KR102722340B1 - Steel structure with reinforced joints - Google Patents

Abstract

The present invention relates to a steel structure in which a plurality of vertical beams formed to support a structure, a connection between the vertical beams, a horizontal beam formed to form a shape of a structure, and a connecting beam connecting the horizontal beams and the vertical beams are firmly connected so that the entire load of the structure can be distributed to the vertical beams, the horizontal beams, and the connecting beams, and the connecting portions are reinforced.

Description

Steel structure with reinforced joints

The present invention relates to a steel structure with reinforced connecting portions, and more specifically, to a steel structure with reinforced connecting portions in which a plurality of vertical beams formed to support a structure, a horizontal beam formed to form a shape of a structure, and a connecting beam connecting the horizontal beams and the vertical beams are firmly connected so that the entire load of the structure can be distributed to the vertical beams, the horizontal beams, and the connecting beams.

A typical steel structure is a structure that forms the frame of a building, factory, or large warehouse, depending on the scale of construction. It uses steel beams with a cross-section in the shape of H or I, and the frame is constructed by connecting and combining these to build a structure.

The steel structure using the above beam is composed of a main column extending vertically above the ground or an existing main column, a steel beam that supports the main column by horizontally arranging a connecting bracket welded horizontally to the main column and connecting both ends horizontally to the connecting bracket, and a connecting plate that connects the connecting bracket and the steel beam, and a connection is made on the outside of the connecting plate by fastening a plurality of bolts and nuts.

Since the steel structure described above is heavy, the beams are transported using a crane, and most of the workers work on top of the structure as it is being built.

In the construction of a structure, the main column refers to both the column that connects steel beams horizontally and the corner column that connects steel beams at right angles.

In addition, the main column, steel beam, and connecting bracket are all steel beams of the same shape, and flanges are welded on both ends of the web with a thickness, and connecting holes are processed in a single row or multiple rows according to the specifications of the steel frame, and connecting holes are also processed and provided in each of the above connecting plates according to the connecting holes, and the structure is constructed in such a way that joints are made according to the design of the structure.

In the above manner, when connecting steel beams, workers at the upper part of the structure each take turns at their assigned positions, inserting bolts and fastening nuts. However, accidents involving dropping joint plates, bolts, nuts, and work hammers frequently occur, so most steel structures take a long time to construct, and there is a problem that safety accidents are caused by the above-mentioned falling factors.

Typically, for connecting brackets, the connecting plates required to connect steel beams are used on both sides of the web, the flat and bottom surfaces of the flange, and the upper and lower sides of the inner portion of the flange, for a total of eight connecting plates.

As steel structures go up to multiple floors, workers also have to move or transport bags containing bolts and nuts and bags containing connecting plates to the appropriate floors, which is inconvenient. In addition, during the jointing work of each connecting plate, workers often drop the connecting plates, especially those intended for the bottom of the web and flange, when matching the connecting plates together. This makes the connection work difficult and poses a safety risk due to falling objects.

Republic of Korea Patent No. 10-2099206

The purpose of the present invention is to provide a structure in which a plurality of vertical beams formed to support a structure, a horizontal beam formed to form a shape of the structure and a connecting beam connecting the horizontal beams to the vertical beams are firmly connected so that the entire load of the structure can be distributed to the vertical beams, the horizontal beams and the connecting beams.

The present invention is characterized by being a steel structure with a reinforced connecting portion formed of a plurality of beams to support the structure.

