KR20060003680A - A directional select valve with regenerative apparatus - Google Patents

Abstract

The present invention does not need to include a stopper for setting the left movement limit of the regeneration valve body in the regeneration passage by installing a retainer bolt on the regeneration valve side for performing the regeneration function of the oil during the lowering operation of the arm. It is about. The present invention comprises a main body having a spool moving hole formed therein and a spool sliding inside the spool moving hole, and a regeneration passage formed in the longitudinal direction is formed in the spool, and a regeneration path is left and right inside the regeneration path. A reversing valve body having a regeneration valve body which is inserted into a regeneration valve which can move to a cylinder and regenerates a part of oil on the cylinder rod side to the cylinder head side when the arm descends, wherein the spool at the inlet of the regeneration passage is A retainer bolt for setting the left shift limit is coupled, and a stopper for setting the left shift limit of the regeneration valve body is integrally formed at the tip of the retainer bolt. According to the configuration of the present invention, there is no need to provide a stopper separately, the number of parts can be reduced, the process of the regeneration passage of the regeneration valve and the coupling process of the retainer bolt can be performed continuously to shorten the number of steps.

Directional Valve, Spool, Retainer Bolt, Regeneration Valve, Pilot Port

Description

A directional select valve with regenerative apparatus

1 is a side cross-sectional view of a directional valve having a regeneration function according to the prior art.

Figure 2 is a side sectional view of a directional valve having a regenerative function according to a preferred embodiment of the present invention.

Figure 3 is a side cross-sectional view showing the configuration of the retainer bolt according to an embodiment of the present invention.

** Description of Codes for Major Configurations of Drawings **

100: direction change valve 102: main body

110: spool moving hole 120: unload passage

130: main supply passage 132: first supply passage

134: second supply passage 142: first load passage

144: second load passage 146: first tank passage

148: second tank passage 150: spool

160: first annular groove 162: second annular groove

164: third annular groove 166: fourth annular groove

170,172: pilot port 174: switching spring                 

176: retainer bolt 176a: male thread

176b: step 176c: stopper

180: regeneration passage 182: concourse

182a: female thread 184: first access passage

186: second connection passage 190: regeneration valve body

192: left pressure chamber 194: right pressure chamber

196: Replay Spring

The present invention relates to a directional valve having a regeneration function, and more particularly, to a directional valve to reduce the number of parts and the number of processes by having a regeneration structure on the side of the retaining bolt of the spool.

Figure 1 is a side cross-sectional view showing the configuration of a conventional direction switching valve having a regenerative function. As shown in FIG. 1, the direction switching valve 1 has a configuration in which the spool 70 is inserted by drilling the spool hole 20 in the main body 10. The main body has an unload passage 30 communicating with the spool hole 20, a supply passage 40, 42, a first load passage 50, a second load passage 52, and a tank passage 60, 62. Is installed.

In the unload passage 30, enlarged portions 32, 34, and 32 having annular grooves are formed in the middle portion of the spool hole 20 so that the spool hole 20 is enlarged. First and second annular grooves 72 and 74 are formed so that the enlarged portions 32, 34 and 32 are connected to the discharge passage connected to the tank and the pump passage connected to the pump, respectively, although not shown in the drawing.

The supply passages 40 and 42 are composed of a first supply passage 40 and a second supply passage 42 branched from the main supply passage 44 connected to the pump. The rod check plate 46 is provided just before branching to the supply passages 40 and 42.

The first supply passage 40 communicates with the spool hole 20 at the left side of the unload passage 30 and the second supply passage 42 at the right side of the unload passage 30, respectively. The first load passage 50 is located on the left side of the first supply passage 40, and the second load passage 52 is located on the right side of the second supply passage 42. The first tank passage 60 is located on the left side of the first load passage 50, and the second tank passage 62 is located on the right side of the second load passage 52.

In addition to the first and second annular grooves 72 and 74 which form the unload passage 30, the spool 70 has a third annular groove at a position corresponding to one side of the first load passage 50 in a neutral state. 76 is formed, and the fourth annular groove 78 is formed at a position corresponding to one side of the second load passage 52, respectively.

In addition, hydraulic pilot chambers are provided at both ends of the spool 70, and reference numerals 80 and 82 denote pilot ports, and the pilot pressure oil can be supplied to the pilot chamber.

On the left side of the spool 70, a switching spring 84 for elastically biasing the spool 70 to the right side is installed, and inside the switching spring 84, the spool 70 is further moved when the left side of the spool 70 moves. The retainer bolts 86 are installed so as not to move leftward. And the cap 88 which protects the pilot port 80 etc. is attached to the outer side of the retainer bolt 86. As shown in FIG.

