KR20090037053A - A pin reclamation type culvert - Google Patents

Abstract

An induction pin buried culvert is provided to strongly maintain the fixed state by increasing the anchoring force between an induction pin and a culvert although shear force is generated. An induction pin buried culvert is composed of a culvert unit(10) having at least one mortar filling grooves(11) in both sections, a plurality of induction pins(20) protruded from the end surface of the culvert unit, and integrally buried in the culvert unit, and an induction pin combining hole(40) in which the induction pin is inserted, and forming the gap in the outer circumference of the induction pin. A plurality of induction pins are buried in one end of the culvert unit at the constant depth. The protruded other end of the induction pin is inserted into the induction pin combining hole of the other culvert unit. The induction pin is integrally fixed to culvert unit by filling mortar in the gap of the induction pin combining hole.

Description

A pin reclamation type culvert}

The present invention relates to a culvert used for forming a waterway such as rainwater / sewage and agricultural industrial water, or to bury passages such as sidewalks and roadways, and telecommunications and hot / cooled pipes. When installing a plurality of culverts connected to each other, the induction pin is embedded in one culvert so that the culvert can be connected firmly so as not to be separated by the load and shear force continuously or irregularly applied, and the mortar after the induction pin is inserted in the other side It is related to the increase in the fixing force by the guide pin and the culvert can be more firmly integrated.

In general, culverts that are constructed to secure waterways for agricultural and industrial waters, or which are constructed to bury passageways such as sidewalks and roadways, or telecommunications and hot / cold pipes, are manufactured in large quantities by producing large-scale cullet units having a certain size. It is assembled and constructed.

Such culverts are to be hermetically bonded to each other by nature, and this is achieved by injecting / curing mortar for mutual bonding.

However, if the culvert is fixed using only mortar, cracks are generated at the joints of the culvert by the action of elevation or settlement of the ground, so that it is difficult to continuously maintain the hermetic bond.

In order to solve this problem, a rubber gasket is placed at the culvert unit contact end, or the guide pin is coupled between the culverts to prevent the culverts from flowing easily even if shear force is generated.

Such a guide pin coupling culvert forms a plurality of coupling holes 120 having a predetermined size at both ends of contact ends of the culvert 100 as shown in FIG. 1, and guide pins having a predetermined length interpolated into the coupling holes 120. It is provided with (110), the induction pin 110 is inserted into the coupling hole 120 for the coupling of the culvert 100, and the other end of the guiding pin 110 to the other end of the coupling hole of the culvert 100 By inserting 120, the guide pin 110 is laid between the mortar injection holes as shown in FIG.

The culvert adhered by inserting a plurality of induction pins 110 as described above allows the induction pin 110 to be firmly fixed by filling the mortar with the mortar injection hole.

However, the conventional induction pin separation culvert as described above is simply inserted without close coupling between the induction pin 110 and the coupling hole 120 by shearing of the induction pin 110 when the shear force is generated due to the elevation or settlement of the ground. It causes the breakage, partial dropping, cracking, etc. of the coupling hole 120, and as a result, there is a problem that can not prevent the flow of the culvert can not maintain the airtight of the culvert.

On the other hand, as a means for more tightly fixing the combined culvert to form a haunch (Hunch) of a predetermined size in the corner portion side of the hollow part of the culvert unit, and forms a steel wire mounting hole through the haunch surface, the steel wire mounting It is implemented to include a steel wire 200 of a predetermined length to be inserted into the hole to connect each culvert, and a steel wire mounting hole 210 for pulling the steel wire strongly through a hydraulic device.

Wherein the steel wire mounting holes 210 is inserted into both ends of the generally used steel wire 200, is fixed while being pulled by the hydraulic device to keep the steel wire 200 taut, the culvert unit for use Including a steel wire mounting groove 220 of a predetermined size communicating with the steel wire mounting hole on one side of the hollow portion.

However, the wire mounting hole 210 has a problem that the fixing force is weakened or released by a long-term pressure to prevent the steel wire to be fixed for a long time, so that the wire mounting groove 220 is embedded with mortar to fix and wire the steel wire 200. The loosening of the sphere 210 is prevented.

At this time, the steel wire mounting groove 220 located at the lower side of the culvert unit is easy to bury, but the steel wire mounting groove located at the upper side is opened in the downward direction, so that the steel wire mounting groove 220 flows down when the mortar is injected, and thus, the steel wire mounting groove 220 is not firmly formed. Sphere 210 is loosened, there was a problem that the steel wire 200 is loose.

