KR102482285B1 - Universal module joint structure - Google Patents

Abstract

The present invention relates to a universal module joint structure formed by joining side plates using plates at the outside of beams and columns facing modules stacked in vertical and horizontal directions. According to the present invention, the universal module joint structure comprises: a universal module formed in a rectangular frame to be variable in vertical and horizontal directions according to standards; vertical columns formed to be variable in the vertical direction on each corner side around the universal module; horizontal beams formed for connection between the vertical columns around the upper and lower parts of the universal module; a junction plate formed for bonding between stacked universal modules; and a plurality of plate connection grooves formed on the junction plate.

Description

Universal module joint structure

The present invention relates to a universal module joint structure, and more particularly, to a universal module joint structure formed by joining side plates using plates on the outside of beams and columns at which modules stacked in vertical and horizontal directions face each other. .

Conventionally, during the construction of a plant structure, components of the plant structure, such as a plurality of column members constituting the plant structure and horizontal and vertical frames, are first manufactured separately in the factory, and then transported to the construction site to connect all members at the site. However, recently, there is a trend of constructing plant structures in a modular method in which blocks or modules are manufactured in a factory and then blocks or modules are assembled and installed on site.

In the case of this conventional method, since all the plurality of connection parts of the plant module must be bolted together, considerable time is required for the construction of the connection part, and the construction period may be delayed due to re-construction due to occurrence of construction errors in the connection part. There was a problem with that.

In addition, when a plant structure is installed by joining plant modules in the vertical direction, there is a problem in that it is not easy to simultaneously match the connection parts of a plurality of pillar members due to construction errors in the field or manufacturing errors of components.

Specifically, since the plant module itself is a large structure and each plant module connection part is formed at a considerable distance in the horizontal direction, the separation distance between the foremost plant module connection part and the rearmost plant module connection part can be further increased. Accordingly, In a large plant structure, it may be more difficult to simultaneously match a plurality of connection parts of a plant module.

Korean Registered Patent No. 10-2004960

An object of the present invention is to join side plates using plates on the outside of beams and columns facing modules stacked in vertical and horizontal directions.

The present invention is characterized in that it is a universal module bonding structure formed so that bonding plates formed on modules stacked in a vertical or horizontal direction are mutually bonded.

In one embodiment, the joint structure is formed to be variable in the vertical direction at each corner side around the universal module and the universal module formed in a square frame so that it can be variable in the vertical and horizontal directions according to the standard The upper and lower edges of the vertical pillars and the horizontal beams formed to connect between the vertical pillars around the upper and lower circumferences of the universal modules and to be variable in the horizontal direction, and the universal modules to be stacked. , It is characterized in that it comprises a plurality of plate connection grooves formed on the junction plate so that the junction plates formed at the upper circumference and the lower circumference edge, respectively, and the junction plates in contact with each other can be coupled through bolts.

In another embodiment, the joint structure includes a plate pulling fixing portion formed to mutually pull the joint plate formed at the same position in the universal module on each side when one universal module and another universal module are joined. The plate pulling fixing part includes a fixing plate fixed to the upper surface of the joining plate formed on one side of the universal module, a fixing housing formed to the center of the upper surface of the fixing plate to support one side of the rotating screw shaft, and fixing the screw shaft. A pin through hole formed on the upper surface of one side of the fixed housing so that a fixing pin for fixing on the housing can pass through, and a shaft support formed on one side of the fixed housing to support the movement of the screw shaft to the fixed housing side during rotation of the screw shaft. A screw shaft formed so that one side is coupled to the shaft support member and the other side is connected to the pull bar inside the movable housing to rotate by pulling the pull bar toward the fixed housing and compressing the clamping spring, and the screw shaft passes through the pin through groove A pin insertion groove formed on one side of the screw shaft so that a fixing pin for fixing can be inserted, and a fixing pin formed so that the screw shaft can be fixed on the fixing housing by passing through the pin through groove and being inserted into the pin insertion groove, When the screw shaft rotates, it detects the close contact with the inner surface of the fixed housing and provides the information about the close contact to the user terminal in real time so that the tightness between the joining plates can be known. A moving plate fixedly formed on the upper surface of the joining plate, a moving housing formed in the center of the upper surface of the moving plate to support the other side of the rotating screw shaft, and a pull bar formed on one side of the screw shaft to compress the clamping spring when the screw shaft rotates and moves, It is characterized in that it consists of a tightening spring formed between the pull bar and the moving housing so that it can be compressed by the pull bar or relaxed when the screw shaft rotates in reverse.

