KR101404716B1 - Surging removing device for constructing shotcrete - Google Patents

Abstract

The present invention relates to a surging removal device for shotcrete construction equipment. A pressure tank is installed in a transfer pipe. A cylinder lifted by a coil spring is installed in the pressure tank. When an opening and closing member is installed in the transfer pipe, concrete is transferred through the transfer pipe and is charged in the pressure tank. When the pressure is released, the opening and closing member closes the transfer pipe in a supply side and the concrete is discharged from the pressure tank to the transfer pipe through the cylinder to remove surging.

Description

TECHNICAL FIELD [0001] The present invention relates to a pulverizer for a shotcrete apparatus,

More particularly, the present invention relates to a pulsation removing apparatus for a shotcrete production facility, and more particularly, to a pulsation removing apparatus for a shotcrete production facility, which comprises a pressure tank on a transfer pipe, a cylinder which is raised and lowered by a coil spring in a pressure tank, When the concrete is fed through the conveying pipe, the concrete is filled in the pressure tank. When the pressure is released, the opening and closing member closes the conveying pipe on the supplying side, and the concrete in the pressure tank is discharged to the conveying pipe through the cylinder to remove the pulsation To a pulsation removal device for a shotcrete installation.

Recently, in order to preserve the ground environment and make efficient use of the land, the construction of tunnels and underground spaces in subways, roads, national railways, .

In this way, as a part of underground construction that is becoming larger, it is called "New Austrian Tunneling Method (NATM)" which is mainly used for construction of tunnels, dams or underground structures. The concept is that the main constituent of the tunnel is the surrounding ground and the ground guard is a means to maintain and reinforce the original strength of the ground. It is a stabilized excavation surface stabilization method that stabilizes the excavation surface by stabilizing the tunnel by using the bolts and shotcrete as supporting materials and stabilizing the ground by utilizing the supporting ability of the paper sheet immediately after excavation of the rock.

Shotcrete used as a supporting material of the excavation surface stabilization method is to prevent collapse by reinforcing the rock or the ground. It does not require a separate form, It is a concrete to be sprayed and fixed by pressure. It prevents the relaxation of the ground and maintains the strength of the paperboard. By sharing the load as a concrete arch, it smoothes the excavation surface to prevent stress concentration. , And minimizing rebound and dust generation.

Among these shotcrete equipment, the concrete pump is roughly classified into a squeeze method and a piston method according to its operating structure. The squeeze concrete pump is composed of a conveying tube and a pressing roller for pressing the conveying pump. The concrete is discharged and transported.

According to the squeeze type concrete pump, since the pulsation phenomenon is small, unlike the piston system described later, the stability of the pumping operation is high. However, since the conveyance tube is made of a soft material such as rubber, There is a disadvantage that it is difficult to transfer to a high place, and the tube is easily worn and damaged, which is costly to maintain.

The piston-type concrete pump is a two-way-two-stroke structure (hereinafter referred to as a 2-2-way piston concrete pump) in which concrete is sucked by a cylinder and the piston is reciprocated to discharge concrete. ).

As shown in FIG. 1, the conventional 2-2-system piston concrete pump includes a hopper 10 that receives and stirs raw concrete discharged from a mixer truck or the like, The first and second discharge cylinders 20 and 20 'for pumping by reciprocating motion of the drive cylinders 21 and 21' connected to the rear ends of the discharge cylinders 20 and 20 ' An S-valve 30 which swings to the left and right to form a discharge passage connected to the discharge cylinder 20 or 20 'alternately and connected to the transfer pipe 12; And left and right shift cylinders 40 and 40 'for swinging the S valve 30 from the rear side of the hopper 10 to the left and right.

The pistons 22 and 22 'are reciprocally reciprocated by hydraulic pressure in the discharge cylinders 20 and 20' and the drive cylinders 21 and 21 '. The pistons 22 and 22' A rod spool 221 and a piston spool 222 are formed on the front and rear ends of the drive cylinders 21 and 21 ' And the rear end of the two drive cylinders 21 and 21 'are also connected to each other by a hydraulic pipe.

The discharge cylinders 20 and 20 'and the drive cylinders 21 and 21' are connected to each other via a water box 24 for cooling and cleaning the load spools 221 and 221 ' , The pistons 22 and 22 'operated in the both cylinders are arranged such that the rod spools 221 and 221' are disposed on the side of the discharge cylinders 20 and 20 ', and the piston spools 222 and 222' Are installed in the drive cylinders 21 and 21 '.

