KR102403606B1 - Foundation structure for walking way in facility using glude laminated timber - Google Patents

Abstract

The present invention relates to a basic structure for a pedestrian facility using a structural laminate, and more particularly, when constructing a pedestrian facility connecting an abutment, walking by a tensile tendon installed to give a tensile force to the inner side of the structural laminate It relates to a basic structure for a pedestrian facility using a structural laminate that not only increases the durability of the facility, but also allows the tensile tendon to be quickly and highly tensioned only by rotating the rotating tension part when the tensile tendon is in high tension.
The present invention relates to a basic structure for a pedestrian facility comprising a pair of laminated structural members 100 spaced apart from each other and a plurality of sub-timber beams 200 installed to interconnect the structural laminates 100, the Tendon 300 for tension installed in the tension member installation hole 110 formed along the longitudinal direction of the structural gluing material 100; In a state in which the structural gluing material 100 is installed to be seated at one end in the longitudinal direction, a tensile portion for tensioning and fixing one longitudinal side of the tensile tendon 300 is a built-in that is inserted into the tension member installation hole 110 . ledger 400; In a state in which the other longitudinal side of the tensile tendon 300 is pressed and fixed, it is installed to be exposed to the outside at the other longitudinal end of the structural laminate 100, and the tensile portion of the tensile tendon 300 is It is configured to include; an exposed rotational tensioning part 500 configured to provide tension to the tensioning tendon 300 while protruding to the outside, and the rotational tensioning part 500 is, the structural laminate 100. It is installed in close contact with the other end in the longitudinal direction of a hollow body sphere 510 having a binding thread 511 formed therein, and a corresponding thread 521 corresponding to the binding thread 511 is formed on the outer periphery. A tension protrusion 520 that is screwed to the inside of the close body sphere 510 and is formed such that the inner diameter gradually decreases from one side to the other in the longitudinal direction, and the tensile protrusion 520 is inserted into the tension protrusion 520 . It is configured to include a plurality of split wedge pieces 530 for fixing the tensile tendon 300 extending inward of the, and when the tensile force of the tensile tendon 300 is lost, the contact body sphere 510 When rotated, the tensile protrusion 520 comes out of the close contact body 510 by the binding screw thread 511 and the corresponding screw thread 521 so that the tensile tendon 300 can be re-tensioned. characterized in that

Description

FOUNDATION STRUCTURE FOR WALKING WAY IN FACILITY USING GLUDE LAMINATED TIMBER}

The present invention relates to a basic structure for a pedestrian facility using a structural gluing material, and more particularly, when constructing a pedestrian facility connecting an abutment, walking by a tensile tendon installed so that a tensile force is imparted to the inner side of the structural gluing material It relates to a basic structure for a pedestrian facility using a structural laminate that not only increases the durability of the facility, but also allows the tensile tendon to be quickly and highly tensioned only by rotating the rotating tension part when the tensile tendon is in high tension.

In general, on trails or hiking trails that require smooth walking by people, such as parks, lakes, and mountains, a beautiful, nature-friendly environment is created in line with the surrounding natural landscape, or it promotes safety and convenience for pedestrians in terrain where it is difficult for pedestrians to walk. As a means to create an optimal walking environment for people, various types of floor decks are being constructed and used.

In particular, wooden bridge decks made of wood are being widely constructed in recent years due to the advantages of being eco-friendly and capable of absorbing shock and vibration efficiently. Such a conventional deck for a wooden bridge installs structural laminated wood fixed in the transverse direction on the upper part of the abutment provided on both sides of the wooden bridge to be constructed, and a plurality of wooden members through fixing means such as nails on the upper part of the structural laminated timber. By installing it fixedly, a deck for a wooden bridge will be constructed.

Here, the structural gluing wood has high dimensional stability and structural reliability by bonding small-sized wood to each other to form a large square material, and since it is manufactured by removing defects peculiar to wood such as knots, the strength can be greater than that of general wood, The length, thickness, and width can be adjusted according to the purpose of use, and the deformation of warping and cracking is significantly less than that of solid wood, so it is widely used for structural columns and beams.

Since the laminated wood used for such a structure is used as a structural material for buildings and bridges, it is in the form of a square material rather than a plate shape. When it is used for rafters, it is often exposed as it is and serves as a finishing material.

However, the structural laminated wood used in this way has the advantage of not only improving strength compared to solid wood, but also retaining the pattern of the wood as it is. When a high load is applied to the span structure or the upper part, the volume of the laminated timber for structural use becomes too large, resulting in very poor practicality and economic feasibility.

As a background technology of the present invention, a wooden deck bridge structure and a construction method thereof of Korean Patent Registration No. 10-1066424 are disclosed.

The present invention was devised in view of the above circumstances, and an object of the present invention is to increase the durability of a walking facility made of wood by a tensile tendon installed so that a tensile force is imparted to the inner side of the structural laminate when the pedestrian facility is installed. For a pedestrian facility using the structural gluing material to increase workability by allowing the tensile tendon to be highly tensioned only by rotating the rotating tension part formed on either side of both ends in the longitudinal direction of the structural gluing material It is to provide the basic structure.