As described above, the convenience of construction is provided by joining modules stacked in vertical and horizontal directions using plates.

1 is a product diagram of the universal module junction structure of the present invention.
Figure 2 is a product diagram showing a vertical bonding state with respect to Figure 1.
Figure 3 is a product diagram showing a horizontal state bonding state with respect to Figure 1.
4 is a view showing another embodiment of the plate pulling fixing part for the present invention.
Figure 5 is a detailed view of Figure 4
6 is a view showing a binding magnetic part, which is another embodiment of the present invention.
FIG. 7 is a detailed view of FIG. 6 .
8 is a view showing a bonded elastic part, which is another embodiment of the present invention.
9 is a detailed view of FIG. 8 .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of illustration, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable one skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other but are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in another embodiment without departing from the spirit and scope of the invention in connection with one embodiment. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all equivalents as claimed by those claims. Like reference numbers in the drawings indicate the same or similar function throughout the various aspects.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a view of a universal module 100 bonding structure 10 of the present invention, FIG. 2 is a product view showing a vertical bonding state with respect to FIG. 1, and FIG. 3 is a product showing a horizontal bonding state with respect to FIG. It is also

As shown in the drawing, the junction structure 10 is characterized in that the junction plates 112 formed in the modules stacked in the vertical direction are formed to be mutually joined.

The junction structure 10 is characterized by consisting of a universal module 100, a vertical column 110, a horizontal beam 111, a junction plate 112, and a plate connection groove 113.

The universal module 100 is characterized in that it is formed in the form of a square frame to be variable in the vertical and horizontal directions according to standards.

The standard of the universal module 100 is characterized in that it can be used by changing it according to the value of the size desired by the user.

The vertical pillar 110 is characterized in that it is formed to be variable in the vertical direction at each corner side around the universal module 100.

The horizontal beam 111 is formed for connection between the vertical pillars 110 and the vertical pillars 110 around the upper and lower parts of the universal module 100, and is characterized in that it is formed to be variable in the horizontal direction.

The junction plate 112 is formed for bonding between the stacked universal modules 100, and the junction plate 112 is formed at upper and lower edges, upper circumference and lower circumference, respectively.

The plate connection grooves 113 are formed so that the joining plates 112 in contact with each other can be coupled through bolts, and the plate connection grooves 113 are formed in plurality on the joining plate 112.

The universal module 100 bonding structure 10 is formed by bonding between a universal module 100 formed in one module unit and another universal module 100 with a bonding plate 112 in the vertical direction, It is characterized in that it is formed by bonding between the bonding plates 112 in the horizontal direction.

4 is a view showing a plate pulling fixing part 200, which is another embodiment of the present invention, and FIG. 5 is a detailed view of FIG.

As shown in the figure, the plate pulling and fixing part 200 is further included in the universal module 100 joint structure 10, and the plate pulling and fixing part 200 is one universal module 100 and It is characterized in that when joining another universal module 100, the joint plates 112 formed at the same position in the universal module 100 on each side are formed to pull each other.

The plate pulling fixing part 200 includes a fixing plate 210, a fixing housing 211, a pin through groove 212, a shaft support member 213, a screw shaft 214, a pin insertion groove 215, and a fixing pin. 216, close contact sensor 217, moving plate 218, moving housing 219, pull bar 220, characterized in that consisting of a tightening spring (221).

