This application is based on and claims priority under 35 USC 119 from Japanese Patent Applications No. 2014-062716 filed on Mar. 25, 2014, the entire content of which is incorporated herein by reference.
1. Field of the Invention
The present invention relates to a pump device and a hydraulic actuator.
2. Description of the Related Art
In a hydraulic actuator used for changing the inclination of an outboard motor with respect to a hull or the like, a switching valve for switching the flow of hydraulic fluid to a lower chamber or an upper chamber is provided in a flow path between a pump and a cylinder device, the inside of which is segmented into the lower chamber (first chamber) and the upper chamber (second chamber) by a piston. The switching valve is configured such that an open valve on a side communicating with the lower chamber and an open valve on a side communicating with the upper chamber coordinate with each other. For each open valve, an actuation valve that slides within a valve chamber and a check valve are combined.
The switching valve operates in the following manner. When hydraulic fluid flows from the pump into the valve chamber of the open valve on the side communicating with the lower chamber, the check valve on the lower chamber side open under pressure of hydraulic fluid, and hydraulic fluid flows to the lower chamber. In parallel with the operation of the check valve, the actuation valve on the lower chamber side that is under pressure due to the hydraulic fluid flowing in is displaced within the valve chamber, and the pressure of the displaced actuation valve causes the actuation valve of the open valve on the side communicating with the upper chamber via a communication path to be displaced within the valve chamber. The displaced actuation valve on the upper chamber side pushes the check valve on the upper chamber side to open the check valve and return hydraulic fluid from the upper chamber to the pump.
When hydraulic fluid flows from the pump into the valve chamber of the open valve on the side communicating with the upper chamber, hydraulic fluid is sent to the upper chamber and hydraulic fluid is returned from the lower chamber to the pump by an operation opposite to that described above.
Conventionally, the valve chamber formed in a pump case accommodates each actuation valve, and a manifold on which the pump case is stacked accommodates the check valve such that the actuation valve to be combined with is opposed. At this time, each actuation valve is arranged to be displaced in the direction of stacking the pump case and the manifold (for example, see Japanese Patent Application Laid-open No. H7-228294).
[Patent Document 1] Japanese Patent Application Laid-open No. H7-228294
In a hydraulic actuator described in the prior art, a valve chamber of a pump case faces the surface of a manifold. Therefore, when hydraulic fluid flows into the valve chamber from the pump, the pressure of the valve chamber acts in a direction to separate the stacked pump case and manifold.
Particularly, when other valves in addition to an actuation valve are to be accommodated in the pump case, it is necessary to form a valve chamber to accommodate those valves, and there is a risk of a decrease in the rigidity of the pump case. In the case where the rigidity of the pump case has decreased, there is a risk of a gap being formed at a stacking surface within the pump case due to pressure that acts on the valve chamber of the actuation valve.
The present invention has been made in view of a situation described above, and an object is to provide a pump device and a hydraulic actuator that can reduce pressure that acts on a stacking surface of a case accommodating an actuation valve and another case (pump case) accommodating a check valve.
A pump device of the present invention includes: a first case accommodating a check valve of a switching valve switching a flow of hydraulic fluid to one of a first chamber and a second chamber of a cylinder device, an inside of which is segmented into the first chamber and the second chamber by a piston; and a second case which is stacked on the first case and in which an actuation valve of the switching valve is accommodated to be displaced in the direction of stacking the first case, such that a valve chamber, accommodating the actuation valve, of the second case has a surface on which pressure of the hydraulic fluid that acts on the valve chamber acts toward the first case.
In another aspect of the present invention, a pump device includes: a first case accommodating a check valve of a switching valve switching a flow of hydraulic fluid to one of a first chamber and a second chamber of a cylinder device, an inside of which is segmented into the first chamber and the second chamber by a piston; and a second case which is stacked on the first case and in which an actuation valve of the switching valve is accommodated to be displaced in the direction of stacking the first case, such that a portion, facing the first case, of a valve chamber, accommodating the actuation valve, of the second case has a diameter smaller than an inner diameter of a portion of the valve chamber within which the actuation valve slides.
The pump devices of the invention may be such that the valve chamber is open on an opposite side to the first case, and a covering member is provided to cover an opened portion of the valve chamber from the opposite side to the first case and resist the pressure of the hydraulic fluid that acts on the valve chamber.