In addition, when the length of the structural gluing material is long and it is provided to the site in a cut state, the cut structural gluing material can be quickly and easily performed on site through a connecting connector, thereby providing improvement in site adaptability and constructability. let it be

The present invention for achieving the above object is a walking facility comprising a pair of structural gluing materials 100 spaced apart from each other and a plurality of sub-timber beams 200 installed to interconnect the structural gluing materials 100 In the base structure for, the tensile tendon 300 is installed in the tension member installation hole 110 formed along the longitudinal direction of the structural gluing material (100); In a state in which the structural gluing material 100 is installed to be seated at one end in the longitudinal direction, a tensile portion for tensioning and fixing one longitudinal side of the tensile tendon 300 is a built-in that is inserted into the tension member installation hole 110 . ledger 400; In a state in which the other longitudinal side of the tensile tendon 300 is pressed and fixed, it is installed to be exposed to the outside at the other longitudinal end of the structural laminate 100, and the tensile portion of the tensile tendon 300 is It is configured to include; an exposed rotational tensioning part 500 configured to provide tension to the tensioning tendon 300 while protruding to the outside, and the rotational tensioning part 500 is, the structural laminate 100. It is installed in close contact with the other end in the longitudinal direction of a hollow body sphere 510 having a binding thread 511 formed therein, and a corresponding thread 521 corresponding to the binding thread 511 is formed on the outer periphery. A tension protrusion 520 that is screwed to the inside of the close body sphere 510 and is formed such that the inner diameter gradually decreases from one side to the other in the longitudinal direction, and the tensile protrusion 520 is inserted into the tension protrusion 520 . It is configured to include a plurality of split wedge pieces 530 for fixing the tensile tendon 300 extending inward of the, and when the tensile force of the tensile tendon 300 is lost, the contact body sphere 510 When rotated, the tensile protrusion 520 comes out of the close contact body 510 by the binding screw thread 511 and the corresponding screw thread 521 so that the tensile tendon 300 can be re-tensioned. characterized in that

In addition, the built-in tensile part 400 includes a mounting plate 410 installed to be seated on one end in the longitudinal direction of the structural gluing material 100, and the tension member installation hole ( 110) is inserted into the inner side of the hollow holding hole 420, which is formed so that the inner diameter gradually decreases from one side to the other in the longitudinal direction, and is installed to be inserted into the inside of the holding hole 420 of the holding hole 420 It is configured to include a split-type wedge mechanism 430 for tension-fixing while pressing the outer periphery of the tensile tendon 300 extending inward.

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In addition, a joint bracket 210 that is fixedly installed at both ends in the longitudinal direction of the sub-timber beam 200 and a locking extension groove 211 extends upwardly from the lower end on one side thereof, and the structural gluing material 100 ) is installed to be mounted on the side of the sliding locking hole 221 that is slidably coupled to the locking extension groove 211 on one side while being caught in the locking extension groove 211 on one side. .

In addition, the structural girder 100 is made of a pair of main girder 120 and a joint girder 170 installed to be connected to the main girder 120 through a connecting connector 130 as a medium, the main girder When connecting 120 and the joint girder 170 through the connecting connector 130, the tension material installation hole 110 formed in the main girder 120 and the tension material installation hole 110 formed in the joint girder 170 A communication hole 160 communicating with the tension member installation hole 110 formed in the main girder 120 and the joint girder 170, respectively, is formed in the connecting connector 130. .

In addition, the connection connector 130 is mounted on the end of the main girder 120, and the binding body 140 is formed so that the binding guide groove 141 extends from the upper end to the downward direction on one side, and the joint girder ( 170) is mounted on both ends in the longitudinal direction, and on one side facing the binding body 140, sliding fasteners 151 that are slidably inserted and caught in the binding guide groove 141 are formed to protrude from the fastening body 150. ) is included.

In addition, the binding body 140 has a grip protrusion 144 formed along the edge of the binding guide groove 141 and protruding inward so that the edge of the sliding fastener 151 can be caught. .

In addition, on the upper side in the longitudinal direction of the fastening body 150, a bolt fixing hole ( A seating cover member 155 is provided with 156) formed therein, and a position groove 145 for allowing the seating cover member 155 to be seated is formed on the upper side of the binding body 140 in the longitudinal direction, so that the bolt fixing hole is formed. A bolt hole 157 passing through 156 is made to be bound to the binding body 140 .

According to the present invention, the durability of a walking facility constructed of wood is improved by a tensile tendon installed in a high tension state inside the structural laminate, and a rotating tension part formed on either side of both ends in the longitudinal direction of the structural laminate. It is possible to easily high-tension the tensioning tendon only by rotating operation of , so that workability is improved, and when the tension of the tensioning tendon is lost due to long-term use, the re-tensioning operation can also be easily performed.

In addition, when a pedestrian facility is provided to the site in a cut state due to the length of the structural gluing material being long due to the situation of the construction site, the cut structural gluing material can be quickly and easily performed at the site through the connecting connector, so that the site adaptability and improvement of constructability can be expected.

