KR101260982B1 - Shoe for wooden bridge - Google Patents

Abstract

PURPOSE: A bridge seat device of a wooden bridge is provided to improve the durability of a bridge seat device by enabling a relative rotation of the upper and lower bracket. CONSTITUTION: A bridge seat device comprises a lower bracket(10), an upper bracket(20), a spacer(17), a shaft(30), and a key member(40). The lower bracket is fixed to a foundation and comprises a first shaft hole(11). The upper bracket is installed on both ends of a girder forming an arch structure and comprises a second shaft hole(21) connected to the first shaft hole. The shaft is inserted into the first shaft hole and the second shaft hole and connects the upper bracket and the lower bracket. The key member is connected to a key groove(31) formed on one side of the shaft.

Description

Wooden Teaching Unit {SHOE FOR WOODEN BRIDGE}

The present disclosure relates to a wood bridge chair, and more particularly, to a wood bridge chair that improves durability and facilitates construction and maintenance.

In general, wooden bridges are compactly installed in narrow waterways located in parks, rivers, and the like, to allow pedestrians to walk. The arched wooden bridge gives the girder an upwardly convex arch to improve stiffness and minimize the deflection of the girder.

Due to the nature of the arch structure, the girder is subject to axial forces at a given load. Axial forces exert a horizontal load on the stabilization device supporting both ends of the girder. Thus, in the case of a normal bridge, one side of the girder is connected to the bridge arrangement by a hinge and the other side has a roller to allow slip.

These roller and hinge stabilization devices are not suitable for wooden bridges with girder arches. Thus, the wood bridge takes the structure of simply placing the girder on the foundation, so that the girder can be separated from the foundation even under a weak vibration.

One embodiment of the present invention is to provide a wood bridge chair device to improve the durability, ease of construction and maintenance.

The wood bridge teaching apparatus according to an embodiment of the present invention, the lower bracket is fixed to the base having a first shaft hole, provided with both ends of the girder forming the arch structure and having a second shaft hole connected to the first shaft hole And a key member coupled to an upper bracket corresponding to a lower bracket, a shaft inserted into the first shaft hole and the second shaft hole to couple the lower bracket to the upper bracket, and a key groove formed on one side of the shaft.

The lower bracket may include a lower plate installed on the base, a pair of first vertical plates formed perpendicular to the lower plate to form a gap therebetween, and having the first shaft hole, and opposite sides of the gap, respectively. It may include a reinforcing plate for connecting the first vertical plate and the lower plate on both sides of the first shaft hole.

The upper bracket may include an upper plate installed in the girder, and a second vertical plate formed in a vertical state to the upper plate and inserted in the gap and having the second shaft hole.

The key member is formed in a plate shape, disposed between the reinforcing plates on the outside of the first vertical plate and partially inserted into the key groove, and mounted to the first vertical plate as a fixing member, and the key member and the key groove. Silver may be coupled in a plane parallel to the lower plate.

The key member is formed in a curved shape, disposed between the reinforcing plates on the outside of the first vertical plate and partially inserted into the key groove, and mounted to the first vertical plate as a fixing member, and the key member and the The key groove may be coupled to the curved surface along the circumference of the axis.

The shaft may include a first hole formed in an axial direction, a second hole penetrating in a radial direction from the first hole, and grease filled in the first hole by being coupled to the first hole. It may include a stopper for supplying the second shaft through the hole.

The lower bracket and the upper bracket may be formed of spherical graphite cast iron, and the shaft may be formed of a rolled steel.

The key member may be formed of a rolled steel material.

The girder may further include a reinforcement part disposed in a vertical direction at a portion connected to the upper bracket.

The girder may further include a mounting plate provided at a lower portion so as to correspond to the upper bracket.

The mounting plate may further include a protrusion that supports a lower surface of the girder and supports a side surface thereof.

