KR101038972B1 - Underground power transmission pipe spacer for apartment building - Google Patents

Abstract

PURPOSE: An apparatus for maintaining the gap between underground pipes for apartments is provided to prevent the escape of underground pipe spacers using a peanut shaped wedge and an eccentric shaft. CONSTITUTION: A wedge inserting groove(50) is formed in an underground pipe spacer(40). A peanut shaped wedge(60) is inserted into the wedge inserting groove. An eccentric shaft(70) is inserted into the vertical hole of the wedge. A locker(80) is inserted into the locker guiding hole of the wedge. A chamfered part is formed at the upper corner part of the location determining groove of the ground pipe spacer.

Description

Underground power transmission pipe spacer for apartment building}

The present invention relates to a underground pipe space keeping device for underground housing, which is buried in the ground for transmission and distribution in a multi-family housing complex. A spacing device.

In general, when constructing a plurality of underground pipes buried in the ground for transmission and distribution, etc., the underground pipes are installed while maintaining a constant interval in the up, down, left and right directions. The interval must be kept constant to prevent sagging or damage of underground pipes and to ensure the safety of household facilities located at the top of the underground pipes.

1 is a view showing the underground pipe space maintenance device for a multi-unit house according to the prior art 1, as shown therein the underground "U" shaped underground pipe inlet at the bottom of the spacer 10 of the wooden board (11) is cut at regular intervals, the sand is covered with a constant height in the lower surface of the excavation surface, and the underground pipe 12 is disposed on the sand, and the spacer 10 is used to uniformly space the underground pipe 12. After grabbing, the gap between the underground pipes 12 and the sides are filled with soil, the spacer 10 is removed, and then covered with soil to finish the underground pipe filling.

However, since the prior art 1 is used only for maintaining the gap before covering the spacer 10 and removes it in the middle, when the soil is covered in the state where the spacer 10 is removed, the ground pipe 12 is separated by the earth pressure. When the gap is difficult to maintain and is installed in a slope or groundwater leaching concerns, there is a problem that the sand located between and below the underground pipe 12 is easily leaked, the vertical pipe spacing in the vertical direction where the earth pressure is large There was a problem that was difficult to maintain.

2 is a view showing the underground pipe space maintenance device for a multi-family house according to the prior art 2, half of the upper and lower outer peripheral surface of the underground pipe 17 to the spacer blocks 15 and 16 divided vertically as shown therein. Semi-circular underground tube contact portions 15a and 16a are formed in close contact with each other, and dovetail protrusions 18a and dovetail grooves 18b are formed on the left and right sides of each spacer block 15 and 16, respectively. It was designed to be used continuously in the direction.

In addition, the hemispherical protrusions 19a and the hemispherical grooves 19b are formed on the divided surfaces of the spacer blocks 15 and 16 so as to prevent misalignment when the spacer blocks 15 and 16 are stacked upward. .

However, this prior art 2 should be coupled to the dovetail protrusion (18a) and the dovetail groove (18b) when coupled laterally, wherein the combination of the dovetail protrusion (18a) and the dovetail groove (18b) is a spacer block (15) (16) was inconvenient to be pushed in the opposite direction from each other in the state shifted back and forth, and furthermore, because all spacer blocks (15) and (16) must be assembled on-site, there was a problem of extending the construction period. .

In addition, the connection of the divided spacer blocks 15 and 16 depends not only on the hemispherical protrusion 19a and the hemispherical groove 19b, but also on the connected spacer blocks 15 and 16 by simply stacking the position by self-weight. Since it is only a degree to be maintained, there was a problem that is easily separated when some earth pressure acts in the front and rear direction on the slope.

Figure 3 is a view showing the underground pipe space maintenance device for a multi-unit house according to the prior art 3, as shown therein the "U" shaped underground tube seating portion 21 on the rectangular square spacer 20 It was formed to have a constant interval in the left and right direction, the anchor insertion hole 22 penetrating in the vertical direction was formed in the middle of the underground tube seating portion 21, the coupling groove in the upper and lower ends of the anchor insertion hole 22 (23) and the coupling boss 24 is formed, and the square spacer 20 is stacked up and down while placing the underground tube 25 in the underground tube seating portion 21 formed in the square spacer 20. After that, the anchors 26 were fixed in the anchor insertion holes 22.

However, in the conventional art 3, the underground pipe 25 is not firmly fixed because a space is formed in the upper portion of the underground pipe 25 located in the underground pipe seating portion 21 formed in the square spacer 20. There was a problem.

