S1300 specifies upper, middle, and lower.

At this time, based on the water flow direction, the upstream side is designated as "top". Based on the direction of water flow, the drain outlet side is designated as “down”.

Further, the pipe includes a straight pipe type pipe and a joint pipe type, and a part of the straight pipe is inserted into the joint pipe. In addition, the fitting tube is provided with straight pipe inserts in the X-axis, Y-axis and Z-axis directions.

In addition, the upward direction and downward direction are designated as the criteria for flowing water by gravity. As the water flows toward the drainage upright direction, the drainage pipe is assigned an ascending number for the corresponding drainage pipe. And, for sewage, the sewage pipe is assigned an ascending number in the direction of the sewage upstream.

Table 1 below shows the calculated cutting length as an example.

In addition, as another method of calculating the length of the pipe, the pipe calculating step (S1300) primarily calculates the horizontal length of the pipe. Next, the pipe calculation step (S1300) calculates an additional length according to the vertical direction. In addition, in the pipe calculation step (S1300), the total length of the pipe is calculated by adding the horizontal length and the additional length along the vertical direction.

In addition, when the overall height of the specific area is set and the height of the lowermost pipe and the height of the uppermost pipe are set, the height difference between one end and the other end of the pipe between the lowermost pipe and the uppermost pipe may be obtained according to the set number.

And the slope of the pipe is calculated through the height difference. As a result, in the pipe calculation step S1300 through the slope, an additional length according to the vertical direction of the pipe can be obtained.

According to the above, the flow direction of drainage or wastewater and the direction of the joint pipe are designated to match, and the pipe calculation step S1300 may accurately calculate the length and the cut length of the straight pipe.

Next, according to the pipe information calculated in the pipe calculation step S1300, the one-touch modular system pipe providing step S1400 provides one pack including at least one of a straight pipe and a joint pipe.

At this time, the straight pipe is cut by the calculated dimension, and the number of joint pipes is provided according to the type.

In addition, the straight pipe inserted into the joint pipe may be provided by marking the insertion length. Accordingly, by seeing the insertion length in the field, the operator can more easily insert and combine the straight pipe into the joint pipe.

In addition, a method of providing a pipe for a one-touch modular system may not be made in advance, but may be provided in a manner of delivering after production when an order is placed.

As shown in FIG. 3, the pipe providing method for a one-touch modular system (S2000) is compared with the method of providing a pipe for a one-touch modular system (S1000) shown in FIG. Only the steps of providing pipes for modular systems are different.

That is, FIG. 2 is for providing a pipe for a one-touch modular system in one specific space, and FIG. 3 is for providing a pipe for a one-touch modular system in a plurality of identical specific spaces, that is, a plurality of households.

More specifically, the method of providing a pipe for a one-touch modular system (S2000) includes an architectural design drawing providing step (S2100), a shop drawing drawing providing step (S2200), a pipe calculation step (S2300), a sample generation one-touch modular system pipe providing step ( S2400), an error correction step (S2500), and a pipe providing step (S2600) for a multi-generation one-touch modular system.

In addition, the architectural design drawing providing step (S2100), the shop drawing drawing providing step (S2200) and the pipe calculating step (S2300) are respectively an architectural drawing providing step (S1100), a shop drawing drawing providing step (S1200), and a pipe calculating step (S1300). Each of the same and detailed descriptions as described above will be omitted.

And according to the pipe information calculated in the pipe calculation step (S2300), the sample generation one-touch modular system pipe providing step (S2400) is cut by the calculated dimension according to the pipe information calculated in the pipe calculation step (S2300). , The sample generation one-touch modular system pipe providing step (S2400) provides one pack including at least one of a straight pipe and a joint pipe.

At this time, in the step of providing the sample generation one-touch modular system pipe (S2400), the straight pipe is cut by the calculated dimension, and the number of joint pipes according to the type is provided. In addition, the sample generation one-touch modular system pipe providing step (S2400) provides the straight pipe and the joint pipe to the sample generation in one pack.

Next, after actually constructing the pipe provided as one pack for the sample generation, and confirming the error according to the construction, the error correction step (S2500) reflects the error in the drawing.

Next, in the step of providing a multi-generation one-touch modular system pipe (S2600), the pipe modified through the error correction step (S2500) is provided to the plurality of households as one pack.

As shown in FIG. 4, in the error correction step (S2500), a measurement device may be used to perform prior error measurement, pipe length calculation, and correction of the calculated pipe length.

In the case of a site where there are many households, such as an apartment, there should be no errors in the vertical direction because the aluminum formwork is used in the area where the pipe will be placed. However, in practice, the probability of error occurrence increases as the floor goes up, so the burden of error management is bound to increase. Therefore, in order to prevent or correct such an error, the operator may take a measurement picture of the sleeve in which the pipe is to be installed (S2510) and transmit it to the one-touch modular system (S2520). When the measurement picture of the sleeve is transmitted, the one-touch modularization system or modularization team measures the on-site sleeve with CAD (S2530) and corrects the ERP (Enterprise Resource Planning, Enterprise Resource Planning) for the length of the pipe (S2540). It can be produced by modifying and predicting the length of the pipe.

As shown in Fig. 5, the design drawing is for a specific area and the pipe is shown.

And for each pipe, set the number in ascending order according to the height.

In other words, the user sets the number according to the height of the pipe. As an example, it is set to 1 to 5 in FIG. 4. And pipe 1 is the sewage pipe connected to the toilet. Pipe 2 is a horizontal pipe, pipe 4 is a joint pipe, pipe 5 is a horizontal pipe, and pipe 3 is a vertical pipe.

In addition, the height of the basin faucet, the height of the toilet faucet, and the height of the shower faucet are set, and the length of the pipe is calculated through a height difference between the pipes connected thereto.

In addition, as an example of calculating the pipe length, in order to calculate the length of the pipe, the length of the pipe in the horizontal direction is primarily calculated, and the additional length according to the vertical direction is calculated.

Then, the total length of the pipe is calculated by adding the horizontal length and the additional length along the vertical direction.

In addition, when the overall height of the specific area is set and the height of the lowermost pipe and the height of the uppermost pipe are set, a height difference between one end and the other end of the pipe between the lowermost pipe and the uppermost pipe may be obtained according to the set number.

And through the height difference, the slope of the pipe is calculated. Consequently, the additional length along the vertical direction of the pipe can be obtained through the inclination.

In the above-described pipe providing system for a one-touch modular system, the one-touch modular system pipe providing unit may be implemented as a pipe production system for a one-touch modular system that cuts and produces a pipe according to specifications. Hereinafter, a pipe production system for a one-touch modular system will be described in detail. Hereinafter,'raw material pipe' is a pipe before cutting with a length of several m,'good pipe' is a straight pipe cut according to a preset standard, and'non-standard pipe' is a remaining pipe after cutting all good pipes from raw material pipes. Means.

In the following description of a pipe production system with a construction confirmation line, it will be described mainly for components that perform main functions, and a known structure can be used in installing any mechanical device, or coupling, support, connection, friction support, etc. For the components that are used for self-explanation, detailed descriptions will be omitted.

In addition, since a plurality of main frames and sub-frames are used, the main frame and sub-frame should be described with the same drawing number even if the positions are different, and the frames for supporting or fixing components other than the main configuration will be described without using a separate drawing number. To

In addition, hereinafter, all components requiring power are operated by receiving power from the outside of the pipe production system, even if not mentioned separately, and may be supplied with power from a battery or the like if necessary.

In this embodiment, the left side is the direction in which the raw material pipe is input, and the right side is the direction in which the raw material pipe is cut, marked and discharged. Therefore, the left side in the longitudinal direction of the main frame is defined as the input end and the right side is the discharge end.

6 is a side view schematically showing a pipe production system for a one-touch modular system according to an embodiment of the present invention. 7 is an enlarged side view of a main part of FIG. 6. 8 is a one-way front view showing some major configurations according to FIG. 6. 9 and 10 are side views illustrating a part of the pipe uploading module according to FIG. 6. 11 is a front view showing the pipe transfer module according to FIG. 6. 12 is a front view showing another part of the pipe transfer module according to FIG. 6. 13 is a diagram showing a detailed shape of a second input stopper according to FIGS. 11 and 12. 14 is a front view showing a part of the pipe rotation lifting unit and the pipe transfer module according to FIG. 6. 15 is a side view illustrating a part of the pipe rotation lifting unit and the pipe transfer module according to FIG. 14. 16 is a front view illustrating the pipe cutting module according to FIG. 6. 17 is a side view illustrating the pipe cutting module according to FIG. 16. 18 is a side view illustrating the pipe lining module according to FIG. 6. 19 is a plan view illustrating the pipe lining module according to FIG. 18. 20 is a plan view illustrating a pipe push module according to FIG. 6. 21 is a side view illustrating the pipe push module according to FIG. 20. 22 is a side view illustrating a clamping part of the pipe push module according to FIG. 20. 23 is a front view showing an installation state of the pipe splitting module according to FIG. 6. 24 is a side view showing the pipe classification module according to FIG. 23. 25 is a plan view showing the pipe classification module according to FIG. 23.

6 to 25, the pipe production system for a one-touch modularization system (OPS) cuts a plurality of raw material pipes 10 having a predetermined length according to a preset standard, and after cutting a pipe with a good quality product meeting the standard It is an automatic pipe cutting system that sorts and provides the remaining non-standard pipes. The pipe production system (OPS) for a one-touch modular system is designed to correspond to the size of the raw material pipe 10 so as to cut the raw material pipe 10 having a preset length and various diameters.

As shown in FIGS. 6 and 7, a pipe production system (OPS) for a one-touch modular system includes a frame assembly 100 that supports several components.

A pipe uploading module 200 is installed on the frame assembly 100 to load the raw material pipe 10 to be cut to the input end of the frame assembly 100. In addition, a pipe transfer module 300 for transferring or stopping the loaded raw material pipe 10 to a cutting position is installed on the frame assembly 100. The raw material pipe 10 transferred to the cutting position by the pipe transfer module 300 is cut to a preset length by the pipe cutting module 500 while being rotated by the pipe rotation lifting unit 400, and the pipe lining module 600 ), the construction confirmation line 32 is printed.

The cutting and printing finished good pipe 30 is moved to the sorting position by the pipe push module 700, and separated into the good pipe 30 and the non-standard pipe 50 by the pipe sorting module 800 to discharge end After being discharged, it is loaded into each storage.

As shown in FIGS. 6 and 7, the frame assembly 100 is a frame in which components of a pipe production system (OPS) for a one-touch modular system are installed and supported. The frame assembly 100 may include a plurality of main frames 110 supporting components, and a plurality of sub-frames 130 auxiliaryly installed on a main portion of the main frame 110.