Therefore, the present invention has been invented in view of the above-described conventional problems, and the first object of the present invention is to manufacture one end of the induction pin integrally with the culvert in order to increase the fixing force between the culverts, and the other end is the induction pin of the other culvert The present invention provides an induction pin embedded culvert having a structure in which a mortar is filled and cured after being inserted into a coupling hole so that the induction pin is integrally fixed with both culverts.

It is a second object of the present invention to provide a guide pin embedded culvert that enables to confirm the degree of mortar filled when the mortar is filled after the induction pin is inserted into the coupling hole.

The third object of the present invention is to bury the steel wire mounting groove for inserting the steel wire mounting hole for fixing the steel wire, the culvert to be injected from the outside of the culvert to facilitate the buried steel wire mounting groove of the haunch located on the upper side To provide.

The above objects and other objects, advantages and features of the present invention will become more apparent from the detailed description for carrying out the invention with reference to the accompanying drawings showing the preferred embodiments.

The device of the present invention according to the above object is provided with a culvert unit is formed at least one or more mortar injection grooves of a predetermined depth on both end surfaces, protrudes a certain length to one end surface of the culvert unit and embedded in the culvert unit integrally It is achieved by having a plurality of induction pins to be produced, formed on the other end of the culvert unit, the induction pins are interpolated, and comprising an induction pin coupling hole formed a predetermined gap to the outer peripheral surface of the induction pins.

In this case, the present invention may be further provided with a check hole of a predetermined size formed through the inner end of the guide pin coupling hole and the side of the culvert unit.

In addition, it may be carried out by further provided with a mortar injection hole of a predetermined size which is located on the upper haunting surface of the upper and lower haunting surface through which the steel wire passes and communicates with the upper surface of the steel wire mounting groove and the culvert unit.

On the other hand, in the implementation of the induction pin coupling hole, the inner diameter may be gradually reduced from the outer end to the inner end. In addition, the attachment plate of a certain size covering the steel wire mounting groove of the upper haunch surface may be further provided, the attachment plate is made of an acrylic plate or a thin steel sheet to be fixed to the steel wire mounting groove outer surface through an adhesive It can be carried out by.

Through the use of the guide pin buried culvert of the present invention obtained through the above object and the means for achieving the object, one end of the guide pin is made integrally with the culvert, and inserted into the guide pin coupling hole of the other culvert of the other end As the mortar is filled and cured, the induction pins are integrally fixed to both culverts, and as a result, the fixing force between the guiding pins and the culverts is increased, so that the culverts can be firmly supported and fixed even if shear force occurs in the upper and lower sides.

In addition, when the check hole is filled with mortar after inserting the induction pin into the induction pin coupling hole, it is possible to check the degree of the mortar that is filled, so that it can be installed correctly. It can be buried so that there is an advantage of preventing the loosening of the steel wire.

Hereinafter will be described in more detail with reference to the accompanying drawings showing an embodiment of the present invention.

The present invention has a culvert unit (10) having at least one or more mortar injection grooves (11) of a predetermined depth formed on both end surfaces as shown in Figure 3, the culvert unit (10) protrudes a predetermined length to one end surface culvert A plurality of induction pins 20 are embedded in the culvert unit 10 during the pouring / curing process of the unit 10 and are integrally formed. The induction pins 20 are formed at the other end of the culvert unit 10. Interpolated, the guide pin 20 is formed to penetrate through the guide pin coupling hole 30, a predetermined gap (G) is formed on the outer circumferential surface, the inner end of the guide pin coupling hole 30 and the side of the culvert unit (10) It is provided with a check hole 40 of a predetermined size.

In implementing the culvert unit 10, the injection groove 11 is made of a groove having a predetermined depth on both end surfaces of the culvert unit 10, for those skilled in the art for easy implementation round, square, Deformation can be carried out to a groove having a cross section such as a polygon.

In addition, the induction pin 20 has a length L1 embedded in the culvert unit 10 is formed to be relatively longer than the length (L2) protruding to the outside to be produced integrally with the culvert unit 10 to cure the induction pin It is desirable to have the structure 20 not be easily released by external pressure.

In this case, the induction pin 20 is further formed by forming a plurality of protrusions 21 on the outer peripheral surface of the induction pin 20, as shown in Figure 4 in order to increase the fixing force when the casting / curing integrally with the culvert unit (10) Can be made.

