KR101584306B1 - Precast culvert - Google Patents

Abstract

The present invention relates to a prefabricated culvert, in which an elastic pad is attached to an outer circumferential surface of an earthquake-proof fin by fitting an earthquake-proof fin and a earthquake-proof fin coupling, And a metal net embedded in the inside of the cage unit is further provided on the outside of the earthquake-proof pin coupling so as to minimize damage to the periphery of the earthquake-proof pin and the earthquake-proof pin.
According to an aspect of the present invention, there is provided a cowling unit comprising: a hollow box having an inner hollow; a plurality of tensile material mounting holes formed in a longitudinal direction thereof; and a fixing groove communicating with the tensile material mounting holes formed on an outer surface thereof; An earthquake-resistant pin installed on a rear side surface of the cowling unit and having an elastic pad attached to an outer circumferential surface of a portion exposed to the outside of the cowling unit; Wherein the pin insertion hole is formed to be larger than or equal to the diameter of the earthquake-resistant fin including the elastic pad, wherein the pin insertion hole is formed in the front side of the cowling unit so that the earthquake- phrase; And a tensile material installed through the tensile material installation holes of the culvert units to pull adjacent culverts and fix the culvert units by a fixture in the fixing grooves.

Description

Precast culvert

The present invention relates to a prefabricated culvert, in which an elastic pad is attached to an outer circumferential surface of an earthquake-proof fin by fitting an adjacent culvert through an earthquake-proof pin and an earthquake-proof pin, Thereby preventing breakage of the culvert joint portion.

Generally, a culvert is used in various forms such as a sewer pipe, a drain pipe, an agricultural water pipe and a water intake pipe in the form of a hollow having an internal hollow. The culvert is mass produced at a certain length in the factory in order to shorten the air and reduce construction costs They are moved to the site, connected to each other, and buried.

The watertightness should be ensured so that the water or sewage leaks to the outside through the connecting part after the culvert is installed in the culvert, or the groundwater or the soil outside the culvert is prevented from entering the inside of the culvert.

If the watertightness of the culvert connection part is not perfect and the water leaks through the connection part, the loss of the water is large. Conversely, if sewage leaks, the soil and groundwater are contaminated. And consequently the contamination of the water.

In addition, the culvert should be prevented from vertical movement (uneven settlement, etc.) of the culvert due to subsidence after the construction.

In order to secure the watertightness of the culvert and to prevent the vertical movement, the adjacent culverts are tensioned by a plurality of tension members and fastened with shear connection members between the culverts so as to improve the fastening force.

However, conventionally, in the process of fixing the tensile material, the fixing grooves of the tensile material are formed to be opened to the inside of the culvert, so that leakage occurs through the fixing grooves or corrosion occurs in the fixing port and the tensile material.

Also, even if the neighboring culvert is connected by using the shear connection material, the shear joint is completely fixed so that the seismic performance of the culvert is low and the shear joint is broken even in a slight external impact, .

Patent Application Publication No. 10-2009-0114525 Published Patent Application No. 10-2012-0134677

In order to solve the above problems, it is an object of the present invention to provide an anti-vibration member which is capable of absorbing an impact through an elastic pad while attaching an elastic pad to an outer peripheral surface of an anti- And a metallic net embedded in the inside of the cage unit is further provided on the outside of the earthquake-proof pin and the earthquake-proof pin coupling so as to minimize damage to the peripheral portion of the earthquake-proof pin and the earthquake-proof pin.

According to an aspect of the present invention, there is provided a method of manufacturing a tension member, the method comprising: forming a plurality of tension member mounting holes in a longitudinal direction; A fixing groove communicating with the fixing groove; An earthquake-resistant pin installed on a rear side surface of the cowling unit and having an elastic pad attached to an outer circumferential surface of a portion exposed to the outside of the cowling unit; Wherein the pin insertion hole is formed to be larger than or equal to the diameter of the earthquake-resistant fin including the elastic pad, wherein the pin insertion hole is formed in the front side of the cowling unit so that the earthquake- phrase; And a tensile material installed through the tensile material installation holes of the culvert units to pull adjacent culverts and fix the culvert units by the fixing holes in the fixing grooves.

And further includes a metal mesh which is fitted to the outer circumferential surface of the earthquake-proof fin and the earthquake-proof pin and which is installed to be embedded in the inside of the rocker unit to prevent the earthquake- .

