The present invention relates to a valve device configured to control the flow of an operating liquid supplied to a hydraulic device.
In hydraulic devices, such as cylinders and motors, the flow direction of an operating liquid is switched by a valve device. The valve device includes a spool which moves in its axial direction by the action of pilot pressure at normal time. At emergency time, the position of the spool is forcibly switched by tilting an operating lever (see PTL 1, for example).
In the valve device of PTL 1 (which is described as a direction switching valve in PTL 1), as shown in
PTL 1: Japanese Laid-Open Patent Application Publication No. 2009-185910
In the valve device of PTL 1, an operating lever 200 is always being coupled to the rotating shaft 201. Therefore, the operating lever 200 is made to be tilted by the movement of the spool 204.
Since the rotating shaft 201 rotates at all times during the movement of the spool 204, the sealing members 205 slide on the hole inner peripheral surface of the spool cover 202. Therefore, contact resistance of the sealing members 205 influences the operation of the spool 204 in some cases. For example, in some cases, the rotating shaft (i.e., the spool) does not move in accordance with a command due to the contact resistance of the sealing members. Such deviation between a current command value with respect to an electromagnetic proportional valve and the flow rate (i.e., the movement distance of the spool) of a pilot liquid through the electromagnetic proportional valve is called hysteresis. Moreover, since the operating lever 200 is always being coupled to the spool 204 at normal time, the operating lever 200 becomes an interfering object which interferes the movement of the spool 204, and this further influences the operation of the spool 204 in some cases.
Furthermore, in the valve device of PTL 1, the rotating shaft 201 rotates each time the spool 204 moves as described above. Therefore, since the sealing members 205 highly frequently slide on the hole inner peripheral surface of the spool cover 202, seal performance needs to be secured.
An object of the present invention is to provide a valve device capable of suppressing influence on the operation of a spool and securing seal performance of a sealing member.
A valve device of the present invention includes: a spool configured to move in an axial direction of the spool in accordance with pilot pressure; a housing main body accommodating the spool such that the spool is slidable; a pilot chamber cover adjacently provided at the housing main body and forming a pilot chamber to which the pilot pressure is introduced, the pilot chamber cover including a through hole extending in a direction intersecting with the axial direction of the spool; an operating pin provided in the pilot chamber and connected to the spool, the operating pin being configured to swing in accordance with movement of the spool in the axial direction; a rotating shaft provided in the pilot chamber and connected to the operating pin, the rotating shaft being configured to turn in accordance with swinging of the operating pin; a coupling plug coupled to the rotating shaft, at least a part of the coupling plug being inserted into the through hole of the pilot chamber cover, the coupling plug being configured to switch between a coupled state where rotational force of the rotating shaft is transmitted to the coupling plug and a canceled state where the transmission of the rotational force of the rotating shaft to the coupling plug is canceled; an operating lever coupled to the coupling plug; and a sealing member provided between an inner peripheral surface of the through hole of the pilot chamber cover and the coupling plug.
According to the present invention, at the time of normal operation, the coupling plug can be moved by the operating lever in the axial direction of the rotating shaft and therefore can be prevented from being coupled to the rotating shaft. On this account, the coupling plug does not turn in accordance with the turning of the rotating shaft at the time of the normal operation. Thus, the coupling plug does not slide on the sealing member. With this, influence on the operation of the spool from the contact resistance of the sealing member can be suppressed. For example, hysteresis between a current command value with respect to an electromagnetic proportional valve and a flow rate property of a pilot liquid can be reduced, the hysteresis being generated due to the contact resistance of the sealing member. Moreover, since the operating lever does not become an interfering object which interferes the movement of of the spool, the influence on the operation of the spool can be further suppressed. Furthermore, since the coupling plug is not coupled to the rotating shaft at normal time as described above, the sealing member does not slide on a hole inner peripheral surface of the pilot chamber cover. With this, the seal performance of the sealing member can be secured. It should be noted that at emergency time, the coupling plug can be moved by the operating lever in the axial direction of the rotating shaft and coupled to the rotating shaft, and therefore, the spool can be forcibly moved in the axial direction.