On the other hand, as shown in Figure 5 and Figure 7 is located in the hollow portion 12 of the culvert unit 10 to the upper haunting surface (H1) of the upper and lower haunting surfaces (H1, H2) through which the steel wire 13 passes. It can be carried out by further provided with a mortar injection hole 50 of a predetermined size to penetrate the wire mounting groove 14 and the culvert unit (10). At this time, the steel wire 13 penetrated into the upper and lower haunch surface (H1, H2) is a PS steel wire (pre-stressed steel), which is a concrete structure, that is, the culvert unit 10 to the tensile stress caused by the external force to a predetermined limit This is to pre-stress the concrete in advance so that it can be offset.

In addition, the upper haunch surface (H1) may be carried out by having a mounting plate 15 of a predetermined size covering the steel wire mounting groove 14, which is modified to various materials for those skilled in the art for easy implementation. It is more preferable, but it is more preferred that the embodiment of the present invention is made of an acrylic plate or a thin steel sheet and fixed to the outer surface of the steel wire mounting groove 14 through an adhesive.

The attachment plate 15 is used to cover the steel wire mounting groove 14 of the upper haunch surface H1, and the mortar is injected into the steel wire mounting groove 14 by using a mortar injection hole 50 penetrating to the upper surface of the culvert unit 10. By filling / filling (M), it is easy to bury the steel wire mounting groove 14 located on the upper side.

On the other hand, in the present invention, the guide pin coupling hole 30 may be implemented to form an inclined angle (A) of the inner diameter gradually reduced from the outer end 31 to the inner end 32, which is shown in FIG. The mortar (M), which is filled with the mortar injection groove 11, flows along the mortar injection groove 11, and then flows into the outer end 31 having a relatively wide surface, thereby causing a gap G of the guide pin coupling hole 30. ) And, as a result, the mortar (M) introduced into the guide pin coupling hole 30 is cured to increase the fixing force of the guide pin 20.

Such a guide pin embedded culvert of the present invention will be described in more detail through the following examples.

<Example>

The present invention is provided with a plurality of culvert units 10 of a predetermined length as shown in Figure 3, the airtight / sewage and agricultural industry water or the passage and the roadway and the like through the inner hollow portion 12 by connecting them in airtight and Telecommunications and hot and cold pipelines are buried.

At this time, in order to maintain the airtightness of the bonding surface of each culvert unit 10 by injecting / curing the mortar (M) in the mortar injection groove 11 around the joint end to ensure that both culvert units 10 are in close contact.

The culvert unit 10 has a plurality of guide pins 20 and steel wires 13 to prevent cracking between the junction ends of the culvert unit 10 and the mortar even if its height is changed due to the elevation or settlement of the ground. Fix by inserting the back.

In the present invention, the induction pin 20 is inserted into the culvert unit 10 during curing to increase the binding force between the culvert unit 10 and the induction pin 20. As another embodiment of the induction pin 20, as shown in Figure 4 by inserting a plurality of protrusions 21 of a predetermined size on one outer peripheral surface of the induction pin 20 is inserted into the culvert unit 10 to cure the culvert unit ( 10) may be implemented by interpolating curing so that the induction pin 20 is firmly fixed so as not to be separated from the culvert unit (10).

On the other hand, the guide pin 20 is relatively longer than the length (L2) protruding the length (L1) interpolated in the culvert unit 10, as shown in Figure 5 so as not to be easily separated without forming a separate projection (21) Can be implemented.

In addition, the other side junction end of the culvert unit 10 is formed with a guide pin coupling hole 30 having a predetermined depth so that the protruding side of the guide pin 20 produced integrally.

At this time, the induction pin coupling hole 30 is made to achieve a predetermined inclination angle (A) by gradually increasing the outer diameter from the inner end 32 to the outer end 31, which is the induction pin coupling hole 30 This is to allow a predetermined gap G to be formed on the outer circumferential surface even when the other end of the 20 is interpolated.

When the gap G of the guide pin coupling hole 30 is filled with the mortar M in the mortar injection groove 11, the mortar M is guide pin coupling hole 30 through the gap G. As a result, the one end of the induction pin 20 is integrated with the culvert unit 10, and the other end is integrally fixed to the other culvert unit 10 through mortar (M) curing.