The earthquake-resistant fin includes a buried portion buried in the inside of the cowling unit and having a plurality of grooves formed on an outer circumferential surface thereof; A projection integrally formed in the buried portion and protruding outside the cage unit to be inserted into a pin insertion hole of the earthquake-proof fin coupling member; And an elastic pad attached to an outer circumferential surface of the protrusion to absorb an impact when the culvert is in motion.

As described above, according to the present invention, by fitting the resilient pin on the earthquake-proof fin and fitting the resilient pin on the earthquake-proof fin, it is possible to absorb the impact by the shear force due to the rising- .

Further, by providing a metal net inside the cage unit by being connected to the earthquake-proof fin and the earthquake-proof fin coupling, there is an effect of preventing the peripheral portion of the earthquake-proof fin and the earthquake-

In addition, mortar is injected into the tensile material mounting hole to protect the tensile material, thereby preventing deterioration of the bonding force between the cage units due to corrosion of the tensile material.

Further, it is a very useful invention that has the effect of preventing leakage of water through the fixing grooves by forming the fixing grooves on the outer surface of the cage unit.

1 is a perspective view showing one side of a cowling unit according to the present invention,
2 is a perspective view showing the other side of the cowling unit according to the present invention,
3 is a front view showing the cowling unit according to the present invention,
4 is a side view showing a coupling process of the cowling unit according to the present invention,
5 is a perspective view showing a coupling structure of an anti-earthquake pin and a anti-earthquake pin coupling according to the present invention,
Fig. 6 is an exemplary view showing a coupling structure according to the first embodiment of the anti-earthquake-proof and anti-earthquake-pin-joint in the portion A of Fig. 4 in the present invention,
Fig. 7 is an exemplary view showing a coupling structure according to a second embodiment of an anti-earthquake-proof and anti-earthquake-pin-joint in A of Fig. 4,
Fig. 8 is a cross-sectional view showing the coupling structure of the cage unit shown in Fig. 4B in the present invention,
Fig. 9 is a sectional view showing the coupling structure of the cage unit shown in Fig. 4C in the present invention,
Fig. 10 is an exemplary view showing an installation structure of the tensile material shown in Fig. 4D in the present invention. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a perspective view showing one side of a cowling unit according to the present invention, FIG. 2 is a perspective view showing another side of a cowling unit according to the present invention, FIG. Fig. 5 is a perspective view showing a coupling structure of a vibration-proof fin-fitting according to the present invention,

As shown in the drawings, the present invention provides a cowling unit 100 including a box-shaped cowling unit 100, which is longitudinally coupled and hollow inside, a cowling unit 100 installed to be partially embedded in a rear side of the cowling unit, And an elastic pad is attached to the outer circumferential surface of the cage unit 100 so that the vibration proof pin 200 is embedded in the front side of the cage unit 100 and the vibration proof pin 200 is inserted when the cage unit 100 is connected in the longitudinal direction. And a pin insertion hole 211 is formed at one end of the pin 210. The pin insertion hole is configured to have a diameter equal to or greater than a diameter of the vibration-resisting pin 200 including the elastic pad, And a tension member 300 which is installed in the longitudinal direction of the fixing unit 100 and fixed through the fixing unit 310 to connect the cage units 100.

The culvert unit 100 is formed in a rectangular box shape and a plurality of tensile material installation holes 110 are formed in the longitudinal direction so that the tensile material 300 can be installed.

The tensile material installation hole 110 is typically formed at four corners of the cage unit 100.

The tensile material installation hole 110 is formed by a sheath pipe 120 buried in the longitudinal direction of the cage unit 100.

Mortar injection grooves 130 are formed on the front and rear side surfaces of the cowling unit 100 so that the shrink-free mortar 140 can be injected when the cage unit 100 is connected.

The mortar injection grooves 130 are integrally formed on the front side and rear side of the cage unit 100 and have an injection port 131 opened to the upper surface of the cage unit 100.

8 and 9, the mortar injection holes 130 are opposed to each other when the mortar injection holes 130 are coupled with the neighboring cage unit 100, (130) is formed.

When the external force is applied to the cage unit 100, the circular mortar injection grooves 130 are formed to disperse the forces, thereby preventing damage to the shrinkage mortar 140 injected into the mortar injection holes 130, So that the connection of the cage unit 100 is performed.

Further, an index material 150 is further attached to both sides of the mortar injection groove 130 so as to be waterproofed to the joint surface of the cage unit 100.