In the above invention, it is preferable that the coupling plug slide in the axial direction of the rotating shaft to switch between the coupled state and the canceled state.
According to the above configuration, the coupling of the coupling plug to the rotating shaft and the uncoupling of the coupling plug from the rotating shaft can be easily performed.
In the above invention, it is preferable that: the rotating shaft include a coupling pin projecting in a radial direction of the rotating shaft; and the coupling plug include a cutout portion provided at such a position that the cutout portion engages with the coupling pin with one end of the rotating shaft inserted into the coupling plug or at such a position that the cutout portion does not engage with the coupling pin.
According to the above configuration, the coupling of the coupling plug to the rotating shaft and the uncoupling of the coupling plug from the rotating shaft can be more easily performed.
In the above invention, it is preferable that: the valve device further include a first guide provided at a first side of the operating lever in the axial direction of the rotating shaft and a second guide provided at a second side of the operating lever in the axial direction of the rotating shaft; and the operating lever be configured to, when coupling the coupling plug to the rotating shaft, be tilted about the first guide serving as a fulcrum, and when uncoupling the coupling plug from the rotating shaft, be tilted about the second guide serving as the fulcrum.
According to the above configuration, the operating lever is easily tilted when coupling the coupling plug to the rotating shaft or uncoupling the coupling plug from the rotating shaft.
According to the present invention, the influence on the operation of the spool can be suppressed, and the seal performance of the sealing member can be secured.
Hereinafter, a valve device according to the present embodiment will be described with reference to the drawings. The valve device described below is just one embodiment. Therefore, the valve device is not limited to the following embodiment, and additions, eliminations, and modifications may be made within the scope of the present invention.
Operating machines, such as tractors, shovels, and forklifts, include apparatuses (such as spreaders), attachments (such as front loaders, booms, and forks), and the like (hereinafter referred to as “loads 3”). The operating machines perform various types of work by the loads 3. Moreover, the operating machines may lift or lower the loads 3 during the work. In order to lift or lower the load 3, as shown in
Specifically, the cylinder 2 includes a rod 2a and a cylinder 2b. The rod 2a is inserted in the cylinder 2b so as to be able to reciprocate. The cylinder 2b includes a rod-side port 2c and a head-side port 2d. The rod 2a operates by supplying the operating liquid to or discharging the operating liquid form the rod-side port 2c or the head-side port 2d. To be specific, when the operating liquid is supplied to the rod-side port 2c and discharged from the head-side port 2d, the rod 2a contracts relative to the cylinder 2b. Moreover, when the operating liquid is supplied to the head-side port 2d and discharged from the rod-side port 2c, the rod 2a expands relative to the cylinder 2b. A hydraulic driving system 4 is connected to the cylinder 2 to supply the operating liquid to the cylinder 2.
The hydraulic driving system 4 includes a main pump 11, a tilt control portion 12, the valve device 1, and a pilot pump 14. For example, the main pump 11 is a variable displacement swash plate pump including a swash plate 11a. The tilt control portion 12 is provided at the main pump 11 to change a tilt angle of the swash plate 11a. The main pump 11 is coupled to a prime mover (not shown), such as an engine or an electric motor. The main pump 11 discharges the operating liquid at a flow rate corresponding to a rotational frequency of the prime mover and a discharge capacity of the prime mover. The discharged operating liquid is introduced from the main pump 11 through a pump passage 15 to the valve device 1.
The valve device 1 controls the flow of the operating liquid supplied to the cylinder 2 and includes a control valve 21. The control valve 21 mainly controls the flow of the operating liquid, discharged from the main pump 11, with respect to the cylinder 2. Specifically, the control valve 21 is mainly connected to the pump passage 15, a tank passage 16, a rod-side passage 17, and a head-side passage 18. The tank passage 16 is connected to a tank 19. The rod-side passage 17 and the head-side passage 18 are respectively connected to the rod-side port 2c and head-side port 2d of the cylinder 2. The control valve 21 includes a spool 31 to switch connection statuses of these four passages 15 to 18.
