KR100915614B1 - Central block for providing and controlling a liquidity to a application device using outer spool guide - Google Patents

Abstract

A central block for providing and controlling fluid pressure to an application device is provided to make installation and maintenance easy by automatically defining the insertion depth of the outer spool guide into the spool assembly hole. A central block for providing and controlling fluid pressure to an application device comprises a body and a spool assembly(800). The spool assembly comprises an outside spool guide(600) of cylindrical shape and an inner spool(500) of cylindrical shape. The outside spool guide is inserted into a spool assembly hole(110), and is composed of through holes and barrier walls protruded from the outside surface toward the inside surface of the spool assembly hole. The inner spool is inserted in the outside spool guide, and is composed of through holes and spool barrier walls protruded toward the inside surface of the outer spool guide.

Description

Central block for providing and controlling a liquidity to a application device using outer spool guide}

The present invention relates to a central box for adjusting the flow rate and hydraulic pressure to the application, and more particularly, to a central box that facilitates replacement and maintenance of parts by additionally equipped with an external spool guide.

Applications using hydraulics, such as agricultural machinery and presses, require a certain pressure or more. In order to provide this hydraulic pressure, the pump is used to regulate the hydraulic pressure exerted externally by the application by drawing a constant or linear flow into or out of the tank to the application. A central block is located between the pump and the application to control this hydraulic pressure.

1 is a view showing a conventional central block, Figures 2a and 2b is a view showing the principle of operation of the spool in the conventional central block.

The conventional central block 1 comprises a body 10 and a spool 50. Body 10 provides a flow path between pump 30 and application 20. The body 10 is formed with a pressure path 15, a pressure reduction path 14, a spool hole 11, a pump path 18 and a drain path 13. The flow rate introduced into the spool hole 11 through the pump 30 and the pump path 918 is routed by the spool 50. At the time of pressurization to the application device 20, the spool 50 pressurizes the hydraulic pressure to the pressurization path 15. The flow rate remaining without being pressurized is introduced into the tank 40 through the drain path 13 and the drain pipe 41.

2A and 2B show the principle in which the spool 50 operates.

The spool 50 inserted into the spool hole 11 is a cylindrical member in which through holes 51a and 51b and partition walls 514 and 516 are formed. The flow rate introduced through the pump path 18 is introduced into the pressure path 15 through the spaces separated by the partitions 514 and 516 and the through holes 51a and 51b. In FIG. 2A, since the flow rate drawn from the pump 18 is blocked by the partitions 514 and 516, the flow rate is not drawn into the pressure path 15. However, when the spool 50 moves in FIG. 2B, the flow rate introduced through the pump path 18 may flow in the order of the lower passage hole 51a-> the upper passage hole 51b-> the pressing passage 15. . At this time, the outflow to the outside by the partitions 52 and 54 is prohibited, and is discharged only to the pressure path 15. In addition, the flow rate exceeding the pressure drawn into the pump path 18 is discharged to the drain path 13 and drawn back into the tank.

However, according to the central block having the structure of the conventional spool, since the spool determines the flow path while sliding in the spool hole formed in the central block, the inner surface s of the spool hole is worn out due to the repeated operation of the spool. It is easy to generate play between the spool and the spool hole, and in this case, a problem arises in that the entire body 10 of the central block needs to be replaced.

In addition, changing the spool hole to a high wear-resistant material in order to reduce such wear causes a problem of an increase in material cost because the entire central block must be used with a high wear-resistant material.

Also, in general, the central block is intricately connected to pumps, tanks, and other pipes. In the case of wear of the spool hole, all of these connections must be disassembled in order to replace the entire central block. This is much more complicated and the cost of doing so increases.

Accordingly, the present invention has been made to solve this problem, and an object of the present invention is to provide a central block in which the maintenance of the central block is easy and the material cost is reduced when the spool hole is worn.

