KR101018849B1 - Prestressed steel and concrete girder assembly - Google Patents

Abstract

PURPOSE: A prestressed steel and concrete girder assembly is provided to reduce construction time and costs by simply coupling a section steel structure to the other section steel structure in a construction field. CONSTITUTION: A PSSC girder assembly comprises section steel structures(110,120), cut parts, connection covers(200), and tendons. Each section steel structure comprises an upper flange, a lower flange, and multiple webs. The webs connect the upper and lower flanges. The cut parts are formed in one side or both sides of the top of the section steel structure. The connection covers cover the cut parts. The tendons are installed in the inner sides of the section steel structures. A female joint is formed in one end of each tendon, and a male joint is formed in the other end.

Description

PSG girder assembly {Prestressed steel and concrete girder assembly}

The present invention relates to a PSSC girder assembly capable of sequencing girder very easily in the shop floor.

Conventionally, Korean Registered Room No. 341097 (hereinafter referred to as a prior art), a groove having a sufficient length so that the continuity means is installed at the end when the girder is manufactured, the upper inner steel is produced so as to protrude the simple beam method to the bridge substructure A technique is known in which a girder is continuous to support the slab concrete load in a continuous beam structure by fixing the upper inner steel material to the nut member through the sequential means before placing the slab concrete.

However, the prior art is provided with a separate sequencing means for connecting the upper inner steel, thereby increasing the number of work processes.

In addition, the end face of the girder and the end face of the other girder were separated by grooves formed so that the sequencing means were installed and had to be connected by a separate connecting wall composed of a diaphragm or a partition wall.

Accordingly, the prior art has a problem in that the workability is long due to low workability that can be immediately installed at the work site when the girder is continuous, resulting in a cost increase.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a PSSC girder assembly that can be easily continuous girder at the shop floor.

PSSC girder assembly of the present invention for achieving the above object, a steel structure comprising a top flange, a lower flange, a plurality of webs connecting the upper flange and the lower flange; A cutout portion in which a portion of an upper portion or both upper portions of the steel structure is cut; A connection cover covering the incision; It includes a tension member installed on the inner side of the steel structure, wherein one end of the tension member is formed with a female coupling portion, the other end of the tension member is characterized in that the male coupling portion is inserted and fixed to the female coupling portion is formed.

According to such a structure, a shaped steel structure can be miniaturized.

In addition, since it is possible to simply combine the steel structure and the other steel structure in the shop floor, it is possible to facilitate the continuous girder.

In addition, in the PSSC girder assembly of the present invention, the shaped steel structure is characterized in that a pair of I-shaped steel is coupled.

In addition, the PSSC girder assembly of the present invention is characterized in that the concrete is poured into one side of the steel structure, which is disposed in the pier, in the steel structure.

According to this structure, a girder can be installed very stably between the piers and the piers.

As described above, the PSSC girder assembly of the present invention has the following advantages.

According to the present invention, the form steel structure can be downsized, so that the form steel structure is easily transported.

In addition, the present invention can easily combine the girder steel structure and another girder steel structure at the work site, so that the girder can be easily continuated, and as a result, the workability of the site can be shortened and the work period can be shortened, and the cost can be reduced. You can.

In addition, in the present invention, the concrete is poured at both ends of the girder, so that the weight of both ends disposed in the piers of the girder is relatively greater than the weight of the girder center disposed between the piers and the piers, between the piers and the piers Can be installed very stably.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

As shown in Figures 1 to 3, the PSSC girder assembly (Prestressed steel and concrete girder assembly) of the present invention, the upper flange 101, the lower flange 102, the upper flange 101 and the lower Shape steel structures 110 and 120 and 130 including a plurality of webs 103a and 103b connecting flanges 102, and one side upper portion or both upper portions of the steel structure structures 110, 120 and 130. A part of which is cut out of the incision 140, and the connecting cover 200 covering the incision 140, and the tension member 160 is installed inside the section steel structure (110, 120, 130) However, one end of the tension member 160 is formed with a female coupling portion 180, the other end of the tension member 160 is formed with a male coupling portion 170 is inserted into the female coupling portion 180 is fixed.

At this time, the shaped steel structure 110, 120, 130 is composed of a pair of I-shaped steel.