The main frame 110 is a form in which a plurality of frames having a length and width sufficient to install the entire components of a one-touch modular system pipe production system (OPS) are mutually assembled. A plurality of components may be installed on the main frame 110, or components may be installed on the sub frame 130 after the sub frame 130 is installed at a required position.

When the raw material pipe 10 is mounted on the main frame 110, a line corresponding to the height may be defined as a pipe input line.

A loading space may be formed by a plurality of sub-frames 130 at the discharge end of the main frame 110. One side of the loading space may be defined as a good product loading part 111 in which the good pipe 30 is loaded, and the other side may be defined as a loss product loading part 112 in which the non-standard pipe 50 is loaded (see FIG. 24).

Referring to FIG. 6, since the raw material pipe 10 is input to the input end of the main frame 110, this section can be defined as a pipe up-loading section. Devices for marking the construction confirmation line 32 on the raw material pipe 10 and cutting the raw material pipe 10 are arranged while rotating the raw material pipe 10 at the center of the main frame 110, so this section is rotated and processed. It can be defined as a section. Since the processed good pipe 30 and the non-standard pipe 50 are discharged at the discharge end of the main frame 110, it may be defined as a pipe unloading section.

7 to 10, the pipe uploading module 200 is a raw material pipe to a feeding position (a position that can be moved by the pipe transfer module) so as to move the raw material pipe 10 to the cutting and lining position. It is a device that loads (10). The pipe uploading module 200 may include a loading unit 210 in which the raw material pipe 10 is loaded and moved, and an uploading driving unit 230 for uploading the raw material pipe 10 from the loading unit 210 to a feeding position. have. The loading part 210 may be installed on one side along the length direction of the main frame 110. The uploading driver 230 may be installed adjacent to the central portion of FIG. 5.

The loading part 210 includes a belt 211 on which the raw material pipe 10 is loaded, a plurality of guide rollers 212 supporting the belt 211 to be movable, and a plurality of A lock plate 213, a tension adjuster 214 for adjusting the tension of the belt 211, a tension bracket 215, and a pipe rail 216 for guiding the raw material pipe 10 to a feeding position.

The belt 211 has a predetermined width and has a plate shape having a length sufficient to support the raw material pipe 10 in the longitudinal direction. Initially, the raw material pipe 10 is manually loaded by the user, but the loaded raw material pipe 10 is automatically transferred and processed. The belt 211 is raised or lowered according to the loading amount of the raw material pipe 10 and should be supported in a curved state by a plurality of guide rollers 212 as shown in FIG. 7. Therefore, the belt 211 is preferably made of a material capable of supporting the load of the raw material pipe 10 and being bent or bent at any curvature.

The plurality of guide rollers 212 may support the belt 211 from the upper side of the sub-frame for supporting a pair to have a'U' shape as shown in FIG. 7. The raw material pipe 10 is loaded in the space formed in the'U' shape. When the raw material pipe 10 is loaded on the belt 211, the belt 211 may be stretched by the loading load. To prevent this, a plurality of lock plates 213 are installed to fix the belt 211 and a tension adjuster 214 is provided.

The lock plate 213 is disposed on one side of the belt 211 based on FIG. 7, and pressurizes the belt 211 according to a control signal to fix or release the pressure to move. The lock plate 213 may fix the belt 211 on the same operating principle as a clamp. However, any type can be applied if it can be fixed so that the belt 211 does not move arbitrarily.

The tension adjuster 214 is fixed on the frame for support by a tension bracket 215. The tension adjuster 214 may adjust the tension of the belt 211 by winding or releasing one end of the belt 211. The tension adjuster 214 allows the belt 211 to always maintain a constant tension.

Meanwhile, the pipe rail 216 is installed adjacent to the guide roller 212 on the opposite side of the tension adjuster 214 based on FIG. 7. The pipe rail 216 supports the raw material pipe 10 to be pushed up from the belt 211 and seated, and then slide to a feeding position to move. Therefore, it is preferable that the uppermost surface of the belt 211 and the upper surface of the pipe rail 216 match, or the upper surface of the pipe rail 216 is disposed somewhat lower than the uppermost surface of the belt 211. Since the raw material pipe 10 must be slid along the pipe rail 216, the pipe rail 216 is preferably in the form of a plate having a size capable of sufficiently supporting the raw material pipe 10. Alternatively, a plurality of pipe rails 216 having a predetermined size may be arranged at regular intervals to support the raw material pipe 10 in a slidable manner.

In the loading unit 210 having the above-described configuration, the belt 211 is moved by the uploading drive unit 230 and the raw material pipe 10 is uploaded to the feeding position.

As shown in FIGS. 8 to 10, the uploading driver 230 includes a loading motor 231 providing a driving force, and first and second sprockets 232 for transmitting driving force generated from the loading motor 231. 233), a belt roller shaft 235 rotated by the loading motor 231, and a plurality of belt clamp rollers 236 installed on the belt roller shaft 235 to wind or unwind the belt 211. have.

The loading motor 231 generates a driving force for winding or releasing the belt 211. The loading motor 231 may be provided as a geared motor. However, if the loading motor 231 can rotate and stop in both directions, any type of motor may be applied. The rotational force of the loading motor 231 is transmitted to the first sprocket 232 by a connecting shaft or the like.

The first sprocket 232 is a rotating body such as a gear that is coupled to the loading motor 231 and transmits the rotational force of the loading motor 231 to the second sprocket 233. The first sprocket 232 is connected to the second sprocket 233 by a belt or chain 234 or the like. To this end, the first sprocket 232 and the second sprocket 233 may have a projection such as a gear formed on the outer circumferential surfaces of the first sprocket 232 and the second sprocket 233 to be coupled to the chain 234.

The second sprocket 233 is fixed to one end of the belt roller shaft 235 and rotates by the first sprocket 232 to rotate the belt roller shaft 235. Since the second sprocket 233 is connected to the first sprocket 232 by a chain 234, when the first sprocket 232 rotates, it rotates together. The second sprocket 233 should be able to rotate the belt roller shaft 235 to a required rotation angle. Therefore, it is possible to design the second sprocket 233 to rotate by the required number of rotations of the belt roller shaft 235 by calculating in advance how much the belt roller shaft 235 rotates when the second sprocket 233 rotates once. Accordingly, diameters of the first sprocket 232 and the second sprocket 233 may vary.

The belt roller shaft 235 is installed on the main frame 110 in the longitudinal direction and is a rotating shaft having a predetermined length. A plurality of belt clamp rollers 236 are installed on the belt roller shaft 235 to fix one end of the belt 211. Therefore, the length of the belt roller shaft 235 is preferably formed to be at least longer than the entire length of the belt 211.

A plurality of belt clamp rollers 236 are fixed on the belt roller shaft 235 at equal or preset intervals. The belt clamp roller 236 serves to wind and release the belt 211 by fixing one end in the longitudinal direction of the belt 211. A method of fixing the belt 211 to the belt clamp roller 236 may be any method such as bolting, bonding with an adhesive, or pressing of a clamp method. 8 and 9, one end in the longitudinal direction of the belt 211 is coupled to the first and second lock plates 213 and the tension adjuster 214, and the other end is coupled to the belt clamp roller 236.

Therefore, when the loading motor 231 rotates, the first sprocket 232 and the second sprocket 233 rotate while rotating the belt roller shaft 235, and the belt clamp roller 236 by rotation of the belt roller shaft 235 ) Rotates. As the belt roller shaft 235 rotates in the forward or reverse direction, the belt 211 is wound or unwound around the belt clamp roller 236.

When the belt 211 is wound around the belt clamp roller 236, as the belt 211 rises in FIG. 8, the'U'-shaped space is reduced, so that the raw material pipe 10 rises. Conversely, when the belt 211 is released from the belt clamp roller 236, the belt 211 descends, thereby increasing the'U'-shaped space. However, since the raw material pipe 10 must be continuously transported to the feeding position for cutting the raw material pipe 10, the belt clamp roller 236 continues to hold the belt 211 until all of the raw material pipe 10 is supplied. It is controlled to rotate only in the winding direction.

In this way, when the belt 211 is wound and pulled up, the raw material pipe 10 rises together, and the raw material pipe 10 is transferred to the feeding position while descending by its own weight along the pipe rail 216 described above. When it is confirmed that the raw material pipe 10 is seated at the feeding position by sensor detection (to be described later), the driving of the loading motor 231 is stopped, and when the processing of the raw material pipe 10 is completed, the loading motor 231 is restarted. It is driven. The uploading operation of the raw material pipe 10 is repeated until all the loaded raw material pipes 10 are exhausted.

When the raw material pipe 10 is seated in the feeding position, the pipe transfer module 300 for transferring the raw material pipe 10 to the cutting and lining position is driven.

7 to 13, the pipe transfer module 300 includes a first input stopper 310 and a second input stopper 320 that block additional uploading of the raw material pipe 10, and the raw material pipe 10. ), a pipe clamp 330 for clamping, a plurality of pipe rolling parts 340, and a pipe feeding part 350 for transferring the uploaded raw material pipe 10 to a cutting position.

As shown in FIG. 11, the first input stopper 310 may be installed adjacent to the pipe rail 216. The first input stopper 310 has a function of blocking other raw material pipes 10 from falling after the raw material pipes 10 falling along the pipe rail 216 of the loading part 210 fall one by one to the feeding position. do.

The first input stopper 310 may be installed on the subframe 130 adjacent to the pipe rail 216. At this time, the first input stopper 310 descends from top to bottom based on FIG. 7 to block the raw material pipe 10 from moving. Since the raw material pipe 10 has a length of several m, a plurality of first input stoppers 310 may be provided.

The first input stopper 310 includes an air cylinder 311 having a cylinder rod, a blocking rod 312 that is coupled to the cylinder rod to move up and down, a speed controller 313 that controls the driving speed of the blocking rod 312, and raw materials. It includes a pipe input guide 314 for guiding the seating position of the pipe 10.

The air cylinder 311 is supplied with electric power to lift the cylinder rod, and the blocking rod 312 coupled to the cylinder rod moves up and down with the lift of the cylinder rod. A pipe input guide 314 is installed to guide the seating position when the raw material pipe 10 is dropped. The pipe input guide 314 may have a plate shape having a predetermined size and may be installed inclined on the sub-frame 130 on which the first input stopper 310 is installed. The pipe input guide 314 is installed to be spaced apart from the pipe rail 216 so as to have a distance corresponding to the diameter of the raw material pipe 10 of various diameters.