The index material 150 is previously attached to the cowling unit 100 so that the watertightness efficiency between the cowling units 100 can be improved by using a water expansition index material that expands when containing water.

The mortar injection hole 130 is formed to be connected to the tensile material installation hole 110 so that the non-shrinkage mortar 140 injected through the mortar injection hole 130 can be injected into the tensile material installation hole 110 .

Shrinkable mortar 140 is injected into the mortar injection hole 130 through the injection port after connection of the cage unit 100 through the tensile force of the tensile material 300 so that the shrinkage mortar 140 is filled in the mortar injection hole 130, Shrinkable mortar 140 is filled into the tensile material installation hole 110 to be filled with water so that the tensile material 300 installed in the tensile material installation hole 110 is prevented from being corroded.

Also, the water tightness and the corrosion of the tensile material 300 between the cage units 100 can be prevented only by injecting the non-shrinkable mortar 140 once through the injection port 131, so that the joint construction can be carried out easily and quickly .

A fixing groove 160 is formed on an outer side surface of the cowling unit 100 to communicate with the tensile material mounting hole 110 and to fix the fixing hole 310.

Such a fixing groove 160 is formed to be opened to the outside of the cage unit 100 to thereby remove the phenomenon of leakage of water through the fixing groove 160 when the cage is formed to open into the hollow of the cage unit 100, .

The cage unit 100 includes a locking step 170 formed to protrude from a lower portion of a front side surface of the cage unit 100 and a hook formed to be upwardly cut out from a lower side of a rear side of the cage unit 100 to correspond to the locking step 170. [ And a step receiving portion 171.

The locking step 170 and the locking step receiving part 171 are formed in the cage unit 100 so that the one side cage unit 100 and the other side cage unit 100 are engaged with each other when the neighboring cage units 100 are joined. 170 and the engaging step receiving portion 171, the bonding force between the cage units 100 is improved.

5, 6 and 7, the earthquake-proof fin 200 includes a buried portion 201 buried in the interior of the cowling unit 100, a cowling unit 200 integrally formed with the buried portion 201, A protrusion 202 protruding outside of the protruding portion 202 and inserted into the pin insertion hole 211 of the protruding pin coupling hole 210 and a resilient member 202 attached to the outer circumferential surface of the protruding portion 202, And a pad 203.

The diameter of the buried portion 201 is formed to be larger than the diameter of the protrusion 202 so that the buried portion 201 can be stably buried in the cage unit 100 and the frictional force is improved, The outer surface may be roughened or the groove 201a may be further formed so as to be buried.

The elastic pad 203 is preferably made of a synthetic resin pad such as rubber or urethane. When the protrusion 202 is inserted into the pin insertion hole 211, The pad 203 is retracted to absorb the impact, thereby preventing the periphery of the earthquake-proof fin 200 and the earthquake-pin interlock 210 from being damaged.

That is, when the protruding portion 202 of the earthquake-proof fin 200 flows inside the pin insertion hole 211 of the earthquake-proof fin 210, the cowling unit is prevented from being damaged by the impact.

When the earthquake-proof fin 200 is coupled to the earthquake-proof fin 210, the elastic pads 203 are spaced apart from the inner surface of the pin insertion hole 211 and are spaced apart from each other, When the shearing force is generated due to the elasticity of the elastic pad 203, the distance L between the protrusion 202 and the pin insertion hole 211 and the contraction amount of the elastic pad 203 acts on the neighboring cage unit 100, It is possible to maintain the airtightness of the joint surface while preventing the phenomenon that the joint surface is damaged.

The pin insertion hole 211 is formed to have the same diameter as the inner diameter of the pin insertion hole 211. When a shearing force is generated due to the rising or sinking of the paper surface, It is possible to maintain the airtightness of the joint surface while preventing the phenomenon of breakage or dropout.

In the meantime, according to the present invention, the earthquake-proof fin 200 and the earthquake-proof fin coupling member 210 are fitted to the outer circumferential surface of the earthquake-proof fin- And the metal mesh to prevent the peripheral portion of the earthquake-proof pin coupling member 210 from being damaged.

The metal net 230 is installed to be embedded in the cage unit 100 and is connected to the reinforcing bars disposed inside the cage unit 100 so that the earthquake pin 200 and the earthquake- You can plug in.

The metal net 230 may be fixed or welded to the earthquake-proof fin 200 and the earthquake-pin 210 through a wire or the like.

On the other hand, the tensile material 300 may be a normal steel wire or a stranded wire, and the fixing hole 310 may be a cone type fixing hole.