The S-valve 30 includes a main tube portion 301 bent in an S-shape, a rotation axis portion 302 formed at one side of the main tube portion 301, a spline portion 303 formed in order at the rear end of the rotation axis portion 302, , And a threaded portion (not shown).

The S valve 30 has a structure in which the front end of the main tube portion 301 is connected to the transfer tube 30 and the rotational axis portion 302 protrudes to the rear of the hopper 10, 301 is attached with a wear plate 32 for preventing direct friction with the inner surface of the hopper 10 at the rear end thereof.

The shift hinge 42 is splined to the spline portion 303 of the S valve 30 and the screw portion 304 is fitted with a lock nut (not shown) for preventing the shift hinge 42 from coming off, The left and right shift cylinders 40 and 40 'for swinging the S valve 30 are connected to the hinge 42. [

The operation of the conventional 2-2 type piston concrete pump having such a structure is as follows.

First, in the first discharge cylinder 20 connected to the S valve 30, the concrete is discharged to the transfer pipe 12 side through the discharge operation in which the piston 22 advances. At the same time, the second discharge cylinder 20 ', the piston 22' sucks the concrete through the backward suction operation.

Subsequently, after the discharge operation of the first discharge cylinder 20 is completed, the S valve 30 swings by the one-side shift cylinder 40 to connect the second discharge cylinder 20 'to the transfer tube 12 The outlet of the first discharge cylinder 20 is opened.

Then, the concrete is sucked through the suction operation in the first discharge cylinder (20), and at the same time, the second discharge cylinder (20 ') discharges the concrete to be conveyed to the conveyance pipe (12).

That is, according to the conventional 2-2-system piston concrete pump, the discharge cylinders 20 and 20 'perform the discharge stroke and the suction stroke to perform the two stroke stroke of the suction stroke and the discharge stroke, The concrete in the hopper 10 is conveyed through the conveyance pipe 12 by alternately connecting the discharge cylinders 20 and 20 'and the conveyance pipe 12 alternately.

According to this conventional technique, since the two discharge cylinders 20 and 20 'simultaneously perform the opposite strokes, during the swing operation of the S valve 30 (when the operation of each cylinder is switched) The pulsation phenomenon is caused, and the conveying boom (not shown) in which the conveying pipe 12 is long attached due to the pulsation phenomenon is irregularly shaken.

When the conveying boom is shaken by the pulsation phenomenon, the length of the conveying boom becomes worse. Therefore, when the conventional 2-2 type piston concrete pump is used, the stability of the shotcrete is lowered significantly and the durability of the conveying boom is lowered. The movement of the boom is not easy and the efficiency of the concrete pouring work is lowered.

In order to solve these problems, Korean Patent Registration No. 10-0626805 (Piston concrete pump) has been developed.

As shown in FIG. 2, the piston concrete pump includes a hopper 10 having a transfer pipe 12 at one side thereof; Two discharge cylinders 20 and 20 'disposed on the other side of the hopper 10 to pump raw concrete supplied to the hopper 10; Two drive cylinders 21 and 21 'respectively connected to the discharge cylinders 20 and 20'; A main pipe portion 501 rotatably connected to the transfer pipe 12 in the hopper 10 and an auxiliary pipe portion 503 formed at the rear portion of the main pipe portion 501 and protruding from the hopper 10 And a branch tube portion 502 branched from one side of the main tube portion 501. The branch tube portion 502 and the discharge cylinder 20 are connected to each other by swinging left and right with the main tube portion 501 as a rotation axis, (SIS) valve 50, which is alternately connected to the exhaust valve 20 '; A portion of the concrete conveyed from the branch pipe portion 502 to the main pipe portion 501 is sucked during the extrusion operation of the discharge cylinders 20 and 20 'by communicating with the auxiliary pipe portion 503 of the S- The auxiliary cylinder 60 (60 ') for removing the pulsation due to the pumping operation disconnection between the two discharge cylinders 20 and 20' by pushing the concrete to the main pipe portion 501 at the operation transition timing of the discharge cylinders 20 and 20 ' ); A shift hinge 42 connected to the auxiliary pipe section 503 of the S-ies valve 50 from the rear of the hopper 10 and a shift hinge 42 connected to the shift hinge 42 to move the S- And a left and right shift cylinder (40) for rotating the swing mechanism. In the figure, reference numeral 62 denotes a piston, 621 denotes a load shovel, and 622 denotes a piston spool.

