The present invention relates to a switching valve having a regeneration mechanism that regenerates return fluid flowing out of a rod side chamber of a cylinder to a piston side chamber.
JP2001-304202A describes this type of switching valve.
JP2001-304202A discloses a switching valve including a spool that operates a cylinder by controlling a direction of working oil supplied from a pump, and has an internally formed regeneration passage through which return oil flowing out of a rod side of the cylinder is regenerated to a piston side chamber.
Further, the regeneration passage of the switching valve disclosed in JP2001-304202A includes a radial direction hole capable of communicating with upper and lower working oil supply/discharge grooves positioned at a first end of the spool, an axial direction hole that communicates with the radial direction hole, and a radial direction hole that communicates with the axial direction hole and communicates with upper and lower working oil supply/discharge grooves positioned at a second end of the spool. The return oil flowing out of the rod side of the cylinder is regenerated to the piston side chamber through the radial direction hole in the second end, the axial direction hole, and the radial direction hole in the first end.
In this type of switching valve, restrictions apply to a sectional area and so on of the spool, making it difficult to increase a diameter of the regeneration passage. The spool is formed with the radial direction holes and peripheral grooves formed in an outer periphery thereof, and therefore, when the diameter of the regeneration passage is increased, a sectional area of a part for forming the radial direction holes and so on decreases, leading to a strength deficiency. In a case where it is difficult to increase the diameter of the regeneration passage in this manner, pressure loss in the fluid passing through the regeneration passage increases, leading to a corresponding increase in a pressure in a rod side chamber. When the pressure in the rod side chamber increases, a pressure in the piston side chamber also increases, and therefore a discharge pressure of a pump must be increased correspondingly. As a result, an increase in energy consumption occurs.
An object of the present invention is to provide a switching valve with which pressure loss in a regeneration passage can be reduced, enabling a reduction in energy consumption.
According to one aspect of the present invention, a switching valve that switches between supply and discharge of a working fluid to and from a cylinder having a piston side chamber and a rod side chamber, includes a spool incorporated into a valve body to be free to slide, a first cylinder port that communicates with the piston side chamber, a second cylinder port that communicates with the rod side chamber, a bridge passage having a pair of openings, a first opening of which is adjacent to the first cylinder port and a second opening of which is adjacent to the second cylinder port, a regeneration passage formed in the spool to connect the second cylinder port communicating with the rod side chamber to the first cylinder port in accordance with a switching position of the spool, and a first communication port and a second communication port formed in the spool to communicate with the regeneration passage. The first communication port communicates with the second opening of the bridge passage, which is adjacent to the second cylinder port, and the second communication port communicates with the second cylinder port in accordance with the switching position of the spool.
An embodiment of the present invention will be described below with reference to the figures.
First, referring to
The switching valve 200 shown in
The bridge passage 7 includes a pair of openings. A first opening 7a is adjacent to the cylinder port 2, and a second opening 7b is adjacent to the cylinder port 4. When the spool S is in a neutral position shown in
Accordingly, pressure fluid from the pump is supplied to the piston side chamber 1 of the cylinder C, and return fluid from the rod side chamber 3 is led into the tank passage 11 such that the cylinder C expands. Further, when the spool S is switched in the rightward direction in the figure from the neutral position, as described above, the cylinder port 4 communicates with the tank passage 11 via the choke groove 10. As a result, pressure loss is generated by the choke groove 10, leading to a corresponding increase in pressure in the cylinder port 4.
A connecting hole 12 is formed in the spool S to extend along an axial center thereof, and a first drilled hole 13 is formed in a cylinder port 4 side tip end part of the connecting hole 12. When the spool S is in the neutral position, the first drilled hole 13 opens onto the second opening 7b of the bridge passage 7. When the spool S moves in the rightward direction from the neutral position, the first drilled hole 13 opens onto the cylinder port 4.
A check valve 14 is incorporated into an end portion of the connecting hole 12 on an opposite side to the end portion in which the first drilled hole 13 is formed. When the check valve 14 opens, a second drilled hole 15 provided adjacent to the first annular groove 8 communicates with the connecting hole 12. In other words, the check valve 14 allows fluid to flow only from the first drilled hole 13 into the second drilled hole 15 through the connecting hole 12.
When the spool S is in the neutral position, the second drilled hole 15 is positioned between the cylinder port 2 and the first opening 7a in the bridge passage 7 and thereby held in a blocked condition. When the spool S is switched in the rightward direction in the figure from this condition, the second drilled hole 15 communicates with the first annular groove 8 via the first opening 7a in the bridge passage 7. Further, when the spool S is switched in the rightward direction, the second drilled hole 15 communicates with the first opening 7a in the bridge passage 7 via a recessed portion 16.