The spool 31 is formed in a substantially columnar shape. The spool 31 can move to three positions that are a neutral position N, an up position U, and a down position D. The connection statuses of the four passages 15 to 18 change depending on these positions. To be specific, when the spool 31 moves to the up position U, the pump passage 15 is connected to the head-side passage 18, and the rod-side passage 17 is connected to the tank passage 16. With this, the operating liquid is supplied to the head-side port 2d and discharged from the rod-side port 2c. Thus, the rod 2a expands, and the load 3 moves upward.
In contrast, when the spool 31 moves to the down position D, the pump passage 15 is connected to the rod-side passage 17, and the head-side passage 18 is connected to the tank passage 16. With this, the operating liquid is supplied to the rod-side port 2c and discharged from the head-side port 2d. Thus, the rod 2a contracts, and the load 3 moves downward. Moreover, when the spool 31 returns to the neutral position N, all the four passages 15 to 18 are disconnected. With this, the supply of the operating liquid to the cylinder 2 and the discharge of the operating liquid from the cylinder 2 can be stopped, and therefore, the upward and downward movements of the load 3 can be stopped.
The spool 31 receives pilot pressures p1 and p2 at both respective end portions thereof and moves to a position corresponding to the received pilot pressures p1 and p2. Specifically, when the spool 31 receives the first pilot pressure p1, the spool 31 moves to the down position D. Moreover, when the spool 31 receives the second pilot pressure p2, the spool 31 moves to the up position U. Furthermore, when the spool 31 does not receive any of the two pilot pressures p1 and p2, or when a pressure difference between these two pilot pressures p1 and p2 falls within a predetermined range, the spool 31 is held at the neutral position N.
For example, the pilot pump 14 is a fixed displacement pump (such as a swash plate pump or a gear pump) and is connected to a prime mover (not shown), such as an engine or an electric motor. The pilot pump 14 discharges a pilot liquid (which is the same as the operating liquid; such as oil or water) to a pilot passage 20 at a flow rate corresponding to the rotational frequency of the prime mover. The pilot passage 20 branches into two parts 20a and 20b at a portion thereof. The parts 20a and 20b are respectively connected to both end portions of the spool 31. A first electromagnetic control valve 24L is interposed on the part 20a that is one of the branched parts, and a second electromagnetic control valve 24R is interposed on the part 20b that is the other branched part. The first and second electromagnetic control valves 24L and 24R control the two pilot pressures p1 and p2 in accordance with a command from a control device (not shown) to adjust the position (stroke amount) of the spool 31.
As shown in
The housing main body 26 accommodates at least an intermediate portion of the spool 31. The housing main body 26 includes a through hole 32. The through hole 32 extends in a left-right direction on the paper surface of
The spool 31 is inserted into the through hole 32 such that: an axis L1 of the spool 31 coincides with an axis of the through hole 32; and the spool 31 is movable in an axial direction thereof. The spool 31 slides on an inner peripheral surface of the housing main body 26 in the axial direction.
First and second axial end portions of the spool 31 project outward from the housing main body 26. A spool cover (corresponding to a pilot chamber cover) 27 covering the first axial end portion of the spool 31 is adjacently provided at the housing main body 26. It should be noted that the housing main body 26 and the spool cover 27 may be provided integrally or separately. A spring cover 28 covering the second axial end portion of the spool 31 is provided at an opposite side of the spool cover 27.