In order to solve the above problems, the present invention, in transferring the flow rate stored in the tank 40 to the application device 20 using the pump 30, between the pump 30 and the application device 20 In the central block 800 to control the path and the hydraulic pressure of the flow rate provided to the application device, the central block 100, the flow rate is passed between the application device and the pump and the tank A body 100 in which a flow path is formed; And a spool assembly 800 inserted into the body 100 to adjust a flow rate flowing from the pump to the application device, wherein the body 100 has a pressure path of the flow rate to the application device 20. Phosphorus application pressure passages 15a and 15b; An application decompression passage 14 which is a decompression path of the flow rate to the application device 20; A pump flow path 18 which is a path through which the flow rate flows from the pump 30; A spool assembly hole 110 disposed between the pump flow path and the application pressure flow passage, into which the spool assembly 800 is inserted; A first drain passage 13 connected to the tank 40 from the spool assembly hole 110; And second drain passages 12a and 12b connected to the tank 40 from the pump passage 18, wherein the spool assembly 800 is a cylindrical member inserted into the spool assembly hole 110. As the outer spool guide including a hole-shaped outer through hole (621, 623, 625) on the outer surface of the cylindrical member and an outer guide partition wall (612, 614, 616) protruding in the direction of the inner circumferential surface of the spool assembly hole 110 from the outer peripheral surface of the cylindrical member ( 600); And a cylindrical member inserted into the outer spool guide 600 and closed at one end thereof, from the inner circumferential surface of the cylindrical member through a hole-shaped inner through hole 510 and an outer circumferential surface of the cylindrical member. The inner spool 500 includes an inner spool partition wall 512, 514, 516 protruding toward the inner circumferential surface of the outer spool 500, the inner spool 500 is generated by sliding the inside of the outer spool guide 600 ( 621, 23, 625, the outer guide partitions 614, 616, the inner spool partitions 514, 516 and the combination of the position of the inner passage hole 510 is characterized in that the flow path flowing into the application device is determined.

In one embodiment, the body 100 is located on the application pressure passages (15a, 15b), the pilot check valve (Pilot Check Valve, PCV) that is a valve for maintaining the hydraulic pressure pressurized by the application device is inserted A pilot check valve hole 17; And a relief valve hole 16 positioned between the pump flow path and the tank and into which a relief valve (RV), which is a valve for preventing excessive pressurization of the flow rate to the application device, is inserted. It is characterized by.

In one embodiment, the spool assembly hole 110 is formed so that the inlet portion of the body 100 stepped, the end of the outer spool guide 600 stepped in a shape corresponding to the inlet portion of the stepped body It is formed to be, characterized in that the depth to which the outer spool guide 600 is inserted is limited.

In one embodiment, the spool assembly hole 110 is formed to step so that the inner diameter becomes wider as it proceeds to the inlet portion of the body, the outer partitions 115, 116, 117 of the outer spool guide 600 is formed to step By forming stepped in a shape corresponding to the inner diameter of the assembly hole 110, the space formed by the flow path selected by the movement of the inner spool 500 is defined by the stepped outer partition wall (115, 116, 117) It is characterized by.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

3 is a view showing a central block 900 according to the present invention, Figures 4a and 4b is a view showing the structure and operation of the spool assembly 800 of the present invention.

The central block 900 according to the present invention includes a body 100 and a spool assembly 800.

As described above, the central block 900 transfers the flow rate stored in the tank 40 to the application device 20 using the pump 30, and between the pump 30 and the application device 20. Position to control the flow path and hydraulic pressure provided to the application.

The body 100 has a flow path through which a flow rate passes between the application device 20, the pump 30, and the tank 40. The body 100 is provided from the application pressure reducing passages 14a and 15b which are the pressure passages of the flow rates to the application device 20, the application pressure reduction passage 14 and the pump 30, which are pressure reducing paths of the flow rates to the application device 20. A pump flow path (18), a path through which a flow rate flows, is located between the pump flow path and the application pressure flow path, and the spool assembly hole (110) into which the spool assembly 800 is inserted, from the spool assembly hole (110) to the tank (40). And a first drain passage 13a connected thereto, and second drain passages 12a and 12b connected to the tank 40 from the pump passage 18.

In Figures 4a and 4b, the spool assembly 800 is inserted into the body 100 to adjust the flow rate flowing from the pump to the application, the spool assembly 800 is the outer spool guide 600 and the inner spool ( 500).

The outer spool guide 600 is a cylindrical member inserted into the spool assembly hole 110. The outer spool guide 600 is formed on the outer surface of the cylindrical member from the outer circumferential surface of the cylindrical outer member through holes 621, 623, 625 and the cylindrical member of the spool assembly hole 110. Outer guide partition walls 612, 614, 616 protruding in the inner circumferential surface direction are formed.