That is, the shape steel structures 110, 120 and 130 are made of I-shaped steel, and arranged so that the upper flange and the lower flange of each of the first steel 104 and the second steel 105 are in the same line, and then separately By combining the upper flange of the first section steel 104 and the upper flange of the second section steel 105, the lower flange of the first section steel 104 and the lower flange of the second section steel 105, respectively, It is composed.

On the other hand, of the shaped steel structure (110, 120, 130) described in the present invention, the shaped steel structure formed with the cut portion 140 on the upper right is the first shaped steel structure 110, the cut portion 140 on both sides upper The formed steel structure is a second steel structure 120, the section structure is formed in the upper cut section 140 is the third steel structure 130.

On the inside of the steel structure (110, 120, 130), the upper flange 101 and the lower flange 102, and the upper flange 101 and the lower flange 102 are formed to be spaced apart from each other ( The space 150 surrounded by the 103a and the web 103b is formed.

The saddle 400 and the tension member 160 is disposed in the space 150.

The saddle 400 is installed on the upper surface of the lower flange 102 so that the saddle 400 is disposed at the inner central portion of the shaped steel structures 110, 120, 130.

The tension member 160 is inserted into an insertion hole formed in the saddle 400 and is supported by a plurality of support pieces arranged to protrude inwardly of the space 160, and a sheath tube inserted into the sheath tube. It consists of a strand.

Such, the tension member 160 is formed in the longitudinal direction of the shaped steel structure (110) (120) 130.

At this time, the tension member 160 of the tension member 160 disposed in the interior of the steel structure 110, 120, 130, the position of the tension member 160 is disposed in the center of the steel structure (110, 120, 130). It is preferable to be disposed so as to be higher than the position of the tension member 160 disposed at both ends of the structure (110, 120, 130).

That is, the tension member 160 has a shape in which a central portion thereof rises.

Meanwhile, the cutout 140 of the first steel structure 110 includes an upper flange 101 of a part of the right side of the first steel structure 110 and a web 103a extending downward from the upper flange 101. After cutting the web 103b by a predetermined length, it is formed by cutting from the ends of the cut webs 103a and the web 103b to the right end surface of the first steel structure 110.

That is, when the first shape steel structure 110 is viewed from the front, the first shape steel structure 110 is a shape in which a portion of the upper right corner is cut in a 'b' shape.

According to this configuration, the cross section of the portion where the cutout portion 140 is formed in the first-shaped steel structure 110 is a '.' Shape.

Similarly, the cutouts formed in the second type steel structure 120 and the third type steel structure 130 are also the same as the structure and configuration of the cutout portion 140 formed in the first type steel structure 110.

However, the cutouts of the second shaped steel structure 120 are formed on both sides of the shaped steel structures 110, 120 and 130, and the cutouts of the third shaped steel structure 130 are the shaped steel structures 110 and 120. It is formed in the upper left of 130.

According to such a configuration, the space portion 150 formed inside the steel structure 110, 120, 130 is in communication with the outside by the cutout 140.

Accordingly, a part of the tension member 160, that is, the male coupling part 170 and the female coupling part 180, installed in the inner space 150 of the shaped steel structures 110, 120, 130 may be formed in the shaped steel structure 110. 120 and 130 are exposed to the outside.

On the other hand, the male coupling portion 170 formed at one end of the tension member 160 is preferably in a circular shape, the epoxy portion 171 formed at the end of the tension member 160 and at the end of the epoxy portion 171 The first inserting portion 172 is formed to be continued and the second inserting portion 173 is formed to include the protruding portion from the end of the first inserting portion 172.

At this time, the insertion member 175 is further formed on the circumferential surface of the first insertion portion 172 toward the front, and the locking projection 184 to be described later is inserted into one side of the insertion member 175. The locking groove 174 is formed.

On the other hand, the female coupling portion 180 formed at the other end of the tension member 160, the receiving member 181 made of epoxy (epoxy) resin is formed.

In the receiving member 181, the first insertion groove 182 and the second insertion groove 183 in which the first insertion portion 172 and the second insertion portion 173 of the male coupling part 170 are accommodated, respectively, are accommodated. ) Is formed.

At this time, the inner circumference of the first insertion groove 182 is formed so that the inclination is increased toward the front, the one side of the locking projection 184 is inserted into the locking groove 174 of the male coupling portion 170 described above. Is formed.