A hydraulic actuator of the present invention includes: a cylinder device, an inside of which is segmented into a first chamber and a second chamber by a piston; and a pump device which includes a first case accommodating a check valve of a switching valve switching a flow of hydraulic fluid to one of the first chamber and the second chamber, and a second case stacked on the first case and in which an actuation valve of the switching valve is accommodated to be displaced in the direction of stacking the first case, such that a valve chamber, accommodating the actuation valve, of the second case is has a surface on which pressure of the hydraulic fluid that acts on the valve chamber acts toward the first case.
In another aspect of the present invention, a hydraulic actuator includes: a cylinder device, an inside of which is segmented into a first chamber and a second chamber by a piston; and a pump device which includes a first case accommodating a check valve of a switching valve switching a flow of hydraulic fluid to one of the first chamber and the second chamber, and a second case which is stacked on the first case and in which an actuation valve of the switching valve is accommodated to be displaced in the direction of stacking the first case, such that a portion, facing the first case, of a valve chamber, accommodating the actuation valve, of the second case has a diameter smaller than an inner diameter of a portion of the valve chamber within which the actuation valve slides.
With the pump device according to the present invention, pressure that acts on a stacked surface of the first case accommodating the actuation valve and the second case accommodating the check valve can be reduced.
With the hydraulic actuator according to the present invention, pressure that acts on a stacked surface of the first case accommodating the actuation valve and the second case accommodating the check valve can be reduced.
22: First case, 23: Second case, 23s: Pressure receiving surface, 51b: First actuation valve, 51e: First check valve, 51f: First valve chamber, 51g: Main oil chamber
<<Embodiment 1>>
An embodiment of the present invention will be described below with reference to the accompanying drawings.
<Schematic Configuration of Trim Tilt Device 100>
As shown in
(Cylinder Device 10)
As shown in
The inside of the cylinder device 10 is segmented by the piston 12 into a first chamber Y1 and a second chamber Y2. The cylinder device 10 extends when oil is supplied to the first chamber Y1, and the cylinder device 10 compresses when oil is supplied to the second chamber Y2. Oil is discharged from the second chamber Y2 when the cylinder device 10 extends, and oil is discharged from the first chamber Y1 when the cylinder device 10 compresses.
At a lower end of the cylinder 11 in the drawing, a pin hole 11a to which a pin (not shown) for connection with a stern bracket 340 a ship propelling machine 300 described below (see
(Tank 80)
The tank 80 is configured of the housing 81 and a tank chamber 82 that is a space surrounded by the housing 81. The housing 81 is formed integrally with the cylinder 11. In the housing 81 and the cylinder 11, as shown in
A part of the cylinder-side and first chamber-side flow path 71A is formed by connecting a first housing hole 81a, a second housing hole 81b, a third housing hole 81c, a first cylinder hole 81d, and a second cylinder hole 81e.
The first housing hole 81a is formed to extend downward from the bottom surface of the housing 81 so as not to penetrate a bottom section of the housing 81. The second housing hole 81b is formed to extend horizontally from the side surface of the bottom section of the housing 81 toward the cylinder 11 so as to intersect with the first housing hole 81a. The third housing hole 81c is formed to extend horizontally from the side surface of a boundary portion between the housing 81 and the cylinder 11 so as to be orthogonal to the second housing hole 81b. The first cylinder hole 81d is formed to extend diagonally upward from the side surface of the cylinder 11 so as to intersect with the third housing hole 81c. The second cylinder hole 81e is formed to extend horizontally from the side surface of the cylinder 11 so as to intersect with the first cylinder hole 81d and be open to the first chamber Y1.
The second housing hole 81b, the third housing hole 81c, the first cylinder hole 81d, and the second cylinder hole 81e are each closed by a plug or the like (not shown) at a portion facing the outside of the housing 81 and a portion facing the outside of the cylinder 11.
A part of the cylinder-side and second chamber-side flow path 72A is formed by connecting a fourth housing hole 81f, a fifth housing hole 81g, a sixth housing hole 81h, a third cylinder hole 81i, and a fourth cylinder hole 81j.