In one embodiment, the steel structure comprises: a vertical beam formed to be fixed to a floor foundation block with anchor bolts to support a load applied to a horizontal beam; a connecting beam formed on the vertical beam to horizontally interconnect a plurality of vertical beams; a horizontal beam formed by joining an upper reinforcing member, a lower reinforcing member, and a side reinforcing member; a connecting beam formed by welding to one side of the vertical beam so that the horizontal beam can be connected to the vertical beam; an upper reinforcing member formed by being joined to one side of the vertical beam at one side to support a load between the horizontal beam and the connecting beam and distributing a load applied to the horizontal beam and the connecting beam toward the vertical beam, and being fixed by being joined to the upper surface of the horizontal beam and the connecting beam at the other side through a connecting bolt; a lower reinforcing member formed by being joined to one side of the vertical beam at one side to support a load between the horizontal beam and the connecting beam and distributing a load applied to the horizontal beam and the connecting beam toward the vertical beam at one side through a connecting bolt; The invention is characterized by including: a side reinforcing member, one side of which is joined to one side of the vertical beam and the other side of which is joined to the side of the horizontal beam and the connecting beam to support a load between a horizontal beam and a connecting beam and to distribute a load applied to the horizontal beam and the connecting beam to the vertical beam, and which is fixedly formed through a connecting bolt; and a plurality of connecting bolts formed so as to mutually penetrate between the vertical beam, the connecting beam, the horizontal beam, the upper reinforcing member, the lower reinforcing member, and the side reinforcing member and be joined through a nut on the other side.

In another embodiment, the steel structure further includes a horizontal tie member to ensure that the load is equally distributed when connecting the connecting beam and the horizontal beam, and to maximize the efficiency of the load applied in the horizontal direction, and the horizontal tie member includes a horizontal upper auxiliary plate that is stably connected to the upper side of the connecting beam and the horizontal beam so that the upper tie member can be fixed, a horizontal lower auxiliary plate that is connected to the lower side of the connecting beam and the horizontal beam so that the upper and lower tie members can be connected and fixed, a plurality of upper tie members formed at a predetermined interval in the horizontal direction on the upper surface of the horizontal upper auxiliary plate, a plurality of upper and lower tie members formed in a square frame shape to surround the perimeter of the connecting beam and the horizontal beam and formed in the horizontal direction, a tie member fixing bar formed on the upper side of the upper tie member and the upper and lower sides of the upper and lower tie members respectively to fix the plurality of upper and lower tie members and to fix the plurality of upper and lower tie members, and a tie member having one side formed to fix the upper and lower tie members to the connecting beam and the horizontal beam. A steel structure includes a tie support bar formed to be fixed to one side of the center of the upper and lower tie bars and the other side fixed to one side of the connecting beam and the horizontal beam, wherein the steel structure further includes a vertical tie member formed around the vertical beam in order to maximize the load efficiency applied to the vertical beam of the foundation structure, or to support the load of the steel structure by replacing the vertical beam without the vertical beam, wherein the vertical tie member includes a vertical bar formed by welding each side fixed to each corner side toward the upper side of the lower fixing member in order to support the load applied to the horizontal beam side, a plurality of bar tie members formed by welding around the vertical bars formed each toward the corner side of the lower fixing member for connection between the respective vertical bars, and formed at a predetermined interval in the vertical direction, a plurality of connecting members formed at a predetermined interval in the upper direction of the vertical bars so that the horizontal beams can be connected, and a lower fixing member formed by fixing the vertical bar to the foundation block on the ground with an anchor bolt so that the foundation block can be fixed.

As described above, the entire load of the structure is distributed toward the horizontal beams for connecting the plurality of vertical beams and the connecting beams for connecting the horizontal beams and the vertical beams, thereby providing the effect of withstanding the load even when using small-sized vertical beams.

Figure 1 is a perspective view of a steel structure with a reinforced connecting portion of the present invention.
Figure 2 is an exploded view of Figure 1.
FIG. 3 is a drawing showing a beam-fitting fixing part according to another embodiment of the present invention.
Figure 4 is a detailed drawing of Figure 3.
FIG. 5 is a drawing showing a beam support fixing part according to another embodiment of the present invention.
Figure 6 is a detailed drawing of Figure 5.
Figure 7 is a drawing showing a work site air purification unit according to another embodiment of the present invention.
Figure 8 is a detailed drawing of Figure 7.

