KR20100075332A - Hydraulic oil regeneration valve assembly for construction machinery - Google Patents

Abstract

PURPOSE: A regeneration valve assembly of construction equipment is provided to improve productivity by facilitating the processing of an orifice flow path. CONSTITUTION: A regeneration valve assembly of construction equipment comprises: a valve body(20) which includes a tank path(22) which is formed to the longitudinal direction of a spool(21), a first port, and a second port(25); a regeneration flow path(30) which is located on the top of the spool and is formed on the valve body in order to be communicated with the other side of a supply flow path(23); and an orifice flow path(40) which is formed inside the valve body and interlinks the regeneration flow path and the tank path.

Description

HYDRAULIC OIL REGENERATION VALVE ASSEMBLY FOR CONSTRUCTION MACHINERY}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction machine such as an excavator, and more particularly, to a regeneration valve assembly of a construction machine for regenerating hydraulic oil in which high pressure is formed by the weight of a working machine such as a boom cylinder or an arm cylinder.

In general, the working machine of a construction machine such as an excavator consists of a boom, an arm and a bucket. The boom, arm and bucket are driven by a hydraulic cylinder to perform work such as excavation work.

The boom is rotatably installed in the upper pivot body in the vertical direction, the arm is rotatably installed in the vertical direction in the boom, and the bucket is installed in the arm to pivot in the vertical direction. Thus, a boom cylinder for driving the boom must support the load of the arms and the bucket as well as the weight of the boom itself.

Therefore, when the boom cylinder is extended to raise the boom, most energy is consumed. On the other hand, when the boom is lowered, the load of the boom, the arm and the bucket raises the pressure of the raising chamber of the boom cylinder very high. In this way, the pressure formed in the rising chamber is lost due to thermal energy and the like while passing through an orifice or the like for preventing a sudden drop of the boom.

In view of such a point, in recent years, studies are being actively conducted to minimize the loss of power by reusing the high pressure formed in the rising chamber of the boom cylinder when the boom is lowered with the rapid increase in the oil price. One example is a flow rate regeneration method for supplying hydraulic oil in the up chamber of the boom cylinder to the down chamber of the boom cylinder when the boom is lowered. Such a flow rate regeneration method reduces the power loss by reducing the flow rate of the hydraulic oil discharged from the pump by supplying the hydraulic oil of the high pressure rising chamber to the lowering chamber. This flow rate regeneration method is equally applicable to the arm cylinder, it is generally implemented by the regeneration valve assembly. An example of a regeneration valve assembly is disclosed in Japanese Patent Laid-Open No. 2001-221351.

Referring to FIG. 1, the regeneration valve assembly disclosed in the Japanese Laid-Open Patent Publication discloses a portion of the hydraulic oil discharged from the chamber in which the high pressure is formed, the tank passage 3 through the orifice 13, the groove bottom 24, and the flow passage 25. To be discharged. Then, the remaining part of the hydraulic oil discharged from the high pressure chamber is supplied to the low pressure chamber through the check valve 11, whereby the hydraulic oil of the high pressure chamber is regenerated.

However, the regeneration valve assembly as described above is a check valve 11 is installed on the lower surface of the valve body 1, so if a failure occurs in the check valve 11, after removing the regeneration valve assembly from the construction machine check valve (11) must be exchanged. Therefore, there is a drawback that not only takes a long time to maintain, but also requires a great deal of labor.

In addition, the orifice 13 for narrowing the flow path of the hydraulic oil discharged from the high-pressure chamber has a structure in which a bolt in which the orifice flow path is formed is provided in the mounting hole. Therefore, an additional part called an orifice bolt has to be used, which not only increases manufacturing costs but also complicates the assembly process of the valve assembly.

In addition, the hydraulic oil passing through the orifice 13 is discharged to the tank passage 3 through the groove bottom 24 and the flow passage 25, but the groove bottom 24 is formed on the outer surface of the valve body 1 and is adjacent to the hydraulic fluid. In order to form a complete flow path, the valve block and the airtight ring must be kept airtight. Therefore, there is a disadvantage that the leaking ring is hardened due to hardening of the airtight ring or the like, and the airtight ring must be used as necessary, and the assembly process is complicated and the manufacturing cost is increased.