The fourth housing hole 81f is formed to extend downward from the bottom surface of the housing 81 so as not to penetrate the bottom section of the housing 81. The fifth housing hole 81g is formed to extend horizontally from the side surface of the bottom section of the housing 81 so as to intersect with the fourth housing hole 81f. The sixth housing hole 81h is formed to extend horizontally from the side surface of the bottom section of the housing 81 toward the cylinder 11 so as to be orthogonal to the fifth housing hole 81g. The third cylinder hole 81i is formed to extend downward from the upper surface of the cylinder 11 so as to be orthogonal to the sixth housing hole 81h. The fourth cylinder hole 81j is formed to extend diagonally downward from the second chamber Y2 so as to intersect with the third cylinder hole 81i.
The fifth housing hole 81g, the sixth housing hole 81h, and the third cylinder hole 81i are each closed by a plug or the like (not shown) at a portion facing the outside of the housing 81 and a portion facing the outside of the cylinder 11.
At a bottom section of the tank chamber 82, the pump device 20 is arranged. Since oil is stored in the tank chamber 82, the pump device 20 is immersed in oil.
(Motor 40)
The motor 40 is placed on the housing 81 close an upper opening of the tank chamber 82 in a liquid-tight manner and is fixed to the housing 81. In this state, a drive shaft 41 (see
The pump device 20 will be described below.
As shown in
The stern bracket 340 and the pin hole 11a of the cylinder 11 of the trim tilt device 100 are coupled by a pin, and the swivel case 330 and the pin hole 13a of the piston rod 13 are coupled by a pin. By the cylinder device 10 extending and compressing, the distance between the stern bracket 340 and the swivel case 330 changes to change an inclination angle θ of the ship propelling machine 300 with respect to the hull 200.
<Hydraulic Circuit of Trim Tilt Device 100>
The inside of the cylinder device 10 is segmented by the piston 12 into the first chamber Y1 and the second chamber Y2. The cylinder device 10 extends when oil is supplied to the first chamber Y1, and the cylinder device 10 compresses when oil is supplied to the second chamber Y2. Oil is discharged from the second chamber Y2 when the cylinder device 10 extends, and oil is discharged from the first chamber Y1 when the cylinder device 10 compresses.
The hydraulic circuit is a circuit that controls supply and discharge of oil to the first chamber Y1 and the second chamber Y2.
Between the gear pump 21 formed of a pair of gears provided to the pump device 20 and the cylinder device 10, a first chamber-side flow path 71 communicating with the first chamber Y1 and a second chamber-side flow path 72 communicating with the second chamber Y2 are formed. In the first chamber-side flow path 71 and the second chamber-side flow path 72, a switching valve 51 is arranged across the first chamber-side flow path 71 and the second chamber-side flow path 72.
(Switching Valve 51)
The switching valve 51 switches the direction of oil flow to the first chamber Y1 or the second chamber Y2. The switching valve 51 includes a first open valve 51a provided on the first chamber-side flow path 71 and a second open valve 52a provided on the second chamber-side flow path 72.
The first open valve 51a includes a first actuation valve 51b and a first check valve 51e. The first actuation valve 51b includes a spool 51c that slides within a first valve chamber 51f and an actuation valve ball 51d built in the spool 51c. The first valve chamber 51f is partitioned by the spool 51c into a main oil chamber 51g on a side communicating with the first check valve 51e and a sub oil chamber 51h on the opposite side. A pump-side and first chamber-side flow path 71B communicating with the first open valve 51a from the gear pump 21 in the first chamber-side flow path 71 is connected to the main oil chamber 51g of the first open valve 51a.
The spool 51c includes a protrusion 51i that protrudes toward the first check valve 51e and pushes the first check valve 51e upon displacement to the first check valve 51e side. As shown in
The actuation valve ball 51d opens the first hole 51j when the pressure of the main oil chamber 51g is higher than the pressure of the sub oil chamber 51h, and closes the first hole 51j when the pressure of the main oil chamber 51g is lower than the pressure of the sub oil chamber 51h.