Thus, according to an embodiment of the present invention, by connecting the lower bracket and the upper bracket to the shaft and by coupling the key member to the shaft, by the shaft to enable the relative rotation of the lower bracket, the staggering device in the axial force of the arched girder There is an effect of improving the durability.

According to one embodiment of the present invention, there is an effect of easily constructing the teaching device by combining the shaft and the key member.

In addition, according to an embodiment of the present invention, by forming the shaft and the key member of the lower strength than the lower bracket, the shaft or key member can be worn before the lower, upper bracket.

Therefore, by replacing the shaft or the key member, there is an effect of maintaining the chair device while using the upper bracket as it is.

1 is an exploded perspective view of a wood bridge teaching apparatus according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along the line II-II of FIG. 1.
3 is a partial side view of a wooden bridge provided with the chair apparatus of FIG.
4 is a partial cross-sectional view of a wood bridge teaching apparatus according to a second embodiment of the present invention.
5 is an exploded perspective view of the wood bridge teaching apparatus according to the third embodiment of the present invention.
FIG. 6 is a cross-sectional view taken along the line VI-VI of FIG. 5.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

1 is an exploded perspective view of a wooden bridge teaching apparatus 100 according to a first embodiment of the present invention, Figure 2 is a cross-sectional view taken along the line II-II of FIG. 1 and 2, the teaching device 100 of the first embodiment includes a lower bracket 10, an upper bracket 20, a shaft 30 and a key member 40, as shown in FIG. 3. As described above, the girder G is configured to be installed on the foundation B.

The lower bracket 10 is fixed to the base B and has a first shaft hole 11, and the upper bracket 20 is fixed to the girder G and has a second shaft hole 21. The first and second shaft holes 11 and 21 are disposed to correspond to each other so that the lower brackets 10 and 20 can be connected to each other by inserting the shaft 30.

The shaft 30 is inserted into the first and second shaft holes 11 and 21 to connect the lower brackets 10 and 20 to each other, and the key member 40 is formed to be concave on one side of the shaft 30. It is coupled to the key groove 31. Accordingly, the shaft 30 is provided with the key member 40 on one side and the head portion 32 on the other side, and provides the fastening force in the axial direction to the upper brackets 10 and 20.

The staircase device 100 is disposed in the same structure at both ends of the girder G, the girder G is fixed to the stairway device 100 at both ends and forms an upwardly convex arch structure. Therefore, by the load acting on the girder G, the bridge device 100 is subjected to the axial force.

For example, the girder G may be formed of an H beam or an I beam (see FIG. 4), and may further include a reinforcement part G1 disposed up and down in a portion connected to the upper bracket 20. (See FIG. 3). The reinforcement part G1 may be provided in plurality spaced apart along the longitudinal direction of the girder G.

3 is a partial side view of a wooden bridge in which the teaching device 100 of FIG. 1 is installed. Referring to FIG. 3, the arch girder G transmits a load to the chair device 100 to generate axial force in the chair device 100. For convenience, only one side of the girder G is shown and the other side is omitted.

As the load changes, the girder G changes the arch. The girder G forms an arch between the horizontal state of the solid line and the maximum arch state of the imaginary line as the load changes and the thermal deformation.

Referring back to FIGS. 1 to 3, the lower bracket 10 includes a lower plate 12, a first vertical plate 13, and a reinforcing plate 14. The lower plate 12 is installed on the base B in a horizontal state.

The base B is provided with a stud bolt 18 projecting upward. The lower plate 12 has a through hole 121 installed in the stud bolt 18 to be penetrated, and is fixed to the base B by a nut 181 fastened to the stud bolt 18.

The first vertical plate 13 is formed in a vertical state on the upper surface of the lower plate 12 and consists of a pair having a distance D from each other. In addition, the pair of first vertical plates 13 have a first shaft hole 11 arranged in a straight line so that the shaft 30 can be inserted in correspondence with each other.