The detailed description of the invention set forth below refers to the accompanying drawings which illustrate, by way of example, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the invention, while different from one another, are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention. It should also be understood that the positions or arrangements 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 invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly so described. Like reference numerals in the drawings designate the same or similar functionality throughout the several aspects.

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

Fig. 1 is a perspective view of a steel structure with a reinforced connecting portion of the present invention, and Fig. 2 is an exploded view of Fig. 1.

As seen in the drawing above, the steel structure (100) with reinforced connecting portion of the present invention is characterized in that the foundation of the structure can be formed by a vertical beam (110), a horizontal beam (111), and a connecting beam (112).

The above steel structure (100) is characterized by including a vertical beam (110), a horizontal beam (111), a connecting beam (112), a connecting bolt (113), an upper reinforcing member (114), a lower reinforcing member (115), and a side reinforcing member (116).

The above vertical beam (110) is formed to support the load applied to the horizontal beam (111), and the above vertical beam (110) is characterized by being formed to be fixed to the floor foundation block with an anchor bolt.

The above horizontal beam (111) is formed to horizontally interconnect a plurality of vertical beams (110), and the horizontal beam (111) is characterized by being formed by joining a connecting beam (112) formed in the vertical beam (110), an upper reinforcing member (114), a lower reinforcing member (115), and a side reinforcing member (116).

The above connecting beam (112) is formed so that the horizontal beam (111) can be connected to the vertical beam (110), and the connecting beam (112) is characterized by being formed by welding to one side of the vertical beam (110).

The upper reinforcing member (114) above supports the load between the horizontal beam (111) and the connecting beam (112), and is formed to distribute the load applied to the horizontal beam (111) and the connecting beam (112) toward the vertical beam (110). The upper reinforcing member (114) is characterized in that one side is joined to one side of the vertical beam (110), and the other side is joined to the upper surface of the horizontal beam (111) and the connecting beam (112) and fixed through a connecting bolt (113).

The lower reinforcing member (115) above is formed to support the load between the horizontal beam (111) and the connecting beam (112), and to distribute the load applied to the horizontal beam (111) and the connecting beam (112) toward the vertical beam (110). The lower reinforcing member (115) is characterized in that one side is joined to one side of the vertical beam (110), and the upper surface of the other side is joined to the lower surface of the horizontal beam (111) and the connecting beam (112) and fixed through a connecting bolt (113).

The above-mentioned side reinforcement member (116) supports the load between the horizontal beam (111) and the connecting beam (112), and is formed to distribute the load applied to the horizontal beam (111) and the connecting beam (112) toward the vertical beam (110). The above-mentioned side reinforcement member (116) is characterized in that one side is joined to one side of the vertical beam (110), and the other side is joined to the side of the horizontal beam (111) and the connecting beam (112) and is fixedly formed through a connecting bolt.

The above connecting bolt (113) is characterized in that it is formed in multiple numbers to penetrate between the vertical beam (110), the connecting beam (112), the horizontal beam (111), the upper reinforcing member (114), the lower reinforcing member (115), and the side reinforcing member (116) and be connected through a nut on the other side.

FIG. 5 is a drawing showing a vertical fastening member (130), which is another embodiment of a reinforced steel structure (100) of the present invention, and FIG. 6 is a construction photograph of FIG. 5.

As seen in the drawing above, the vertical fastening member (130) is a configuration further included in the steel structure (100) of the present invention, and the vertical fastening member (130) is formed around the vertical beam (110) to maximize the load efficiency applied to the vertical beam (110) of the foundation structure, or is formed to support the load of the steel structure (100) by replacing the vertical beam (110) without the vertical beam (110).

The above vertical fastening member (130) is characterized by including a vertical bar (131), a bar fastening member (132), a connecting member (133), and a lower fixing member (134).