Blocking rod 312 After one or more of the raw material pipes 10 are uploaded on the pipe rail 216, the blocking rod 312 is in an elevated state until it falls by its own weight and is seated on the first support roller 341. Controlled to maintain. When one raw material pipe 10 is seated on the first support roller 341, the blocking rod 312 descends to block the other raw material pipe 10 from falling to the feeding position.

However, since the raw material pipe 10 has a length of several m, there is a risk of falling to the feeding position by applying an operating vibration generated during an operation such as pipe cutting. To prevent this, a second input stopper 320 may be installed to block the falling of the raw material pipe 10 in a direction opposite to the first input stopper 310.

As shown in FIG. 13, the second input stopper 320 has the same structure as the first input stopper 310, but the blocking rod 322 rises from the bottom to the top based on FIG. Block 10 so that it does not fall. If the first input stopper 310 contacts one side of the outer circumferential surface of the raw material pipe 10, the second input stopper 320 may be installed to contact the other side of the outer circumferential surface of the raw material pipe 10. The second input stopper 320 is controlled to operate simultaneously with the first input stopper 310. In addition, at least one second input stopper 320 may be installed adjacent to the first input stopper 310, but a plurality of second input stoppers may be installed as necessary.

As described above, when one raw material pipe 10 is seated in the feeding position, the raw material pipe 10 is clamped by the pipe clamp 330.

11, 12, and 14, the pipe clamp 330 is a device for clamping the raw material pipe 10 so as to be rotatable while the raw material pipe 10 is seated at the feeding position. A plurality of pipe clamps 330 may be provided to be installed adjacent to the pipe rolling unit 340 and the pipe feeding unit 350. The pipe clamp 330 serves to clamp the raw material pipe 10 from the upper side after the raw material pipe 10 is seated on the first support roller 341 and the second support roller 351 to be described later. The pipe clamp 330 includes a clamping air cylinder 331 providing a driving force, a floating joint 333 connected to the cylinder rod of the clamping air cylinder 331, and a pair of clamping rollers connected to the floating joint 333 It includes (334). A speed controller 332 may be installed to adjust the speed of the clamping air cylinder 331.

When the cylinder rod of the clamping air cylinder 331 descends, the clamping roller 334 connected to the floating joint 333 clamps the upper side of the outer peripheral surface of the raw material pipe 10. At this time, the contact position of the clamping roller 334 must be changed in accordance with the diameter of the raw material pipe 10. That is, if the diameter of the raw material pipe 10 is small, the descending distance of the clamping roller 334 should be increased, and if the diameter of the raw material pipe 10 is large, the descending distance of the clamping roller 334 should be reduced than when the diameter is small. do. This control may be performed by a controller to be described later.

The clamping of the raw material pipe 10 does not fix the raw material pipe 10, but prevents the raw material pipe 10 from being lifted or separated, so that it is in close contact with the first support roller 341 and the second support roller 351, which will be described later. Keep it After the raw material pipe 10 is clamped, the raw material pipe 10 is transferred to the cutting position.

As shown in FIGS. 8 and 11, each pipe rolling part 340 rotatably supports a first support roller 341 and a first support roller 341 for supporting the raw material pipe 10. And a first roller rotation shaft 342 to rotate, and a first coupling 343 for rotatably supporting the first support roller 341 with respect to the first roller rotation shaft 342.

As shown in FIG. 10, the first support roller 341 is a roller in the form of a long tool having a'V'-shaped groove vertically in a side view. The raw material pipe 10 is seated in the'V'-shaped part. Since the raw material pipe 10 has a length of several m before being cut, a plurality of first support rollers 341 are required to support it. Therefore, a plurality of pipe rolling units 340 must be provided. The first support roller 341 is inserted on the first roller rotation shaft 342 fixed on the sub frame 130 and is rotatably supported by the first coupling 343. The first support roller 341 is a free roller that is not separately driven to rotate, but rotates together when the raw material pipe 10 is rotated by the rotation of the second support roller 351.

8 and 12, the pipe feeding part 350 supports the raw material pipe 10, and a second support roller 351 installed spaced apart from the first support roller 341, and a second support Includes a second roller rotation shaft 352 rotatably supporting the roller 351 and a second coupling 353 rotatably supporting the second support roller 351 with respect to the second roller rotation shaft 352 do. In addition, a roller rotation motor 354 that generates a rotational driving force is coupled to the second roller rotation shaft 352 of the second support roller 351 via a third coupling 355.

The second support roller 351 has the same shape as the first support roller 341 described above, and the raw material pipe 10 is seated in a'V'-shaped groove. The second roller rotation shaft 352 is fixed on the sub frame 130, and the second support roller 351 is fixed on the second roller rotation shaft 352 by a second coupling 353. In addition, a roller rotation motor 354 is coupled to the second roller rotation shaft 352 via a third coupling 355 to rotate the second roller rotation shaft 352. In other words, unlike the first support roller 341, the second support roller 351 is fixed to the second roller rotation shaft 352 and the second roller rotation shaft 352 is rotated by the roller rotation motor 354. The roller 351 is rotated.

Alternatively, the second support roller 351 is rotatably coupled to the second roller rotation shaft 352, and the roller rotation motor 354 is directly connected to the second support roller 351 by the third coupling 355 As a result, the second support roller 351 may be rotated.

8 or 12 is a view of the second support roller 351 from the discharge end side, so when the second support roller 351 is rotated by the roller rotation motor 354, the raw material pipe 10 ) Moves from the input end to the discharge end. For example, when the roller rotation motor 354 rotates the second support roller 351 in a clockwise direction based on FIG. 6, the raw material pipe 10 may move from the input end to the discharge end.

The roller rotation motor 354 may be provided as an induction motor. When the second support roller 351 is rotated while the roller rotation motor 354 rotates, the raw material pipe 10 seated on the second support roller 351 rotates while the plurality of first support rollers 341 also rotate. Is done. As the first support roller 341 and the second support roller 351 rotate, the raw material pipe 10 seated on the first support roller 341 and the second support roller 351 rotates and moves to the cutting position. .

When the raw material pipe 10 is transferred to the cutting position, the raw material pipe 10 is cut by the pipe cutting module 500 while the raw material pipe 10 is rotated by the pipe rotation lifting unit 400.

14 and 15, the pipe rotation lifting unit 400 is a drive motor 411 that provides rotational driving force in a configuration for rotating the raw material pipe 10 at a cutting position, and a drive motor 411 The first timing pulley 412 for outputting the rotational force of the, the pipe rotation roller 413 rotated by the drive motor 411, and the second timing pulley 414 that transmits the rotational force to the pipe rotation roller 413 And a timing belt 415 connecting the first timing pulley 412 and the second timing pulley 414. The pipe rotation roller 413 may further include a clamp 416 and a clamping roller 417 for clamping the raw material pipe 10 to be rotatably clamped without separation.

In addition, the pipe rotation lifting unit 400 is a configuration for raising or lowering the pipe rotation roller 413, and is installed under the drive motor 411 to lift the aforementioned drive motor 411 and components for power transmission. It includes a main air cylinder 431 and an auxiliary air cylinder 432, a loading detection sensor 433 for detecting the raw material pipe 10, and a shock absorber 434 for absorbing shock. Components for rotating the raw material pipe 10 are installed on the upper side of the lower base 400a, and components for elevating the raw material pipe 10 are installed on the lower side of the lower base 400a.

The drive motor 411 may be provided as an induction motor, and rotates by receiving external power. The drive motor 411 is in close contact with the raw material pipe 10 to generate a rotational driving force for rotating the pipe rotation roller 413 that rotates the raw material pipe 10. The rotational force generated by the driving motor 411 is transmitted to the first timing pulley 412 connected to the rotation shaft of the driving motor 411 to rotate the first timing pulley 412.

The first timing pulley 412 is coupled to the rotation shaft of the drive motor 411 and rotates, and is connected to the second timing pulley 414 by a timing belt 415 to reduce the rotational force of the drive motor 411 to the second timing pulley ( 414). Since the second timing pulley 414 is coupled to the rotation shaft of the pipe rotation roller 413, the pipe rotation roller 413 is rotated by the second timing pulley 414.

The pipe rotation roller 413 rises by the main air cylinder 431 and is in close contact with the lower side of the outer circumferential surface of the raw material pipe 10 transferred to the cutting position. Since the pipe rotation roller 413 rotates while the pipe rotation roller 413 is in close contact with the raw material pipe 10, the raw material pipe 10 rotates at the cutting position.

At this time, the clamp 416 descends from the upper side of the pipe rotation roller 413 so that the clamping roller 417 clamps the raw material pipe 10 to be rotatable. Therefore, the raw material pipe 10 can rotate stably. The clamp 416 is coupled to the lower portion of the auxiliary air cylinder 432 to be described later.

Components for rotating the above-described raw material pipe 10 are installed on an upper portion of the lower base 400a disposed under the driving motor 411. The lower base 400a is a plate-shaped frame having a predetermined size. A main air cylinder 431 is installed to lift the lower base 400a.

The main air cylinder 431 is provided in plural and is installed under the lower base 400a. The cylinder rod 431a of the main air cylinder 431 is coupled to the lower surface of the lower base 400a to support the lower base 400a so as to be able to rise or fall. When the main air cylinder 431 receives external electric power and the cylinder rod 431a rises, the lower base 400a rises and rises to the pipe rotation roller 413 as well as the drive motor 411. Accordingly, the pipe rotation roller 413 may be in close contact with the lower side of the outer peripheral surface of the raw material pipe 10.

The auxiliary air cylinder 432 is installed above the pipe rotation roller 413. When the cylinder rod 431a of the main air cylinder 431 rises, the auxiliary air cylinder 432 descends oppositely, thereby maximizing the adhesion force so that the pipe rotation roller 413 more closely adheres to the raw material pipe 10.

The loading detection sensor 433 is a sensor that detects whether the raw material pipe 10 has been moved to the cutting position. To this end, the loading detection sensor 433 may be installed on the sub-frame 130 adjacent to the pipe rotation roller 413. When it is confirmed by the loading detection sensor 433 that the raw material pipe 10 has been moved to the cutting position, the roller rotation motor 354 of the pipe transfer module 300 is stopped. Thereafter, the raw material pipe 10 is rotated by the above-described driving motor 411 and rises to the cutting position.

The shock absorber 434 absorbs the impact applied to the raw material pipe 10 when the pipe rotation roller 413 rises by the main air cylinder 431 and contacts the lower outer circumferential surface of the raw material pipe 10, 10) to prevent damage. To this end, the shock absorber 434 is formed at a position capable of contacting the lower base 400a when the lower base 400a is raised.