The fixing plate 210 is characterized in that it is fixed to the upper surface of the joint plate 112 formed on the universal module 100 on one side.

The fixing housing 211 is formed to support one side of the rotating screw shaft 214, and the fixing housing 211 is formed at the center of the upper surface of the fixing plate 210.

The pin through groove 212 is formed so that a fixing pin 216 for fixing the screw shaft 214 on the fixing housing 211 can pass through. ) characterized in that it is formed as an upper surface on one side.

The shaft support member 213 is formed to support the screw shaft 214 so that it can be moved toward the fixed housing 211 when the screw shaft 214 rotates, and the shaft support member 213 is a fixed housing ( 211) characterized in that it is formed on one side.

The screw shaft 214 is formed to compress the clamping spring 221 by pulling the pull bar 220 toward the fixed housing 211, and one side of the screw shaft 214 is coupled to the shaft support member 213. And, it is characterized in that the other side is formed to be connected to the pull bar 220 inside the moving housing 219 to be rotated.

The pin insertion groove 215 is formed so that a fixing pin 216 for fixing the screw shaft 214 can be inserted through the pin through groove 212, and the pin insertion groove 215 is a screw shaft. (214) characterized in that it is formed on one side.

The fixing pin 216 penetrates the pin through groove 212 and is inserted into the pin insertion groove 215 so that the screw shaft 214 can be fixed on the fixing housing 211.

The adhesion sensor 217 detects the adhesion to the inner surface of the fixed housing 211 when the screw shaft 214 rotates, and provides information about the adhesion to the user terminal in real time so that the adhesion between the bonding plates 112 can be known. To be formed, the close contact sensor 217 is characterized in that formed on one side of the inner surface of the fixed housing (211).

The movable plate 218 is characterized in that it is fixed to the upper surface of the joint plate 112 formed on the universal module 100 on the other side.

The moving housing 219 is characterized in that it is formed in the center of the upper surface of the moving plate 218 to support the other side of the rotating screw shaft 214.

The pull bar 220 is formed to compress the clamping spring 221 when the screw shaft 214 rotates, and the pull bar 220 is formed on one side of the screw shaft 214.

The tightening spring 221 is compressed by the pull bar 220 or is formed to be relaxed when the screw shaft 214 reversely rotates. 219) characterized in that it is formed between.

6 is a view showing a binding magnetic unit 300, which is another embodiment of the present invention, and FIG. 7 is a detailed view of FIG.

As shown in the figure, the binding magnetic part 300 is further included in the universal module 100 junction structure 10, and the binding magnetic part 300 is one universal module 100 and another It is characterized in that it is formed to increase the binding force by magnetism when one universal module 100 is joined.

The binding magnetic part 300 includes a variable side fixing plate 310, a variable member 311, a fixing table embedded groove 312, a variable fixing table 313, a variable hinge 314, a variable nut 315, an insertion side fixing plate ( 316), an insertion member 317, a holder groove 318, a magnetic plate 319, and a magnetic lever 320.

The variable side fixing plate 310 is characterized in that it is fixedly formed on the upper surface of the joining plate 112 formed in one universal module 100.

The variable member 311 is formed so that the variable fixing table 313 can be rotated and embedded, and the variable member 311 is formed as an upper surface of the variable side fixing plate 310.

The fixing rod embedded groove 312 is formed so that the variable fixing rod 313 can be embedded and stored, and the fixing rod embedded groove 312 is formed on the upper surface of the variable member 311.

The variable fixture 313 is connected to the variable hinge 314 formed on one side of the holder embedded groove 312 to be rotatable, and is inserted into the holder groove 318 formed in the insertion-side fixing plate 316 to be caught. It is formed and characterized in that it is formed to be variable by driving the variable nut 315 according to the distance between the universal modules 100 and the universal modules 100.