In the switching valve 200, when the spool S is switched in the rightward direction in the figure from the neutral position shown in
When the cylinder port 4 communicates with the tank passage 11 via the choke groove 10 in this manner, pressure loss occurs in the fluid passing through the choke groove 10, leading to an increase in the pressure in the cylinder port 4. High-pressure fluid increased in pressure in the cylinder port 4 passes through the first drilled hole 13 and the connecting hole 12, and then pushes open the check valve 14 so as to be supplied into the bridge passage 7 through the second drilled hole 15. As a result, the return fluid from the rod side chamber 3 of the cylinder C is regenerated to the piston side chamber 1 of the cylinder C.
In the switching valve 200, the return fluid from the rod side chamber 3 of the cylinder C is regenerated via the connecting hole 12 formed in the spool S. However, restrictions apply to a sectional area and so on of the spool S, making it difficult to increase a diameter of the connecting hole 12. The first and second annular grooves 8, 9 and the first drilled hole 13 are formed in the spool S, and therefore, when the diameter of the connecting hole 12 is increased, a sectional area of a part in which the first and second annular grooves 8, 9 and the first drilled hole 13 are formed decreases, leading to a strength deficiency. In a case where it is difficult to increase the diameter of the connecting passage 12 in this manner, pressure loss in the fluid passing through the connecting passage 12 increases, leading to a corresponding increase in the pressure in the rod side chamber 3. When the pressure in the rod side chamber 3 increases, the pressure in the piston side chamber 1 also increases, and therefore a discharge pressure of the pump must be increased correspondingly. As a result, an increase in energy consumption occurs.
Next, referring to
The switching valve 100 controls an operation of the cylinder C by switching between supply and discharge of a working fluid such as working oil to and from the cylinder C. The switching valve 100 is used in a construction machine or the like having a function for regenerating return fluid in the rod side chamber 3 of the cylinder C.
The switching valve 100 includes the spool S incorporated into the valve body B to be free to slide, the cylinder port 2 formed in the valve body B and connected to the piston side chamber 1 of the cylinder C, and the cylinder port 4 formed in the valve body B and connected to the rod side chamber 3. The pump port 5 communicating with the pump, not shown in the figure, is formed in the valve body B. The pressure fluid led into the pump port 5 passes through the passage not shown in the figures, and is led into the bridge passage 7 via the load check valve 6.
The bridge passage 7 includes the pair of openings, the first opening 7a of which is adjacent to the cylinder port 2 and the second opening 7b of which is adjacent to the cylinder port 4. When the spool S is in a neutral position shown in
Accordingly, the pressure fluid from the pump is supplied to the piston side chamber 1 of the cylinder C, and the return fluid from the rod side chamber 3 is led into the tank passage 11 via the second annular groove 9 and the choke groove 10 such that the cylinder C expands. The cylinder port 4 communicates with the tank passage 11 via the choke groove 10, and therefore pressure loss is generated by the choke groove 10, leading to a corresponding increase in the pressure in the cylinder port 4. The reason for increasing the pressure on the cylinder port 4 side by providing the choke groove 10 in this manner is to introduce a regeneration flow, to be described below, into the cylinder port 2 of the cylinder C. The switching valve 100 includes pilot chambers 17, 17 facing respective end portions of the spool S, and centering springs 18, 18 provided respectively in the pilot chambers 17, 17. By introducing a pilot pressure into one of the pilot chambers 17, 17, the position of the spool S is switched. The centering springs 18, 18 bias the spool S such that when the pilot pressure is not exerted on either of the pilot chambers 17, 17, the spool S is held in the neutral position.
An incorporation hole 19 for incorporating a single direction flow valve V is formed in the spool S from a right end of the figure, which serves as a front end of a movement direction of the spool S when the spool S moves in a regeneration direction, i.e. the rightward direction in the figure. An opening portion of the incorporation hole 19 is blocked by a plug 20. By forming the incorporation hole 19 from the front end of the direction in which the spool S moves during regeneration in this manner, an axial direction length of the incorporation hole can be shortened in comparison with a case where the incorporation hole is formed from an opposite side, for example.
Further, as shown in
The spool S includes, on either side of the seat portion 21, a first communication port 22a formed on the pump port 5 side to communicate with the connecting passage 22c, and a second communication port 22b that communicates with an incorporation passage 19 on an opposite side to the first communication port 22a. The first communication port 22a and the second communication port 22b are opened in an outer peripheral surface of the spool S. When the spool S is in the neutral position shown in
When the spool S is switched to a right side position, as shown in
A spacer 23 is provided in the incorporation hole 19, and a spring 24 is interposed between the spacer 23 and the single direction flow valve V. The single direction flow valve V includes a poppet portion 25 that contacts the seat portion 21, a fitting portion 26 that has a larger diameter than the poppet portion 25 and is fitted into the incorporation hole 19, and a projecting portion 27 provided on a tip end of the poppet portion 25. The single direction flow valve V is configured such that normally, the poppet portion 25 contacts the seat portion 21 such that the seat portion 21 is closed.