The right side of the spool 70 is provided with a regeneration valve (90). The regeneration valve 90 is formed with a regeneration passage 90a having a regeneration plate (not shown). The regeneration passage 90a includes a central hole 92 bored in the longitudinal direction of the spool 70, and first and second connection passages 94 and 96 penetrated in the radial direction on the outer peripheral wall thereof. It is configured to include.

The central hole 92 extends from the inner side of the second annular groove 74 to the right end with respect to the drawing, and the spool type regeneration valve body which is movable on one side inside the central hole 92 ( 98 is inserted, and the stopper 99 is fixed to the other side inside the central hole (98). An o-ring 99a is installed between the regeneration valve 90 and the stopper 99 to prevent leakage of regeneration oil.

In the neutral state of the spool 70, a third connection passage 93 in the radial direction is provided on the right outer circumferential wall of the fourth annular groove 78 so as to be located between the second load passage 52 and the second tank passage 62. ) Is formed to penetrate through.

In the state in which the regeneration valve body 98 is accommodated in the center hole 90, a left pressure chamber 97a and a right pressure chamber 97b are formed on the left side of the regeneration valve body 98. The left pressure chamber 97a is in constant communication with the second annular groove 74 through the fourth connecting passage 95. Thus, the regeneration valve body 98 is moved left and right by the pressure difference between the left and right pressure chambers (97a, 97b).

According to the conventional directional valve 1 as described above, the head side 4 is connected to the first load passage 50 and the rod side 6 is connected to the second load passage 52. By the switching operation, the arm (not shown) can be moved up and down, and when the lowering, the above regeneration function is exerted.

However, the above-described directional valve having a regeneration function of the prior art has the following problems.

Looking at the configuration of the spool according to the prior art, the retainer bolt 86 is screwed to the left side of the spool 70, the regeneration valve 90 is provided with a regeneration passage 90a on the right side of the spool 70 It is installed. Therefore, the left side of the spool 70 is to be screwed to the retainer bolt 86, and then the turn valve 1 is rotated 180 degrees, and then the regeneration passage 90a of the spool 70 must be processed. At this time, rotating the body of the direction switching valve (1) as much as 20kg to 50kg is not only a simple task, there is a problem that the number of processes increases, the workability is reduced.

In addition, after the regeneration passage 90a is processed, the regeneration valve body 98 is inserted, and then a stopper 99 for restricting the movement of the regeneration valve body 98 is installed, and regeneration is performed to prevent leakage of regeneration oil. Since the O-ring 99a is installed between the passage 90a and the stopper 99, the number of parts increases.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to change the structure of the retainer bolt is coupled to the left side of the spool and the stopper is installed separately on the right side of the spool It is to provide a directional valve with a regeneration structure that reduces the number of parts and parts.

According to a feature of the present invention for achieving the object as described above, the present invention is composed of a main body formed with a spool moving hole and a spool sliding the inside of the spool moving hole, the inside of the spool perforated in the longitudinal direction A regeneration path is formed, and a regeneration valve body of a spool type for moving the regeneration path left and right is inserted into the regeneration path to regenerate a part of the oil on the cylinder rod side to the cylinder head side when the arm descends. In the reversing valve provided, the retainer bolt is coupled to the inlet of the regeneration passage, and the stopper for integrally setting the left movement limit of the regeneration valve body is integrally formed at the tip of the retainer bolt.

A female thread is formed inside the regeneration passage inlet of the spool, and a male thread is formed outside the stopper rear of the retainer bolt, such that the retainer bolt and the spool are screwed together.

It is preferable that a step is formed at one side of the retainer bolt to be in close contact with the end of the spool to be hermetically sealed.

A plurality of unload passages 120 are formed at a central side of the spool moving hole so that the diameter of the moving holes is enlarged, and the first and second annular grooves are formed at one side of the outer circumferential surface of the spool, respectively, so that the unloading passages are formed. It is connected to the discharge passage connected to the tank and the pump passage connected to the pump corresponding to the two annular groove, respectively, the main supply passage is formed on one side of the main body connected to the pump, the first supply passage to both sides of the main supply passage And the second supply passage are branched, the first supply passage is connected to the spool moving hole at the left side of the unload passage and the right side of the unload passage, respectively, and has a first load at the left side of the first supply passage. The passage is located and the second load passage is located on the right side of the second supply passage, the first tank passage is located on the left side of the first load passage and the second tank passage is on the right side of the second load passage. And a third annular groove is formed at both sides of the first and second annular grooves of the spool to correspond to one side of the first load passage, and the fourth annular groove is positioned at a position corresponding to one side of the second load passage. Pilot ports for supplying pilot pressure oil to pilot chambers are formed at both ends of the spool, respectively, and a switching spring for maintaining the spool in a neutral state when no pressure oil is supplied to the pilot port is installed at one pilot port. do.