On the outer surface of the female coupling portion 180 receiving member 186, a pressing member 185 sliding to press the receiving member 186 is formed.

By such a configuration, when the male coupling part 170 is inserted into the female coupling part 180 such that the locking protrusion 184 is caught by the locking groove 174, the receiving member 186 is provided by the pressing member 185. By pressing the outer side, the water coupling portion 170 and the female coupling portion 180 can be firmly coupled.

On the other hand, the connecting cover 200, the upper flange 210, and comprises a plurality of webs (220a, 220b) formed to extend to the lower portion of the upper flange (210).

That is, the cross section of the connecting cover 200 is a 'ㅠ' shape.

A space 250 is formed between the web 220a and the web 220b of the connection cover 200.

The width of the web 220a and the web 220b is preferably formed to be equal to the width of the web 103a and the web 103b of the shaped steel structures 110, 120, and 130.

At this time, the connecting cover 200 may be configured by a pair of T-shaped steel is coupled.

That is, the connecting cover 200 may be configured by arranging each upper flange of the pair of T-shaped steels to be in the same line, and then combining the upper flange with a separate joint plate or the like.

Hereinafter, the first type steel structure 110 and the second type steel structure 120 is coupled, the connecting cover (140) formed in the cutout 140 formed in the first and second steel structure 110 and 120, respectively ( The structure and structure covered by 200 will be described.

For reference, a plurality of through holes are formed in the upper flange joint plate, the lower flange joint plate, and the web joint plate so that the coupling means can be fastened, and the upper flange, the lower flange, and the web also pass through the upper flange plate. A plurality of through holes are formed in communication with the balls.

First, one side and the second side of the first steel structure 110 so that the cut portion 140 formed in the first steel structure 110 and the cut portion 140 formed in the second steel structure 120 are adjacent to each other. One side of the shaped steel structure 120 is disposed to abut.

As described above, when the first-shaped steel structure 110 and the second-shaped steel structure 120 is disposed, cut portions 140 are formed, respectively, inside of the first-shaped steel structure 110 and the second-shaped steel structure 120. The space 150 is exposed to the outside.

In addition, a third lower flange joint plate 323 is disposed on an upper surface of each lower flange 102 in contact with the first steel structure 110 and the second steel structure 120, and a first lower flange joint is disposed on a lower surface thereof. The plate 321 is disposed.

Thereafter, the first lower flange joint plate 321 and the third lower flange joint plate 323 may be fastened using a coupling means 700a formed of a bolt and a nut.

In this case, a second lower flange joint plate 322 is disposed on an upper surface of the lower flange 102 disposed outside the web 103a and the web 103b, and the second lower flange joint plate is coupled to the coupling means 700a. 322 and the first lower flange joint plate 321 is fastened.

In addition, the side surfaces of the web 103a and the web 103b of the first shaped steel structure 110 and the side surfaces of the web 103a and the web 103b of the second shaped steel structure 120 come into contact with each other. The four web joint plate 334 is disposed, and the second web joint plate 332 is disposed on the outer side, and then the second web joint plate 332 and the fourth web joint plate 334 are connected to the coupling end 700b. ).

Accordingly, the coupling between the first type steel structure 110 and the second type steel structure 120 can be more robust.

Meanwhile, the tension member 160 installed in the inner space 150 of the first steel structure 110 and the second steel structure 120 may also be formed by the cutout 140 to form the first steel structure 110. And exposed to the upper portion of the second steel structure 120.

Therefore, the worker may connect the male coupling part 170 formed at one end of the tension member 160 of the first steel structure 110 to the female coupling part 180 formed at the other end of the tension member 160 of the second steel structure 120. By inserting, the tension member 160 of the first steel structure 110 and the tension member 160 of the second steel structure 120 may be coupled.

As described above, when the first-type steel structure 110 and the second-type steel structure 120 is coupled, the cut portions 140 formed in the first-type steel structure 110 and the second-type steel structure 120 are connected to each other. The cover 200 is connected.

On the lower end surfaces of the webs 220a and 220b of the connecting cover 200, an upper plate 341 is formed to be fixed by welding or the like to protrude outward of the webs 220a and 220b.

Meanwhile, the upper surfaces of the webs 103a and 103b in which the cutouts 140 are formed in the first and second steel structures 110 and 120 are fixed by welding or the like, so that the webs 103a and 103b are fixed. A bottom plate 342 protruding outward is formed.