The inner spool 500 is inserted into the outer spool guide 600 and is a cylindrical member whose one end is blocked. The inner spool 500 includes a hole-shaped inner through hole 510 formed in the outer surface of the cylindrical member and inner spool partition walls 512, 514, 516 protruding from the outer circumferential surface of the cylindrical member in the direction of the inner circumferential surface of the outer spool guide 600. .

4A and 4B, the operation of the spool assembly will be described.

First, the outer spool guide 600 is inserted into the spool assembly hole 110. At this time, the first outer through hole 621 of the outer through holes (621, 623, 625) formed in the outer spool guide is connected to the application pressure passage 15, the second outer through hole 623 and the application pressure passage (15) The third external through hole 625 is positioned at a position connected to the application pressure reducing passage 14 at a position not connected to any flow path of the application pressure reducing passage 14 and at the same time as the pump passage 18. The outer spool guide 600 is inserted into the spool assembly hole 110. Here, 'connected position' means that the space is separated by the outer guide partitions (612, 614, 616) to communicate with each other.

In FIG. 4A, the inner spool 500 is inserted into the outer spool guide 600. In FIG. 4A, the flow rate introduced into the pump path 18 is sequentially introduced into the outer passage hole 623-> the inner passage hole 510a, but the application pressure flow path 15 is formed by the position combination of the inner spool partition wall and the outer spool partition wall. Not meet). Therefore, the introduced flow rate is discharged to the drain flow path 13.

It is different in FIG. 4B. Because, the flow rate introduced into the pump path 18 due to the sliding of the inner spool 500 is the outer passage hole (623)-> inner passage hole (510a)-> inner passage hole (510b)-> outer passage hole (621) It may be introduced into the pressure path (15) through). In other words, in the spool assembly of the present invention, the inner spool 500 is formed by sliding in the outer spool guide 600, the outer through-holes (621, 23, 625), the outer guide partitions (612, 614, 616), the inner spool partitions (514, 516) and the inner The flow path introduced into the application device 20 is determined by the combination of the positions of the through holes 510.

According to the present invention, since the inner spool 500 is inserted into the outer spool guide 600 while the outer spool guide 600 is inserted into the spool assembly hole 110, the spool assembly hole 110 is not worn. As a result, there is no need to replace the central block due to abrasion during repeated operation of the inner spool. That is, since only the external spool guide 600 needs to be replaced instead of the entire central block, component replacement cost is reduced. In general, since the part price of the central block is 20 to 50 times higher than the part price of the external spool guide, the effect of reducing the part price is very large.

In addition, in particular, the central block has a complicated connection between the pump, the tank and the external piping. Since the central block does not need to be replaced, it is very easy to replace parts, that is, maintenance work. Facilitating maintenance work results in a reduction in the cost of manpower spent on maintenance work, which in turn can lead to a reduction in maintenance costs.

In addition, according to the invention, the cost is reduced when changing the material of the part to reduce wear. This is because in the present invention, instead of changing the entire material of the central block, only the material of the outer spool guide needs to be changed. In other words, according to the present invention, the cost required to increase the durability according to the application of the central block is reduced.

In a variant embodiment of the invention, the body 100 further comprises a pilot check valve hole 17 and a relief valve hole 16.

The pilot check valve hole 17 is a hole-shaped member located on the application pressure passages 15a and 15b, into which a pilot check valve (PCV), which is a valve for maintaining hydraulic pressure pressurized by an application device, is inserted. It is a hole-shaped member. The pilot check valve is a valve that pressurizes separately from the outside to prevent a phenomenon in which the hydraulic pressure pressurized by the application device is minutely reduced by leakage, and thus the description thereof is omitted since the operation of the valve itself is well known to those skilled in the art. .

In addition, the relief valve hole 16 is a hole-shaped member located between the pump flow path and the tank, into which a relief valve (RV), which is a valve for preventing excessive pressurization of the flow rate to the application device, is inserted. It is a hole-shaped member. The operation of the relief valve itself is also well known in the art.

According to this embodiment, the first pilot check valve is formed by arranging the space in which the pilot check valve and the relief valve are formed in the central block, in particular, between the application pressure flow path and the flow path between the pump flow path and the tank. And the installation of the relief valve is easy, and secondly, it is possible to reduce the size of the third central block product without the need for additional equipment for the installation of such a valve.