The above vertical bar (131) is formed to support the load applied toward the horizontal beam (111), and the above vertical bar (131) is characterized in that one side is formed to be fixed to each corner side by welding toward the upper side of the lower fixing member (134).

The above-mentioned tie-down member (132) is formed for connection between each vertical bar (131), and the tie-down member (132) is welded around the vertical bar (131) formed at each corner of the lower fixing member (134), and is characterized in that a plurality of tie-down members are formed at a certain interval in the vertical direction.

The above connecting member (133) is formed so that a horizontal beam (111) can be connected, and the above connecting member (133) is characterized in that a plurality of connecting members (133) are formed at a certain interval in the upper direction of the vertical bar (131).

The above lower fixing member (134) is formed so that a vertical bar (131) can be fixed to a foundation block on the ground, and the above lower fixing member (134) is characterized by being formed by being fixed to the foundation block with an anchor bolt.

FIG. 7 is a drawing showing a beam-bonding fixing part (200) which is another embodiment of the present invention, and FIG. 8 is a detailed drawing of FIG. 7.

As seen in the drawing above, the beam-fitting fixing member (200) is a configuration further included in the steel structure (100) of the present invention, and the beam-fitting fixing member (200) is characterized by being configured to pull and fix the horizontal beam (111) toward the connecting beam (112).

The above beam-fixing member (200) is characterized by including a motor fixing plate (210), a shaft motor (211), a shaft fixing member (212), a motor rotation shaft (213), a rotation engaging member (214), a stopper (215), a fixing pin (216), a pin groove (217), a pressure sensor (218), and a pressure plate (219).

The above motor fixing plate (210) is formed to support the shaft motor (211), and the motor fixing plate (210) is characterized by being formed on one side of the upper portion of the connecting beam (112).

The above-mentioned shaft motor (211) is formed to generate rotational power for rotating the motor rotation shaft (213), and the above-mentioned shaft motor (211) is characterized by being formed on one side of the motor fixing plate (210).

The above-mentioned shaft fixing member (212) is formed so that one side of the motor rotation shaft (213) can be fixedly joined, and the above-mentioned shaft fixing member (212) is characterized by being formed on one side of the upper portion of the horizontal beam (111).

The above motor rotation shaft (213) is formed so that it can rotate by receiving rotational power from the shaft motor (211), and the motor rotation shaft (213) is characterized in that one side is connected to the shaft motor (211) and the other side is formed by being coupled to the shaft fixing member (212).

The above-mentioned rotation engaging member (214) is formed to prevent it from coming off from the shaft fixing member (212), and the above-mentioned rotation engaging member (214) is characterized by being formed at one end of the motor rotation shaft (213).

The above stopper (215) is formed to forcibly insert the fixed pin (216) toward the pin home (217), and is characterized in that the stopper (215) is formed on one side of the lower portion of the connecting beam (112).

The above fixed pin (216) is formed so that it can be inserted into the pin groove (217) by protruding to one side when the stopper (215) is driven, and the above fixed pin (216) is characterized by being formed on one side of the stopper (215).

The above pin groove (217) is formed so that the fixed pin (216) can be forcibly inserted, and the pin groove (217) is characterized by being formed on one side of the lower portion of the horizontal beam (111).

The above pressure sensor (218) is formed to detect the contact pressure between the connecting beam (112) and the horizontal beam (111) by driving the shaft motor (211) when in contact with the pressure plate (219), and the pressure sensor (218) is characterized by being formed on one side of the connecting beam (112).

The above pressure plate (219) is formed to adhere to the pressure sensor (218) when in contact with it, and the pressure plate (219) is characterized by being formed on one side of the horizontal beam (111).

FIG. 9 is a drawing showing a beam support fixing part (300) which is another embodiment of the present invention, and FIG. 10 is a detailed drawing of FIG. 9.