The fitting portion 26 is fitted into the incorporation hole 19 to be free to slide, and a fitting length of the fitting portion 26 relative to the incorporation hole 19 is set to be considerably greater than an outer diameter of the fitting portion 26. Thus, the single direction flow valve V can operate with stability. Further, an outer diameter of the poppet portion 25 is smaller than the outer diameter of the fitting portion 26 such that a step portion 28 is formed in a boundary part between the poppet portion 25 and the fitting portion 26.
The projecting portion 27 is formed to project further toward the first communication port 22a than the seat portion 21 when the single direction flow valve V closes the seat portion 21, whereby the projecting portion 27 is housed in the connecting passage 22c. A through hole 29 is formed in the projecting portion 27 and the poppet portion 25 to penetrate respective centers thereof. Further, a back pressure chamber 30 that communicates with the through hole 29 and houses the spring 24 is formed in the single direction flow valve V. The back pressure chamber 30 is formed such that when the single direction flow valve V closes the seat portion 21, a pressure receiving surface area of the back pressure chamber 30 is larger than a pressure receiving surface area of the step portion 28. Accordingly, pressure fluid flowing in through the first communication port 22a flows into the back pressure chamber 30 housing the spring 24 through the through hole 29, whereby the pressure of the fluid led into the back pressure chamber 30 acts on the single direction flow valve V in a direction for closing the seat portion 21.
Hence, in this embodiment, the first communication port 22a and the second communication port 22b communicate with each other via the incorporation hole 19, the seat portion 21, and the connecting passage 22c. Further, in this embodiment, a passage linking the first communication port 22a to the second communication port 22b serves as a regeneration passage 22. In other words, the incorporation hole 19, the seat portion 21, and the connecting passage 22c constituting the passage linking the first communication port 22a to the second communication port 22b together function as the regeneration passage 22. More specifically, a passage formed from the incorporation hole 19 and the single direction flow valve V, the seat portion 21, and the connecting passage 22c constitute the regeneration passage 22. Furthermore, a signal passage 31 is provided on an opposite side of the valve body B to the regeneration passage 22.
Next, actions of the switching valve 100 according to this embodiment will be described.
When the spool S is switched from the neutral position shown in
When the spool S is switched to the right side position shown in
As described above, during the process in which the spool S is switched to the right side position, the second communication port 22b communicates with the cylinder port 4, and at a slight delay relative to the communication timing of the second communication port 22b, the first communication port 22a communicates with the second opening 7b in the bridge passage 7. When the second communication port 22b communicates with the cylinder port 4, the relatively increased pressure on the cylinder port 4 side acts on the step portion 28 of the single direction flow valve V. Then, at a slightly delayed timing, the first communication port 22a communicates with the second opening 7b in the bridge passage 7.
Hence, a pump pressure introduced from the second opening 7b in the bridge passage 7 acts within the back pressure chamber 30, while the relatively high pressure in the cylinder port 4 acts on the step portion 28, and therefore the single direction flow valve V opens the seat portion 21 against the spring 24. When the seat portion 21 is opened, the return fluid led into the cylinder port 4 is led into the bridge passage 7 through the second communication port 22b, the regeneration passage 22, and the first communication port 22a.
It should be noted that since the projecting portion 27 is formed on the tip end of the poppet portion 25, a throttle effect is exhibited between the projecting portion 27 and the incorporation hole 19, and therefore a situation in which the pressure on the cylinder port 4 side becomes too low such that the single direction flow valve V closes the seat portion 21 does not arise.
The fluid led into the bridge passage 7 converges with the pressure fluid from the pump port 5 and is supplied thus to the piston side chamber 1 of the cylinder C. In other words, the return fluid in the rod side chamber 3 of the cylinder C is regenerated to the piston side chamber 1.
It should be noted that an opening portion of the first communication port 22a according to this embodiment is a circular hole, but instead, as shown in
According to the embodiment described above, following effects are obtained.
In the switching valve 100 according to this embodiment, the cylinder port 4 and the second opening 7b of the bridge passage 7 communicate with each other via the regeneration passage 22, and therefore the return fluid from the rod side chamber 3 of the cylinder C is led into the cylinder port 2 through the bridge passage 7 and then regenerated to the piston side chamber 1 of the cylinder C. A sectional area of the bridge passage 7 can be made considerably larger than that of the connecting hole 12 formed conventionally in the spool S. In other words, pressure loss can be reduced in comparison with a case where the return fluid passes through the small-diameter connecting hole 12, enabling a reduction in a flow passage resistance during regeneration of the return fluid. As a result, the pressure in the rod side chamber 3 during regeneration can be reduced relatively, enabling a reduction in a load exerted on the pump, not shown in the figures, and a corresponding reduction in energy consumption.