In the present invention, the cutting position refers to a position at which the raw material pipe 10 is cut by the pipe cutting module 500. When the raw material pipe 10 enters the cutting position, the raw material pipe 10 is cut according to a preset interval by the pipe cutting module 500, and the laser on the good-quality pipe 30 cut by the pipe lining module 600 Marking (printing the construction confirmation line 32 on the pipe surface) is made.

For example, the length of the raw material pipe 10 is 4m, it may be set to cut at 50cm intervals. In addition, the construction confirmation line 32 may be set to be marked at a distance of 2 cm from one end of the cut good pipe 30. In this case, theoretically, the raw material pipe 10 is cut into eight 50cm long good-quality pipes 30 by the pipe cutting module 500.

However, when the raw material pipe 10 is cut in the pipe cutting module 500, there is a thickness that is lost by the cutter 510, so the number of good pipes 30 may vary when the loss thickness is considered. For example, if the loss thickness during cutting is 2mm, 7 good-quality pipes 30 are produced, and the rest remain as non-standard pipes 50.

When the raw material pipe 10 reaches a cutting position in which the pipe cutting module 500 operates, cutting is performed from one end to a set length. Thereafter, the remaining portion of the raw material pipe 10 is continuously moved to the cutting position and is cut to a set length, and the non-standard pipe 50 is finally left. At this time, after cutting one good pipe 30, the raw material pipe 10 is moved to perform laser marking, and then cutting is made to a set length. Alternatively, after setting all marking positions in advance in consideration of the cutting set length, the loss thickness during cutting, and the marking interval, laser marking may be completed on the entire raw material pipe 10 and then cutting may be performed. However, in the exemplary embodiment of the present invention, laser marking is performed sequentially while cutting the good-quality pipe 30 in order to reduce working time and simplify the machine configuration.

7, 16 and 17, when the raw material pipe 10 is transferred to the cutting position of the pipe cutting module 500, the pipe clamp 330 is operated again to clamp the raw material pipe 10. . At this time, the raw material pipe 10 is rotated at the cutting position, and the pipe cutting module 500 is operated to start cutting.

The pipe cutting module 500 includes a cutter 510 disposed below the pipe input line of the main frame 110, a cutter driving unit 530 that drives the cutter 510, and the cutter 510 so as to be elevated and supported. It includes a cutter lift (550).

The cutter 510 is a device that cuts the raw material pipe 10 by rotationally driven by the cutter driving unit 530. The cutter 510 may be provided with a circular saw in the form of a disk. The cutter 510 is rotatably supported by a cutter rotation shaft 511. The cutter 510 cuts the raw material pipe 10 while rising from the lower side of the pipe input line of the main frame 110 toward the upper side.

The cutter driving unit 530 includes a cutter rotation motor 531 that generates a driving force for rotating the cutter 510 and a first cutter roller 532 for transmitting the driving force of the cutter rotation motor 531 to the cutter 510 And a belt 534 connecting the second cutter roller 533 and the first cutter roller 532 and the second cutter roller 533 to each other.

The cutter rotation motor 531 may be provided as an induction motor and generates a driving force for rotating the cutter 510. The first cutter roller 532 is coupled to the rotation shaft of the cutter rotation motor 531, and the second cutter roller 533 is coupled to the cutter rotation shaft 511. The rotation of the first cutter roller 532 is transmitted to the second cutter roller 533 by the belt 534 to rotate the cutter 510.

The cutter 510 rises only when cutting the raw material pipe 10 and comes into contact with the raw material pipe 10 and should not be in contact with the raw material pipe 10 when moving to the cutting position. For this purpose, a cutter lifting part 550 is provided.

The cutter lifting part 550 may be installed on the sub-frame 130 under the cutter driving part 530. It may include a support frame 551 and a lifting rod 552, and an air cylinder 553 for a cutter for lifting the support frame 551.

The support frame 551 is a plate material coupled to the lower portion of the cutter driving unit 530 and supports the cutter driving unit 530. It is preferable that the support frame 551 has a size larger than at least the cutter rotation motor 531. An elevating rod 552 is coupled to the lower portion of the support frame 551.

The lifting rod 552 ascends or descends by an air cylinder 553 for a cutter and supports the support frame 551 so as to be able to ascend and descend. The lifting rod 552 may be directly connected to the cylinder rod of the air cylinder 553 for the cutter, and it is installed separately from the air cylinder 553 for the cutter, but connected to the air cylinder 553 for the cutter, so that it can be raised or lowered by pneumatic pressure. May be.

The cutter air cylinder 553 is installed under the lifting rod 552 to receive external power to provide a driving force for lifting the cutter driving unit 530 and the cutter 510. A speed controller 570 may be installed adjacent to the cutter air cylinder 553. The lifting speed of the air cylinder 553 for the cutter is controlled by the speed controller 570.

The cutter 510 is finally raised and lowered by the cutter air cylinder 553, and the raw material pipe 10 cut by the cutter 510 becomes a good-quality pipe 30 cut to a preset standard.

It is convenient if the good pipe 30 is provided with a construction confirmation line 32 that guides an appropriate insertion position when assembled with other pipes on site.

When connecting a pipe to a pipe or a pipe to a pipe connector, a rubber ring for airtightness maintenance and a fastening member for preventing the pipe from separating are required. Conventionally, the tightening member and the rubber ring were sequentially manually inserted into the outer circumference of the pipe, and then connected to other pipes or pipe connectors. Therefore, there is an inconvenience of manually separating the rubber ring and the fastening member by hand when connecting and dismantling the pipe and the pipe or connecting and dismantling the pipe and the pipe connector. To solve this problem, a one-touch pipe connection device was developed as disclosed in Korean Patent Registration No. 10-1755002, which is a registered patent of the applicant.

According to the above-described registered patent, it is a one-touch method in which the connection of the pipe is completed by inserting a pipe to be connected and tightening the cap while the cap having a structure in which the sealing member is inserted is connected to a connection pipe part such as a pipe or pipe connector to be connected.

The above-described one-touch modular system pipe system also provides such a one-touch connection pipe. Therefore, in order to improve the convenience in the field, the straight pipe inserted into the joint pipe (the good pipe of the present embodiment) may be provided by displaying the insertion length. Accordingly, by seeing the insertion length in the field, the operator can more easily insert and combine the straight pipe into the joint pipe.

Here, the insertion length may be defined as a minimum length capable of maintaining a coupling position without separating the straight pipe when a straight pipe is inserted into a joint pipe to which a one-touch cap is applied. If such an insertion length is displayed and provided on a straight pipe, as described above, the work speed and precision in the field are improved, so that product construction defects can be greatly reduced.

Therefore, when the production of the good pipe 30 for the one-touch modular system, the construction confirmation line 32 that guides the above-described insertion length is marked on the good pipe 30 and provided. To this end, a pipe lining module 600 is provided.

7, 18 and 19, the pipe lining module 600 is installed adjacent to the pipe cutting module 500, and is disposed above the main frame 110. In more detail, the pipe lining module 600 is disposed above the pipe input line. The pipe lining module 600 includes a laser unit 610 for irradiating a laser, a lining support 530 for supporting the laser unit 610, and a position adjustment unit 650 for adjusting the position of the laser unit 610 , It includes a plurality of height detection sensors 670 for detecting the distance to the raw material pipe (10).

The laser unit 610 generates a construction check line 32 on the outer peripheral surface of the raw material pipe 10 by irradiating a laser. The laser unit 610 has a conventional structure, and components that generate a laser and control the irradiation direction of the laser are accommodated in the unit body 611. The generated laser is irradiated through the laser head 612.

The laser head 612 is coupled to the head supporter 613 and is coupled to the lining support 530 to be described later. The head supporter 613 may be coupled to the support frame 631 by a screw method in which the height is adjusted by raising or lowering by rotation. The laser unit 610 may use a known conventional laser irradiation apparatus.

As the raw material pipe 10 is rotated, the construction confirmation line 32 is marked, so that the laser unit 610 must maintain an appropriate distance between the laser head 612 to which the laser is irradiated with the outer peripheral surface of the raw material pipe 10. To this end, a plurality of the above-described height detection sensors 670 may be installed. The laser unit 610 and the height detection sensor 670 are installed on the lining support 530.

The lining support 530 supports the laser support frame 631 on which the head supporter 613 is mounted, the vertical frame 632 supporting the laser support frame 631, and the vertical frame 632 from the bottom, and the unit body 611 ) May include a base frame 633 coupled to. The support frame 631 and the base frame 633 are disposed along the length direction of the main frame 110, and a vertical frame 632 is installed between them. One end of the vertical frame 632 is coupled to the support frame 631 and the other end is coupled to the base frame 633.

The support frame 631 may be coupled to the vertical frame 632 to allow height adjustment. The head supporter 613 moves up and down along the height direction of the vertical frame 632 by the position adjusting unit 650, and accordingly, the height of the laser head 612 is adjusted. Accordingly, the distance between the laser head 612 and the raw material pipe 10 is also adjusted.

The position control unit 650 includes an induction motor 651, a motor sprocket 352 coupled to the induction motor 651, a support sprocket 653 coupled to the head support 613, a motor sprocket 352, and It includes a chain 654 connecting the supporter sprocket 653. When the induction motor 651 is driven, the motor sprocket 352 rotates together, and the rotational force of the motor sprocket 352 is transmitted to the supporter sprocket 653 by the chain 654 to rotate the head supporter 613. When the head supporter 613 rotates and rises from the support frame 631, the height of the laser head 612 increases and the distance between the laser head 612 and the raw material pipe 10 increases.

Conversely, when the head supporter 613 rotates in the opposite direction and descends from the support frame 631, the height of the laser head 612 decreases, and the distance between the laser head 612 and the raw material pipe 10 is shortened. In this way, the distance between the laser head 612 and the raw material pipe 10 can be adjusted.

As described above, the good-quality pipe 30 on which the generation of the cutting and construction confirmation line 32 is completed is transferred to the sorting position by the pipe push module 700. In addition, the raw material pipe 10 to be moved to generate the cutting and construction confirmation line 32 is transferred to the sorting position by the pipe push module 700.

As shown in FIGS. 7, 20 to 22, the pipe push module 700 includes a clamping part 710 that clamps the end of the raw material pipe 10 when lining the raw material pipe 10, and the raw material pipe 10 is cut. It includes a pushing pipe push unit 730 and a push power unit 750.

When the construction confirmation line 32 is marked by the pipe lining module 600, the clamping part 710 clamps the front end of the raw material pipe 10 (the end at which cutting is started or cut based on FIG. 6). . The clamping part 710 holds the end of the raw material pipe 10 together with the above-described pipe clamp 330 and thus serves as an auxiliary function to balance the raw material pipe 10 so that it does not shake.