In a modified embodiment of the present invention, the spool assembly hole 110 is formed so that the inlet portion of the body 100 stepped, the end of the outer spool guide 600 in a shape corresponding to the inlet portion of the stepped body formed It is formed to be stepped, characterized in that the depth to which the outer spool guide 600 is inserted is limited. In FIG. 3, the spool assembly hole 110 has a structure in which the inlet portion 114 is stepped, and the end 601 of the outer spool guide 600 is also stepped so as to correspond to the inlet portion 114.

According to this embodiment, the insertion depth of the external spool guide 600 inserted into the spool assembly hole 110 is stopped (limited) by the stepped structure, whereby the insertion position of the external spool guide can be fixed. That is, according to the present embodiment, the user only needs to insert the external spool guide 600 into the spool assembly hole 110 to the end by a predetermined depth. It is easy to install and replace because there is no need to consider the relative position of external through hole. In particular, the present invention further increases this effect because the combination of the positions of the outer passage holes (621, 23, 625), the outer guide partitions (612, 614, 616), the inner spool bulkheads (514, 516), and the inner passage hole (510) is important for determining the flow path. do.

5 is a diagram illustrating a central block according to another embodiment of the present invention.

In a modified embodiment of the present invention, the spool assembly hole 110 is formed so as to step so that the inner diameter becomes wider as it proceeds to the inlet portion of the body, the outer partition walls 115, 116, 117 of the outer spool guide 600 so as to step Since the formed spool assembly hole 110 is formed to be stepped in a shape corresponding to the inner diameter of the formed spool assembly hole, the space formed by the flow path selected by the movement of the inner spool 500 is formed by the stepped outer partition walls 115, 116 and 117. It is characterized by being limited.

In Figure 5, the spool assembly hole 110 is stepped so that the inner diameter is wider as it proceeds to the inlet portion of the body. That is, the spool assembly hole 110 has a first step 115, a second step 116, and a third step 117 from the inside, and the outer partitions 612, 614, and 616 of the outer spool guide 600 have the first to It protrudes by a height corresponding to the fourth step.

This step provides a vertical plane, which is easier to achieve a closed structure. That is, according to the present embodiment, the space formed by the flow path selected by the movement of the inner spool 500 is defined by the vertical structure by the stepped outer partitions 115, 116, and 117, so that the outer partition of the outer spool guide ( 612, 614, 616 and the clearance between the inner surface of the spool assembly hole 110 can be reduced and more closely. That is, if the play between the spool assembly hole 110 and the outer bulkheads (612, 614, 616) occurs by repeated use, the user further pushes the outer spool guide in the horizontal direction to bring it into close contact or the vertical surface of the step (not the horizontal plane). Increased play can be eliminated by inserting sealants, such as O-rings. This embodiment solves the problem caused by the fact that it is not possible to increase the diameter of the outer partition to reduce the play when the play occurs by repeated use.

6A to 6D are photographs showing the actual product of the present invention.

6A is a cross-sectional view of a central block in accordance with the present invention. It can be seen that the upper, lower, and side surfaces are formed with the entrances of the various flow paths and holes shown in FIG. 3 (the central block has several flow paths or holes formed in a solid structure inside).

6B is a photograph showing a state in which the spool assembly is inserted into the spool assembly hole. The spool assembly 800 is inserted into the spool assembly hole 110. A stepped shape can be seen as the inner diameter of the spool assembly hole increases toward the inlet.

6C illustrates the spool assembly 800. A step 118 is formed at the end of the spool assembly. As described in the modified embodiment of Figure 3, to limit the depth to which the spool assembly is inserted.

6d is an exploded view of the spool assembly, and shows the outer spool guide 600 and the inner spool 500. Referring to FIG. 6B, it can be seen that the external spool guide 600 is inserted into the spool assembly hole 110 and the inner spool 500 is inserted into the external spool guide 600. Due to this structure, it is necessary to replace only the spool assembly 800 or even the external spool guide 600 without having to replace the entire central block 100 when worn due to repetitive action. This is easy.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

As described above, according to the present invention, only when the spool assembly or the external spool guide need to be replaced without the need to replace the entire central block when play occurs due to the repeated operation of the central block by the structure of the added external spool guide. Therefore, the maintenance cost of the central block is reduced.

In addition, according to the present invention, the central block is complicatedly connected to the pump, the tank and the external pipe, there is no need to replace the central block, it is very easy to replace parts, that is, maintenance work.