As seen in the drawing above, the beam support fixing member (300) is a configuration further included in the steel structure (100) of the present invention, and the beam support fixing member (300) is characterized by increasing the fixing force of the horizontal beam (111) coupled on the connecting beam (112).

The above beam support fixing member (300) includes a side contact means (310) and a lower contact means (330), and the side contact means (310) is characterized by being for fixing the side of the connecting beam (112) and the horizontal beam (111).

The above-mentioned side contact means (310) is characterized by including a side contact cylinder (311), a side cylinder hinge (312), a side contact member (313), a side member hinge (314), a side contact groove (315), and a side contact sensor (316).

The above-mentioned side contact cylinder (311) is formed to generate power for pushing the side contact member (313) into the side contact groove (315), and is characterized in that the side contact cylinder (311) is formed on each side of the connecting beam (112).

The above-mentioned side cylinder hinge (312) is formed so that the side contact cylinder (311) can rotate toward the horizontal beam (111), and the above-mentioned side cylinder hinge (312) is characterized by being formed on one side of the side contact cylinder (311).

The above-mentioned side contact member (313) is formed to be inserted into the side contact groove (315) by driving the side contact cylinder (311) and to push the side contact sensor (316). The above-mentioned side contact member (313) is characterized by being formed to be connected to the cylinder shaft of the side contact cylinder (311).

The above-mentioned side member hinge (314) is formed so that the side contact member (313) can rotate from the side contact cylinder (311) when the side contact member (313) is inserted and pressed into the side contact groove (315), and the above-mentioned side member hinge (314) is characterized by being formed to be connected to the cylinder axis of the side contact cylinder (311).

The above side contact groove (315) is formed so that the side contact member (313) can be inserted into it, and the side contact groove (315) is characterized by being formed on each side of the horizontal beam (111).

The above-mentioned side contact sensor (316) is formed to check the insertion status of the side contact member (313) into the side contact groove (315), and the above-mentioned side contact sensor (316) is characterized by being formed on one side inside the side contact groove (315).

The above lower fastening means (330) is characterized by being used to fix and support the lower side of the connecting beam (112) and the horizontal beam (111).

The above lower contact means (330) is characterized by including a lower contact cylinder (331), a lower cylinder hinge (332), a lower contact member (333), a lower member hinge (334), a lower contact groove (335), and a lower contact sensor (336).

The lower contact cylinder (331) is formed to generate power to push the lower contact member (333) into the lower contact groove (335), and the lower contact cylinder (331) is characterized by being formed at the bottom of the connecting beam (112).

The lower cylinder hinge (332) is formed so that the lower contact cylinder (331) can rotate toward the horizontal beam (111), and the lower cylinder hinge (332) is characterized by being formed on one side of the lower contact cylinder (331).

The above lower contact member (333) is formed to be inserted into the lower contact form by driving the lower contact cylinder (331) and to push the lower contact sensor (336). The lower contact member (333) is characterized by being formed to be connected to the cylinder axis of the lower contact cylinder (331).

The lower member hinge (334) is formed so that the lower contact member (333) can rotate from the lower contact cylinder (331) when the lower contact member (333) is inserted into the lower contact groove (335) and is in close contact with it. The lower member hinge (334) is characterized by being formed to be connected to the cylinder axis of the lower contact cylinder (331).

The above lower sealing groove (335) is formed so that the lower sealing member (333) can be inserted into it, and the lower sealing groove (335) is characterized by being formed on one side of the lower portion of the horizontal beam (111).

The above lower contact sensor (336) is formed to check the insertion status of the lower contact member (333) into the lower contact groove (335), and the lower contact sensor (336) is characterized by being formed on one side inside the lower contact groove (335).

FIG. 11 is a drawing showing a work site air purification unit (400) which is another embodiment of the present invention, and FIG. 12 is a detailed drawing of FIG. 11.

As seen in the drawing above, the work site air purification unit (400) is a configuration further included in the steel structure (100) of the present invention, and the work site air purification unit (400) is characterized by being for purifying the air generated in the surroundings during installation work of the steel structure (100).