1 is a state diagram showing an installation state of a basic structure for a pedestrian facility using a structural gluing material according to the present invention;
2 is a state diagram showing a planar state of a basic structure for a pedestrian facility using a structural gluing material according to the present invention;
3 is a cross-sectional view showing the state of the built-in tensile part according to the present invention;
4 is a state diagram showing a state in which the built-in tensile part according to the present invention is installed in the structural gluing material;
5 is a state diagram showing the state of the split-type wedge mechanism according to the present invention;
6 is a state diagram showing another embodiment of the built-in tensile part according to the present invention;
7 is a state diagram showing the state of the rotary tension part according to the present invention;
8 is a state diagram showing the mounting state of the rotary tension part according to the present invention;
9 is a state diagram showing a state in which the structural girder according to the present invention is composed of a main girder and a joint girder;
10 is a state diagram showing the flat state of the structural girder according to the present invention consisting of a main girder and a joint girder;
11 is a state diagram showing a state in which the main girder and the joint girder are connected by a connecting connector according to the present invention;
12 and 13 are enlarged state views of the binding body and the fastening body according to the present invention;
14 is a state diagram showing the connection state of the binding body and the fastening body according to the present invention;
15 and 16 are state diagrams showing another embodiment of the binding body and the fastening body according to the present invention;
17 is a state diagram showing a state in which a sub-wood beam according to the present invention is connected via a joint bracket and a fastening bracket;
18 is a plan sectional view showing a cross-sectional state of the joint bracket and the fastening bracket according to the present invention;
19 and 20 are state diagrams showing another embodiment of the joint bracket and the fastening bracket according to the present invention;
21 is a state diagram showing another embodiment of a basic structure for a pedestrian facility according to the present invention;
22 is a state diagram showing another embodiment of the basic structure for a pedestrian facility according to the present invention.

Hereinafter, with reference to the accompanying drawings, a basic structure for a pedestrian facility using the structural gluing material according to the present invention will be described in detail. Prior to this, in the description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, the terms to be described later are terms set in consideration of the function in the present invention, and these terms may vary according to the intention or custom of the producer or manufacturer producing the product, and the thickness of the lines shown in the drawings or the size of the components etc. may be exaggerated for clarity and convenience of explanation, and the configuration shown in the embodiments and drawings described in this specification is only the most preferred embodiment of the present invention and does not represent all of the technical spirit of the present invention. Therefore, it should be understood that there may be various equivalents and modifications that can be substituted for them at the time of filing the present application.

In addition, when a part is 'connected' to another part throughout the specification, this includes not only 'directly connected' but also 'indirectly connected' with another element interposed therebetween. do. In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

1 is a state diagram showing the installation state of the basic structure for a pedestrian facility using the structural gluing material according to the present invention, and FIG. 2 is a state diagram showing the plan state of the basic structure for a pedestrian facility using the structural gluing material according to the present invention. 3 is a cross-sectional view showing the state of the built-in tensile part according to the present invention, FIG. 4 is a state diagram showing the state in which the built-in tensile part according to the present invention is installed in the structural gluing material, and FIG. 5 is the state of the split wedge mechanism according to the present invention is a state diagram showing a state diagram, FIG. 6 is a state diagram showing another embodiment of the built-in tension unit according to the present invention, FIG. 7 is a state diagram showing the state of the rotation type tension unit according to the present invention, and FIG. 8 is a rotation type according to the present invention It is a state diagram showing the mounting state of the tenon, FIG. 9 is a state diagram showing a state in which the structural girder according to the present invention consists of a main girder and a joint girder, and FIG. It is a state diagram showing a state, and FIG. 11 is a state diagram showing a state in which the main girder and the joint girder are connected by a connecting connector according to the present invention, and FIGS. 12 and 13 are enlarged states of the binding body and the fastening body according to the present invention 14 is a state diagram showing a connection state between the binding body and the fastening body according to the present invention, and FIGS. 15 and 16 are state diagrams showing another embodiment of the binding body and the fastening body according to the present invention, FIG. 17 is a state diagram showing a state in which a sub-wood beam according to the present invention is connected via a joint bracket and a fastening bracket, and FIG. 18 is a plan sectional view showing a cross-sectional state of the joint bracket and the fastening bracket according to the present invention, FIGS. 20 is a state diagram showing another embodiment of the joint bracket and the fastening bracket according to the present invention.

As shown in FIGS. 1 to 20, the basic structure for a pedestrian facility using the structural laminate according to the present invention includes a pair of structural laminates 100 and the structural laminates 100 that are spaced apart from each other at regular intervals. In the basic structure for a walking facility consisting of a plurality of sub-timber beams 200 installed to be connected, the tensile tendon 300 installed inside the structural laminate 100, and the structural laminate 100 A built-in tensile part 400 for tensilely fixing the tensile tendon 300 from one side in the longitudinal direction, and an exposed rotation type for tensilely fixing the tensile tendon 300 from the other longitudinal side of the structural laminate 100 It is configured to include a book (500).