In this case, through holes penetrating the upper plate 341 and the lower plate 342 up and down are formed on the protruding surfaces of the upper plate 341 and the lower plate 342 protruding outward.

Therefore, after arranging the lower surface of the upper plate 341 on the upper surface of the lower plate 342 so that the through holes respectively formed in the upper plate 341 and the lower plate 342 communicate with each other, the coupling means composed of bolts and nuts. Fasten using (700c).

According to such a configuration, the connecting cover 200 is covered and connected to the cutout 140 of the first and second steel structures 110 and 120.

Thereafter, the side surface of the connecting cover 200, the web 220a and the web 220b, and the boundary surface where the side surfaces of the first and second steel structures 110 and 120 form the web 103a and the web 103b abut. The third web joint plate 333 is disposed on the inner side of each other, and the first web joint plate 331 is disposed on the outer side thereof, and then, as the coupling means 700b, the third web joint plate 333 and the first web are disposed. The joint plate 331 is fastened.

At this time, the space 150 is preferably formed to the height and width of the upper and lower flanges and the web constituting the space 150 to 1m or more so that the worker can enter the work inside. .

In addition, the inner side (upper flange 210) of the interface between the side of the upper cover 210 of the connecting cover 200, the side of the upper flange 101 of the first steel structure 110 and the second type steel structure 120. The lower surface of 101) is arranged with a third upper flange joint plate 313, respectively, on the outer side (top flange 210, 101) of the first upper flange joint plate 311, respectively, the coupling means At 700a, the third upper flange joint plate 313 and the first upper flange joint plate 311 are fastened to each other.

Accordingly, the coupling between the first type steel structure 110 and the second type steel structure 120 and the connecting cover 200 can be made more robust.

Meanwhile, as shown in FIG. 9, the first steel structure 110 and the third steel structure 110 which are disposed in the piers 500 and the piers 500, respectively, among the form steel structures 110, 120, and 130. Inside one side of 130 is poured concrete.

Although not shown, a separate filling hole is formed in the upper portion of the first type steel structure 110 and the third type steel structure 130 so as to communicate with the space portion 150 therein.

In addition, inside the first type steel structure 110 and the third type steel structure 130, a separate concrete pouring portion 600 is formed in communication with the filling hole, and the concrete is poured through the filling hole.

As such, for the construction of placing concrete in the space portion 150 inside the first and second steel structures 110 and 130, the Korean Patent No. 754789 to which the applicant has applied for the patent, Detailed description thereof will be omitted.

Accordingly, according to the PSSC girder assembly of the present invention, when the girders are installed on the pier 500 and the pier 500, the first steel structure 110 and the third steel structure 110 and the third girder 500 are disposed on the pier 500 and the pier 500. Since the weight of the steel structure 130 is greater than the weight of the center portion, that is, the second steel structure 120 disposed between the pier 500 and the pier 500, the steel structure 110, 120, 130 Since the girder made of) can be minimized from shaking (swinging, etc.), the girder can be stably installed in the piers 500.

In other words, in the present invention, the concrete is poured at both ends of the girder, so that the weight of both ends arranged in the piers among the girders is relatively greater than the weight of the center of the girders disposed between the piers and the piers, between the piers and the piers The girder can be installed very stably.

At this time, the applicant of the applicant between the pier 500 and the pier 500, and between the first and second type steel structure 110 and the third type steel structure 130 are respectively installed in the pier 500 and the pier 500, respectively. It is preferable that a known support member 800 is installed in Korean Patent Laid-Open Publication No. 2003-75361 (synthetic teaching device for seismic reinforcement).

Therefore, severe damage and falling accidents may be prevented by the collision between the first and second steel structures 110 and 130 and the piers 500.

As described above, the PSSC girder assembly of the present invention can miniaturize the steel structure, so that the transportation of the steel structure is very easy.

In addition, it is possible to easily combine the girder steel structure and another girder steel structure at the work site, which makes the girder continuity very easy, and as a result, the field construction is possible, which can shorten the working period and reduce the cost. .

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or changes to the present invention without departing from the spirit and scope of the invention described in the claims below It can be modified.

The present invention is suitably used to facilitate the continuous girder of the girders by simply joining the section steel structure and another section steel structure at the work site.

