KR101439974B1 - Jack for crushing rock - Google Patents

Abstract

The present invention relates to a jack for crushing rock, and it provides a structure in which a sleeve is provided on a wall surface of a cylinder so as to use high-pressure hydraulic fluid in order to increase crushing force, And more particularly, to a jack for crushing rock, which improves the durability and service life of the jack, and improves the workability by increasing the crushing force by the nasaparator.
According to the present invention, there is provided a cylinder assembly comprising: a cylinder in which an operating chamber having an opening at one end thereof is formed and in which an injection hole for sending external operating fluid to a working chamber is formed; A stop ring provided at an opening of the cylinder and having an inner diameter smaller than an inner diameter of the operation chamber; A piston which is formed at one end portion of the piston rod in contact with the inner circumferential surface of the working chamber and reciprocates while the other end portion is in contact with the inner circumferential surface of the stop ring; The jack is formed with a cap provided at the other end of the piston. An insertion groove is formed in the inner surface of the cylinder contacting with the end of the stop ring. The outlet is connected to the insertion groove, And a ring-shaped sleeve having a predetermined width is inserted into the jack.

Description

{Jack for crushing rock}

The present invention relates to a jack for crushing rock, and it provides a structure in which a sleeve is provided on a wall surface of a cylinder so as to use high-pressure hydraulic fluid in order to increase crushing force, And more particularly, to a jack for crushing rock, which improves the durability and service life of the jack, and improves the workability by increasing the crushing force by the nasaparator.

In civil engineering and construction work, it takes a lot of time and money to shred rocks and rocks that are encountered when excavating the ground. In the rock excavation, a plurality of holes are drilled at predetermined intervals, and a jack is inserted into each hole to break the rock by extending the hole.

The structure of the jack includes a cylinder having an operating chamber having an opening at one end thereof and an injection hole for supplying external operating fluid to the operating chamber; A stop ring provided at an opening of the cylinder and having an inner diameter smaller than an inner diameter of the operation chamber; A piston which is formed at one end portion of the piston rod in contact with the inner circumferential surface of the working chamber and reciprocates in contact with the inner circumferential surface of the stop ring; And a cap provided at the other end of the piston.

In this case, the inner circumferential surface of the operating chamber of the cylinder and the outer circumferential surface of the protruding portion formed at one end of the piston are operated in an airtight state, so that the outer circumferential surface of the protruding portion is sealed with an O-ring or the like. The outer surface of the other side of the piston and the contact surface of the stop ring are sealed with an O-ring or the like. The cylinder of the stop ring portion is formed with a discharge port through which hydraulic oil having a predetermined pressure is discharged.

Such a conventional jack is inserted into a hole drilled in a rock or a rock, and the piston is pushed outward by the injection of hydraulic oil through the injection hole to enlarge the perforated surface of the rock or rock to cause crushing.

When the operating oil is injected at a predetermined pressure, the piston is pushed to move, and then the stopper collides with the stop ring to stop. As a result, the impact of the stones and stop rings damaged various components of the jack. Particularly, this impact caused the deformation of the stop ring, making it impossible to disassemble and replace the jack, thus allowing only the entire jack to be exchanged.

Due to such a problem, in the conventional case, the pressure of the operating oil is reduced so as not to be significantly damaged even when collision between the stone ring and the stop ring occurs. That is, in the conventional case, a pressure of about 1,400 kg / cm 2 was used, and the jack could not be used because the jack was damaged.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a jack for crushing rock, which has a structure capable of increasing the crushing force by increasing the pressure of the operating oil for operating the jack, and preventing the damage of the jack even if high-

In order to achieve the above object, the present invention provides a structure for relieving the pressure of the hydraulic oil after the piston and the cap are moved a certain distance by the high-pressure hydraulic oil, The sleeve is provided with a very narrow gap so that there is no abrasion of the seal. By providing a ring-shaped sleeve, a fine gap can be formed around the entire circumference to enable a sufficient pressure to be lowered and a jack capable of applying a pressure of 2,000 kg / do.