The clamping part 710 includes a clamping roller 334 that clamps the outer circumferential surface of the raw material pipe 10 rotatably from the upper side, and a ball bearing 712 that supports the outer circumferential surface of the raw material pipe 10 rotatably from the lower side, It includes a supporter 713 supporting them, and a detection sensor 714 detecting completion of the lining.

The clamping roller 334 is rotatably coupled to a support shaft installed vertically from a supporter 713 installed perpendicular to the length direction of the main frame 110. The clamping roller 334 may be provided as a urethane roller having a bearing therein. The clamping rollers 334 are provided in a pair to stably clamp the upper outer circumferential surface of the raw material pipe 10 from both sides. In addition, since a bearing is provided inside, the raw material pipe 10 can be rotatably supported in a clamped state.

The ball bearing 712 is disposed under the clamping roller 334 and is disposed between a pair of clamping rollers 334. The ball bearing 712 is also rotatably coupled to a support shaft vertically installed from the supporter 713 to rotatably support the lower outer circumferential surface of the raw material pipe 10.

The detection sensor 714 is a sensor that detects the number of rotations of the raw material pipe 10, or an image sensor that detects whether the creation of the construction check line 32 is completed by photographing the surface of the raw material pipe 10 and analyzing an image. May be. The detection sensor 714 may be applied without limitation to its type as long as the controller can determine whether the generation of the construction check line 32 is completed.

The pipe push unit 730 includes a timing belt 415 for moving the raw material pipe 10, a belt supporter 732 for supporting the timing belt 415, and an auxiliary supporter 733 for adjusting the tension of the timing belt 415. ).

The timing belt 731 serves to movably support the raw material pipe 10 after laser marking and cutting are completed. The timing belt 731 is arranged in an elliptical shape, and both sides of the inner circumferential surface are supported by the belt supporter 732. The timing belt 415 is rotated by the push power unit 750 to move the raw material pipe 10.

The belt supporter 732 may be installed on the main frame 110 or the sub frame 130 adjacent to the clamping part 710. The belt supporter 732 is rotatably coupled to the bracket 732a by the bracket 732a coupled to the main frame 110 or the sub frame 130, which is horizontal with the installation surface, and a ball bearing 732b and a rotating shaft. The timing pulley 732c may include an end cap 732d that is coupled to an end of the rotation shaft to prevent the timing pulley 732c from being separated.

The belt supporters 732 are provided in a pair, are installed at predetermined intervals, and support the timing belt 731 from both sides. A plurality of auxiliary supporters 733 may be installed between the belt supporters 732.

A plurality of auxiliary supporters 733 may be installed between a pair of belt supporters 732. The auxiliary supporter 733 is rotatable to the bracket 733a coupled to the main frame 110 or the sub frame 130 horizontal to the installation surface, the shaft 733b connected to the bracket 733a, and the shaft 733b. It may include a free roller (733c) to be combined. The free roller 733c may be installed at a position that presses the inner circumferential surface of the timing belt 415 in a downward direction. The reason why the free roller 733c is installed in this position is because the free roller 733c serves to push the timing belt 415 to maintain tension. The timing belt 415 may maintain a constant tension by the auxiliary supporter 733.

The push power unit 750 includes a stepping motor 751 and a reducer 752 for providing power. The stepping motor 751 is rotated at a preset angle to move the raw material pipe 10 by a preset length. The stepping motor 751 is controlled by a speed reducer 752 to prevent stop and reverse rotation. The stepping motor 751 is installed adjacent to the belt supporter 732 opposite to the clamping part 710. The timing belt 415 is rotated while the belt supporter 732 rotates by the stepping motor 751. Accordingly, the raw material pipe 10 may be cut by moving to the cutting position by a predetermined length.

After the cutting and laser marking is completed, the good pipe 30 is moved to the storage box by the pipe push unit 730 after the clamping is released from the clamping unit 710 and classified by the pipe sorting module 800.

23 to 25, the pipe classification module 800 is installed adjacent to the pipe cutting module 500 and the pipe lining module 600, and includes a good pipe 30 and a non-standard pipe 50. Classify.

The pipe sorting module 800 is installed on the sorting frame 810 and the sorting frame 810 which are arranged and installed diagonally below the discharge end from which the good pipes 30 are discharged. It may include a guide plate 830 for guiding to 111, an air cylinder 850 for moving the guide plate 830, and a cylinder rod 851.

The classification frame 810 is a frame that supports the guide plate 830, the air cylinder 850, and the cylinder rod 851. The classification frame 810 may be disposed to form a predetermined angle with the lower portion of the main frame 110. When the sorting frame 810 is installed inclined, when the cutting and conveying finished good pipe 30 falls to the good product loading part 111 by its own weight, it can be slowly dropped without being damaged.

The guide plate 830 is movably coupled to the upper end of the sorting frame 810. When the guide plate 830 extends to the maximum from the sorting frame 810, the passage toward the loss product loading part 112 is blocked, so that the pipe is moved only toward the good product loading part 111. Therefore, the good pipe 30 can be classified simply.

Conversely, if the guide plate 830 does not extend from the sorting frame 810, a gap occurs between the loss product loading part 112 and the sorting frame 810. This spacing is larger than the maximum diameter of pipes that can be processed in this system. Therefore, the pipe is immediately dropped to the loss product loading portion 112. Using this principle, if the guide plate 830 is returned to its original position at the turn of the non-standard pipe 50 after the production of the good pipe 30 is completed, the non-standard pipe 50 is transferred to the loss product loading part 112 It falls into and is loaded.

Therefore, the good pipe 30 and the non-standard pipe 50 can be classified and loaded separately with a simple structure.

The above-described one-touch modular system pipe production system may separately include a controller that controls the entire system. The controller may be provided in the production system or may be separately provided outside the production system. The controller receives the detection result from each sensor, controls the entire production system, and transmits various information and control status to the operator's portable terminal. The controller may be implemented in the form of a computer or a separate control device.

A brief description of the process of processing the raw material pipe 10 by the above-described configuration is as follows.

The cut good pipe 30 should be provided with a construction confirmation line 32 guiding an appropriate assembly depth and position when assembling at least one end. Therefore, as described above in order to more easily mark the construction check line 32 on the good pipe 30, the construction check line 32 is also marked while cutting the raw material pipe 10.

For example, it may be set to form a construction confirmation line 32 at one end of the good pipe 30 based on FIG. 23. At this time, after clamping one end of the raw material pipe 10, laser marking is first performed, and after laser marking is completed, a good quality pipe 30 may be produced by performing a cutting process. In this case, a good pipe 30 is produced and a non-standard pipe 50 remains at the end. Alternatively, on the contrary, the length at which the non-standard pipe 50 is generated may be calculated in advance, cut first, and then a good pipe 30 may be produced.

The produced good-quality pipe 30 and non-standard pipe 50 are transferred to the right side of the main frame 110 by the pipe push module 700 and classified by the pipe sorting module 800. If this process is repeated, a plurality of good pipes 30 are produced from one raw material pipe 10.

The process of producing the good pipe 30 will be described in more detail as follows.

First, the worker loads the raw material pipe 10 on the loading part 210 of the pipe uploading module 200. The raw material pipe 10 loaded on the belt 211 is uploaded onto the main frame 110 by the uploading driving unit 230.

The uploaded raw material pipe 10 is transferred to the cutting position by the pipe transfer module 300, in which case the raw material pipes 10 are transferred one by one to the feeding position, and the rest are first input stopper 310 and second input stopper ( 320) blocks the transfer to the feeding position.

One raw material pipe 10 transferred to the feeding position is transferred to the cutting position by the pipe rolling unit 340 and the pipe feeding unit 350 while being clamped by the pipe clamp 330.

The raw material pipe 10 transferred to the cutting position is rotated by the pipe rotation lifting unit 400 in a clamped state. At this time, the raw material pipe 10 is rotated in a state in which one end of the main frame 110 at the discharge end is clamped by the clamping unit 710 of the pipe push module 700. In this way, the construction confirmation line 32 is laser marked on the raw material pipe 10 by the pipe lining module 600 in a state where both sides of the raw material pipe 10 are stably clamped.

Thereafter, the raw material pipe 10 is cut to a predetermined length by the pipe cutting module 500 to produce a good-quality pipe 30. The produced good pipe 30 is transferred to the pipe sorting module 800 by the pipe push unit 730 of the pipe push module 700.

The transferred good product pipe 30 is loaded into the good product loading unit 111, and the above-described process is repeated to produce a plurality of good product pipes 30.

When the non-standard pipe 50 is finally left after the production of the good pipe 30 is completed, the non-standard pipe 50 is automatically sorted into the loss product loading unit 112 and loaded.

Therefore, it is possible to automatically produce the pipe of the length required by the pipe providing system for the one-touch modular system. In addition, even if the length and diameter of the raw material pipe 10 are changed by changing the preset cutting length and the location of the construction check line, it is possible to produce a pipe that meets the required design specifications.

Hereinafter, an order server for a one-touch modular system that provides an order service so that a customer can order a pipe for a one-touch modular system produced by the pipe production system having the above-described configuration, and an operation method thereof will be described.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

26 is a system block diagram schematically showing an order system for a one-touch modular system including an order server of the one-touch modular system according to the present invention. FIG. 27 is an exemplary diagram for calculating the center length described in the pipe material type definition when the pipe material order information shown in FIG. 26 is the center length for each package. 28 is an exemplary view showing an embodiment of a pipe material type definition generated based on the pipe material order information shown in FIG. 29 is an exemplary view showing an embodiment of an installation drawing generated based on the pipe material type definition document shown in FIG. 28. 30 is a flow chart showing a method of operating an order server for a one-touch modular system according to the present invention.

Referring to FIG. 26, the pipe order system 100 ′ for a one-touch modular system may include a customer terminal 110 ′, a pipe material production plant server 120 ′, and an order server 130 ′ for a one-touch modular system. have.

The customer terminal 110 ′ is a terminal through which a customer can input pipe material order information pf to the one-touch modular system order server 130 ′, for example, a smartphone, a tablet PC, or a PDA (Personal Digital Assistant). It may be a computing device including, and may be a wireless computing device including a handheld device having other wireless connectivity functions, or a processing device connected to another wireless modem.

In an embodiment, the customer terminal 110 ′ may be a device used by a site manager for managing a construction site, a material manager for managing materials on the site, and a construction company performing a construction site, but is not limited thereto.

Pipe material order information (pf) is information for ordering at least one of a plurality of pipes and joint pipes to be installed in a plurality of specific areas at a construction site, for example, specifications for each package of at least one of the plurality of pipes and joint pipes , At least one of a center length for each package of at least one of the plurality of pipes and joint pipes, an installation type of at least one of the plurality of pipes and joint pipes, and a design diagram for each package of at least one of the plurality of pipes and joint pipes, It may include field information of at least one of the plurality of pipes and joint pipes.