The above work area air purification unit (400) is characterized by including a rotary motor (410), a motor shaft (411), a chamber support plate (412), a purification chamber (413), a settling pad (414), a water tank (415), a spray nozzle (416), a circulation pump (417), a circulation filter (418), and a circulation pipe (419).

The above-mentioned rotary motor (410) is formed to generate power to rotate the motor shaft (411) to rotate the chamber support plate (412) connected to the motor shaft (411), and the above-mentioned rotary motor (410) is characterized by being formed on one side of the vertical beam (110).

The above motor shaft (411) is formed so that one side of the chamber support plate (412) can be coupled and rotated, and the motor shaft (411) is characterized by being formed as one side of the rotation motor (410).

The chamber support plate (412) is formed so that the purification chamber (413) is installed thereon and can rotate when the rotary motor (410) is driven by being coupled to the motor shaft (411). The chamber support plate (412) is characterized by being formed by being coupled to the motor shaft (411).

The above purification chamber (413) is formed to prevent workers from breathing contaminated air by sucking in and purifying the air around the steel structure (100), and the above purification chamber (413) is characterized by being formed to be installed on the chamber support plate (412).

The above-mentioned settling pad (414) is formed to enable the purification chamber (413) to be attached to the chamber support plate (412) and to prevent vibrations generated in the purification chamber (413) from being transmitted to the chamber support plate (412). The above-mentioned settling pad (414) is characterized by being formed on the lower surface of the purification chamber (413).

The above water tank (415) is formed so that water to be sprayed toward the purification chamber (413) can be stored, and the water tank (415) is characterized by being formed above the purification chamber (413).

The above injection nozzle (416) is formed to spray water provided from the water tank (415) into the inside of the purification chamber (413), and the above injection nozzle (416) is characterized by being formed on one side of the inside of the purification chamber (413).

The above circulation pump (417) is formed to recirculate the sprayed water toward the water tank (415), and the above circulation pump (417) is characterized by being formed on one side of the water tank (415).

The above circulation filter (418) is formed to filter out foreign substances mixed in the water that is sprayed and discharged, and the above circulation filter (418) is characterized by being formed at one end of the circulation pipe (419).

The above circulation pipe (419) is formed so that water inside the purification chamber (413) can move toward the water tank (415) when the circulation pump (417) is driven. The above circulation pipe (419) is characterized in that one side is connected to the lower side of the purification chamber (413) and the other side is connected to one side of the circulation pump (417).

The above-described embodiments are for illustrative purposes, and those skilled in the art will appreciate that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. Therefore, the above-described embodiments should be understood as illustrative and not restrictive in all respects. For example, each component described as a single entity may be implemented in a distributed manner, and likewise, components described as distributed may be implemented in a combined manner.

The scope of protection sought by this specification is indicated by the claims described below rather than the detailed description above, and should be interpreted to include all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts.

100 : Steel Structure
110: vertical beam 111: horizontal beam
112 : Connecting beam 113 : Connecting bolt
114: Upper reinforcing member 115: Lower reinforcing member
116: Side reinforcement member
200: Beam fixing part 210: Motor fixing plate
211: Axle motor 212: Axle fixing member
213: Motor rotation shaft 214: Rotation stop
215 : Stopper 216 : Fixed pin
217 : Pin Home 218 : Pressure Sensor
219 : Pressure plate
300: Beam support fixing member 310: Side fastening means
311: Side contact cylinder 312: Side cylinder hinge
313: Side contact member 314: Side member hinge
315: Side contact groove 316: Side contact sensor
330: Lower sealing means 331: Lower sealing cylinder
332: Lower cylinder hinge 333: Lower contact member
334: Lower hinge 335: Lower contact groove
336: Lower contact sensor
400: Work area air purification unit 410: Rotation motor
411: Motor shaft 412: Chamber support plate
413: Purification chamber 414: Settling pad
415: Water tank 416: Spray nozzle
417: Circulation pump 418: Circulation filter
419 : Circulatory system