According to the present invention, it is possible to solve the problem that the crushing force is weak by using the conventional operating oil of about 1,400 kg / cm 2, thereby providing a structure in which the high-pressure operating oil is used up to 2,000 kg / , And various construction sites and civil engineering works, it guarantees very high performance in crushing of rock, rock or concrete structures.

1 shows a state in which the jack of the present invention is inserted into a perforation in a rock
Figure 2 is a horizontal cross-sectional view of the jack of Figure < RTI ID = 0.0 > AA &
Fig. 3 shows an operating state in which the piston is moved outward to crush the rock mass
Figure 4 shows an exploded view of the jack

A rocking crushing jack (100) of the present invention comprises a cylinder (50) in which a working chamber (1) having one end opened is formed and in which an injection hole (2) for sending external working oil to the working chamber (1) is formed; A stop ring (60) provided at an opening of the cylinder (50) and having an inner diameter smaller than an inner diameter of the operation chamber (1); A piston (70) formed at one end of the piston (3) in contact with the inner circumferential surface of the working chamber (1) and reciprocating in contact with the inner circumferential surface of the stop ring (60); And a cap (80) provided at the other end of the piston (70).

Particularly, the present invention provides a method of manufacturing a high-strength, high-strength, high-strength, high-strength, high- And a structure for allowing the hydraulic oil to be discharged. Another feature is that the structure for discharging high-pressure operating oil does not damage the sealing.

Therefore, the above-mentioned characteristic structure and the effect thereof are achieved by the sleeve 4. [ That is, the insertion groove 5 is formed in the inner surface of the cylinder 50 in contact with the end of the stop ring 60, and the discharge port 6 is formed to communicate with the outside so as to be connected to the insertion groove 5 , And a ring-shaped sleeve (4) having a predetermined width is inserted into the insertion groove (5), thereby achieving the object of the present invention.

The inner surface of the sleeve 4 has the same diameter as that of the inner surface of the operating chamber 1 and the inner surface of the sleeve 4 and the one side surface of the insertion groove 5 and one side surface of the stop ring 60 The piston 70 is pushed with a strong force and the protrusion 3 formed on one end of the piston 70 is pressed against the stop ring 60 by a force of 0.008 to 0.012 mm, Thereby preventing an impact from being applied.

The outlet 6 is provided with a check valve 7 through which the hydraulic fluid exits from the operating chamber 1 to the outside and the flow of hydraulic fluid from the outside to the operating chamber 1 is blocked.

The operation of the present invention having the above-described characteristic structure will be described in detail with reference to the accompanying drawings.

As shown in Fig. 1, the jack 100 of the present invention is inserted into the pierced hole by preliminarily piercing the rock bed or rock to be crushed.

The inserted jack 100 is largely composed of a cylinder 50 and a piston 70 and a cap 80 is attached to the end of the piston 70. Therefore, the cylinder 50 and the cap 80 are brought into contact with the perforated surface, and the force is transmitted to both sides by the extension of the piston 70, so that the rock is broken.

The jack 100 inserted in the perforation is as shown in Fig. That is, the operation chamber 1 is in communication with the injection hole 2 for receiving the high-pressure hydraulic fluid supplied from the outside, and the outer peripheral surface of the ridge 3 is in contact with the inner surface of the operation chamber 1. [ Of course, a sealing ring is provided around the outer circumferential surface of the protrusion 3 for airtight sealing, and a sealing ring is also provided in the stop ring 60 so as to be hermetically sealed with the outer circumferential surface of the piston.

In this state, high-pressure hydraulic fluid is supplied through the injection hole. The present invention can be used by supplying operating oil at a high pressure of 2,000 kg / cm 2 or more due to its structural characteristics. This is an improvement of the crushing force compared with the conventional use of operating oil of about 1,400 kg / cm 2.

When the high-pressure operating fluid is supplied to the operating chamber 1 through the injection hole 2, the piston 70 is pushed by the pressure. Therefore, the piston 70 is gradually moved to the right in the state of FIG. 2, and is moved to the state shown in FIG.