Here, the package-specific specifications may include a standard, length, and number of at least one of the plurality of pipes and joint pipes installed in the specific area directly manufactured by the customer.

In addition, the center length for each package of at least one of the plurality of pipes and joint pipes may be the center length of at least one of the pipe and joint pipe input by the customer after viewing the blueprint.

In addition, the installation type of at least one of the plurality of pipes and joint pipes is 59 ~ 131 m ² when the construction site is an apartment It may be one of types A, B, and C types and information on the number of households.

The design drawing for each package of at least one of the plurality of pipes and joint pipes may be a design drawing for the specific area in which at least one of the plurality of pipes and joint pipes is installed at a construction site.

When the pipe material production plant server 120' receives the pipe material production information (pg) transmitted from the one-touch modular system order server 130', it requests each of a plurality of specific areas according to the pipe material production information (pg). One pipe package including at least one of a plurality of pipes and joint pipes and a pipe installation diagram may be produced and shipped to the customer. The pipe material production plant server 120 ′ may be a server of a production plant that controls the pipe production system (OPS) for the one-touch modular system described above.

The order server 130 ′ for a one-touch modular system may include an input module 132 ′, a definition document generation module 134 ′, and an information generation module 136 ′.

The input module 132 ′ may receive the pipe material order information pf transmitted from the customer terminal 110 ′, and may transmit the pipe material order information pf to the definition form generation module 134 ′.

The definition document generation module 134 ′ may generate a pipe material type definition document pt for at least one of the plurality of pipes and joint pipes based on the pipe material order information pf input from the input module 132 ′. have.

At this time, when the pipe material order information pf includes the center length for each package of at least one of the plurality of pipes and joint pipes, the definition statement generation module 134 ′ comprises a pipe for the pipe based on the center length for each package. Based on the specification and the pipe specification, a pipe material type definition (pt) including the specification of the joint pipe for the joint pipe may be generated.

In addition, when the pipe material order information pf includes at least one installation type of the plurality of pipes and joint pipes, the definition statement generation module 134 ′ includes a pipe specification and a joint pipe for a pipe set according to the installation type. You can create a pipe material type definition document (pt) that includes the specification for the joint pipe.

In addition, when the pipe material order information pf includes a blueprint for each package of at least one of the plurality of pipes and joint pipes, the definition document generation module 134' creates a shop drawing drawing through the design diagram for each package, A pipe material type definition (pt) including a pipe specification for a pipe calculated through the shop drawing drawing and a joint pipe specification for a joint pipe may be generated.

The above-described pipe material type definition (pt) includes the pipe specification including the name, specification, length and number of the pipe and the pipe material including the connection pipe specification including the name, size, and number of the joint pipe. Specifications can be defined, but are not limited thereto.

In addition, the definition document generation module 134 ′ may determine the material requirements for each pipe type for at least one of a plurality of pipes and joint pipes according to the pipe material type definition document pt, and provide the information to the information generation module 136 ′. However, it is not limited thereto.

The information generation module 136 ′ is the pipe material including at least one of a package pipe specification and a package joint pipe specification for each of a package pipe and a package joint included for each pipe material package based on a pipe material type definition (pt). Pipe material production information pg including a pipe specification for each package and an installation diagram for installing at least one of the package pipe and the package joint pipe included for each pipe material package may be generated.

That is, in the case of including at least one of the plurality of and and joint pipes, the installation diagram is marked with'up' on the upstream side of the pipe based on the flow of water, and'down' on the downstream side of the pipe. Thus, it is possible for a worker at a construction site to easily connect at least one of a plurality of pipes and joint pipes included in one pipe package.

In addition, in the installation diagram, when the flow of water is formed from one side of the fitting tube to the other side based on the package fitting tube, one side of the fitting tube is indicated as'up', and the other side of the fitting tube is' It can be expressed as'ha'.

In addition, in the installation diagram, when the package fitting pipe is of the LT type, it is marked as'up' on the upstream side of the package fitting pipe based on the flow of water, and marked as'bottom' on the downstream side of the package fitting pipe. , It may be marked as'medium' on the middle side between the upstream side and the downstream side of the package fitting pipe.

In addition, the installation diagram may include two first and second joint pipes, and a length of a pipe connected between the first and second joint pipes may be displayed.

For example, by connecting the center line of the first pipe connected to the first pipe and the center line of the second pipe connected to the second joint pipe and the center line of the third pipe, the center crossing point of the first and third pipes and The center length between the center intersections of the second and third pipes may be calculated. In this case, the length of the third pipe calculated by minus the length of the third pipe in which the third pipes of each of the first and second joint pipes do not overlap may be displayed from the center length.

In this case, the pipe material specification may include a diameter, type, length, and number of at least one of the plurality of pipes and joint pipes corresponding to the pipe installation diagram.

As described above, the order system for a one-touch modular system according to the present invention includes an installation diagram and a pipe material package for at least one of a plurality of pipes and joint pipes based on the pipe material order information pf input by the customer terminal 110 ′. By generating pipe material production information (pg) including the pipe material package specifications that separate the package pipe specifications and package joint specifications for each of the package pipes and package joints included by each pipe, There is an advantage of being able to facilitate an order for at least one.

Referring to FIGS. 27 and 28, pipe material order information pf may calculate a center length L of a pipe that is actually applied when a length T of a pipe is input.

In other words, the one-touch modular system order server 130' crosses the center line of the pipe (① V type 956) and the center line of the pipe (120/100A) and pipe (② V type 698) crossing each other. The length of the line (T), joint pipe (V-3L) and joint pipe (V-45L) and pipe (① V-type 956) length (A) and joint pipe (V-3L) and joint pipe (V-45L) ) The length (L) of the pipe (① V-type 956) can be calculated based on the distance (B) between each center intersection and the end.

In addition, the order server 130 ′ for a one-touch modular system may extract the length of at least one of a pipe and a joint pipe from the pipe material order information pf, but is not limited thereto.

The order server 130 ′ for a one-touch modular system has an advantage that a field engineer can easily construct or install by writing the above-described number and a joint pipe type name on at least one of a plurality of pipes and joint pipes.

According to FIG. 28, when the pipe material order information pf includes a specification for each package of at least one of a plurality of pipes and joint pipes, the definition statement generation module 134' is a specification for each package, that is, a plurality of pipes and joints. A pipe specification and a fitting pipe specification may be generated according to a sample pipe specification made as a sample for at least one of the pipes and a sample fitting pipe specification.

That is, the definition generating module 134 ′ is the pipe material specification including the pipe specification including the name, specification, length, and number of the pipe and the connection pipe specification including the name, specification, and number of the joint pipe. You can create a pipe type definition (pt) that defines.

Here, as shown in FIG. 28, the pipe material type definition (pt) includes the construction company, the construction site name, the type name, the facility company, the designation for the straight pipe, the specification (length) and the number (number) of the pipe. It may include a joint pipe specification including the name, size, and number (quantity).

Referring to FIG. 29, the order server 130 ′ for a one-touch modular system may generate a pipe material type definition document based on pipe material order information pf, and then generate a pipe installation diagram based on the pipe material type definition document. have.

FIG. 29 shows the pipe installation diagram generated by the one-touch modular system order server 130 ′, that is, in the case of an apartment 84A type shared bathroom, an installation diagram for installing at least one of the plurality of pipes and joint pipes .

For example, in the pipe installation drawing, the installation number, type, and length of the pipe may be indicated as "① V-type 956", and in the case of a joint pipe, the type or type of the joint pipe may be indicated as "V-3L". have.

Briefly, in the case of a toilet (not shown), the one-touch modular system order server 130' is a joint pipe (V-3L) connected to the pipe 120/100A connected to the drain pipe of the toilet (not shown), and the joint Pipe (① V-type 956) connected to pipe (V-3L), joint pipe (V-45L) connected to pipe (① V-type 956), pipe connected to joint pipe (V-45L) (② V-type 698) May be indicated on the pipe installation diagram, and the pipe (② V-shaped 698) is connected to the upright pipe of the toilet, that is, a vertical pipe.

Here, in the pipe 120/100A, “A” may indicate the inner diameter or the outer diameter of the pipe, “120” may indicate the length of the pipe, and “100” may indicate the diameter of the pipe.

In addition, in the case of a bathroom sink (not shown), the pipe server 130 for a one-touch modular system is connected to the multi-height pipe 140/35A of the bathroom sink (not shown). Connected pipe (③ 420/35A), pipe (CLT50×35) connected to pipe (③ 420/35A), pipe (④ 160/50A) connected to pipe (CLT50×35), pipe (④ 160/50A) Joint pipe connected to (LT50×50), pipe connected to joint pipe (LT50×50) (⑤ 169/50A), joint pipe connected to pipe (⑤ 169/50A) (PT50), joint pipe (PT50) and multiple heights Pipe (⑥ 160/50A), then pipe (⑦ 253/50A) connected to joint pipe (LT50×50), joint pipe (LT50×50) connected to pipe (⑦ 253/50A), joint pipe (LT50×50) Pipe connected to (⑧ 169/50A), joint pipe (PT50) connected to pipe (⑧ 169/50A), joint pipe (PT50) and multi-height pipe (⑨ 180/50A) and joint pipe (LT50×50) and bathroom Pipes (⑩ 306/50A) connected to upright pipes of drainage pipes can be marked.

At this time, by assigning a number corresponding to the connection order in the case of pipes to the installation diagram shown in FIG. 29, the operator can check and construct at least one of a plurality of pipes and joint pipes included in one pipe package, and A site supervisor, such as a site manager, can make it easy to recognize the construction situation by checking the pipe installation diagram.

Here, the pipe server 130 for a one-touch modular system may indicate'up' on the upstream side of the pipe and'down' on the downstream side of the pipe based on the flow of water in the pipe installation diagram. If the pipe is a'L'-shaped or'V'-shaped type in which water flow is formed from one side to which the straight pipe is connected to the other side to which the other pipe is connected, one side of the joint pipe is marked as'up', and the other side of the joint pipe It can be expressed as'bottom', but is not limited thereto.

Referring to FIG. 30, the order server 130 ′ for a one-touch modular system may receive pipe material order information pf transmitted from the customer terminal 110 ′ (S110).

That is, when the customer terminal 110' is connected to the order server 130' for one-touch modularization system, inputs pipe material order information (pf) on the connection screen and selects input completion, the pipe material order information (pf) is Can receive.