That is, the basic structure for a pedestrian facility using the structural gluing material according to the present invention is installed so that a tensile force is imparted to the inside of the structural gluing material 100 during the construction of a walking facility that interconnects the abutment, that is, a deck rod. As well as to increase the durability of the walking facility by a high tension operation of the tensile tendon 300 installed inside the structural gluing material 100, the tensile To increase the workability by allowing the tendon 300 for use in high tension, especially when the chest wall 20 is formed on the upper part of the abutment 10, the chest wall 20 and the structural laminate 100 The work equipment is put into the space 30 formed between the ends of the rotatable tensioning part 500 so that the tensioning tendon 300 can be highly tensioned only by rotating the rotary tensioning part 500 to increase workability.

The tensile tendon 300 is to be installed in the tension member installation hole 110 formed along the longitudinal direction of the structural gluing material 100, and the tensile tendon 300 is a deformed iron wire, PC steel wire (Prestressed Concrete steel wire) ), a steel bar, and a plurality of strands may be made of any one of a twisted structure wire in which a plurality of strands are rolled around an axis in a spiral shape.

At this time, it is preferable to use the tensile tendon 300 having a low elongation, and one tensile tendon can be installed in the structural gluing material 100, but the present invention is not limited thereto. 100) to clarify that a plurality can be installed.

In addition, the built-in tensile part 400 is installed to be seated on one end in the longitudinal direction of the structural gluing material 100, and the tensile portion for fixing one side in the longitudinal direction of the tensile tendon 300 is the tension member installation hole. (110) is installed to be inserted into the inside.

That is, the tensile portion of the built-in tensile unit 400 is inserted into the inner side of the tension material installation hole 110 to prevent damage or breakage of the tensile area due to long-term use, so that the bearing capacity of the deck rod can be smoothly maintained for a long time. will do

The built-in tensile part 400 as an embodiment includes a mounting plate 410 installed to be seated on one end of the structural gluing material 100 in the longitudinal direction, and the tension member installed in the mounting plate 410 . The hollow holding hole 420 is inserted into the ball 110 and is formed so that the inner diameter gradually decreases from one side to the other in the longitudinal direction, and the holding hole 420 is installed to be inserted inside the holding hole 420 . ) may be configured to include a split-type wedge mechanism 430 for tension-fixing while pressing the outer periphery of the tensile tendon 300 extending inward.

That is, the mounting plate 410 is installed to be seated on one end in the longitudinal direction of the structural gluing material 100 in a flat-panel structure having a predetermined area, and the holding hole 420 is the mounting plate 410 in the It is formed to extend in the direction of the tension member installation hole 110 , and the mounting plate 410 has a mounting through-hole 411 communicating with the inside of the holding hole 420 .

Here, the inner diameter of the holding hole 420 is formed such that the inner diameter gradually decreases from one side in the direction of the mounting plate 410 to the other side in the direction of the tension member installation hole 110, and the split wedge mechanism 430 is The outer periphery of the tensile tendon 300 is pressed and fixed by the inner diameter of the holding hole 420 that is inserted into the holding hole 420 and gradually becomes smaller.

At this time, the split-type wedge mechanism 430 is a plurality of arc splitting spheres 431 having an arc-shaped outer periphery and inner periphery and an elastic wrapping sphere 432 installed to surround the upper side of the arc splitting sphere 431 ) The arc splitter 431 is connected via the elastic lapping sphere 432 to form a tendon insertion hole 433 that allows the tensioning tendon 300 to be inserted into the central portion. .

As described above, in the present invention, as the split wedge mechanism 430 has a structure corresponding to the gradually decreasing inner diameter of the holding hole 420, when the tension tendon 300 is tensioned, the arc splitter 431 ) is prevented from being warped, so that it is possible to easily achieve compression fixation of the tensile tendon 300 .

Here, the holding hole 420 may be installed such that one side in the longitudinal direction is fixed to the mounting plate 410 or rotatably installed by being caught in the mounting plate 410 , and the holding hole 420 is the mounting plate 410 . When it is rotatably installed while being caught in the plate 410, a joint hole 412 through which the holding hole 420 can pass is formed in the mounting plate 410, and the joint hole 412 is formed. A seating and engaging end 413 inclined in an inward direction may be formed at the edge of the .

In addition, the holding hole 420 is formed with a contact seating hole 421 caught by the seating stopper end 413 , and the contact seating hole 421 has an outer periphery diameter to correspond to the seating locking end 413 . This structure is gradually increased so that when the contact seating hole 421 is caught by the seating and stopping end 413, one end of the holding hole 420 and the surface of the mounting plate 410 are positioned on the same line. .

In addition, the exposed rotational tensioning unit 500 is installed to be exposed to the outside at the other longitudinal end of the structural laminate 100 in a state in which the other longitudinal side of the tensile tendon 300 is pressed and fixed to the outside to be rotated. As a result, the tensile portion of the tensile tendon 300 protrudes to the outside, and thus a tension force can be applied to the tensile tendon 300 .