In addition, the first vertical plate 13 forms a region around the first shaft hole 11 with a first thickness T1, and a region located remotely from the first shaft hole 11 with a second thickness T2. Form. Since the first thickness T1 is formed thicker than the second thickness T2, the strength of the first vertical plate 13 weakened around the first shaft hole 11 by the first shaft hole 11 is reinforced.

The reinforcing plate 14 connects the first vertical plate 13 and the lower plate 12 on each of the opposite sides of the gap D to reinforce the strength of the first vertical plate 13. For example, the reinforcing plate 14 is disposed on both sides of the first shaft hole 11 to reinforce the weakened strength of the first vertical plate 13 by the first shaft hole 11.

The upper bracket 20 includes an upper plate 23 and a second vertical plate 24. The upper bracket 20 is coupled to the lower bracket 10 and connected to the girder G, as shown in FIG.

The girder G further includes a mounting plate 15 at a lower portion thereof, and the girder G and the mounting plate 15 have a mounting hole 151 penetrating in the vertical direction. The mounting plate 15 may be welded to the bottom of the girder G.

The upper plate 23 has a through hole 231 and is fixed to the girder G and the mounting plate 15 by bolts 16 and nuts 161 fastened thereto.

The second vertical plate 24 is formed to be perpendicular to the upper plate 23, and is formed to be inserted into the gap D between the pair of first vertical plates 13. In addition, the second vertical plate 24 includes a second shaft hole 21 disposed in line with the first shaft hole 11 so that the shaft 30 can be inserted therein.

In addition, the second vertical plate 24 forms a region around the second shaft hole 21 with a third thickness T3, and has a fourth thickness T4 of a region located at a distance from the second shaft hole 21. Form. Since the third thickness T3 is formed thicker than the fourth thickness T4, the strength of the second vertical plate 24 weakened around the second shaft hole 21 by the second shaft hole 21 is reinforced.

Since the third thickness T3 around the second shaft hole 21 is formed to be larger than the first thickness T1 of the first shaft hole 11, the strength of the one second vertical plate 24 is one pair. 1 may correspond to the strength of the vertical plate (13).

The third thickness T3 of the second vertical plate 24 is set smaller than the distance D of the first vertical plate 13. In addition, spacers 17 are provided between the first and second vertical plates 13 and 24, respectively. When the upper brackets 10 and 20 rotate relative to each other due to the arch deformation of the girder G, the spacer 17 is formed between the first and second vertical plates 13 and 24. 13, 24) to prevent direct friction and wear on the side.

The shaft 30 has a first hole 33 formed in the axial direction, a second hole 34 penetrating in the radial direction from the first hole 33, and a stopper 35 coupled to the first hole 33. ). The stopper 35 is coupled to the first hole 33 to supply grease filled in the first hole 33 from the second hole 34 to the second shaft hole 21.

Grease discharged into the second hole 34 is supplied between the shaft 30 and the second shaft hole 21 of the second vertical plate 24. The second shaft hole 21 and the shaft 30 are relatively rotated portions, and when the arch of the girder G is changed, the second shaft hole 21 and the shaft 30 can be relatively rotated smoothly by grease. Accordingly, wear of the shaft 30 and the second vertical plate 24 is reduced. In addition, grease discharged into the second hole 34 is supplied between the second vertical plate 24 and the spacer 17 and between the spacer 17 and the first vertical plate 13 to lubricate.

The key member 40 is formed in a plate shape, disposed between the reinforcing plates 14 on the outside of the first vertical plate 13 and partially inserted into the key groove 31, and fixed to the side of the first vertical plate 13. It is mounted with the member 41. Therefore, the shaft 30, the key member 40 and the lower bracket 10 are integrally formed and connected to the structure fixed to the base B.

At this time, the key member 40 and the key groove 31 are coupled in a parallel plane. The planar coupling structure of the key member 40 and the key groove 31 is parallel (FIG. 3) or inclined (not shown) to the lower plate 12 depending on the fastening position of the fixing member 41 and the first vertical plate 13. It may be formed.