Pipe material order information (pf) is information for ordering at least one of a plurality of pipes and joint pipes to be installed in a plurality of specific areas at a construction site, for example, specifications for each package of at least one of the plurality of pipes and joint pipes , At least one of a center length for each package of at least one of the plurality of pipes and joint pipes, an installation type of at least one of the plurality of pipes and joint pipes, and a design diagram for each package of at least one of the plurality of pipes and joint pipes, It may include field information of at least one of the plurality of pipes and joint pipes.

Here, the package-specific specifications may include a standard, length, and number of at least one of the plurality of pipes and joint pipes installed in the specific area directly manufactured by the customer.

In addition, the center length for each package of at least one of the plurality of pipes and joint pipes may be the center length of at least one of the pipe and joint pipe input by the customer after viewing the blueprint.

In addition, the installation type of at least one of the plurality of pipes and joint pipes is 59 ~ 131 m ² when the construction site is an apartment It may be one of types A, B, and C types and information on the number of households.

The design drawing for each package of at least one of the plurality of pipes and joint pipes may be a design drawing for the specific area in which at least one of the plurality of pipes and joint pipes is installed at a construction site.

The order server 130 ′ for a one-touch modular system may generate at least one pipe material type definition document pt among the plurality of pipes and joint pipes based on the pipe material order information pf (S120).

Here, the pipe material type definition (pt) may include a construction site type, a standard and number of at least one of the plurality of pipes and joint pipes included in one pack, and a unit price for the one pack. There is no limit.

In addition, the order server 130 ′ for a one-touch modular system may determine a material requirement for each type of at least one of a plurality of pipes and joint pipes according to a pipe material type definition (pt).

The one-touch modular system order server 130 ′ generates the pipe installation diagram for installing at least one of the plurality of pipes and joint pipes based on the pipe material type definition (pt), and according to the pipe installation diagram, the Pipe material production information pg may be generated by generating the pipe material specification including the diameter, type, length, and number of at least one of a plurality of pipes and joint pipes.

At this time, in the pipe installation diagram,'up' is indicated on the upstream side of the pipe based on the flow of water, and'down' is indicated on the downstream side of the pipe, so that a plurality of workers at the construction site are included in one pack. It is possible to facilitate the connection of at least one of the pipe and the joint pipe.

In addition, in the pipe installation drawing, when the flow of water is formed from one side of the joint pipe to the other side based on the joint pipe, one side of the joint pipe is marked as'up', and the other side of the joint pipe is' It can be expressed as'ha'.

In addition, the pipe installation diagram includes two first and second joint pipes, and a length of a straight pipe connected between the first and second joint pipes may be displayed.

For example, by connecting the center line of the first straight pipe connected to the first joint pipe and the center line of the second straight pipe connected to the second joint pipe and the center line of the third straight pipe, the center crossing point of the first and third straight pipes and The center length between the center intersections of the second and third straight pipes can be calculated. In addition, the length of the third straight pipe calculated by minus the depth of overlap at which the third straight pipes of the first and second joint pipes do not overlap may be displayed from the center length.

In this case, the pipe material specification may include a diameter, type, length, and number of at least one of the plurality of pipes and joint pipes corresponding to the pipe installation diagram.

The one-touch modular system order server 130 ′ transmits a pipe material type definition (pt) to the customer terminal 110 ′, and a plurality of pipes installed in each of a plurality of specific areas included in the pipe material order information pf And pipe material production information pf may be transmitted to the pipe material production plant server 120 ′ so that one pack including a pipe installation diagram connecting at least one of the joint pipes and the plurality of pipes is produced and shipped. (S140).

As described above with reference to the drawings illustrated for the present invention, the present invention is not limited by the embodiments and drawings disclosed in the present specification, and various by a person skilled in the art within the scope of the technical idea of the present invention. It is obvious that transformation can be made. In addition, even if not explicitly described and described the effects of the configuration of the present invention while describing the embodiments of the present invention, it is natural that the predictable effects of the configuration should also be recognized.

100: frame assembly 200: pipe uploading module
300: pipe transfer module 400: pipe rotation lifting unit
500: pipe cutting module 600: pipe lining module
700: pipe push module 800: pipe sorting module

Claims (40)