The regeneration passage further includes first and second connecting passages radially penetrating the outer peripheral wall thereof.

According to the directional valve having a regeneration function according to the present invention having such a configuration there is an advantage that the number of parts and the number of processes can be shortened.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of a directional valve having a regeneration function according to the present invention having the configuration as described above will be described in detail.

2 is a side cross-sectional view of the configuration of the directional valve according to a preferred embodiment of the present invention, Figure 3 is a side cross-sectional view of the configuration of the retainer bolt according to an embodiment of the present invention.

As shown in FIG. 2, the direction switching valve 100 according to the present invention includes a main body 102 having a spool moving hole 110 formed therein and a spool 150 sliding inside the spool moving hole 110. Consists of. The unload passage 120 is formed at one central side of the spool moving hole 110 to enlarge the diameter of the moving hole.

First and second annular grooves 160 and 162 are formed at one side of the outer circumferential surface of the spool 150, so that the unload passage 120 corresponds to the first and second annular grooves 160 and 162 so as to be connected to the tank. It is connected to a passage (not shown), and is connected to a pump passage (not shown) that connects to the pump.

The first supply passage 132 and the second supply passage 134 branched from the main supply passage 130 are formed on the left and right sides of the main supply passage 130 connected to the pump. The first supply passage 132 is connected to the spool movement hole 110 on the left side of the unload passage 120, and the second supply passage 134 is respectively connected to the spool movement hole (right) of the unload passage 120. 110).

The first load passage 142 is positioned on the left side of the first supply passage 132, and the second load passage 144 is positioned on the right side of the second supply passage 134. The first tank passage 146 is positioned on the left side of the first load passage 142, and the second tank passage 148 is positioned on the right side of the second load passage 144.

In addition to the first and second annular grooves 160 and 162 forming the unload passage 120, the spool 150 has a third annular groove 164 corresponding to one side of the first load passage 142 in a neutral state. The fourth annular groove 166 corresponding to one side of the second load passage 144 is formed, respectively.

In addition, pilot ports 170 and 172 are formed at both ends of the spool 150 to supply pressure oil to the pilot chamber, and when the pressure oil is not supplied to the pilot chamber, the spool (usually by the switching spring 174). 150 is to maintain a neutral state.

The spool 150 includes a central hole 182 drilled in the longitudinal direction of the spool 150 and first and second connection passages 184 and 186 radially penetrating the outer circumferential wall thereof. Passages 180 are formed respectively.

The central hole 182 extends from the inside of the first annular groove 162 to the left end of the central hole 182, and moves the central hole 182 to one side inside the central hole 182. The regeneration valve body 190 of the spool type can be inserted. The regeneration valve 191 composed of the regeneration passage 180 and the regeneration valve body 190 performs a regeneration function of oil.

In the embodiment of the present invention, the regeneration valve 191 is installed on the left side of the direction change valve 100 based on the drawings. That is, the central hole 182 of the regeneration passage 180 is formed on the left side of the spool 150, and the switching spring 174 is installed on the left side of the directional charge valve to maintain the spool 150 in a neutral state. A retainer bolt 176 is installed inside the switching spring 174. A male thread 176a is formed at the front outer side of the retainer bolt 176, and a female thread 182a is formed at an inner inlet of the central hole 182 of the spool 150. And spool 150 are screwed.                     

In addition, since the regeneration oil inside the regeneration valve 191 is sealed by the threaded portion of the retainer bolt 176 and the spool 150, it is not necessary to include a separate oil leakage preventing member such as an O-ring. In other words, according to the embodiment of the present invention, the retainer bolt 176 by forming a step 176b having a predetermined height in the retainer bolt 176 coupled to the end of the spool 150 as shown in FIG. 3. Keeping the coupling of the spool 150 and the airtight, it is to perform the function that the regeneration oil does not leak to the outside by the metal sealing.

The left pressure chamber 192 and the right pressure chamber 194 are formed to the left and right in the state where the regeneration valve body 190 is accommodated inside the central hole 182, and a regeneration spring is formed at the left pressure chamber 192. 196 is provided.

In the embodiment of the present invention, a stopper 176c for setting the left movement limit of the regeneration valve body 190 is integrally formed at the tip of the retainer bolt 176.

Hereinafter, the operation of the direction switching valve with a regeneration function according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

When the hydraulic oil is supplied to the pilot port 170, the spool 150 is moved to the right side by the elastic force of the regeneration spring 196, and the unload passage 120 is blocked so that the second load passage 144 is the fourth annular groove. 166 is connected to the tank passage 148, and at the same time the first supply passage 132 is connected to the first load passage 142 through the third annular groove 164, the rod side 200 ) Is supplied with pressure oil so that the oil is discharged from the head side 202 to lift the arm.                     