The variable hinge 314 is formed so that the variable fixing base 313 can be rotated with respect to one side of the fixing rod embedded groove 312, and the variable hinge 314 is coupled to one side of the fixing rod embedded groove 312. to be characterized

The variable nut 315 is formed to adjust the length of the variable fixing table 313, and the variable nut 315 is formed to be rotatable towards the center of the variable fixing table 313.

The insertion side fixing plate 316 is characterized in that it is fixedly formed on the upper surface of the joint plate 112 formed on another universal module 100.

The insertion member 317 is characterized in that formed on the upper surface of the insertion side fixing plate (316).

The fixing base groove 318 is formed so that the variable fixing base 313 can be inserted and bound thereto, and the fixing base groove 318 is formed on the upper surface of the insertion member 317.

The magnetic plate 319 is formed to fix the binding variable fixing base 313 by magnetism, and the magnetic plate 319 is characterized in that it is formed on the bottom surface of the fixing base groove 318.

The magnetic lever 320 is formed to turn on/off the magnetic driving on the magnetic plate 319, and the magnetic lever 320 is formed on one side of the insertion member 317.

FIG. 8 is a view showing a bonded elastic part 400 according to another embodiment of the present invention, and FIG. 9 is a detailed view of FIG. 8 .

As shown in the drawing, the bonding elastic part 400 is further included in the universal module 100 bonding structure 10, and the bonding elastic part 400 is one universal module 100 in the vertical direction. It is characterized in that it is intended to have elasticity when bonding with another universal module 100 so as not to be separated from each other due to vibration and shock.

The bonding elastic part 400 includes a seating plate 410, a support plate 411, a plate binding member 412, a binding screw 413, a binding nut 414, a compression housing 415, and a housing end 416. , It is characterized by consisting of a compression member 417, a member projection 418, a compression spring 419, a spring member 420, and an elastic spring 421.

The seating plate 410 is characterized in that it is formed on the lower surface of the bonding plate 112 formed on the lower surface of the universal module 100 when bonding the universal module 100 in the vertical direction.

The support plate 411 is characterized in that it is formed on the upper surface of the universal module 100 when bonding the universal module 100 in the vertical direction.

The plate binding member 412 is formed so that the binding screw 413 is inserted and coupled when the seating plate 410 and the support plate 411 are coupled through the binding screw 413, the plate binding member 412 It is characterized in that the seating plate 410 and the support plate 411 are formed on one side, respectively.

The binding screw 413 has one side screwed with the seating plate 410 and the other side screwed with the support plate 411 so that the binding nut 414 is rotated and rotated so that the seating plate 410 and the support plate 411 ) is characterized in that it is formed so that it is pulled in a mutually facing direction.

The binding nut 414 is formed to rotate the binding screw 413, and the binding nut 414 is formed at the center of the binding screw 413.

The compression housing 415 is formed so that the compression spring 419 is embedded, and the compression housing 415 is formed on both sides of the seating plate 410.

The housing end 416 prevents the compression spring 419 from falling out and is formed so that the inserted member protrusion 418 is caught, and the housing end 416 is formed as the lower end of the compression housing 415. to be characterized

The compression member 417 is formed such that a portion thereof is inserted into the compression housing 415 in a direction facing the compression housing 415, and the compression member 417 is formed on both sides of the upper surface of the support plate 411. to be characterized

The member protrusion 418 is formed so that the compression member 417, which is inserted into the compression housing 415 and has a buffering action, is caught on the housing end 416 without falling out of the compression housing 415, and the member projection 418 ) is characterized in that formed on the top of the compression member 417.

The compression spring 419 is formed to prevent a gap between the universal modules 100 from occurring when vibration and shock occur, and the compression spring 419 is formed inside the compression housing 415.