The second open valve 52a is similar in configuration to the first open valve 51a. That is, the second open valve 52a includes a second actuation valve 52b and a second check valve 52e. The second actuation valve 52b slides within a second valve chamber 52f and includes a spool 52c including a protrusion 52i that pushes a second check valve 52e and formed with a first hole 52j and a second hole 52k and an actuation valve ball 52d built in the spool 52c to open and close the first hole 52j in accordance with a high-low relationship of pressures of a main oil chamber 52g and a sub oil chamber 52h. The second valve chamber 52f is partitioned by the spool 52c into the main oil chamber 52g on a side communicating with the second check valve 52e and the sub oil chamber 52h on the opposite side. A pump-side and second chamber-side flow path 72B communicating with the second open valve 52a from the gear pump 21 in the second chamber-side flow path 72 is connected to the main oil chamber 52g of the second open valve 52a.
The sub oil chamber 51h of the first open valve 51a and the sub oil chamber 52h of the second open valve 52a are communicated by the communication path 51R.
For example, oil fed to the pump-side and first chamber-side flow path 71B from the gear pump 21 by a positive rotation of the gear pump 21 flows into the main oil chamber 51g of the first open valve 51a. The first check valve 51e is opened by an increase in pressure of the main oil chamber 51g. Oil flows from the first open valve 51a to the cylinder-side and first chamber-side flow path 71A communicating with the first chamber Y1 of the cylinder device 10 in the first chamber-side flow path 71, flows into the first chamber Y1 of the cylinder device 10, and pushes the piston 12 toward the second chamber Y2.
Oil that has flowed into the main oil chamber 51g of the first open valve 51a opens the actuation valve ball 51d within the spool 51c of the first actuation valve 51b and flows into the sub oil chamber 51h. Oil that has flowed into the sub oil chamber 51h reaches the sub oil chamber 52h of the second open valve 52a through the communication path 51R. Since the actuation valve ball 52d of the second actuation valve 52b is closed, oil in the sub oil chamber 52h presses the spool 52c to the main oil chamber 52g side.
The second check valve 52e is pushed and opened by the second actuation valve 52b moving to the main oil chamber 52g side, such that the pump-side and second chamber-side flow path 72B and the cylinder-side and second chamber-side flow path 72A communicating with the second chamber Y2 of the cylinder device 10 from the second open valve 52a are communicated in the second chamber-side flow path 72. Accordingly, oil in the second chamber Y2 on a side pushed by the piston 12 is discharged to the second chamber-side flow path 72 and returns to the gear pump 21 through the second chamber-side flow path 72.
The flow of oil fed to the pump-side and second chamber-side flow path 72B from the gear pump 21 by a negative rotation of the gear pump 21 is similar to the case of the positive rotation of the gear pump 21. That is, oil flows into the main oil chamber 52g of the second open valve 52a, opens the second check valve 52e, flows to the cylinder-side and second chamber-side flow path 72A, flows into the second chamber Y2 of the cylinder device 10, and pushes the piston 12 toward the first chamber Y1.
Oil that has flowed into the main oil chamber 52g of the second open valve 52a opens the actuation valve ball 52d within the spool 52c of the second actuation valve 52b, flows into the sub oil chamber 52h, reaches the sub oil chamber 51h of the first open valve 51a through the communication path 51R, and presses the spool 51c of the first actuation valve 51b to the main oil chamber 51g side. The pressed spool 51c pushes and opens the first check valve 51e, the cylinder-side and first chamber-side flow path 71A and the pump-side and first chamber-side flow path 71B are communicated, and oil in the first chamber Y1 on a side pushed by the piston 12 is discharged to the first chamber-side flow path 71 and returns to the gear pump 21 through the first chamber-side flow path 71.
In this manner, the first actuation valve 51b and the second actuation valve 52b have a function of being displaced under pressure of oil from the gear pump 21 to cause the second check valve 52e or the first check valve 51e to open in the displacement direction by the displacement.
The first check valve 51e and the second check valve 52e have a function of being opened by the displacement of the second actuation valve 52b or the first actuation valve 51b to return oil from the cylinder device 10 and a function of being opened by pressure that acts on the first valve chamber 51f or the second valve chamber 52f to supply oil to the cylinder device 10.
(Up Blow Valve 53)
The pump-side and first chamber-side flow path 71B is connected with an up blow valve 53 (first chamber-side relief valve). The up blow valve 53 is normally closed and opens when the pressure of the pump-side and first chamber-side flow path 71B has become greater than or equal to a pressure set in advance to allow oil in the pump-side and first chamber-side flow path 71B to escape to a first open flow path 73 communicating with the tank 80.