That is, in a state in which one side of the tensile tendon 300 is pressed and fixed to the built-in tensile unit 400 and the other side of the tensile tendon 300 is pressed and fixed to the rotational tensile unit 500, the shift 10 ) of the chest wall 20 and the end of the structural laminate 100 by putting equipment into the space 30 and rotating the rotary tension part 500 by pressing the tension tendon 300 As the fixed tensile portion protrudes to the outside, the tensile tendon 300 can be highly tensioned.

In addition, when the tensile tendon 300 is installed such that a pair is positioned at the upper and lower sides on the cross-section of the structural laminate 100 , one side in the longitudinal direction of the structural laminate 100 has the rotation-type tension part 500 on the upper side. ) is located and the built-in tensile part 400 is positioned at the bottom, and the built-in tensile part 400 is positioned on the other side in the longitudinal direction of the structural laminate 100 at the upper part, and the rotary-type tensile part 500 is positioned at the lower part. It will be preferable to effectively achieve the tension of the tensile tendon 300 installed on the upper and lower sides on the cross-section of the structural laminate 100 by positioning it.

Here, the rotary tension part 500 as an embodiment is installed in close contact with the other end in the longitudinal direction of the structural gluing material 100, and a hollow body close-fitting body sphere 510 having a binding screw 511 formed therein. And, on the outer periphery, a corresponding thread 521 corresponding to the binding thread 511 is formed, and is screwed to the inside of the close contact body sphere 510, and the inner diameter gradually decreases from one side to the other in the longitudinal direction. A plurality of split wedge pieces 530 for tensile fixing the protrusion 520 and the tensile tendon 300 inserted inside the tensile protrusion 520 and extending to the inside of the tensile protrusion 520 are included. is composed

That is, the tensile protrusion 520 is screwed to the inside of the close contact body 510 in close contact with the end of the structural gluing material 100 , and the plurality of divisions installed inside the tensile protrusion 520 . When the close contact body 510 is rotated in a state in which the tensile tendon 300 is fixed in tension by the wedge piece 530, the tensile protrusion 520 is connected to the binding screw thread 511 and the corresponding screw thread 521. By this, it is possible to easily high-tension the tensile tendon 300 while coming out of the close contact body 510, or to easily perform a re-tensioning operation when tension is lost due to long-term use.

At this time, a body support plate 540 that allows the close contact body 510 to be in close contact with the end of the structural gluing material 100 may be installed, and the close contact body piece 510 has a circular shape in cross section. However, the present invention is not limited thereto, and it is to be noted that it may have a polygonal shape such as a hexagon or an octagon for easy rotation operation using a tool.

In addition, the plurality of split wedge pieces 530 are made to have the same structure as the arc splitter 431 , and one side of the split wedge piece 530 has an elastic fixing ring such as the elastic lapping piece 432 ( When the 531 is installed and a plurality of split wedge pieces are connected via the elastic fixing ring 531, a tendon fitting hole 532 for inserting the tensile tendon 300 is formed in the central portion.

On the other hand, the structural gluing material 100 is installed to be connected to a pair of main girder 120 installed to be seated on the upper part of the abutment 10 and the main girder 120 via a connection connector 130 . It may be made of a joint girder 170 to be.

That is, when the length of the structural gluing material 100 is increased, it is cut to a certain length for ease of transport and provided to the site, and the cut and transported structural gluing material 100 is assembled at the site with each other, in this process In a state where the mounting plate closely adheres to or wraps around the outer surface of the cut part of the structural gluing material is installed, a plurality of binding bolts pass through the mounting plate and are embedded in the side of the structural gluing material to connect the structural gluing material cut to a certain length will do

However, in the case of such an operation, the connection workability for connecting the mounting plate and the binding bolt in a state in which the upper surface of the cut structural laminate is leveled is significantly reduced, and the binding bolt is installed on the side of the structural laminate In the process, cracks are generated on the outer surface of the laminate for structural purposes, resulting in reduced durability.

Therefore, in the present invention, the main girder 120 and the joint girder 170 can be easily connected via the connecting connector 130, and cracks between the main girder 120 and the joint girder 170 are prevented in advance. Thus, it is possible to install a solid structural laminate.

Here, when the main girder 120 and the joint girder 170 are connected through the connecting connector 130 , the tension material installation hole 110 formed in the main girder 120 and the tension material formed in the joint girder 170 . The installation hole 110 is made to be located on the same line, and the connection connector 130 has a communication hole communicating with the tension member installation hole 110 formed in the main girder 120 and the joint girder 170, respectively. 160) may be formed.

This allows the main girder 120 and the joint girder 170 to be easily connected and installed by the connecting connector 130 and through the communication between the tension member installation hole 110 and the communication hole 160 for the tensioning This is to facilitate the installation of the tendon 300 .

The connecting connector 130 as an embodiment is mounted on the end of the main girder 120, the binding body 140 formed to extend from the upper end to the lower direction on one side of the binding guide groove portion 141, and the joint A fastening body in which a sliding fastener 151 that is slidably inserted into and caught on the binding guide groove 141 on one side facing the binding body 140 in a state of being mounted on both ends of the girder 170 in the longitudinal direction is formed to protrude. 150 may be included.