4 is a view showing the underground pipe space maintenance device for a multi-family house according to the prior art 4, and inserted into the upper side of the underground pipe 27, as shown therein, an underground “U” shaped underground pipe insertion The portion 28h was formed in an open form from the bottom of the underground pipe spacer 28 toward the upper side, and the positioning grooves 29a coupled to the upper and lower surfaces of the underground pipe spacer 28 stacked up and down. The positioning protrusion 29b was formed, and the fitting groove 29c and the fitting protrusion 29d were formed on the left side and the right side of the underground pipe spacer 28 which are closely attached to the left and right sides.

Such a prior art 4, when the underground pipe spacer 28 is inserted in parallel to the ground pipe spacers 28 and are stacked vertically while being in close contact with each other, the upper and lower sides and the left and right sides of the underground pipe spacer 28 The positioning groove 29a and the positioning protrusion 29b and the fitting groove 29c and the fitting protrusion 29d were formed to align the underground pipe spacer 28.

However, since the prior art 4 has not been provided to hold the underground pipe spacer 28 in the front and rear directions by earth pressure during the cover process, the underground pipe spacer 28 is shifted in the front and rear directions. There was a problem leaving.

Further, in the prior art 4, the positioning grooves 29a and the positioning protrusions 29b and the fitting grooves 29c and the fitting protrusions 29d are simply fitted to each other at the time of coupling, so that the underground pipe spacers 28 are opposite to each other. There was a problem that easily escaped when receiving power.

The present invention has been made to solve the above problems, an object of the present invention is to provide a underground tube space maintenance device for a multi-family housing can be achieved firmly.

In order to achieve the object of the present invention to form a wedge insertion groove having a narrow connection passage in the upper edge portion of the lateral contact surface of the underground pipe spacer, the wedge of the peanut-shaped wedge having a narrow waist and a thick head close to the left and right Insert the eccentric shaft, which has a hexagonal groove formed at the top, into the vertical holes formed on the left and right sides of the wedge, respectively, and inserts the rocker locking hole horizontally penetrated from the inner wall of the wedge insertion groove toward the positioning groove. And a locker is inserted into the rocker guide hole penetrating outward from the inner wall surface of the vertical hole formed in the wedge, and caught on both ends of the arcuate sector groove formed at the upper edge of the vertical hole, Positioning groove is formed on the upper edge of the eccentric shaft to determine the angle of rotation for positioning. The cavity houses underground pipe cavity-holding apparatus is provided with chamfered portions formed on the inner top edge part.

As described above, the present invention uses a peanut-shaped wedge and an eccentric shaft when combining neighboring underground pipe spacers to prevent the vertical pipe spacers from escaping up, down, left, and right and forward directions, thereby making the coupling effect secure. In particular, the chamfer formed at the upper edge of the positioning groove has the effect of preventing interference with the edge when working by tilting a tool such as a flat head screwdriver or a cramp used to retract the rocker. .

1 is a view showing a underground pipe space maintenance device for a multi-unit house according to the prior art 1
2 is a view showing the underground pipe space maintenance device for a multi-unit house according to the prior art 2
3 is a view showing a underground pipe space maintenance device for a multi-unit house according to the prior art 3
Figure 4 is a view showing the underground pipe space maintenance device for a multi-unit house according to the prior art
Figure 5 is an exploded perspective view showing the underground pipe space maintenance device for a multi-unit house according to the invention
Figure 6 is a partial cross-sectional exploded perspective view showing the structure of the wedge and the eccentric shaft according to the present invention
Figure 7 is a front sectional view showing a underground pipe space maintenance device for a multi-family house according to the present invention

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

As shown in FIGS. 5 to 7, an inverted “U” shaped underground pipe inserting portion 41 which is inserted into the upper side of the underground pipe 30 and is located above the bottom of the underground pipe spacer 40 is shown. It is formed in an open shape toward the, and has a conventional structure in which the positioning grooves 42 and the positioning projections 43 are mutually coupled to the upper and lower surfaces of the underground tube spacer 40 stacked up and down.

The wedge insertion groove 50 for inserting the peanut-shaped wedge 60 having a narrow waist 61 and a thick head 62 and 63 is attached to the side surface of the underground pipe spacer 40. ) It is formed on the upper edge part.

In addition, the wedge insertion groove 50 has a narrow connecting passage 51 opened toward the side contact surface 44, and when the underground pipe spacer 40 is in close contact with the left and right through the connecting passage 51 The wedge insertion groove 50 located in is integrated into one passage to form a peanut shape.