The spool cover 27 forms therein a pilot chamber (first pilot chamber 27a). In the present embodiment, the spool cover 27 accommodates the first axial end portion (left end portion in
On the other hand, the spring cover 28 is formed in a substantially cylindrical shape. The spring cover 28 is fixed to the housing main body 26 such that an opening thereof faces the housing main body 26. The spring cover 28 forms therein a second pilot chamber 28a. The second axial end portion of the spool 31 projects from the housing main body 26 to the second pilot chamber 28a. Moreover, the spring cover 28 includes a second pilot port 28b connected to the second pilot chamber 28a. The second pilot port 28b is connected to the part 20b that is the other branched part of the pilot passage 20. To be specific, the second pilot pressure p2 output from the second electromagnetic control valve 24R is introduced through the second pilot port 28b to the second pilot chamber 28a.
The second pilot chamber 28a accommodates a spring mechanism 35. In order to return the spool 31 to the neutral position N, the spring mechanism 35 includes a spacer bolt 36, a pair of spring seats 37L and 37R, and a return spring 38. The spacer bolt 36 is formed in a substantially columnar shape. A tip end portion of the spacer bolt 36 is threadedly engaged with the second axial end portion of the spool 31 such that an axis of the spacer bolt 36 and the axis of the spool 31 coincide with each other. The pair of spring seats 37L and 37R are externally attached to an intermediate portion of the spacer bolt 36.
The spring seat 37L includes a flange 371 extending at an opening end portion thereof over the entire periphery in a circumferential direction, and the spring seat 37R includes a flange 37r extending at an opening end portion thereof over the entire periphery in a circumferential direction. The return spring 38 is interposed between the flanges 371 and 37r. The return spring 38 is a compression coil spring and biases the spring seats 37L and 37R in directions opposite to each other.
The spring mechanism 35 is accommodated in the second pilot chamber 28a such that when the spool 31 is located at the neutral position N, the flange 371 contacts a second end surface of the housing main body 26, and the flange 37r contacts a bottom surface of the spring cover 28. According to this configuration, when the spool 31 moves to the down position D or the up position U, the return spring 38 applies biasing force to the spool 31 such that the spool 31 returns to the neutral position N.
As shown in
The manual operation mechanism 61 includes an operating pin 62 and an operating lever 64. The operating pin 62 is arranged in the first pilot chamber 27a of the spool cover 27. The operating pin 62 couples the operating lever 64 to the spool 31 and transmits rotational motion of the operating lever 64 to the spool 31. In the present embodiment, as one example, the operating pin 62 includes a turning portion 62a and a coupling portion 62b. The turning portion 62a is coupled to a below-described rotating shaft 63. Specifically, the turning portion 62a is formed in a substantially O shape. The rotating shaft 63 is fitted in an inner hole of the turning portion 62a. With this, the operating pin 62 is connected to the rotating shaft 63. It should be noted that the turning portion 62a and the rotating shaft 63 are fixed to each other by a fixing pin 79 (see
Moreover, the operating pin 62 is connected to the spool 31. In the present embodiment, as one example, the coupling portion 62b is provided at the turning portion 62a. The coupling portion 62b extends from the turning portion 62a in a radial direction of the turning portion 62a. Furthermore, the spool 31 includes a spool pin 31a attached to the first axial end portion thereof with a fastener, such as a screw. The coupling portion 62b is coupled to the spool pin 31a. Specifically, the spool pin 31a includes an insertion hole 31g extending in a direction (upper-lower direction in
and the spool pin 31a is inserted and fitted in the hole. Or, the coupling portion 62b and the spool pin 31a may be coupled to each other with a fastener, such as a bolt.