The following case is an example of a case where the pressure of the pump-side and first chamber-side flow path 71B becomes greater than or equal to a pressure set in advance. That is, such a case is when the rotation of the gear pump 21 does not stop even after the cylinder device 10 has extended to a maximum extension-compression range due to supply of oil to the first chamber Y1 of the cylinder device 10, such that oil continues to be supplied to the first chamber-side flow path 71. In this case, the up blow valve 53 opens to return oil supplied to the pump-side and first chamber-side flow path 71B to the tank 80 through the first open flow path 73.
(Down Blow Valve 54)
The pump-side and second chamber-side flow path 72B is connected with a down blow valve 54 (second chamber-side relief valve). The down blow valve 54 is normally closed and opens when the pressure of the pump-side and second chamber-side flow path 72B has become greater than or equal to a pressure set in advance to allow oil in the pump-side and second chamber-side flow path 72B to escape to a second open flow path 74 communicating with the tank 80.
The following case is an example of a case where the pressure of the pump-side and second chamber-side flow path 72B becomes greater than or equal to a pressure set in advance. That is, such a case is when the rotation of the gear pump 21 does not stop even after the cylinder device 10 has compressed to a minimum extension-compression range due to an increase in pressure of the second chamber-side flow path 72 corresponding to an increase in volume of the piston rod 13 entering the second chamber Y2 upon compression of the cylinder device 10 or supply of oil to the second chamber Y2 of the cylinder device 10, such that oil continues to be supplied to the second chamber-side flow path 72. In this case, the down blow valve 54 opens to return oil supplied to the pump-side and second chamber-side flow path 72B to the tank 80 through the second open flow path 74.
Upon compression and extension of the cylinder device 10, a large portion of oil in the first chamber Y1 and oil in the second chamber Y2 is merely circulating via the switching valve 51 and the gear pump 21. However, as described above, the total amount of oil in the first chamber Y1 and oil in the second chamber Y2 changes in accordance with the amount of entrance of the piston rod 13 to the second chamber Y2. Therefore, in the case where the amount of oil fed to the first chamber Y1 or the second chamber Y2 is insufficient, an amount of oil corresponding to the insufficiency is supplied to the gear pump 21 from the tank 80 through a first supply flow path 77 or a second supply flow path 78 respectively provided with check valves 57 and 58. Whether the flow path for supply of oil to the gear pump 21 from the tank 80 is the first supply flow path 77 or the second supply flow path 78 is determined in accordance with the rotating direction of the gear pump 21.
(Third Relief Valve 55)
The cylinder-side and first chamber-side flow path 71A is connected with a third relief valve 55 (third relief valve). The third relief valve 55 is normally closed and opens when the pressure of the cylinder-side and first chamber-side flow path 71A has become greater than or equal to a pressure set in advance (pressure higher than the pressure at which the up blow valve 53 is opened) to allow oil in the cylinder-side and first chamber-side flow path 71A to escape to a third open flow path 75 communicating with the tank 80.
The following case is an example of a case where the pressure of the cylinder-side and first chamber-side flow path 71A becomes greater than or equal to a pressure set in advance. That is, such a case is when load such as an impact is applied in a direction to compress the cylinder device 10 in a state where the cylinder device 10 is extended or when the pressure of the cylinder-side and first chamber-side flow path 71A has risen due to a rise in temperature of oil. In this case, the third relief valve 55 opens to return oil supplied to the cylinder-side and first chamber-side flow path 71A to the tank 80 via the third open flow path 75.
In the flow path communicating with the tank 80, a filter 83 is provided to prevent foreign matter or the like mixed in oil within the tank 80 from flowing into the respective flow paths described above.
<Pump Device 20>
As shown in
The pump device 20 is configured integrally, as shown in
The first case 22 is formed with a groove 22b at the bottom surface. The first case 22 is formed with a pump chamber 22a that accommodates the gear pump 21, check valve chambers 22g and 22h that accommodate the check valves 57 and 58, and a first check valve chamber 22m (see
The first check valve chamber 22m and the second check valve chamber 22n are each formed to penetrate in the direction of stacking the first case 22 and the second case 23.