Then, the eccentric shaft 70 having the hexagonal grooves 71 formed on the upper end is inserted into the vertical holes 64 and 65 formed on the left and right sides of the wedges 60, respectively, and the position is from the inner wall surface of the wedge insertion groove 50. The rocker engaging hole 52 which penetrates horizontally toward the crystal groove 42 is formed in the underground tube spacer 40.

In addition, the eccentric shaft 70 forms large-diameter cylindrical portions 73 and 74 at the upper and lower ends thereof, the center of which coincides with the vertical holes 64 and 65, and the center and the eccentricity of the large-diameter cylindrical portions 73 and 74. The small diameter eccentric portion 75 having a diameter smaller than the large diameter cylindrical portions 73 and 74 is integrally formed between the large diameter cylindrical portions 73 and 74.

In addition, the contact surface of the rocker 80 in close contact with the small diameter eccentric portion 75 is formed in a concave curved surface to be in surface contact with the outer circumferential surface of the small diameter eccentric portion 75, vertical holes 64, 65 formed in the wedge 60 The rocker 80 is inserted into the rocker guide hole 66 which penetrates outward from the inner wall of the inner wall.

Then, the rotation angle limiting projection (72) for determining the release position and the locking position of the eccentric shaft (70) while being caught by both ends of the arcuate sector groove (67) formed at the upper edges of the vertical holes (64) (65). Is formed at the upper edge portion of the eccentric shaft (70).

That is, in the illustrated example, when the rotation angle limiting projection 72 is caught at one end of the sector groove 67 by turning the eccentric shaft 70 by 180 degrees in the counterclockwise direction, the rocker 80 protrudes by the eccentric shaft 70. If the locker 80 is caught by the rocker engaging hole 52 and the eccentric shaft 70 is rotated 180 degrees clockwise, the rotation angle limiting projection 72 is caught by the other end of the sector groove 67. The space that 80 can retreat is maximized so that the locker 80 can be released by pushing it with a release tool such as a driver.

In addition, the upper surface of the wedge 60 in which the sector grooves 67 are formed may be engraved with an arrow or a character indicating “release” and “hang”, thereby making it more convenient to use.

The positioning groove 42 is coupled to the positioning protrusion 43 to prevent the underground pipe spacers 40 stacked up and down from being separated in the left and right directions, and at the same time, the locker engaged with the locker engaging hole 52 It can also be used to insert a tool for releasing the 80, for this purpose by forming a chamfer 45 in the upper inner corner of the positioning groove 42 to push the rocker 80, such as a driver Make sure that the tool does not get caught in the corners.

Hereinafter, the operation according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figs. 5-7, sand is laid flat on the bottom surface of the excavation site to bury the power lines in the ground of the multi-family house, and the underground pipes 30 are arranged in parallel at approximately regular intervals on the sand. Then, the underground pipe spacer 40 is inserted into the underground pipe 30 so that the upper portion of the underground pipe 30 is inserted into the underground pipe inserting portion 41 formed in the underground pipe spacer 40. When it is in close contact with the left and right, the connecting passage 51 formed in the upper left and right corners of the neighboring underground pipe spacer 40 meets the neighboring wedge insertion groove 50 is connected to each other to form a peanut shape.

At this time, when the wedge 60 is inserted into the wedge insertion groove 50 forming a peanut shape, the adjacent underground pipe spacers 40 are connected by the wedge 60.

That is, since the wedge 60 has a narrow waist 61 and a thick head 62, 63, the wedge 60 serves to prevent the lateral separation of the underground tube spacer 40 connected to the left and right, the wedge ( When lightly hitting with a hammer when inserting 60 into the wedge insertion groove 50, the wedge 60 can be easily driven into the wedge insertion groove 50.

Then, when the eccentric shaft 70 is rotated 180 degrees counterclockwise by inserting a fastening tool such as a hexagon wrench into the hexagonal groove 71 formed at the upper end of the eccentric shaft 70 installed in the wedge 60, the eccentric shaft ( The rotation angle limiting projection 72 formed at the upper end of the 70 is caught on one end of the sector groove 67 so that the eccentric shaft 70 can no longer be rotated counterclockwise, in which case the eccentric shaft 70 The rocker 80 is protruded to the maximum by the small-diameter eccentric portion 75 constituting this.

That is, the large diameter cylindrical portions 73 and 74 constituting the eccentric shaft 70 are rotated concentrically in the vertical holes 64 and 65, and the small diameter eccentric portion 75 is the large diameter cylindrical portions 73 and 74. Since it is eccentric with the eccentric rotation, the rocker 80 is pushed out by the eccentric amount of the large diameter cylindrical portions 73 and 74 and the small diameter eccentric portion 75.