The spring member 420 is formed to support the elastic spring 421, and the spring member 420 is formed in the center of the lower surface of the seating plate 410 and the center of the upper surface of the support plate 411.

The elastic spring 421 is formed to damp vibration between the vertically joined universal modules 100, and the elastic spring 421 is formed on the seating plate 410 and the support plate 411. to be

The above-described embodiments are for illustrative purposes, and those skilled in the art to which the above-described embodiments belong can easily transform into other specific forms without changing the technical spirit or essential features of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope to be protected through this specification is indicated by the following claims rather than the detailed description above, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof. .

10: junction structure
100: universal module 110: vertical column
111: horizontal beam 112: joint plate
113: plate connection groove
200: plate pulling fixing part 210: fixing plate
211: fixed housing 212: pin through groove
213: shaft support member 214: screw shaft
215: pin insertion groove 216: fixing pin
217: contact sensor 218: moving plate
219: moving housing 220: pull bar
221: tightening spring
300: binding magnetic part 310: variable side fixing plate
311: variable member 312: fixed base embedded groove
313: variable fixture 314: variable hinge
315: variable nut 316: insertion side fixing plate
317: insertion member 318: holder groove
319: magnetic plate 320: magnetic lever
400: joint elastic part 410: seating plate
411: support plate 412: plate binding member
413: binding screw 414: binding nut
415: compression housing 416: housing end
417: compression member 418: member protrusion
419: compression spring 420: spring member
421: elastic spring

Claims (3)

In the universal module bonding structure formed so that bonding plates formed in modules stacked in a vertical or horizontal direction are mutually bonded,
The junction structure,
A universal module formed in a square frame to be variable in vertical and horizontal directions according to standards;
A vertical pillar formed around the universal module so as to be variable in the vertical direction at each corner side,
A horizontal beam formed to connect between vertical columns around the upper and lower parts of the universal module and to be variable in the horizontal direction;
Joining plates formed at upper and lower edges, upper and lower circumferential edges, respectively, for bonding between stacked universal modules;
It consists of a plurality of plate connection grooves formed on the joint plate so that the mutually abutting joint plates can be coupled through bolts,

The junction structure,
Further comprising a plate pulling fixing portion formed to mutually pull the joining plates formed at the same position in the universal module on each side when one universal module and another universal module are joined,
The plate pulling fixing part,
A fixed plate fixed to the upper surface of the joint plate formed on one side of the universal module;
A fixed housing formed in the center of the upper surface of the fixed plate to support one side of the rotating screw shaft;
A pin through-hole formed on an upper surface of one side of the fixing housing so that a fixing pin for fixing the screw shaft on the fixing housing can pass through;
A shaft support member formed on one side of the fixed housing to support the screw shaft to be moved to the fixed housing side when the screw shaft rotates;
A screw shaft having one side coupled to the shaft support member and the other side connected to the pull bar inside the movable housing to be rotated so as to compress the clamping spring by pulling the pull bar toward the fixed housing;
A pin insertion groove formed on one side of the screw shaft so that a fixing pin for fixing the screw shaft can be inserted through the pin through groove;
A fixing pin formed so that the screw shaft can be fixed on the fixing housing by passing through the pin through groove and being inserted into the pin insertion groove;
An adhesion sensor formed on one side of the inner surface of the fixed housing to detect adhesion to the inner surface of the fixed housing during rotational movement of the screw shaft and to provide information on the adhesion to the user terminal in real time so as to know the adhesion state between the joining plates;
A moving plate fixed to the upper surface of the joint plate formed on the other universal module;
A moving housing formed in the center of the upper surface of the moving plate to support the other side of the rotating screw shaft;
A pull bar formed on one side of the screw shaft to compress the clamping spring during rotational movement of the screw shaft;
A universal module junction structure characterized in that it consists of a clamping spring formed between the pull bar and the moving housing so that it can be compressed by the pull bar or relaxed when the screw shaft rotates in reverse.
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