However, in the conventional piston concrete pump, the concrete of the auxiliary cylinder is not transferred to the transfer pipe when the valve is moved, but is discharged to the discharge cylinder or the hopper side on the side where the pressure is relatively low, so that the actual pulsation can not be removed .

Further, since the conventional piston concrete pump operates the auxiliary cylinder by using the hydraulic pressure, the hydraulic line becomes complicated and the control becomes complicated, raising a problem that the equipment cost is increased.

Korean Patent Registration No. 10-0626805 Domestic Registered Utility Model Bulletin No. 20-0305816 Korean Patent Registration No. 10-0351332

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a pressure tank on a transfer tube, a cylinder which is raised and lowered by a coil spring in a pressure tank, When the concrete is fed through the concrete, the concrete is filled in the pressure tank. When the pressure is released, the opening and closing member closes the feed pipe at the feed side, and the concrete of the pressure tank is discharged to the conveyance pipe through the cylinder to remove the pulsation. And a pulsation removing device.

In addition, the present invention eliminates pulsation by installing a pressure tank, a cylinder, and an opening / closing member operated in a simple mechanical structure in a transfer pipe, thereby reducing the pulsation of the shotcrete construction equipment There is another purpose in providing the device.

According to another aspect of the present invention, there is provided a pulsation removing apparatus for a shotcrete apparatus,

A conveyance pipe formed into a cylindrical shape to convey concrete; A pressure tank installed vertically to the conveyance pipe so as to communicate with the conveyance pipe; A damper installed vertically to the pressure tank and descending when the pressure in the conveyance pipe is released when concrete is filled in the pressure tank to discharge the concrete to the discharge side of the conveyance pipe; And a pressure regulating member formed at one side of the damper to regulate the pressure of the damper.

Here, the pulsation removing device for the shotcrete construction equipment is provided between the supply side of the transfer pipe and the one side of the transfer pipe, and between the concave and the convex formed by bending inward, and when the pressure is released in the transfer pipe, An opening and closing member which is hermetically closed and which is moved when pressure is applied to the concrete in the conveyance pipe to open the supply side of the conveyance pipe; And a release preventing member which is formed in the shape of a U-shaped band and whose one end is fixed to the concave and convex of the conveying pipe and the other end is fixed to a portion corresponding to the concavity and convexity of the conveyance pipe to prevent the opening / .

Here, the conveying pipe is formed with a stopper inside the side surface of the concave and convex so as to prevent the opening and closing member from being moved to the supply side and to seal the inside of the conveyance pipe.

Here, the pressure tank is provided above the concave and convex portions of the conveyance pipe.

Here, the damper is provided with a coil spring on the rod, and a head is formed at the end of the rod. When the pressure in the conveyance pipe is released, the concrete in the pressure tank is pushed out to the discharge side of the conveyance pipe.

Here, the pressure of the coil spring is smaller than the pressure of the conveyance pipe at the position of the pressure tank when the concrete is pumped, and the pressure in the pressure tank is lower than the pressure of discharging the concrete in the pressure tank to the conveyance pipe It has a large value.

Here, the damper is set to be equal to or longer than a period of time during which the concrete in the pressure tank is discharged to the conveyance pipe.

Here, the opening and closing member is a ball.

Here, the head of the damper and the opening and closing member are connected to each other by an elastic body to move the opening / closing member in accordance with the ascending and descending of the head of the damper to seal or open the conveying pipe.

Here, the pressure regulating member may include a fixing plate installed at an upper end of the pressure tank; A press-fit plate provided at an upper end of the coil spring inside the pressure tank; And a position adjusting bolt having one end fixed to the fixing plate and the other end fixed to the pressing plate to move the pressing plate upward and downward.

According to the pulsation removing device for a shotcrete production facility of the present invention, the pressure tank is provided on the transfer pipe, the cylinder is lifted and lowered by the coil spring in the pressure tank, and the opening and closing member is provided on the transfer pipe When the concrete is fed through the conveying pipe, the concrete is filled in the pressure tank. When the pressure is released, the opening and closing member seals the conveying pipe on the supplying side and the concrete in the pressure tank is discharged to the conveying pipe through the cylinder. have.