On the other hand, since the flow passage 25 for communicating the groove bottom 24 and the tank passage 3 is formed in the arrangement direction of the spool, processing is difficult, which leads to not only a rise in manufacturing cost but also a decrease in productivity.

The present invention has been made in view of the above-mentioned point, and provides a regeneration valve assembly for construction machinery that can reduce the number of parts, simplify the manufacturing process, reduce manufacturing costs, and improve maintainability. The purpose is.

Regeneration valve assembly of the construction machine according to the present invention for achieving the above object is installed spool 21 is movable, the tank passage 22 is formed in the lower portion of the spool 21, the spool A supply flow passage 23 is formed at an upper portion of 21 and communicates with the first chamber 11 of the cylinder 10 and selectively communicates with one side of the supply flow passage 23 according to the position of the spool 21. A first port 24 formed therein, and communicating with the second chamber 12 of the cylinder 10 and selectively communicating with the other side of the supply flow path 23 according to the position of the spool 21. A valve body 20 in which a port 25 is formed; A regeneration flow path 30 disposed above the spool 21 and formed in the valve body 20 to communicate with the other side of the supply flow path 23; And an orifice flow passage 40 formed inside the valve body 20 to connect the regeneration flow passage 30 and the tank passage 22, wherein the spool 21 is connected to the first port 24. When the supply flow path 23 is converted to a position where the communication flows, the second port 25 communicates with the regeneration flow path 30 and flows into the valve body 20 through the second port 25. A hydraulic oil is supplied to the first port 24 through the regeneration flow path 30 and the supply flow path 23, and a part of the hydraulic oil introduced into the regeneration flow path 30 passes through the orifice flow path 40. It is discharged to the tank passage 22.

According to one embodiment of the invention, the tank passage 22 is formed in the longitudinal direction of the spool 21, the orifice flow path 40 is the tank passage 22 from the lower surface of the valve body 20 Through the hole to the regeneration passage 30 is formed.

On the other hand, the regeneration valve assembly is inserted in the mounting hole 51 formed from the upper surface of the valve body 20 to the regeneration flow path 30 from the upper surface of the valve body 20 check installed in the regeneration flow path 30 The valve 50 may further include.

According to the problem solving means described above, since the orifice flow path directly connects the regeneration flow path and the tank passage, it is possible to omit the groove bottom and the flow path in the past, thereby eliminating the machining process and improving productivity. have.

In addition, since the orifice flow path is formed inside the valve body, an airtight ring for sealing with an adjacent valve assembly can be omitted, thereby reducing the number of parts, simplifying the assembly process, and leaking hydraulic fluid. It can be prevented beforehand.

In particular, by forming the orifice flow path by hole processing from the lower surface of the valve body through the tank passage formed in the longitudinal direction of the spool in the lower portion of the spool, the orifice flow path can be easily processed, and the productivity can be further improved.

On the other hand, by attaching a check valve installed in the regeneration flow path to a mounting hole machined from the upper surface of the valve body, in the event of a failure of the check valve, the check valve can be replaced and serviced without removing the valve assembly, thereby improving serviceability. You can.

Hereinafter, a regeneration valve assembly of a construction machine according to an embodiment of the present invention will be described in detail.

2 and 3, the regeneration valve assembly of a construction machine according to an embodiment of the present invention includes a valve body 20, a regeneration flow path 30, an orifice flow path 40, and a check valve 50. It includes.

On the upper surface of the valve body 20, a first port 24 communicating with the first chamber 11 of the cylinder 10, and a second port 25 communicating with the second chamber 12 of the cylinder 10. ) Is formed. In addition, the valve body 20 is provided with a spool 21 for adjusting the flow direction and the flow rate of the working oil flowing along the first and second ports 24 and 25 in the left and right directions. A tank passage 22 for discharging the hydraulic oil to the drain tank is formed in the lower portion of the spool 21 in the longitudinal direction of the spool 21, and the hydraulic oil is provided in the upper portion of the spool 21 to the first and second ports. The supply flow path 23 for supplying to the 24 and 25 is formed.