The second case 23 is formed with the first valve chamber 51f and the second valve chamber 52f. The first valve chamber 51f and the second valve chamber 52f are each formed to also penetrate in the thickness direction of the second case 23. The second case 23 is formed with an up blow valve chamber 23a that accommodates the up blow valve 53, a down blow valve chamber 23b that accommodates the down blow valve 54, and a third relief valve chamber 23c that accommodates the third relief valve 55.
The cover plate 24 is, for example, an iron plate and closes an opening 23x (see
As shown in
The up blow valve 53 and the down blow valve 54 are arranged respectively in the up blow valve chamber 23a and the down blow valve chamber 23b. The up blow valve 53 includes a valve ball 53d for opening and closing between the pump-side and first chamber-side flow path 71B continuous with the check valve chamber 22g and the first open flow path 73 continuous with the tank chamber 82, a push pin 53c that contacts the valve ball 53d from above, an adjustment screw 53a that is coaxial with the push pin 53c and screwed and joined to the up blow valve chamber 23a such that an upper section formed with a groove 53e for a tool protrudes upward from the second case 23, and a coil spring 53b arranged between the push pin 53c and the adjustment screw 53a to cause an elastic force in the axis direction in accordance with the distance between the push pin 53c and the adjustment screw 53a to act with respect to the push pin 53c.
With the up blow valve 53 configured in this manner, the screw depth of the adjustment screw 53a with respect to the second case 23 can be changed by inserting an easily available tool such as, for example, a slotted driver to the groove 53e of the adjustment screw 53a that protrudes outside the second case 23 and rotating the tool about the axis.
As the screw depth of the adjustment screw 53a increases, the distance between the pushpin 53c and the adjustment screw 53a decreases, the initial compression amount of the coil spring 53b increases, the elastic force of the coil spring 53b to press the push pin 53c downward increases, and the load by which the valve ball 53d in contact with the push pin 53c closes the pump-side and first chamber-side flow path 71B increases. This means that the pressure of the pump-side and first chamber-side flow path 71B for transition to an operation of opening the closed up blow valve 53 has been set to be higher.
As the screw depth of the adjustment screw 53a decreases, the distance between the pushpin 53c and the adjustment screw 53a increases, the initial compression amount of the coil spring 53b decreases, the elastic force of the coil spring 53b to press the push pin 53c downward decreases, and the load by which the valve ball 53d in contact with the push pin 53c closes the pump-side and first chamber-side flow path 71B decreases. This means that the pressure of the pump-side and first chamber-side flow path 71B for transition to an operation of opening the closed up blow valve 53 has been set to be lower.
In this manner, the adjustment screw 53a of the up blow valve 53 is a pressure adjustment mechanism that adjusts the pressure (working pressure) for actuation (transition from a closed state to an open state) of the up blow valve 53.
In a similar manner to the up blow valve 53, the down blow valve 54 includes a valve ball 54d for opening and closing between the pump-side and second chamber-side flow path 72B continuous with the check valve chamber 22h and the second open flow path 74 continuous with the tank chamber 62, a push pin 54c that contacts the valve ball 54d from above, an adjustment screw 54a that is coaxial with the push pin 54c and screwed and joined to the down blow valve chamber 23b such that an upper section formed with a groove 54e for a tool protrudes upward from the second case 23, and a coil spring 54b arranged between the push pin 54c and the adjustment screw 54a to cause an elastic force in the axis direction in accordance with the distance between the push pin 54c and the adjustment screw 54a to act with respect to the pushpin 54c. The adjustment screw 54a of the down blow valve 54 is also a pressure adjustment mechanism similar to the adjustment screw 53a of the up blow valve 53.
The adjusting action for the working pressure of the down blow valve 54 is the same as the adjusting action by the up blow valve 53, and therefore description is omitted.
The check valves 57 and 58 are respectively arranged in the check valve chambers 22g and 22h formed in the first case 22. The check valves 57 and 58 are arranged in the respective check valve chambers 22g and 22h in a step before the first case 22 and the second case 23 are stacked.