When pressure oil is supplied to the head side 202, the oil is discharged from the rod side 200, and as the pressure of the rod side 200 increases, the arm descends and the pressure of the second load passage 144 also increases. Therefore, the oil increases the internal pressure of the right pressure chamber 194 through the first connection passage 184 of the spool 150. When the pressure in the right pressure chamber 194 exceeds the set pressure of the regeneration spring 196 installed in the left pressure chamber 192, the regeneration valve body 190 moves to the left side, and part of the oil does not enter the tank. However, most of the rest is transferred to the first supply passage 132 through the second connection passage 186, so that the oil of the first supply passage 132 passes through the second supply passage 134 to the head side ( Playing back to 202).

When the spool 150 is installed in the spool moving hole 110 of the directional valve 100, the assembly process of the directional valve with a regeneration function according to the present invention is briefly described. The central hole 182 of the regeneration passage 180 is formed, and the male thread 176a is machined outside the entrance of the central hole 182. After inserting and installing the regeneration valve body 190 in the regeneration passage 180, the retainer function of the spool 150 and the retainer bolt 176 serving as the stopper of the regeneration valve body 190 are screwed in the related art. In comparison, the processing and assembly are simplified.

As described above, although a retainer bolt is provided on one pilot port side and a regeneration passage is provided on the other pilot port side spool, a regeneration valve for regenerating oil is usually installed. Regeneration path is formed in the port side spool, and the screw of the retainer bolt which performs the retainer function and the stopper function directly in the regeneration path reduces the number of processes and parts and reduces the number of processes and parts of the regeneration path of the spool. It can be seen that the technical idea is a configuration in which the bolting process is continuously performed. Within the scope of the basic technical spirit of the present invention, many other modifications will be possible to those skilled in the art.

As described above, according to the configuration of the present invention, the following effects can be expected.

By having the regenerated structure on the retainer bolt side, the number of steps is significantly reduced compared to the regenerated structure on the opposite side of the retainer bolt, thereby making it easier to assemble and manufacture the spool. That is, the number of processes can be shortened by continuously performing the process of regeneration passage of the regeneration valve and the process of combining the retainer bolts.

By forming a stopper on one side of the retainer bolt, the retainer bolt simultaneously performs the retainer function and the stopper function, and the number of parts is significantly reduced, thereby reducing the cost.

It does not require a separate O-ring to prevent oil from leaking inside the regeneration path, which shortens the manufacturing process and increases productivity, thereby enabling mass production.

Claims (4)

The main body is formed with a spool moving hole and a spool for sliding the inside of the spool moving hole, and a regenerated passage formed in the longitudinal direction is formed in the spool, and the regenerating passage can be moved left and right in the regenerating passage. In the directional spool valve having a regeneration function of a spool type regeneration valve body is inserted, and regenerates a part of the oil on the cylinder rod side back to the cylinder head side when the arm is lowered, A retainer bolt is coupled to the inlet of the regeneration passage, and a stopper for integrally forming a stopper for setting a left movement limit of the regeneration valve body at the tip of the retainer bolt is integrally formed. The regeneration function according to claim 1, wherein a female thread is formed inside the regeneration passage inlet of the spool, and a male thread is formed outside the stopper rear of the retainer bolt to screw the retainer bolt to the spool. Directional valve with a. The directional valve according to claim 1 or 2, wherein a step is formed on one side of the retainer bolt to be in close contact with the end of the spool and is sealed. According to claim 1 or 2, wherein the central one side of the spool moving hole is formed with a plurality of unload passages 120 to enlarge the diameter of the moving hole, the first and second annular grooves are formed on one side of the outer peripheral surface of the spool, respectively The unloading passage is connected to the discharge passage connected to the tank and the pump passage connected to the pump in correspondence with the first and second annular grooves, and a main supply passage is formed on one side of the main body. The first supply passage and the second supply passage are branched to both sides of the main supply passage, and the first supply passage is connected to the spool moving hole at the left side of the unload passage and the right side of the unload passage, respectively. The first load passage is located on the left side of the first supply passage and the second load passage is located on the right side of the second supply passage, and the first tank passage is located on the left side of the first load passage and the second load is located. A second tank passage is located on the right side of the furnace, and a third annular groove is formed at a position corresponding to one side of the first load passage on both sides of the first and second annular grooves of the spool, and corresponds to one side of the second load passage. Fourth annular grooves are respectively formed at positions of the spool, and pilot ports for supplying pilot pressure oil to pilot chambers are formed at both ends of the spool, and the one pilot port is neutral when no pressure oil is supplied to the pilot port. A switching spring for maintaining the state is provided, wherein the regeneration passage has a first and second connecting passages radially penetrated in the outer peripheral wall around the circumferential wall is formed with a regeneration function.

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