With this structure, the spool 21 is moved in the left or right direction so that any one of the first and second ports 24 and 25 communicates with the tank passage 22, and the other is It is in communication with the supply passage 23.

Meanwhile, a parallel feeder 26 is formed between the supply flow passage 23 and the spool 21, and a load check 27 is installed between the parallel feeder 26 and the supply flow passage 23. A neutral flow passage 28 called a center bypass passage is formed below the supply flow passage 23. The neutral flow path 28 is a flow path through which hydraulic oil discharged from the pump passes while the work machine is not driven, and communicates with the parallel feeder 26. Therefore, when the neutral flow path 28 is blocked by the spool 21, the hydraulic oil of the pump is supplied to the parallel feeder 26, thereby increasing the pressure of the parallel feeder 26. When the pressure of the parallel feeder 26 rises, the parallel feeder 26 and the supply flow path 23 communicate with each other while the load check 27 is converted upward.

The spool 21 is formed with a first annular groove portion 21a and a second annular groove portion 21b. The first annular groove portion 21a functions to selectively communicate the supply passage 23 and the first port 24 according to the position of the spool 21, and the second annular groove portion 21b is a spool. It functions to selectively communicate the supply flow passage 23 and the second port 25 in accordance with the position of 21.

The regeneration flow path 30 is disposed on the right side of the valve body 20 and is disposed above the spool 21. The regeneration flow path 30 is connected to the supply flow path 23 to provide a part of the working oil discharged through the second port 25 to the first port 24 through the supply flow path 23. Do it. This can reduce the flow rate of the hydraulic oil discharged from the pump it is possible to save energy. For example, the arm cylinder 10 has a high pressure is formed in the load chamber 12 and the low pressure is formed in the head chamber 11 by the weight of the arm and the bucket when the arm is lowered. Therefore, while the flow rate of the working oil discharged from the rod chamber 12 is suddenly increased, the flow rate supplied to the head chamber 11 is insufficient. In order to solve this problem, the flow rate discharged from the rod chamber 12 through the orifice flow passage 40 to the tank passage 22 is reduced, and the flow rate of the reduced hydraulic oil is supplied to the head chamber 11 to regenerate the flow rate. Hereinafter, the head chamber 11 is referred to as a first chamber 11 and the load chamber 12 is referred to as a second chamber 12.

Although the arm cylinder 10 is illustrated in the present embodiment, the boom cylinder also reproduces the flow rate in the same principle, and the idea of the present invention can be equally applied to the boom cylinder. However, in the case of the boom cylinder, the first chamber 11 will be a load chamber and the second chamber 12 will be a head chamber.

As described above, the orifice flow passage 40 is to reduce the flow rate of the hydraulic oil discharged from the second chamber 12 to the tank passage 22 and to supply the flow rate to the first chamber 11. The orifice flow path 40 is formed inside the valve body 20. More specifically, the orifice flow path 40 is formed by processing a hole from the lower surface of the valve body 20 through the tank passage 22. And the processing hole 41 formed in the lower surface of the valve body 20 is cut off from the outside by the plug 42. Thus, by forming the orifice flow path 40 directly inside the valve body 20, the manufacturing process is greatly simplified as well as the conventional way in which the flow path is formed, as compared with the method of mounting the bolt with the flow path formed in the mounting hole. Orifice bolts can be omitted, so the number of parts can be reduced. On the other hand, by directly connecting the orifice flow path 40 to the tank passage 22, it is possible to omit the processing of the groove bottom or the distribution path in the past, thereby simplifying the manufacturing process and maintaining the groove bottom and airtight It is possible to prevent the leakage of the hydraulic fluid due to the hardening of the member, such as the airtight ring for the assembly or assembly error.

The check valve 50 is for preventing the hydraulic oil of the supply flow path 23 from flowing back to the regeneration flow path 30. The check valve 50 is inserted from the upper surface of the valve body 20 into the mounting hole 51 formed from the upper surface of the valve body 20 to the regeneration flow path 30 and installed in the regeneration flow path 30. . In this way, the check valve 50 is installed on the upper surface of the valve body 20, so that the check valve 50 can be maintained and replaced without removing the valve assembly from the construction machine, thereby improving maintenance.