At this time, the rocker 80 is protruded laterally by the eccentric shaft 70 and enters and is locked into the locker engaging hole 52 formed to penetrate between the wedge insertion groove 50 and the positioning groove 42. The rocker 80 caught in the hole 52 serves to prevent the wedge insertion groove 50 from escaping from the upper side of the wedge 60, and the underground pipe spacers 40 adjacent to the left and right are moved forward and backward and up and down. It also acts to prevent deviations.

That is, the underground tube spacer 40 closely contacted with the left and right is firmly coupled by the wedge 60 and the rocker 80 so as not to move in the front, rear, left, and right directions.

When stacking another underground pipe spacer 40 on the underground pipe spacer 40 coupled to the left and right as described above, stacked on the upper side in the positioning groove 42 formed in the upper portion of the underground pipe spacer 40 located at the lower side. When the underground pipe spacers 40 are laminated while combining the positioning protrusions 43 formed at the lower portion of the underground pipe spacer 40 to be raised, the underground pipe spacers (by the positioning grooves 42 and the positioning protrusions 43) 40) front and rear, right and left positioning is made easily.

On the other hand, when the combined underground pipe spacer 40 is coupled to a hexagonal wrench 71 formed on the upper end of the eccentric shaft 70, such as a wrench and then turning the eccentric shaft 70 by 180 degrees clockwise The rotation angle limiting projection 72 formed at the upper end of the eccentric shaft 70 is caught between the other end of the sector groove 67 and is formed between the small diameter eccentric portion 75 and the rocker 80 forming the eccentric shaft 70. A space is formed in which the rocker 80 can retreat.

At this time, through the positioning groove 42 formed on the upper surface of the underground pipe spacer 40, a flat head screwdriver or a tool having a slightly bent end is inserted, and then slightly inclined to be inserted into the locker engaging hole 52, and then the locker 80 is inserted. When pushed, the rocker 80 withdraws into the space formed between the small-diameter eccentric portion 75 and the rocker 80 of the eccentric shaft 70 to be released into the locker engaging hole 52.

In this process, the chamfer 45 formed at the top of the positioning groove 42 serves to prevent interference when the tool is inclined.

After inserting the wedge 60 into the hexagonal groove 71 using a tool such as a pliers, pick it up and pull it upwards, or drill a hole in the center of the top surface of the wedge 60 using a drill, and then drive the screw and pull it out. When the wedge 60 is separated from the wedge insertion groove 50, the underground tube spacer 40 is separated.

30: underground tube 40: underground tube spacer
41: underground pipe insert 42: positioning groove
43: positioning projection 44: side contact surface
45: chamfer 50: wedge insertion groove
51: connecting passage 52: locker locking hole
60: wedge 61: waist
62,63 head 64,65 vertical hole
66: rocker guide hole 67: sector groove
70: eccentric shaft 71: hexagon groove
72: rotation angle limiting projection 73,74: large diameter cylindrical portion
75: small diameter eccentric 80: locker

Claims (1)

An inverted “U” shaped underground pipe insertion portion 41, which is inserted into the upper portion of the underground pipe 30, is formed in an open shape from the lower side of the underground pipe spacer 40 toward the upper side, and is stacked up and down. In the underground pipe space maintenance device for a multi-family house in which the positioning grooves 42 and the positioning projections 43 are coupled to the upper and lower surfaces of the underground pipe spacer 40,
A wedge insertion groove 50 having a narrow connecting passageway 51 is formed in the upper edge portion of the side surface contact surface 44 of the underground pipe spacer 40, and the narrow waist portion 61 and the thick head 62 and 63 are formed. Peanut-shaped wedge 60 having a) is inserted into the wedge insertion groove 50 in close contact with the left and right, vertical holes formed in the left and right sides of the eccentric shaft 70 formed with a hexagonal groove 71 on the top Inserted into (64) and (65), respectively, and formed in the underground pipe spacer (40), a rocker engaging hole (52) penetrated horizontally from the inner wall of the wedge insertion groove (50) toward the positioning groove (42). And inserting the rocker 80 into the rocker guide hole 66 penetrating outward from the inner wall surface of the vertical holes 64 and 65 formed in the wedge 60, and the upper edge portion of the vertical holes 64 and 65. Eccentric shaft 70 has a rotation angle limiting projection 72 for determining the release position and the locking position of the eccentric shaft 70 while being caught at both ends of the arc-shaped sector groove 67 formed in the Cavity houses underground pipe cavity-holding device, characterized in that is configured to form an inner mounting (45) facing the top edge of the top edge to form the part, the positioning groove 42.

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