Claims (3)

In steel structures with reinforced connecting parts,
The above steel structure is,
A vertical beam formed to be fixed to the floor foundation block with anchor bolts to support the load applied to the horizontal beam,
A connecting beam formed on a vertical beam to horizontally interconnect multiple vertical beams, and a horizontal beam formed by joining the upper reinforcing member, the lower reinforcing member, and the side reinforcing member,
A connecting beam formed by welding on one side of a vertical beam so that a horizontal beam can be connected to a vertical beam,
An upper reinforcing member that supports the load between the horizontal beam and the connecting beam and distributes the load applied to the horizontal beam and the connecting beam to the vertical beam, with one side joined to one side of the vertical beam and the other side joined to the upper surface of the horizontal beam and the connecting beam and fixed through a connecting bolt;
A lower reinforcing member that supports the load between the horizontal beam and the connecting beam and distributes the load applied to the horizontal beam and the connecting beam to the vertical beam, with one side joined to one side of the vertical beam and the other side's upper surface joined to the lower surface of the horizontal beam and the connecting beam and fixed through a connecting bolt;
A side reinforcing member that supports the load between the horizontal beam and the connecting beam and distributes the load applied to the horizontal beam and the connecting beam to the vertical beam, with one side joined to one side of the vertical beam and the other side joined to the side of the horizontal beam and the connecting beam and fixed through a connecting bolt;
Including a plurality of connecting bolts formed to mutually penetrate between the vertical beam, the connecting beam, the horizontal beam, the upper reinforcing member, the lower reinforcing member, and the side reinforcing member and to be connected through nuts from the other side,

The above steel structure is,
It is designed to ensure that the load is distributed equally between the connecting beam and the horizontal beam, and further includes a horizontal tie to maximize the efficiency of the load applied in the horizontal direction.
The above horizontal fastening part is,
A horizontal upper auxiliary plate that is fixedly connected to the upper side of the connecting beam and the horizontal beam so that the upper tie-in muscle can be fixed,
A horizontal lower auxiliary plate that is formed by joining the lower side of the connecting beam and the horizontal beam so that the upper and lower tie-lines can be connected and fixed,
A plurality of upper tie-lines are formed at equal intervals in the horizontal direction on the upper surface of the horizontal upper auxiliary plate,
A plurality of upper and lower tie-lines are formed in a square frame shape to surround the perimeter of the connecting beam and the horizontal beam, and are formed in a horizontal direction.
In order to fix multiple upper and lower tether muscles, a tether muscle fixation bar is formed on the upper side of the upper tether muscle and the upper and lower sides of the upper and lower tether muscles, respectively.
It includes a tie support bar formed so that one side is fixed to the center side of the upper and lower tie muscles and the other side is fixed to one side of the connecting beam and the horizontal beam to fix the upper and lower tie muscles to the connecting beam and the horizontal beam.

The above steel structure is,
In order to maximize the load efficiency applied to the vertical beam of the foundation structure, it further includes a vertical tie to support the load of the steel structure by forming it around the vertical beam or replacing the vertical beam without the vertical beam.
The above vertical joint is,
A vertical bar formed by welding each corner side to the upper side of the lower fixing member to support the load applied to the horizontal beam side,
A plurality of bar tie bars are formed at regular intervals in the vertical direction and are joined by welding around the vertical bars formed on the edge of the lower fixing member for connection between each vertical bar,
A plurality of connecting members are formed at regular intervals in the upper direction of the vertical bar so that horizontal beams can be connected,
A steel structure with a reinforced connection section, characterized in that it includes a lower fixing member formed by fixing a vertical bar to a foundation block with an anchor bolt so that the vertical bar can be fixed to the foundation block on the ground.
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