In addition, according to the invention, the cost is reduced when changing the material of the part to reduce wear. Instead of changing the entire material of the central block, you only need to change the material of the outer spool guide.

In addition, according to the present invention, since the insertion depth of the spool assembly hole is automatically limited by the stepped structure of the inlet end of the spool assembly hole, the installation and maintenance work of the user is facilitated.

In addition, according to the present invention, a stepped structure between the spool assembly hole and the outer spool guide enables a structure of vertical contact between the inner surface of the spool assembly hole and the outer partition of the outer spool guide, thereby further increasing the adhesion. There are a variety of ways to increase the adhesion.

1 is a view showing a conventional central block.

2A and 2B are diagrams illustrating the principle of operation of a spool in a conventional central block.

3 is a diagram illustrating a central block 900 according to the present invention.

4A and 4B illustrate the structure and operation of the spool assembly 800 of the present invention.

5 is a diagram illustrating a central block according to another embodiment of the present invention.

6A to 6D are photographs showing the actual product of the present invention.

Claims (4)

In the system for transmitting the flow rate stored in the tank 40 to the application device 20 using the pump 30, the flow path provided between the pump 30 and the application device 20 provided to the application device In the central block 900 to select and adjust the hydraulic pressure, The central block 900 may include a body 100 having a flow path through which the flow rate passes between the application device, the pump, and the tank; And a spool assembly 800 inserted into the body 100 to adjust a flow rate flowing from the pump to the application device. The body 100, Application pressure passages 15a and 15b, which are pressure passages of the flow rate to the application device 20; An application decompression passage 14 which is a decompression path of the flow rate to the application device 20; A pump flow path 18 which is a path through which the flow rate flows from the pump 30; A spool assembly hole 110 disposed between the pump flow path and the application pressure flow passage, into which the spool assembly 800 is inserted; A first drain passage 13 connected to the tank 40 from the spool assembly hole 110; And A second drain passage (12a, 12b) connected to the tank (40) from the pump passage (18), The spool assembly 800, A cylindrical outer spool guide 600 is inserted into the spool assembly hole 110, the outer surface of the outer spool guide 600 from the outer circumferential surface of the hole-shaped outer through holes (621, 623, 625) and the outer spool guide 600 An outer spool guide 600 including an outer guide partition wall 612, 614, 616 protruding in an inner circumferential direction of the spool assembly hole 110; And A cylindrical inner spool 500 inserted into the outer spool guide 600 and closed at one end thereof, and includes a hole-shaped inner through hole 510 and an inner spool 500 formed on an outer surface of the inner spool 500. An inner spool 500 including inner spool bulkheads 512, 514, 516 protruding from the outer circumferential surface in the direction of the inner circumferential surface of the outer spool guide 600, The inner spool 500 of the outer through-holes (621, 623, 625), the outer guide partitions (614, 616), the inner spool partitions (514, 516) and the inner through hole 510 generated by sliding in the interior of the outer spool guide (600) Central block characterized in that the flow path to the application device is determined by the combination of positions. The method of claim 1, wherein the body 100, A pilot check valve hole 17 located on the application pressure passages 15a and 15b and into which a pilot check valve (PCV), which is a valve for maintaining the hydraulic pressure pressurized by the application device, is inserted; And It further comprises a relief valve hole 16 which is located between the pump flow path and the tank, the relief valve (RV) is inserted, which is a valve for preventing excessively pressurized flow to the application device Featuring a central block. According to claim 1, The spool assembly hole 110 is formed so as to step so that the inner diameter of the spool assembly hole is wider as it proceeds to the inlet portion of the body 100, The end of the outer spool guide 600 is formed so as to step in a shape corresponding to the inner diameter of the spool assembly hole, the central block, characterized in that the depth to which the outer spool guide 600 is inserted. According to claim 3, The spool assembly hole 110 is formed so as to step so that the inner diameter of the spool assembly hole 100 is wider as it proceeds to the inlet portion of the body 100, The outer partition walls 115, 116, 117 of the outer spool guide 600 are formed to step in a shape corresponding to the inner diameter of the spool assembly hole 110, such that a path of a flow rate selected by the movement of the inner spool 500 is formed. The central block is characterized in that the space to be formed is defined by the outer partition wall (115, 116, 117) of the outer spool guide (600).