Here, in the binding body 140, a plurality of bolt through holes 143 for installing the binding bolt 142 bound to the end of the main girder 120 are formed to penetrate from one side to the other side, and the The binding guide groove portion 141 is formed with a predetermined length in the downward direction from the upper end of the binding body 140 so that the sliding fastener 151 of the fastening body 150 moves from the upper side of the binding body 140 to the downward direction. It is made so that it can be inserted by sliding.

In addition, the fastening body 150 is installed to be mounted on the longitudinal end of the joint girder 170, a plurality of bolt installation holes 153 for installation of the binding bolt 142 from one side to the other side The sliding fastener 151 is formed to protrude to correspond to the binding guide groove portion 141 .

At this time, the binding body 140 has a grip protrusion 144 formed along the edge of the binding guide groove 141 and protruding inwardly so that the edge of the sliding fastener 151 can be caught, and , the grip protrusion 144 is made to have a wedge-shaped structure in which the width is gradually narrowed from the edge to the end direction of the binding guide groove portion 141 in cross section.

In addition, it is preferable that a sliding locking hole 154 that can be caught by the grip protrusion 144 is formed to protrude from the edge of the sliding fastening hole 151 of the fastening body 150 .

Briefly looking at the state in which the main girder 120 and the joint girder 170 are connected by the binding body 140 and the fastening body 150 configured as described above, the binding body 140 and the fastening body 150 are shown. In a state in which each of the main girder 120 and the joint girder 170 is mounted on the ends, the sliding fastener 151 of the fastening body 150 is inserted into the binding guide groove 141 of the binding body 140. When sliding, the upper surfaces of the main girder 120 and the joint girder 170 can be connected to each other while being positioned on the same horizontal line. It is possible to increase the binding force between the girder 120 and the joint girder 170 .

In addition, in the longitudinal direction of the upper side of the fastening body 150, the bolt fixing hole 156 is formed to extend in the lateral end direction of the fastening body 150 in a state of being connected to the sliding fastener 151 and penetrates from the upper side to the lower side. ) is formed, a position groove 145 is formed on the upper side in the longitudinal direction of the binding body 140 to allow the seating cover member 155 to be seated, so that the bolt fixing hole ( A bolt hole 157 passing through 156 is bound to the binding body 140 .

That is, when the sliding fastener 151 of the fastening body 150 is slidably fastened to the binding guide groove 141 of the binding body 140 , the seating cover member 155 is seated in the position groove 145 . In such a state, as the bolt sphere 157 passing through the bolt fixing hole 156 is bound to the upper side of the binding body 140, the coupling state of the binding body 140 and the fastening body 150 is determined. This will make it more robust.

In addition, when the joint girder 170 is connected to the main girder 120 as the seating cover opening 155 of the fastening body 150 is seated in the position groove 145 of the binding body 140, The downward movement of the joint girder 170 is restricted so that the upper surface of the main girder 120 and the upper surface of the joint girder 170 can be positioned on the same horizontal line.

In addition, a connector accommodating groove 121 for accommodating the binding body 140 and the fastening body 150 may be formed at an end of the main girder 120 .

That is, the connector accommodating groove 121 is formed to have a predetermined depth at the end of the main girder 120 and is formed to have a predetermined length in the downward direction from the upper side of the main girder 120 , the connector receiving groove When the fastening body 150 mounted on the end of the joint girder 170 is slidably fastened to the binding body 140 in a state where the binding body 140 is installed inside the binding body 140, the binding body ( 140) and the fastening body 150 have a structure built-in to the inside of the connector receiving groove 121, so that the connecting connector 130 made of iron composed of the binding body 140 and the fastening body 150 is Since it is not exposed to the outside, it is possible to prevent deformation in the event of a fire, thereby preventing secondary accidents such as collapse. At this time, it is preferable that the lower end of the binding body 140 is installed to be seated on the lower surface of the connector receiving groove 121 .

As described above, in the present invention, when the length of the structural gluing material 100 is increased and provided to the site in a cut state, it is cut through the connecting connector 130 composed of the binding body 140 and the fastening body 150 . It is possible to quickly and easily fasten the structural laminates on site to improve the workability, as well as to increase the workability of the deck by horizontally connecting the cut top surfaces of the structural laminates.

In addition, in a state in which the binding body 140 and the fastening body 150 are mounted on the ends of the main girder 120 and the joint girder 170 via the binding bolt 142, the main girder 120 and In the case of connecting the joint girder 170, the binding bolt 142 is fastened in the fiber direction of the main girder 120 and the joint girder 170, thereby reducing the holding force of the binding bolt may occur, but in the present invention By enabling the main girder 120, the joint girder 170, and the tensioning tendon 300 penetrating the connecting connector 130 to easily respond to a decrease in the binding force of the binding bolt 142, It is possible to increase the durability of the laminated material 100 for the structure.