The connection of the assembled culvert according to the present invention will be described. The culvert units 100 are installed on the bottom surface of the culvert.

The cage unit 100 is engaged with the earthquake-resistant pin 200 of the one-side cage unit 100 by inserting it into the earthquake-proof pin-fitting unit 210 of the other side cage unit 100.

At this time, the vibration-proofing pin 200 is inserted such that the elastic pad 203 attached to the protrusion 202 is spaced apart from the inner surface of the pin insertion hole 211 of the vibration-damping pin coupling hole 210 to form a constant separation distance L, And is inserted into the pin insertion hole 211 closely.

The tension member 300 is inserted through the tension member installation hole 110 of the cage unit 100 and one end of the tension member 300 is fixed to the fixing groove 160 of the one cage unit 100 through the fixing hole 310 And the other side end is pulled by a tension device (not shown), and then fixed and fixed to the fixing groove 160 at the other side through the fixing hole 310. [

The tensile material 300 applies stress to the concrete in advance so as to cancel the tensile stress generated in the culvert unit 100 by a predetermined limit.

Thereafter, the non-shrinkable mortar 140 is injected through the injection port 131 formed on the upper part of the cowling unit 100 to fill the mortar injection hole 130.

At this time, the mortar injection hole 130 is formed to be connected to the tensile material installation hole 110 so that the non-shrinkage mortar 140 injected into the mortar injection hole 130 is injected into the tensile material installation hole 110, .

The non-shrinkage mortar 140 closes the tensile material installation hole 110 to block water or other foreign matter from entering the tensile material installation hole 110, thereby preventing the tensile material 300 from being corroded, The tensile force of the cage unit 100 can be prevented from being lowered.

When the elastic pad 203 is attached to the protruding portion 202 of the earthquake-proof fin 200 according to the present invention, when the shear force due to the rising or sinking of the ground is generated, So that the joint portions of the cage units 100 are prevented from being broken.

The earthquake-proof pin 200 and the earthquake-proof pin coupling hole 210 are further provided by being installed inside the cage unit 100 and further including the metal net 230 so as to be fitted into the earthquake-proof pin 200 and the earthquake- So that the cowling unit can be stably bonded.

In addition, mortar is injected into the tensile material mounting hole 110 to protect the tensile material 300, thereby preventing the deterioration of the bonding force between the cage units 100 due to the corrosion of the tensile material 300.

Further, by forming the fixing grooves on the outer surface of the cage unit 100, it is possible to prevent leakage of water through the fixing grooves.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

(100): culvert unit (110): tensile material installation hole
(120): Sheath tube (130): Mortar injection groove
(131): Inlet (140): Non-shrinkable mortar
(150): Index material (160): Fixing groove
(170): a locking step (171): a locking step
(200): earthquake-proof fin (201): buried portion
(201a): groove (202): projection
(203): elastic pad (210): earthquake-resistant pin coupling hole
(211): pin insertion hole (212): through hole
(220): anchor pin (230): metal mesh
(300): tensile material (310): anchorage

Claims (3)

A plurality of tensile material mounting holes are formed in the longitudinal direction and a fixing groove communicating with the tensile material mounting holes is formed on the outer surface of the box unit;
A protruding portion integrally formed at the buried portion and protruding outwardly of the culvert unit; and a protruding portion attached to the outer circumferential surface of the protruding portion so as to absorb the impact when the culvert is in motion An earthquake-resistant pin made of an elastic pad;
A pin insertion hole is formed in the front side of the cage unit so that the anti-earthquake pin can be inserted into a side of the cage, and the pin insertion hole is formed to have the same diameter as the protrusion diameter of the anti- ;
A tensile material installed through tensile material installation holes of the culvert units to pull adjacent culverts and to fix the culvert units by fixing holes in a fixing groove;
And a metal net that is fitted to the outer circumferential surface of the earthquake-proof fin and the earthquake-proof fin-fitting and is embedded in the inside of the quarry unit to prevent damage to the periphery of the earthquake- Being
The earthquake-resistant pin is embedded in the inside of the cowling unit and has a plurality of recesses formed on the outer circumferential surface thereof. The earthquake-resistant pin is integrally formed at the buried portion and protruded to the outside of the cowling unit and inserted into the pin insertion hole of the earthquake- And an elastic pad attached to an outer circumferential surface of the protruding portion to absorb an impact when the culvert is in motion.








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