In addition, according to the present invention, a pressure tank, a cylinder, and an opening / closing member, which are operated in a simple mechanical configuration, are installed in the transfer pipe to remove pulsation, so that the structure is relatively simple and the equipment cost can be relatively reduced.

1 and 2 are views showing the construction of a conventional piston concrete pump.
3 is a perspective view illustrating the construction of a pulsation removal device for a shotcrete installation according to the present invention.
4 is a partial cutaway perspective view of FIG.
FIG. 5 is an explanatory view for explaining the concept of a pulsation removing apparatus for a shotcrete installation according to the present invention.
FIGS. 6 and 7 are explanatory diagrams for explaining the operation of a pulsation removing apparatus for a shotcrete installation according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the construction of a pulsation removal device for a shotcrete installation according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, 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. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

FIG. 3 is a perspective view showing the construction of a pulsation removing apparatus for a shotcrete installation according to the present invention, FIG. 4 is a partial cutaway perspective view of FIG. 3, and FIG. 5 is a view for explaining the concept of a pulsation removal apparatus for a shotcrete construction work according to the present invention Fig.

3 to 5, a pulsation removal apparatus 100 for a shotcrete installation according to the present invention includes a transfer pipe 110, a pressure tank 120, a damper 130, an opening / closing member 140, A release preventing member 150, an elastic body 160, and a pressure regulating member 170.

First, the conveyance pipe 110 is formed in a cylindrical shape so as to convey concrete, and one side of the conveyance pipe 110 is bent inward to form concave and convex portions 111. At this time, the concavities and convexities 111 are formed in a "?" Here, the transfer pipe 110 prevents the opening / closing member 140 from moving to the supply side, and a stopper 113 (not shown) is provided inside the side surface of the unevenness 111 so that the opening / closing member 140 can seal the inside of the transfer pipe 110 And the interval of the stopper 113 is narrower than the diameter of the opening and closing member 140 to be described later and the inclined surface 115 is formed on one side.

The pressure tank 120 has an elliptical or quadrangular cross-sectional shape and is formed integrally with the transfer pipe 110 at an upper portion of the concavity and convexity 111 of the transfer pipe 110.

The damper 130 is vertically installed in the pressure tank 120 and descends when the pressure in the conveyance pipe 110 is released in a state where the concrete is filled in the pressure tank 120 to convey the concrete to the conveyance pipe 110 And discharged to the discharge side. Here, the damper 130 is provided with a coil spring 133 on the rod 131, a hemispherical head 135 formed on the end of the rod 131 to release the pressure in the transfer tube 110, (120) to the discharge side of the conveyance pipe (110). 5, the pressure q of the coil spring 133 is smaller than the pressure p of the conveyance pipe 110 where the pressure tank 120 is located when the concrete is pumped, 120 to the conveying pipe 110 at a position where the pressure tank 120 is located. Here, it is preferable that the time for discharging the concrete in the pressure tank 120 to the conveyance pipe 110 is set to be equal to or longer than the time during which the pulsation occurs.

The opening and closing member 140 is provided as a ball between the supply side of the transfer tube 110 and the protrusion 111 so as to seal the supply side of the transfer tube 110 when the pressure is released in the transfer tube 110, When the pressure is applied to the concrete by the conveyer 110, the conveying pipe 110 is opened. The opening and closing member 140 is connected to the head 135 of the damper 130 by the elastic body 160 and moves together with the upward and downward movement of the head 135 to close or open the conveying pipe 110 . The diameter of the opening and closing member 140 is preferably smaller than the diameter of the pressure tank 120 so that interference does not occur when the concrete is discharged from the pressure tank 120.

The release preventing member 150 is formed in a U-shaped band shape so as not to interfere with the conveyance of the concrete. One end of the release preventing member 150 is fixed to the projections and depressions 111 of the conveyance pipe 110, Is fixed to a portion corresponding to the concavity and convexity 111, that is, a portion where the pressure tank 120 is installed, thereby preventing the opening / closing member 140 from being separated.

The elastic body 160 is formed in a bar shape and interconnected between the head 135 of the damper 130 and the opening and closing member 140 so that the opening and closing member 140) to close or open the transfer tube (110).