The operating lever 64 manually moves the spool 31 in the axial direction at emergency time. To be specific, the operating lever 64 forcibly moves the spool 31. Specifically, the operating lever 64 can be tilted by manually operating a holding portion 64a provided at an upper end portion of the operating lever 64. Specifically, when the operating lever 64 is tilted and is made to fall down toward one side about the axis of the rotating shaft 63, the operating pin 62 turns counterclockwise in
The rotating shaft 63 is provided in the first pilot chamber 27a and turns in accordance with the swinging of the operating pin 62. Specifically, the rotating shaft 63 is arranged in such a direction that the axis L2 intersects with (preferably, is perpendicular to) the axis L1 of the spool 31. In addition, the rotating shaft 63 is supported so as to be turnable about the axis L2. Specifically, as shown in
As shown in
The coupling plug 77 is coupled to the operating lever 64. In the present embodiment, as one example, the coupling plug 77 is provided with a lever connecting member 78 which is formed in a substantially cylindrical shape and includes an elongated hole 71 penetrating an outer peripheral wall thereof in the radial direction. As shown in
A sealing member 74 is provided between an outer peripheral surface of the coupling plug 77 and the inner peripheral surface of the through hole 70 of the spool cover 27. In the present embodiment, as one example, the sealing member 74 is provided so as to be fitted in an annular groove formed on a hole peripheral wall of the spool cover 27. The sealing member 74 prevents the operating oil in the first pilot chamber 27a from leaking to an outside.
The coupling plug 77 can switch between a coupled state where the coupling plug 77 is coupled to the rotating shaft 63, and therefore, rotational force of the rotating shaft 63 is transmitted to the coupling plug 77 and a canceled state (hereinafter referred to as an uncoupled state) where the transmission of the rotational force from the rotating shaft 63 is canceled. In the uncoupled state, the coupling plug 77 is not coupled to the rotating shaft 63. Therefore, even when the rotating shaft 63 rotates, the coupling plug 77 does not turn in accordance with the rotation of the rotating shaft 63. On the other hand, the coupled state is formed only at emergency time, i.e., when the spool 31 is forcibly moved in the axial direction by the operating lever 64 with the coupling plug 77 coupled to the rotating shaft 63. To be specific, the uncoupled state is a state where the coupling plug 77 turns only at emergency time.
In the present embodiment, the coupling plug 77 slides in the axial direction of the rotating shaft 63 to switch between the coupled state where the coupling plug 77 and the rotating shaft 63 are coupled to each other and the uncoupled state where the coupling plug 77 and the rotating shaft 63 are uncoupled from each other. The coupling plug 77 is configured to slide toward a first side or a second side in the axial direction of the rotating shaft 63. In the present embodiment, when the coupling plug 77 slides toward the rotating shaft 63, the coupling plug 77 is coupled to the rotating shaft 63, and the coupling plug 77 and the rotating shaft 63 integrally turns. In the present embodiment, as one example of a coupler by which the coupling plug 77 and the rotating shaft 63 are coupled to each other, the coupling plug 77 includes cutout portions (notch portions) 72 each provided at such a position that the cutout portion 72 engages with the corresponding coupling pin 73 with one end of the rotating shaft 63 inserted into the coupling plug 77 or at such a position that the cutout portion 72 does not engage with the corresponding coupling pin 73. The cutout portions 72 are formed on a peripheral wall of the coupling plug 77.
As shown in
In the above configuration, at emergency time caused due to malfunction of the electromagnetic proportional valve 24L or 24R, sticking of the spool 31, or the like, as shown in
On the other hand, when disengaging the cutout portions 72 from the coupling pins 73 at normal time, the operating lever 64 is tilted to the right side in the axial direction of the rotating shaft 63 about the second guide 80 serving as a fulcrum. With this, the coupling plug 77 moves to the left side, and the cutout portions 72 are disengaged from the coupling pins 73. When the cutout portions 72 do not engage with the coupling pin 73, the rotating shaft 63 turns independently from the coupling plug 77.
As described above, according to the valve device 1 of the present embodiment, at the time of normal operation, the coupling plug 77 can be moved by the operating lever 64 in the axial direction of the rotating shaft 63 and therefore can be prevented from being coupled to the rotating shaft 63. On this account, the coupling plug 77 does not turn in accordance with the turning of the rotating shaft 63 at the time of the normal operation. Thus, the coupling plug 77 does not slide on the sealing member 74. With this, influence on the operation of the spool 31 from the contact resistance of the sealing member 74 can be suppressed. For example, the hysteresis generated due to the contact resistance of the sealing member 74 can be reduced. Moreover, since the coupling plug 77 and the rotating shaft 63 are not coupled to each other at normal time, the operating lever 64 does not become an interfering object which interferes the movement of the spool 31. Therefore, the influence on the operation of the spool 31 can be further suppressed. Furthermore, as described above, since the coupling plug 77 is not coupled to the rotating shaft 63 at normal time, the sealing member 74 does not slide on a hole inner peripheral surface of the spool cover 27. With this, seal performance of the sealing member 74 can be secured.