As such, the lower and upper brackets 10 and 20 are connected to the shaft 30 and the key member 40 is coupled to the shaft 30 to receive the support of the shaft 30 fixed to the lower bracket 10. The upper bracket 20 can rotate relative.

Therefore, durability of the seating apparatus 100 is improved also in the axial force of the arched girder G, and even when the arch of the girder G changes, the seating apparatus 100 can support the girder G stably. In addition, the chair apparatus 100 may be easily installed by the coupling of the shaft 30 and the key member 40.

For example, the lower bracket 10 and the upper bracket 20 may be formed of spherical graphite cast iron of FCD400 in JIS standard, and the shaft 30 may be formed of rolled steel of S45C in JIS standard. The key member 40 may be formed of a rolled steel of SS400 according to JIS standards.

Relatively, the upper and lower brackets 10 and 20 are formed of high strength cast iron, and the shaft 30 is formed of low strength rolled steel. Therefore, the shaft device 100 may be worn down in comparison with the lower brackets 10 and 20 in the chair device 100, and the maintenance of the chair device 100 may be performed by replacing the shaft 30.

In addition, since the key member 40 is formed of a material having a higher strength than the shaft 30, even when the shaft 30 is replaced several times, the maintenance of the stapling device 100 can be performed by replacing the key member 40 once. It is possible. That is, the maintenance of the teaching device 100 is easy, and the cost thereof is low.

Hereinafter, various embodiments of the present invention will be described. For convenience, the description of the same configuration of the first embodiment and the previously described embodiment will be omitted, and different configurations will be described.

4 is a partial cross-sectional view of the wood bridge teaching apparatus 200 according to a second embodiment of the present invention. Referring to FIG. 4, the mounting plate 25 further includes a protrusion 251. The girder G and the mounting plate 25 are provided with mounting holes 252 penetrating in the vertical direction. Mounting plate 25 may be coupled to the bottom of the girder (G).

In the first embodiment, the mounting plate 15 supports only the bottom surface of the girder G, whereas in the second embodiment, the mounting plate 25 supports the bottom and side surfaces of the girder G with the protrusion 251. Therefore, the protrusion 251 makes the connection structure of the chair apparatus 200 and the girder G more firm.

FIG. 5 is an exploded perspective view of the wood bridge teaching apparatus 300 according to the third embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along the line VI-VI of FIG. 5. In the first embodiment, the key member 40 is formed in a plate shape, whereas in the third embodiment, the key member 50 is formed in a curved shape (for example, U-shaped).

The key member 40 of the first embodiment is planarly coupled to the key groove 31 on one side of the shaft 30. In contrast, the key member 50 of the third embodiment is curvedly coupled to the key groove 61 around the shaft 60.

For example, the key member 50 is disposed between the reinforcing plates 14 on the outside of the first vertical plate 13 to be partially inserted into the key groove 61, and the fixing member 41 to the first vertical plate 13. ) Is mounted.

The key groove 61 is formed along the circumferential surface of the shaft 60, and the curved key member 40 is coupled to the curved surface along the circumference of the shaft 60. Therefore, the contact area between the key groove 61 of the shaft 60 and the key member 40 is increased, so that the shaft 60 can be more stably supported.

For example, the shaft 60 does not rotate unless the key groove 61 is formed in a portion not in contact with the key member 50. In this case, relative rotation occurs between the shaft 60 and the second shaft hole 21 of the upper bracket 20.

In addition, when the key groove 61 is formed in the entire circumferential surface of the shaft 60, the shaft 60 may rotate. In this case, relative rotation occurs between the shaft 60 and the first shaft hole 11 of the lower bracket 10, and relative rotation occurs between the shaft 60 and the second shaft hole 21 of the upper bracket 20. . Grease supplied to the second hole 34 may be further supplied to the first shaft hole 11 via the second shaft hole 21 and the shaft 60.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And it goes without saying that the invention belongs to the scope of the invention.