The pressure regulating member 170 includes a fixed plate 171 provided at an upper end of the outer side of the pressure tank 120 and a press fitting plate 173 provided at the upper end of the coil spring 133 inside the pressure tank 120, And a position adjusting bolt 175 which is installed at one end of the fixing plate 171 and the other end of which is provided at the press-in plate 173 to move up and down the press-in plate 173 to adjust the pressure of the coil spring 133 .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the construction of a pulsation removal device for a shotcrete installation according to the present invention will be described in detail with reference to the accompanying drawings.

FIGS. 6 and 7 are explanatory diagrams for explaining the operation of a pulsation removing apparatus for a shotcrete installation according to the present invention.

6, when the concrete is fed from one cylinder of the concrete pump to the conveyance pipe 110, the head 135 of the damper 130 overcomes the compressive force of the coil spring 133 by the pressure of the concrete, Concrete is filled in the pressure tank (120). At this time, the opening and closing member 140 is also moved toward the release preventing member 150 by the pressure and the elastic body 160 to open the transfer pipe 110.

In this state, the pressure in the transfer pipe 110 is released at the time the S valve is operated to transfer the concrete through the other cylinder.

7, the head 135 of the damper 130 is lowered by the compressive force of the coil spring 133 to discharge the concrete filled in the pressure tank 120 to the conveyance pipe 110.

At this time, the opening and closing member 140 is also moved to the stopper 135 together with the descending of the head 135 to close the conveying pipe 110.

As a result, the concrete which has been filled in the pressure tank 120 in the conveyance pipe 110 is discharged to the discharge side of the conveyance pipe 110, so that the occurrence of pulsation is blocked.

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. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

110: Feed pipe 120: Pressure tank
130: damper 140: opening / closing member
150: release preventing member 160: elastic member

Claims (10)

A conveyance pipe formed into a cylindrical shape to convey concrete;
A pressure tank installed vertically to the conveyance pipe so as to communicate with the conveyance pipe;
Wherein the rod is provided with a coil spring, a head is formed at an end of the rod, and when the pressure in the conveyance pipe is released in a state where concrete is filled in the pressure tank, To the discharge side of the damper; And
And a pressure adjusting member formed on one side of the damper to adjust the pressure of the damper. The method according to claim 1,
The pulsation removal device for a shotcrete installation includes:
Wherein the conveying pipe is provided between the supply side of the conveyance pipe and the convexo-concaves formed by bending inwardly on one side of the conveyance pipe, the supply side of the conveyance pipe is sealed when the pressure is released in the conveyance pipe, An opening / closing member that is moved when the supply pipe is applied and opens the supply side of the transfer pipe;
And a release preventing member formed in a U-shaped band shape and having one end fixed to the concavo-convex of the conveyance pipe and the other end fixed to a portion corresponding to the concavity and convexity of the conveyance pipe to prevent the opening / Characterized in that the pulsating device for shotcrete construction equipment. 3. The method of claim 2,
The conveying pipe
Wherein a stopper is formed inside the side surface of the concave and convex so as to prevent the opening and closing member from being moved to the supply side and to seal the inside of the conveyance pipe by the opening and closing member. 3. The method of claim 2,
The pressure tank may include:
Wherein the pulverizer is installed above the concave and convex of the conveyance pipe. delete The method according to claim 1,
The pressure of the coil spring,
Wherein the pressure of the concrete is smaller than the pressure of the conveyance pipe at the position of the pressure tank when the concrete is pumped and is greater than the pressure of discharging the concrete in the pressure tank to the conveyance pipe at the position of the pressure tank. Pulse removal device for equipment. The method according to claim 1,
The damper includes:
Wherein the time for discharging the concrete in the pressure tank to the conveyance pipe is set to be equal to or longer than a period of time during which the pulsation occurs. 3. The method of claim 2,
The open /
Wherein the pulverizer is a ball. 3. The method of claim 2,
Wherein the head of the damper and the opening /
And the opening and closing member is moved in accordance with the rising and falling of the head of the damper to close or open the conveyance pipe. The method according to claim 1,
The pressure regulating member
A fixing plate installed at an outer upper end of the pressure tank;
A press-fit plate provided at an upper end of the coil spring inside the pressure tank; And
And a position adjusting bolt having one end fixed to the fixing plate and the other end fixed to the pressing plate to move up and down the pressing plate.

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