A frame assembly in which raw material pipes before cutting are loaded and transferred, and a plurality of frames are combined;
A pipe uploading module installed on the frame assembly and supplying the raw material pipe to a feeding position which is a transfer position of one side of the frame assembly;
A pipe transfer module installed on the frame assembly and transferring the raw material pipe supplied from the pipe uploading module to a cutting position, but rotatably clamping one side of the raw material pipe in a longitudinal direction;
A pipe push module installed on the frame assembly, rotatably clamping the other side of the raw material pipe transported from the pipe transport module in a longitudinal direction, and pushing the raw material pipe in a direction opposite to the pipe uploading module;
A pipe lining module installed on the frame assembly and marking a construction confirmation line on the outer circumferential surface of the raw material pipe with a laser while the other side of the raw material pipe in the longitudinal direction is clamped by the pipe push module;
Pipe cutting that is installed on the frame assembly and includes a cutter for cutting the raw material pipe while the other side of the raw material pipe in the longitudinal direction is clamped by the pipe push module to generate a plurality of good-quality pipes having a preset length module; And
A pipe sorting module for separately loading the good pipe and the non-standard pipe by classifying the good pipe and the non-standard pipe remaining after the production of the good pipe;
Including,
The cutting length of the raw material pipe,
The length and number of pipes for a one-touch modular system installed in a specific space are calculated in the pipe calculation unit using the shop drawing drawings created in the shop drawing drawing creation unit based on the architectural design drawings for construction work created by the architectural design drawing provider. Characterized in that it is determined according to the results
Pipe production system for one-touch modular system.
The method of claim 1,
The pipe uploading module
A belt in which a plurality of raw material pipes are loaded in a longitudinal direction, a plurality of guide rollers coupled to one side of the frame assembly to rotatably support the belt, and a plurality of guide rollers installed adjacent to one side of the belt to bring the raw material pipes to a feeding position. A loading portion provided with a pipe rail to guide; And
A belt roller shaft rotatably installed on the frame assembly, a plurality of belt clamp rollers coupled on the belt roller shaft to fix one end of the belt so that the belt is wound when the belt roller shaft rotates, the belt roller Including; an uploading driving unit having a loading motor for rotating the shaft,
When the belt is wound around the belt clamp roller, the raw material pipe is raised toward the pipe rail.
Pipe production system for one-touch modular system.
The method of claim 2,
The frame assembly
It includes a main frame disposed in the horizontal direction on the installation surface to support the raw material pipe in the longitudinal direction,
The pipe transfer module
At least one pipe clamp installed on the main frame and having a clamping roller rotatably clamping the raw material pipe from an upper side after the raw material pipe is uploaded to the feeding position on the main frame;
At least one pipe rolling unit installed under the pipe clamp and having a first support roller rotatably supporting the raw material pipe from the lower side after the raw material pipe is uploaded to the feeding position on the main frame; And
A second support roller installed under the pipe clamp and rotatably supporting the raw material pipe from the lower side after the raw material pipe is uploaded to the feeding position on the main frame, and a roller rotating the second support roller Pipe feeding unit having a rotation motor;
Including
Pipe production system for one-touch modular system.
The method of claim 3,
The pipe transfer module
A blocking rod installed adjacent to the pipe rail and blocking movement of the raw material pipe by contacting one side of the outer circumferential surface of the remaining raw material pipe when one raw material pipe moving along the pipe rail is supplied to the feeding position; Further comprising a first input stopper having an air cylinder providing a driving force to move the blocking rod
Pipe production system for one-touch modular system.
The method of claim 4,
The pipe transfer module
Having the same configuration as the first input stopper, the blocking rod further comprises a second input stopper blocking the movement of the raw material pipe by contacting the other side of the outer peripheral surface of the raw material pipe.
Pipe production system for one-touch modular system.
The method of claim 3,
A pipe rotation roller installed on the main frame and installed adjacent to the pipe cutting module, the pipe rotation roller supporting the raw material pipe rotatably from the lower side during operation of the cutter and marking of the construction check line, and the pipe rotation roller. A pipe rotation lifting unit provided with a driving motor that rotates and a main air cylinder for lifting the rotation roller;
Further comprising
Pipe production system for one-touch modular system.
The method of claim 6,
A clamping unit installed on the main frame, installed adjacent to the pipe lining module, rotatably clamping one end of the raw material pipe adjacent to the pipe cutting module, and a preset moving distance of the raw material pipe toward the cutter A pipe push module including a pipe push unit provided with a timing belt for transporting by the amount and a push power unit for moving the timing belt;
Containing more
Pipe production system for one-touch modular system.
The method of claim 7,
The push power unit
When the marking of the construction confirmation line on the raw material pipe is completed, the stepping motor rotates at an angle corresponding to the preset moving distance.
Pipe production system for one-touch modular system.
The method of claim 1,
The frame assembly
Arranged adjacent to the pipe sorting module, including a good product loading portion in which the good-quality pipe is loaded, and a loss product loading portion in which the non-standard pipe is loaded
Pipe production system for one-touch modular system.
The method of claim 9,
The pipe classification module
A sorting frame installed on the frame assembly and obliquely disposed with a floor surface on which the frame assembly is installed, a guide plate movably coupled to one end of the sorting frame, and installed on the sorting frame and coupled to the guide plate It includes an air cylinder for moving the guide plate with a cylinder rod,
Characterized in that the between the good product loading part and the loss product loading part is blocked by the movement of the guide plate
Pipe production system for one-touch modular system.
The method of claim 10,
The pipe classification module
When the good pipe is generated and transported, the guide plate extends from the sorting frame to block the entrance of the loss product loading unit, and when the non-standard pipe is transported, the guide plate is fixed to the end of the sorting frame, and the Characterized in that opening the entrance of the loss product loading section
Pipe production system for one-touch modular system.
An architectural design drawing providing unit that provides architectural design drawings for construction work;
A shop drawing drawing providing unit for creating a shop drawing drawing through the architectural design drawing;
A pipe calculator configured to calculate at least one of a length, a type, and a number of pipes by using programming of preset conditions for the shop drawing drawing; And
A pipe providing unit for a one-touch modular system that cuts the pipe according to the pipe information calculated through the pipe calculation unit, and provides a single pack according to the type and number of pipes required for a specific area,
The pipe calculation unit
Calculate the depth value of the straight pipe inserted into the joint pipe, calculate the inclination in the direction of gravity, calculate the length of the straight pipe, and use the pipe production system for a one-touch modular system according to any one of claims 1 to 11 above. Providing length information of
Pipe supply system for one-touch modular system.
An architectural design drawing providing step in which a construction company provides architectural design drawings for construction construction;
A shop drawing drawing creation step of a facility company creating a shop drawing drawing through the architectural design drawing;
A pipe calculation step of calculating at least one of a length, a type, and a number of pipes using programming of preset conditions for the shop drawing drawing; And
Cut the pipe in the pipe production system for a one-touch modular system according to any one of claims 1 to 11 according to the information of the pipe calculated through the pipe calculation unit, and the type and number of pipes required for a specific area Including the step of providing a pipe for a one-touch modular system provided in one pack according to,
The pipe calculation step
Calculate the depth value at which the straight pipe is inserted into the joint pipe in which the straight pipe insertion portion is formed in the X-axis, Y-axis and Z-axis directions, and calculate the length of the straight pipe by calculating the slope in the direction of gravity,
In the step of providing a pipe for the one-touch modular system, the insertion depth of the straight pipe inserted into the joint pipe is displayed and provided.
How to provide pipes for one-touch modular system.
The method of claim 13,
The pipe calculation step
Calculate the length from the center of one end to the center of the other end of the pipe,
Based on the flow of water, the upstream side is designated as “Up” and the drain outlet side is designated as “Bottom” to calculate the cut length of the pipe.
How to provide pipes for one-touch modular system.
The method of claim 13,
The pipe calculation step
The receiving height, which is the height of the pipe to be connected, is set, the vertical length of the pipe is calculated through the height difference between the pipes connected to the pipe, and the length of the pipe is calculated through the horizontal length and the vertical length. doing
How to provide pipes for one-touch modular system.
The method of claim 13,
The pipe calculation step
Calculate the length of the pipe in the horizontal direction, calculate the additional length along the vertical direction of the pipe, and calculate the total length of the pipe by adding the additional length along the vertical direction to the horizontal length.
How to provide pipes for one-touch modular system.
In the pipe for a one-touch modular system provided by the method for providing a pipe for a one-touch modular system of claim 13,
The pipe for the one-touch modular system includes at least one straight pipe
Pipe for one-touch modular system.
The method of claim 17,
The pipe for the one-touch modular system further comprises a joint pipe connected to the straight pipe
Pipe for one-touch modular system.
The method of claim 17,
A straight pipe insertion part into which at least a part of the straight pipe is inserted is formed in the joint pipe
Pipe for one-touch modular system.
An architectural design drawing providing step in which a construction company provides architectural design drawings for construction construction;
A shop drawing drawing creation step of a facility company creating a shop drawing drawing through the architectural design drawing;
A pipe calculation step of calculating at least one of a length, a type, and a number of pipes using programming of preset conditions for the shop drawing drawing;
Cut the pipe in the pipe production system for a one-touch modular system according to any one of claims 1 to 11 according to the information of the pipe calculated through the pipe calculation unit, and the type and number of pipes required for a specific area In accordance with the step of providing a pipe for a sample generation one-touch modular system provided to the sample generation in one pack;
An error correction step of actually constructing the pipe provided as one pack in the sample generation, checking the error according to the construction, and reflecting the error in the drawing; And
And a pipe providing step for a multi-generation one-touch modularization system for providing the pipe corrected through the error correction step to a plurality of households as one pack,
The pipe calculation step
Calculate the depth value at which the straight pipe is inserted into the joint pipe in which the straight pipe insertion portion is formed in the X-axis, Y-axis and Z-axis directions, and calculate the length of the straight pipe by calculating the slope in the direction of gravity,
In the step of providing a pipe for the one-touch modular system, the insertion depth of the straight pipe inserted into the joint pipe is displayed and provided.
How to provide pipes for one-touch modular system.
The method of claim 20,
The error correction step,
Measuring and correcting the ERP contents by measuring the sleeve using the measurement photo of the sleeve at the site taken with a measuring instrument.
How to provide pipes for one-touch modular system.
A definition document generation module receiving pipe material order information transmitted from a customer terminal and generating a pipe material type definition statement defining a pipe material specification based on the pipe material order information; And
Pipe material production information including specifications and installation drawings for each pipe material package is generated according to the pipe material type definition so that a pipe package including at least one of a plurality of pipes and joint pipes and a pipe installation diagram is produced. Including an information generation module for transmitting the pipe material production information to the production plant server,
Order server for one-touch modular system.
The method of claim 22,
The pipe material order information is,
The specifications for each package of at least one of the plurality of pipes and joint pipes, the center length of each package for at least one of the plurality of pipes and joint pipes, an installation type of at least one of the plurality of pipes and joint pipes, and the plurality of pipes And at least one of the design drawings for each package of at least one of the joint pipes, and site information in which at least one of the plurality of pipes and the joint pipe is installed,
Order server for one-touch modular system.
The method of claim 22,
The pipe material order information is,
Including a center length for each package for at least one of the plurality of pipes and joint pipes,
The definition document generation module,
Generating the pipe material type definition including a pipe specification for a pipe and a joint pipe specification for a joint pipe based on the pipe specification based on the center length of each package,
Order server for one-touch modular system.
The method of claim 22,
The pipe material order information is,
Including at least one installation type of the plurality of pipes and joint pipes,
The definition document generation module,
Generating the pipe material type definition including a pipe specification for a pipe set according to the installation type and a joint pipe specification for a joint pipe,
Order server for one-touch modular system.
The method of claim 22,
The pipe material order information is,
Including a design diagram for each package of at least one of the plurality of pipes and joint pipes,
The definition document generation module,
Creating a shop drawing drawing through the package-specific design drawing, and generating the pipe material type definition document including the straight pipe specification for the pipe calculated through the shop drawing drawing and the joint pipe specification for the joint pipe,
Order server for one-touch modular system.
The method of claim 22,
In the above pipe material type definition,
Defined the pipe material specification including the pipe specification including the name, size, length and number of the pipe and the connection pipe specification including the name, size and number of the joint pipe,
Order server for one-touch modular system.
The method of claim 22,
The pipe material type definition,
Define the pipe material specification including at least one of a pipe specification and a joint pipe specification for at least one of the plurality of pipes and joint pipes,
The information generation module,
The pipe material package specification including at least one of a package pipe specification and a package joint pipe specification for each of a package pipe and a package joint pipe included for each pipe material package, based on at least one of the pipe specification and the joint pipe specification And generating the pipe production information including the installation diagram for installing at least one of the package pipe and the package joint pipe included for each pipe material package,
Order server for one-touch modular system.
The method of claim 22,
The above installation diagram,
Based on the flow of water, it is marked as'up' on the upstream side of the first package pipe, and'lower' on the downstream side of the first package pipe,
'Up' is displayed on the upstream side of the package fitting pipe connected to the downstream side of the first package pipe, and'upstream' is displayed on the downstream side of the package fitting pipe connected to the upstream side of the second package pipe different from the first package pipe. Denoted by'ha',
Order server for one-touch modular system.
The method of claim 22,
The above installation diagram,
When the package fitting pipe is of the LT type, it is marked as'up' on the upstream side of the package fitting pipe based on the flow of water, and marked as'bottom' on the downstream side of the package fitting pipe. Marked as'middle' on the middle side between the upstream side and the downstream side,
Order server for one-touch modular system.
Receiving pipe material order information transmitted from a customer terminal;
Generating a pipe material type definition that defines a pipe material specification based on the pipe material order information; And
Pipe material production information including specifications and installation drawings for each pipe material package is generated according to the pipe material type definition, so that a pipe package including at least one of a plurality of pipes and joint pipes and a pipe installation diagram is produced. Including the step of transmitting the pipe material production information to the production plant server,
How to operate order server for one-touch modular system.
The method of claim 31,
The pipe material order information is,
At least one package specification of the plurality of pipes and joint pipes, a center length of at least one package of the plurality of pipes and joint pipes, an installation type of at least one of the plurality of pipes and joint pipes, and the plurality of pipes and At least one of the design drawings for each package of at least one of the joint pipes, and field information of at least one of the plurality of pipes and joint pipes,
How to operate order server for one-touch modular system.
The method of claim 31,
The pipe material order information is,
Including at least one package-specific specification of the plurality of pipes and joint pipes,
The step of generating the pipe material type definition,
To generate the pipe material type definition including a pipe specification for a pipe and a joint pipe specification for a joint pipe corresponding to the specifications for each package,
How to operate order server for one-touch modular system.
The method of claim 31,
The pipe material order information is,
Including a center length for each package of at least one of the plurality of pipes and joint pipes,
The step of generating the pipe material type definition,
Generating the pipe material type definition including a pipe specification for a pipe and a joint pipe specification for a joint pipe based on the pipe specification based on the center length of each package,
How to operate order server for one-touch modular system.
The method of claim 31,
The pipe material order information is,
Including at least one installation type of the plurality of pipes and joint pipes,
The step of generating the pipe material type definition,
Generating the pipe material type definition including a pipe specification for a pipe set according to the installation type and a joint pipe specification for a joint pipe,
How to operate order server for one-touch modular system.
The method of claim 31,
The pipe material order information is,
Including a design diagram for each package of at least one of the plurality of pipes and joint pipes,
The step of generating the pipe material type definition,
Creating a shop drawing drawing through the package-specific design drawing, and generating the pipe material type definition document including a pipe specification for a pipe calculated through the shop drawing drawing and a joint pipe specification for a joint pipe,
How to operate order server for one-touch modular system.
The method of claim 31,
In the above pipe material type definition,
Including a pipe specification including the name, standard, length and number of the pipe and a joint pipe specification including the name, standard, and number of the joint pipe,
How to operate order server for one-touch modular system.
The method of claim 31,
The pipe material type definition,
Define the pipe material specification including a pipe specification and a joint pipe specification for at least one of the plurality of pipes and joint pipes,
Transmitting the pipe material production information,
The pipe material package specification including at least one of a package straight pipe specification and a package joint pipe specification for each of a package pipe and a package joint pipe included for each pipe package, based on at least one of the pipe specification and the joint pipe specification, and Generating the pipe material production information including the installation diagram for installing the package pipe and the package joint pipe included for each pipe material package,
How to operate order server for one-touch modular system.
The method of claim 31,
The above installation diagram,
Based on the flow of water, it is marked as'up' on the upstream side of the first package pipe, and'lower' on the downstream side of the first package pipe,
'Up' is displayed on the upstream side of the package fitting pipe connected to the downstream side of the first package pipe, and'upstream' is displayed on the downstream side of the package fitting pipe connected to the upstream side of the second package pipe different from the first package pipe. Denoted by'ha',
How to operate order server for one-touch modular system.
The method of claim 31,
The above installation diagram,
When the package fitting pipe is of the LT type, it is marked as'up' on the upstream side of the package fitting pipe based on the flow of water, and marked as'bottom' on the downstream side of the package fitting pipe. Marked as'middle' on the middle side between the upstream side and the downstream side,
How to operate order server for one-touch modular system.

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