1 is a perspective view of the present invention PSSC girder assembly.

Figure 2 is an exploded perspective view of the present invention PSSC girder assembly.

3 is a front view of the present invention PSSC girder assembly.

4 is a plan view of the present invention PSSC girder assembly.

5 is a rear view of the present invention PSSC girder assembly.

6 is a cross-sectional view of a section A of FIG. 3.

7 is a cross-sectional view of the male coupling portion of the present invention PSSC girder assembly.

8 is a cross-sectional view of the female coupling portion of the present invention PSSC girder assembly.

9 is a use state diagram schematically showing a state in which the present invention PSSC girder assembly is installed in the piers.

<Explanation of symbols for the main parts of the drawings>

101: upper flange 102: lower flange 103a, 103b: web

104: first section steel 105: second section steel 110: first section steel structure

120: second type steel structure 130: third type steel structure 140: incision

150: space portion 160: tension member 170: water coupling portion

171: epoxy part 172: first insertion part 173: second insertion part

174: locking groove 180: female coupling portion 181: epoxy portion

182: first insertion groove 183: second insertion groove 184: locking projection

185: sliding part 200: connecting cover 210: upper flange

220a, 220b: web 250: space

311: first upper flange joint plate 312: second upper flange joint plate

313: third upper flange joint plate 321: first lower flange joint plate

322: second lower flange joint plate 323: third lower flange joint plate

331: first web plate 332: second web plate

333: third web joint plate 334: fourth web joint plate

341: upper plate 342: lower plate

400: Saddle 500: Pier 600: Concrete pouring part

700a, 700b, 700c: coupling means 800: support member

Claims (5)

A steel structure including an upper flange, a lower flange, and a plurality of webs connecting the upper flange and the lower flange to form an inner space surrounded by the upper flange, the lower flange, and the web; It includes a tension member which is installed in the inner space portion of the steel structure, The tension member is formed by coupling at least one tension member to each other in a line, one end of the tension member is coupled to the female coupling portion is formed, the other end portion of the tension member coupled to the tension member is formed with a male coupling portion, A locking groove and a locking protrusion are formed in each of the female coupling portion and the male coupling portion, so that the locking protrusion is caught in the locking groove, so that the tension member coupled at both sides is firmly tensioned, Cutting portions formed on one side or both sides of the steel structure by cutting the upper flange and the web; PSSC girder assembly comprising a connecting cover coupled to the incision. The method of claim 1, The water coupling portion, An epoxy part formed at the end of the tension member; A first inserting portion protruding from the end of the epoxy portion; A second insertion part which projects from the end of the first insertion part and protrudes; An inserting member having a lower inclination toward the front of the first inserting portion; One side of the insertion member includes a locking groove formed, The female coupling portion, A receiving member; A first insertion groove and a second insertion groove formed in the accommodation member and accommodating the first insertion portion and the second insertion portion, respectively; The inner circumference of the first insertion groove is formed to be inclined toward the front, the one side is formed with a locking projection is inserted into the locking groove of the male coupling portion, PSSC girder assembly characterized in that the pressing member is formed on the outer surface of the receiving member to slide the pressing member. The method of claim 1, PSSC girder assembly, characterized in that the concrete is poured in one side of the steel structure, which is disposed in the piers in the steel structure. A pair of I-shaped steels having an upper flange, a lower flange, and a web connecting the upper flange and the lower flange are directly contacted with each other on both sides, thereby forming an inner space surrounded by the upper flange, the lower flange, and the web. A structure; It includes a tension member which is installed in the inner space portion of the steel structure, The tension member is formed by coupling at least one tension member to each other in a line, one end of the tension member is coupled to the female coupling portion is formed, the other end portion of the tension member coupled to the tension member is formed with a male coupling portion, A locking groove and a locking protrusion are formed in each of the female coupling portion and the male coupling portion, so that the locking protrusion is caught in the locking groove, so that the tension member coupled at both sides is firmly tensioned, A joint plate disposed on both sides of the upper flange and the lower flange of the steel structure; Coupling means for coupling the flange and the joint plate through the upper flange and the lower flange of the section steel structure and the joint plate; PSSC girder assembly characterized in that. The method of claim 4, wherein PSSC girder assembly characterized in that the concrete is poured only at both ends of the PSSC girder assembly.

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