On the other hand, the sub-timber beam 200 may be connected to the side of the structural laminate 100 via a joint bracket 210 and a fastening bracket 220 . That is, through the joint bracket 210 and the fastening bracket 220, the sub-wood beam 200 can be quickly and easily installed to the structural laminate 100, while the damage to the sub-wood beam 200 is prevented. to be able to prevent it.

The joint bracket 210 is fixedly installed at both ends in the longitudinal direction of the sub-wood beam 200, and a locking extension groove 211 is formed to extend upwardly from the lower end on one side, the joint bracket 210 A plurality of anchor holes 212 for through-installation of the fastening bolts 213 to the sub-timber beam 200 may be preferably formed.

In addition, the fastening bracket 220 is installed to be mounted on the side of the structural gluing material 100, a sliding locking hole 221 that is slidably coupled while being caught in the locking extension groove 211 on one side is at the lower end. It is formed to extend upward, and it is preferable that a plurality of passing holes 222 are formed in the fastening bracket 220 for through installation of the locking fixture 223 fastened to the side surface of the structural gluing material 100 . something to do.

At this time, at the lower side in the longitudinal direction of the fastening bracket 220 , the screw fixing hole 227 is formed to extend in the lateral end direction of the fastening bracket 220 while being connected to the sliding locking hole 221 , and penetrates from the lower side to the upper side. ) is formed, and at the lower side in the longitudinal direction of the joint bracket 210, when the joint bracket 210 and the fastening bracket 220 are slidably coupled, the support sphere 226 can be located. A support corresponding groove 216 may be formed to allow it.

That is, when the joint bracket 210 installed at the end of the sub-timber beam 200 is slidably coupled to the fastening bracket 220 mounted on the side of the structural laminate 100, in the support corresponding groove 216 As the support member 226 has a structure in which it is positioned, the joint bracket 210 is supported by the support member 226, thereby limiting the downward movement of the sub-timber beam 200, and thus a plurality of the As the sub-timber beam 200 is installed between the structural gluing materials 100 at the same position, the joist member is installed horizontally when the joist member for installation of the deck material is installed on the upper portion of the sub-timber beam 200 it will become possible

In addition, a locking grip end 215 protruding inwardly is formed on the edge of the locking extension groove 211, and the locking grip end 215 is, in cross section, from the edge of the locking extension groove 211 toward the end direction. It is made to have a wedge-shaped structure in which the width is gradually narrowed, and at the edge of the sliding locking hole 221, a corresponding grip end 225 to be caught by the engaging grip end 215 is formed to protrude, The joint bracket 210 and the fastening bracket 220 are made to increase the binding force.

In addition, a bracket accommodating groove 230 for accommodating the joint bracket 210 and the fastening bracket 220 may be formed at an end of the sub-wood beam 200 .

That is, the bracket accommodating groove 230 is formed to have a certain depth at the end of the sub-timber beam 200 and is formed to have a certain length in the upward direction from the lower side of the sub-timber beam 200, and to accommodate the bracket When the joint bracket 210 is installed inside the groove 230 and the joint bracket 210 is slidably fastened to the fastening bracket 220, the joint bracket 210 and the fastening bracket 220 are connected to the bracket receiving groove 230. It has a structure built-in to the inside of the , so that the joint bracket 210 and the fastening bracket 220 are not exposed to the outside, thereby preventing deformation in case of fire. At this time, it is preferable that the lower end of the joint bracket 210 be installed to be seated on the lower surface of the bracket receiving groove 230 .

As described above, in the present invention, when the sub-timber beam 200 is connected to the structural laminate 100, the sub-timber beam 200 is installed through sliding coupling between the joint bracket 210 and the fastening bracket 220. can be carried out quickly and easily, so that the effect of improving constructability can be expected.

In addition, a plurality of sub-wood beams 200 are fastened to a pair of main girder 120 by the joint bracket 210 and fastening bracket 220 to form one main block unit 600, and a pair A plurality of sub-wood beams 200 are fastened to the joint girder 170 of By interconnecting the main block unit 600 and the connecting block unit 700 through the connecting connector 130 made of the fastening body 150, the on-site assembly efficiency can be improved.

In addition, as shown in FIG. 21, a plurality of structural gluing materials are installed one after another in a state in which a plurality of alternations are installed to be spaced apart from each other at regular intervals, or as shown in FIG. It is to be noted that it can be made of a structure that is sequentially installed on top of a plurality of abutments by interconnecting them by

Although specific embodiments of the present invention have been described in detail as described above, various modifications may be made to those skilled in the art without departing from the scope of the present invention. Therefore, the scope of the present invention is not limited to the above-described embodiments, and should be defined by not only the claims described below, but also the claims and equivalents.