10: lower bracket 11, 21: first and second shaft holes
12: lower plate 13: first vertical plate
14: reinforcing plate 15, 25: mounting plate
16 bolt 17 spacer
18: stud bolt 20: upper bracket
23: upper plate 24: second vertical plate
30, 60: shaft 31, 61: keyway
32: head part 33, 34: 1st, 2nd hole
35: stopper 40, 50: key member
41: fixing member 100, 200, 300: wood bridge chair
151, 252: mounting holes 161, 181: nuts
231 through hole 251 projection
B: Foundation D: Spacing
G: Girder G1: Reinforcement
T1, T2: first and second thickness T3, T4: third and fourth thickness

Claims (11)

A lower bracket fixed to the base and having a first shaft hole and including a pair of first vertical plates;
An upper bracket provided at both ends of the girder forming an arch structure and having a second shaft hole connected to the first shaft hole, the upper bracket including a second vertical plate corresponding to the first vertical plate of the lower bracket;
A spacer provided between the first vertical plate and the second vertical plate;
A shaft inserted into the first shaft hole and the second shaft hole and coupling the lower bracket and the upper bracket; And
A key member coupled to a key groove formed at one side of the shaft
Including,
The first vertical plate is
Forming a region around the first shaft hole thicker than an area located remotely from the first shaft hole,
The second vertical plate is
An area around the second shaft hole is formed thicker than an area located remotely from the second shaft hole,
The area around the second shaft hole is
It is formed thicker than the area around the first shaft hole,
The axis is
A first hole formed in the axial direction,
A second hole penetrating in the radial direction from the first hole, and
A stopper coupled to the first hole to supply grease filled in the first hole to the second shaft hole, the spacer, the region around the first shaft hole, and the region around the second shaft hole through the second hole.
Including;
The second hole,
Corresponds to an area around the second shaft hole in the second vertical plate,
The spacer
Disposed between an area around the first shaft hole and an area around the second shaft hole
Woodworking device.
The method of claim 1,
The first vertical plate,
Are formed perpendicular to the lower plate to form a gap with each other,
The lower bracket,
A lower plate installed on the foundation, and
Reinforcing plate for connecting the first vertical plate and the lower plate to each of both sides of the first shaft hole on each of the opposite side of the gap
The teaching aids device comprising a further.
The method of claim 2,
The upper bracket,
Upper plate installed on the girder
Further comprising:
The second vertical plate,
Is formed in a vertical state on the top plate and the bridge device for wood bridge insertion.
The method of claim 3,
The key member is
Formed into plates,
Disposed between the reinforcement plates at an outer side of the first vertical plate and partially inserted into the key grooves,
It is mounted to the first vertical plate as a fixing member,
The key member and the key groove,
Coupled in a plane parallel to the bottom plate
Woodworking device.
The method of claim 3,
The key member is
Is formed in a curved shape,
Disposed between the reinforcement plates at an outer side of the first vertical plate and partially inserted into the key grooves,
It is mounted to the first vertical plate as a fixing member,
The key member and the key groove,
Coupled to the surface along the circumference of the axis
Woodworking device.
delete The method of claim 1,
The lower bracket and the upper bracket is formed of spherical graphite cast iron,
The shaft is formed of a rolled steel
Woodworking device.
The method of claim 7, wherein
And said key member is formed of a rolled steel material.
The method of claim 1,
The above-
The wood bridge chair device further comprises a reinforcing portion disposed in the vertical direction in the portion connected to the upper bracket.
The method of claim 1,
The above-
Further comprising a mounting plate provided on the lower portion so as to correspond to the upper bracket
Woodworking device.
The method of claim 10,
The mounting plate,
Further forming a protrusion for supporting the lower surface of the girder and supporting the side
Woodworking device.

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