Hereinafter, the operation of controlling the flow direction of the hydraulic oil by the regeneration valve assembly having the configuration as described above will be described.

4A is a view schematically showing a state in which the spool 21 is moved so that hydraulic oil is supplied to the second chamber 12. Referring to FIG. 4A, a high pressure is formed in the parallel feeder 26 while the neutral flow path 28 is blocked, thereby converting the load check 27 upward. As a result, the hydraulic oil supplied through the parallel feeder 26 sequentially passes through the supply flow passage 23, the second annular groove portion 21b, and the second port 25 to the second chamber 12 of the cylinder 10. Supplied. On the other hand, the hydraulic oil of the first chamber 11 is sequentially drained through the first port 24, the first annular groove portion 21a and the tank passage 22.

4B schematically shows a state in which the spool 21 is moved so that hydraulic oil is supplied to the first chamber 11, in which flow rate regeneration occurs.

Referring to FIG. 4B, the hydraulic oil supplied through the parallel feeder 26 sequentially passes through the supply passage 23, the first annular groove 21a, and the first port 24, and is supplied to the first chamber 11. do. On the other hand, the hydraulic fluid of the second chamber 12 flows through the second port 25 and the second annular groove 21b, and a part of the hydraulic oil passing through the second annular groove 21b is the orifice flow path 40. Through the tank passage 22. In addition, the remaining portion of the hydraulic oil passing through the second annular groove portion 21b flows through the regeneration flow path 30, converts the check valve 50 upward, and is supplied to the supply flow path 23. The regeneration hydraulic oil supplied to the supply flow passage 23 is supplied to the first chamber 11 through the first annular groove portion 21a and the first port 24.

Although the present invention has been described in detail only with respect to the specific embodiments described, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and such modifications and modifications belong to the appended claims. .

1 is a cross-sectional view schematically showing a conventional regeneration valve assembly;

2 is a plan view schematically showing a regeneration valve assembly according to an embodiment of the present invention;

3 is a cross-sectional view taken along line III-III of FIG. 2;

4A and 4B are cross-sectional views illustrating that the flow direction of the hydraulic oil is controlled by the regeneration valve assembly of FIG. 2.

DESCRIPTION OF THE REFERENCE NUMERALS OF THE DRAWINGS

10; Cylinder 11; First chamber

12; Second chamber 20; Valve body

21; Spool 22; Tank passage

23; Supply flow paths 24 and 25; First and second port

30; Regeneration euro 40; Orifice Euro

50; Check valve

Claims (3)

The spool 21 is movably installed, a tank passage 22 is formed below the spool 21, a supply flow path 23 is formed above the spool 21, and the cylinder 10 A first port 24 is formed in communication with the first chamber 11 and selectively in communication with one side of the supply passage 23 according to the position of the spool 21, and the second chamber of the cylinder 10 is formed. A valve body (20) in communication with (12) and having a second port (25) formed in communication with the other side of the supply flow path (23) in accordance with the position of the spool (21); A regeneration flow path 30 disposed above the spool 21 and formed in the valve body 20 to communicate with the other side of the supply flow path 23; And An orifice flow passage 40 formed in the valve body 20 to communicate the regeneration flow passage 30 with the tank passage 22, When the spool 21 is converted to a position where the first port 24 and the supply flow passage 23 communicate with each other, the second port 25 communicates with the regeneration flow passage 30 and the second port The hydraulic oil introduced into the valve body 20 through 25 is supplied to the first port 24 through the regeneration flow path 30 and the supply flow path 23, and also flows into the regeneration flow path 30. A part of the operating oil is discharged to the tank passage (22) through the orifice flow passage (40). The method of claim 1, The tank passage 22 is formed in the longitudinal direction of the spool 21, The orifice flow path (40) is a regeneration valve assembly of a construction machine, characterized in that formed by hole processing from the lower surface of the valve body (20) to the regeneration flow path (30) through the tank passage (22). The method of claim 1, And a check valve 50 inserted into the regeneration flow path 30 by being inserted from the top surface of the valve body 20 into a mounting hole 51 formed from the top surface of the valve body 20 to the regeneration flow path 30. Regeneration valve assembly of a construction machine, characterized in that.

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