Furthermore, the single direction flow valve V is provided, and therefore, when the switching valve 100 according to this embodiment is used in a construction machine, for example, the pressure in the rod side chamber 3 can be kept low during an excavation operation in which the pressure in the piston side chamber 1 must be kept high and the pressure in the rod side chamber 3 must be kept low. If, during the excavation operation, the pump side pressure opens the single direction flow valve V and flows into the rod side chamber 3, the discharge pressure of the pump acts on the rod side chamber 3, leading to a reduction in the efficiency of the excavation operation. With the switching valve 100 according to this embodiment, however, the pressure in the rod side chamber 3 is kept low by providing the single direction flow valve V, as described above, and therefore the efficiency of the excavation operation does not deteriorate.
Furthermore, when the spool S is switched, the timing at which the second communication port 22b communicates with the cylinder port 4 is set to be earlier than the timing at which the first communication port 22a communicates with the second opening 7b of the bridge passage 7, and therefore, at the start of regeneration for regenerating the return fluid from the rod side chamber 3, the pressure of the return fluid acts on the single direction flow valve V before the first communication port 22a opens in the bridge passage 7. Hence, the single direction flow valve V opens at the same time as the first communication port 22a communicates with the bridge passage 7, leading to an improvement in a responsiveness of the single direction flow valve V.
Moreover, the first communication port 22a is formed in a position where the first communication port 22a does not communicate with the pump port 5, which is formed in the valve body B and into which the pressure fluid from the pump is introduced, regardless of the position of the spool S. Since the first communication port 22a does not communicate with the pump port 5, the pressure fluid from the pump port 5 can be reliably prevented from flowing back into the regeneration passage 22. When the pressure fluid from the pump port 5 flows back into the regeneration passage 22, the switching valve 100 becomes unable to control the cylinder C, but with the switching valve 100 according to this embodiment, no loss of control occurs.
Further, by forming the first communication port 22a from a variable communication port, a communication opening with the bridge passage 7 can be increased gradually during the movement process of the spool S, and therefore the pressure in the bridge passage 7 can be prevented from increasing rapidly. As a result, a shock exerted on the cylinder C can be alleviated.
Furthermore, the incorporation hole 19 for incorporating the single direction flow valve V is formed in the spool S from the front end of the movement direction in which the spool S moves during regeneration, and therefore the axial direction length of the incorporation hole 19 can be shortened, thereby facilitating hole formation.
Moreover, the single direction flow valve V is provided to open and close the seat portion 21 formed in the incorporation hole 19, and in a condition where the seat portion 21 is closed by the single direction flow valve V, the pressure receiving surface area on which the second communication port 22b side pressure is received is larger than the pressure receiving surface area on which the first communication port 22a side pressure is received. The seat portion 21 is therefore opened by an action of the second communication port 22b side pressure, whereby the fluid flowing in from the cylinder port 4 side is led into the bridge passage 7. By inserting the single direction flow valve V from the open end of the incorporation hole 19 in this manner, a single direction flow control function can be realized.
Further, the projecting portion 27 is formed on the single direction flow valve V, and therefore, even when the single direction flow valve V is fully open, flow passage resistance can be maintained in relation to the fluid during regeneration. As a result, the pressure in the rod side chamber 3 of the cylinder C can be maintained at an appropriate level.
Furthermore, the axial direction fitting length of the single direction flow valve V relative to the incorporation hole 19 is greater than the diameter of the fitting portion 26, and therefore the single direction flow valve V can be incorporated in a stable condition.
Embodiments of this invention were described above, but the above embodiments are merely examples of applications of this invention, and the technical scope of this invention is not limited to the specific constitutions of the above embodiments.
This application claims priority based on Japanese Patent Application No. 2012-180235 filed with the Japan Patent Office on Aug. 15, 2012, the entire contents of which are incorporated into this specification.
Number | Date | Country | Kind |
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2012-180235 | Aug 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/071662 | 8/9/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/027621 | 2/20/2014 | WO | A |
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5161575 | Morikawa et al. | Nov 1992 | A |
5862831 | Chung | Jan 1999 | A |
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Number | Date | Country |
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55-051104 | Apr 1980 | JP |
2-101179 | Feb 1990 | JP |
4-31302 | Mar 1992 | JP |
04-351384 | Dec 1992 | JP |
2001-304202 | Oct 2001 | JP |
2006-112619 | Apr 2006 | JP |
Number | Date | Country | |
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20150167699 A1 | Jun 2015 | US |