At this time, in order to completely fill the mortar (M) into the gap (G) of the induction pin coupling hole 30, the check hole 40 in communication with the inner end 32 of the induction pin coupling hole 30 culvert unit (10) Form on the side. This mortar (M) is filled to the end of the guide pin coupling hole 30, as shown in Figure 6, the mortar (M) is recognized in the check hole 40 provides the accuracy of the construction.

Meanwhile, as shown in FIG. 7, prestressing is performed between the culvert units 10 connected in series by interpolating the steel wires 13 to the upper and lower haunting surfaces H1 and H2, and for this purpose, the upper and lower haunting surfaces H1 and H2 (13) The steel wire mounting groove 14 for fixing is formed, and the steel wire mounting holes J are inserted into the steel wire mounting groove 14 to fix the steel wire 13 at both ends.

After fixing the steel wire 13 through the steel wire mounting holes (J), and filling the mortar (M) in the steel wire mounting groove 14 to fix the wire wire mounting holes (J).

At this time, when embedding the steel wire mounting groove 14 located on the upper haunch surface (H1), using the attachment plate 15 to block the open side of the steel wire mounting groove 14, the mortar injection from the upper surface of the culvert unit (10) Mortar (M) is injected into the steel wire mounting groove 14 through the ball 50, and the steel wire mounting groove 14 of the upper haunch surface H1 is embedded.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be readily apparent to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. It is obvious that all modifications belong to the appended claims.

1 is a perspective view showing an example of a conventional guide pin detachable culvert.

Figure 2 is a partial cross-sectional view showing an example of a conventional guide pin detachable culvert.

Figure 3 is a perspective view showing an example of the guide pin buried culvert of the present invention.

Figure 4 is a side view showing another embodiment of the induction pin in the guide pin embedded culvert of the present invention.

Figure 5 is a plan view showing an example of the guide pin coupling hole in the guide pin embedded culvert of the present invention.

Figure 6 is a side cross-sectional view showing an example of coupling the induction pin buried culvert of the present invention.

Figure 7 is a side cross-sectional view showing an example of the mortar injection hole for the upper haunch of the guide pin buried culvert of the present invention.

[Explanation of symbols on the main parts of the drawings]

10: Culvert Unit 11: Mortar Injection

12: hollow part 13: steel wire

14: steel wire mounting groove 15: mounting plate

20: guide pin 21: protrusion

30: guide pin coupling hole 31: outer end

32: inner end 40: check hole

50: mortar injection hole A: inclination angle

G: gap H1, H2: upper and lower haunting surface

J: Steel Wire Mount M: Mortar

Claims (5)

In the prefabricated culvert having a predetermined length and a hollow portion penetrating therein, A culvert unit 10 in which at least one mortar injection groove 11 of a predetermined depth is formed on both end surfaces; A plurality of induction pins 20 protruding to one end surface of the culvert unit 10 and embedded integrally in the culvert unit 10; It is formed on the other end surface of the culvert unit 10, the guide pin 20 is interpolated, comprising a guide pin coupling hole 30 is formed a predetermined gap (G) to the outer peripheral surface of the guide pin 20, The plurality of induction pins 20 are embedded in one end of the culvert unit 10 to a predetermined depth, and the other end protruding from the guiding pins 20 is interpolated into the induction pin coupling hole 30 of the other culvert units 10. When the mortar is injected into the mortar injection groove 11, the mortar is filled into the gap G of the guide pin coupling hole 30 so that the guide pin 20 is fixed to both side culvert units 10 integrally. Guide pin embedded culvert. The method of claim 1, Guidance pin embedded culvert, characterized in that it further comprises a check hole 40 of a predetermined size formed to penetrate through the inner end of the guide pin coupling hole 30 and the culvert unit (10). The method according to claim 1 or 2, Mortar injection hole of a predetermined size which is located in the upper haunting surface (H1) of the upper and lower haunting surfaces (H1, H2) through which the steel wire (13) penetrates to communicate the upper surface of the steel wire mounting groove (14) and the culvert unit (10). Guide pin embedded culvert, characterized in that further comprises a (50). The method according to claim 1 or 2, The guide pin coupling hole 30, the guide pin embedded culvert, characterized in that the inner diameter is gradually reduced from the outer end 31 to the inner end 32. The method according to claim 1 or 2, It is further provided with an attachment plate 15 having a predetermined size to cover the steel wire mounting groove 14 of the upper haunch surface (H1) and made of an acrylic plate or a thin steel sheet and bonded to the steel wire mounting groove 14 by an adhesive. Induction pin embedded culvert, characterized in that.

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