100: structural laminate 110: tension member installer
120: main girder 130: connecting connector
140: binding body 150: fastening body
160: communication hole 170: joint girder
200: sub-wood beam 210: joint bracket
220: fastening bracket 230: bracket receiving groove
300: tensile tendon 400: built-in tensile unit
410: mounting plate 420: holding sphere
430: split-type wedge mechanism 500: rotational tension unit
510: tight body sphere 520: tension protrusion
530: split wedge piece 540: body support plate

Claims (8)

In the basic structure for a pedestrian facility comprising a pair of laminated materials for structural use (100) spaced apart from each other and a plurality of sub-timber beams (200) installed to interconnect the laminated materials for structures (100),
Tendon 300 for tension installed in the tension member installation hole 110 formed along the longitudinal direction of the structural gluing material 100; In a state in which the structural gluing material 100 is installed to be seated at one end in the longitudinal direction, a tensile portion for tensioning and fixing one longitudinal side of the tensile tendon 300 is a built-in that is inserted into the tension member installation hole 110 . ledger 400; In a state in which the other longitudinal side of the tensile tendon 300 is pressed and fixed, it is installed to be exposed to the outside at the other longitudinal end of the structural laminate 100, and the tensile portion of the tensile tendon 300 is It is configured to include; an exposed rotational tensioning part 500 configured to provide tension to the tensioning tendon 300 while protruding to the outside;
The built-in tensile part 400 includes a mounting plate 410 installed to be seated at one end in the longitudinal direction of the structural gluing material 100, and the tension member installation hole 110 in a state installed on the mounting plate 410. A hollow holding hole 420 that is inserted into the inner side of the longitudinal direction so that the inner diameter gradually decreases from one side to the other side, and is installed to be inserted inside the holding hole 420 to the inside of the holding hole 420 . It is configured to include a split wedge mechanism 430 for tension-fixing while pressing the outer periphery of the extension tendon 300 for tension,
The rotary tension part 500 is installed in close contact with the other end in the longitudinal direction of the structural gluing material 100 and a hollow body sphere 510 having a binding thread 511 formed therein, and the binding to the outer periphery. A screw thread 521 and a corresponding thread 521 are formed to be screwed to the inside of the close contact body 510, and the tensile protrusion 520 is formed so that the inner diameter gradually decreases from one side to the other in the longitudinal direction, and the It is inserted into the inner side of the tensile protrusion 520 and is configured to include a plurality of split wedge pieces 530 for tensilely fixing the tensile tendon 300 extending inside the tensile protrusion 520 , the tensile tendon When the tension force of 300 is lost, when the contact body sphere 510 is rotated, the tension protrusion 520 is formed on the outside of the contact body sphere 510 by the binding screw thread 511 and the corresponding screw thread 521 . A basic structure for a pedestrian facility using laminated materials for structural use, characterized in that it is made to re-tension the tensile tendon 300 while exiting with a plywood.
According to claim 1,
A joint bracket 210 that is fixedly installed at both ends in the longitudinal direction of the sub-timber beam 200 and a locking extension groove 211 extends upwardly from the lower end on one side thereof, and the structural gluing material 100 A sliding locking hole 221 that is installed to be mounted on the side and slidably coupled to one side while being caught in the locking extension groove 211 is configured to further include a fastening bracket 220 formed in an upward direction from the lower end. A foundation structure for pedestrian facilities using structural gluing materials.
According to claim 1,
The structural gluing material 100 is made of a pair of main girder 120 and a joint girder 170 installed to be connected to the main girder 120 through a connecting connector 130 as a medium, but the main girder 120 ) and the joint girder 170 through the connecting connector 130, the tension material installation hole 110 formed in the main girder 120 and the tension material installation hole 110 formed in the joint girder 170 are the same It is made to be positioned on a line, and the connecting connector 130 has a communication hole 160 that communicates with the tension member installation hole 110 formed in the main girder 120 and the joint girder 170, respectively. A foundation structure for pedestrian facilities using structural gluing materials.
4. The method of claim 3,
The connecting connector 130 is mounted on the end of the main girder 120 and has a binding body 140 in which the binding guide groove 141 extends from the upper end to the lower side on one side thereof, and the joint girder 170. A fastening body 150 in which a sliding fastener 151 that is slidably inserted into and caught on the binding guide groove 141 on one side facing the binding body 140 in a state of being mounted on both ends in the longitudinal direction of the body 150 is formed to protrude. A basic structure for pedestrian facilities using structural gluing materials, characterized in that it is configured to include.
5. The method of claim 4,
The binding body 140 has a grip protrusion 144 formed along the edge of the binding guide groove 141 and protruding inward so that the edge of the sliding fastener 151 can be caught. A foundation structure for pedestrian facilities using structural gluing materials.
6. The method according to claim 4 or 5,
On the upper side in the longitudinal direction of the fastening body 150, a bolt fixing hole 156 that is formed to extend in the lateral end direction of the fastening body 150 in a state of being connected to the sliding fastening hole 151 and penetrates from the upper side to the lower side. The formed seating cover member 155 is provided, and a position groove 145 for allowing the seating cover member 155 to be seated is formed on the upper side of the binding body 140 in the longitudinal direction, so that the bolt fixing hole 156 is formed. ) through the bolt hole 157 is a basic structure for a pedestrian facility using a laminated material for structural use, characterized in that made to be bound to the binding body (140).
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