At emergency time (when manually moving the position of the spool 31), the operating lever 64 is tilted to the first side (left side in
Other Embodiments
The coupling plug and the rotating shaft may be coupled to each other by the following configuration.
As shown in
Moreover, the following modified example is applicable to the valve device 1. In the above embodiments, the coupling plug 77 and the rotating shaft 63 are coupled to each other by the engagement of the coupling pins 73 with the cutout portions 72, or the coupling plug 177 and the rotating shaft 163 are coupled to each other by the engagement of the projection(s) 171 with the recess(es) 164. However, the above embodiments are not limited to these. Other coupling methods may be used as long as when the coupling plug turns about the axis of the rotating shaft, the rotating shaft surely turns in accordance with the turning of the coupling plug.
For example, the coupling method may be such that: the coupling plug and the rotating shaft are provided with gears; and the coupling plug and the rotating shaft are coupled to each other by meshing of these gears.
Moreover, in the above embodiment, each of the first guide 65 and the second guide 80 is formed in a circular-arc shape. However, the above embodiment is not limited to this. Each of the first guide 65 and the second guide 80 is only required to be configured such that when the operating lever 64 is tilted about the axis of the rotating shaft 63, each of the first guide 65 and the second guide 80 contacts the operating lever 64 to serve as the fulcrum of this tilting.
Moreover, in the above embodiment, two cutout portions 72 are provided so as to correspond to the number of coupling pins 73. However, the above embodiment is not limited to this. Each of the number of coupling pins 73 and the number of cutout portions 72 corresponding to the number of coupling pins 73 may be one or three or more.
Moreover, in the above embodiment, the operating pin 62 and the spool 31 are coupled to each other in such a manner that the coupling portion 62b of the operating pin 62 is fitted in the insertion hole 31g of the spool pin 31a. However, the above embodiment is not limited to this. For example, the operating pin 62 and the spool 31 may be coupled to each other in such a manner that: a rack is provided at the spool pin 31a; and a pinion is provided at an upper end portion of the operating pin 62.
Moreover, in the above embodiment, the valve device 1 is applied to the cylinder 2. However, the above embodiment is not limited to this. The valve device 1 may be applied to other hydraulic devices, such as motors.
Moreover, in the above embodiment, the valve device 1 is a three-position (neutral position, up position, down position) switching valve. However, the above embodiment is not limited to this. The above embodiment is applicable to a two-position switching valve. Furthermore, at least a part of the coupling plug 77 is only required to be inserted into the through hole 70 of the spool cover 27.
Moreover, the valve device 1 of the above embodiment is mainly applied to operating machines. However, the above embodiment is not necessarily limited to such machines. For example, the valve device 1 of the above embodiment may be applied to robots including hydraulic cylinders, excavators, aerial work platform vehicles, and the like. The field to which the valve device 1 of the above embodiment is applied is not limited. Furthermore, the cylinder 2 is not necessarily have to lift or lower the load and may be configured to move the load in a horizontal direction.
1 valve device
21 control valve
26 housing main body (housing)
27 spool cover (pilot chamber cover)
27
a first pilot chamber (pilot chamber)
31 spool
32 through hole
62 operating pin
63, 163 rotating shaft
64 operating lever
65 first guide
70 through hole
72 cutout portion
73 coupling pin
74 sealing member
77, 177 coupling plug
80 second guide
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/035307 | 9/9/2019 | WO | 00 |