During the movement of the piston 70, the outer circumferential sealing of the boss 3 is moved in close contact with the inner surface of the working chamber 1 and then passes through the sleeve 4 mounted on the insertion groove 5. As shown in FIG. 3, the protuberance 3 passes first on the left side of the sleeve 4. The left end of the sleeve 4 is formed with a clearance due to an assembly tolerance or a machining tolerance with the left wall of the insertion groove 5, and the width of the clearance is about 0.008 to 0.012 mm.

The width of the clearance is a narrow gap where the seal is not damaged even if the sealing of the protrusion 3 passes. Even in such a narrow gap, since the present invention is a clearance formed by the ring-shaped sleeve 4, Since the inner side is formed around the ice core, there is no problem in escaping the high-pressure hydraulic fluid.

Therefore, when the protrusion 3 of the piston 70 passes through the clearance, the high-pressure hydraulic fluid flowing into the left operating chamber 1 escapes to the discharge opening 6 through the gap formed on the left side of the sleeve 4. Since the discharge port 6 is communicated to the outside and the check valve 7 is provided on the pipe line of the discharge port 6, the high-pressure hydraulic fluid can escape from the inside to the outside.

When the high-pressure hydraulic fluid thus escapes to the outside through the gap and the discharge port 6 and the check valve 7, the pressure of the working chamber 1 becomes low so that the movement of the piston 70 also causes a weak force . Therefore, even if the piston 70 is continuously moved to the right side, the ridge 3 will strike the stop ring 60 with a weak force. However, most of the pressure is discharged to the outside through the gap, so that even if the stop ring 60 is struck against the stop ring 60, there is no shock that damages the stop ring 60 or other parts.

When the piston 70 is stretched in the above-described process, the cap 80 pushes the rock in the pore, and a crack is generated between the pore and the pore. Therefore, the rock can be easily crushed and removed.

In order to further advance the piston 70 in the reverse direction, a working fluid of a predetermined pressure may be supplied through the discharge port 6. The discharge port 6 is provided with a check valve 7, And the right end of the sleeve 4 and the sleeve 4 are introduced into the gap of the insertion groove 5 into which the sleeve 4 is inserted as shown in Fig. Of course, at this time, a pressure smaller than the pressure of the hydraulic oil for crushing is used. Therefore, the piston 70 is moved to the left side and returned to the initial state as shown in FIG.

1: working chamber 2: injection hole
3: Loose 4: Sleeve
5: insertion groove 6: outlet
7: Check valve 50: Cylinder
60: stop ring 70: piston
80: Cap 100: Jack for rock breaking

Claims (3)

A cylinder 50 in which a working chamber 1 having an opening at one end is formed and in which an injection hole 2 for sending external operating fluid to the working chamber 1 is formed; A stop ring (60) provided at an opening of the cylinder (50) and having an inner diameter smaller than an inner diameter of the operation chamber (1); A piston (70) formed at one end of the piston (3) in contact with the inner circumferential surface of the working chamber (1) and reciprocating in contact with the inner circumferential surface of the stop ring (60); In the jack 100 constituted by the cap 80 provided at the other end of the piston 70, the insertion groove 5 is formed in the inner surface of the cylinder 50, which is in contact with the end of the stop ring 60, Wherein a ring-shaped sleeve (4) having a predetermined width is inserted and installed in the insertion groove (5) so that the discharge port (6) is connected to the outside so as to be connected to the insertion groove (5) jack.
The sleeve (4) according to claim 1, wherein the inner surface of the sleeve (4) has the same diameter as the inner surface of the working chamber (1), and both side ends of the sleeve (4) And a gap of 0.008 to 0.012 mm is formed between the one side wall surface of the jacket and the high pressure working oil leaking through the gap.
2. The automatic transmission according to claim 1, characterized in that a discharge valve (6) is provided with a check valve (7) through which the hydraulic fluid escapes from the working chamber (1) to the outside and the flow of hydraulic fluid from the outside to the working chamber Jack for shredding.

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