The check valve chambers 22g and 22h communicate with holes 22c and 22d that extend downward. The holes 22c and 22d are formed in such a size to be closed by the check valves 57 and 58 and are continuous with the groove 22b formed in the lower surface of the pump case 25. Since the pump device 20 is immersed in oil in the tank chamber 82, the groove 22b is filled with oil. The holes 22c and 22d correspond to the first supply flow path 77 and the second supply flow path 78 in the hydraulic circuit.
As shown in
By the cover plate 24 being stacked on and fixed to the second case 23 in a state where the first actuation valve 51b is arranged in the first valve chamber 51f and the second actuation valve 52b is arranged in the second valve chamber 52f, the upper surfaces of the first valve chamber 51f and the second valve chamber 52f are closed. At this time, O-rings 24a and 24b are attached respectively between the first valve chamber 51f and the cover plate 24 and between the second valve chamber 52f and the cover plate 24 to ensure liquid-tightness of the first valve chamber 51f and the second valve chamber 52f.
Since the first valve chamber 51f and the second valve chamber 52f are each formed to penetrate in the thickness direction of the second case 23, the accommodated first actuation valve 51b and second actuation valve 52b both slide along the direction of stacking the first case 22 and the second case 23.
The second case 23 is formed with the communication path 51R described with the hydraulic circuit to connect the sub oil chamber 51h of the first valve chamber 51f and the sub oil chamber 52h of the second valve chamber 52f.
On the first case 22 side in the main oil chamber 51g, a step section 23m that protrudes toward the inner side of the main oil chamber 51g is formed.
By protruding toward the inner side of the main oil chamber 51g, the step section 23m forms a pressure receiving surface 23s on which a pressure p1 that acts on the main oil chamber 51g acts toward the first case 22. The pressure receiving surface 23s is formed in an annular shape parallel to stacked surfaces 22A and 23A of the first case 22 and the second case 23.
The inner circumferential edge of the annular pressure receiving surface 23s is formed to have a diameter D2 smaller than an inner diameter D1 of a portion of the main oil chamber 51g within which the spool 51c slides. The main oil chamber 51g faces the surface 22A of the first case 22 by the inner diameter D2 of the pressure receiving surface 23s.
Although not shown in the drawing, the second valve chamber 52f is similar in configuration to the first valve chamber 51f shown in
The first check valve chamber 22m formed in the first case 22 is formed in a portion opposing the first valve chamber 51f in a state where the first case 22 and the second case 23 are stacked. The second check valve chamber 22n formed in the first case 22 is formed in a portion opposing the second valve chamber 52f in a state where the first case 22 and the second case 23 are stacked.
The first check valve 51e is configured to include an O-ring 51m, a valve case 51n, a valve ball 51p, a push pin 51q, a coil spring 51r, a spring holder 510, and an O-ring 51t.
The valve case 51n is fitted to the first check valve chamber 22m with the O-ring 51m therebetween. At an upper section of the valve case 51n, a small hole 51u is formed for the protrusion 51i of the opposing first actuation valve 51b to be passed through. The valve ball 51p, the push pin 51q, and the coil spring 51r are arranged in a case inner chamber 51s formed on the inner side of the valve case 51n.
The valve ball 51p is formed in such a size to close the small hole 51u formed in the valve case 51n. The pushpin 51q is arranged beneath the valve ball 51p such that the valve ball 51p contacts the upper surface. The spring holder 51o is fitted to a lower section of the first check valve chamber 22m to support the valve case 51n from below. The O-ring 51t is arranged around the spring holder 510. The coil spring 51r is arranged between the push pin 51q and the spring holder 51o to cause an elastic force in the axis direction to act with respect to the push pin 51q.
In a state where the pump device 20 is fixed to the housing 81 as shown in
In the first check valve 51e configured in this manner, the push pin 51q held upward by the elastic force of the coil spring 51r pushes the valve ball 51p upward such that the valve ball 51p closes the small hole 51u of the valve case 51n. Accordingly, it is closed between the main oil chamber 51g of the first actuation valve 51b and the case inner chamber 51s of the first check valve 51e.
When oil is supplied to the main oil chamber 51g of the first actuation valve 51b and the pressure of the main oil chamber 51g rises, the pressure of the main oil chamber 51g acts on the valve ball 51p through the small hole 51u, the valve ball 51p is pushed downward against the elastic force of the coil spring 51r, the main oil chamber 51g and the case inner chamber 51s are communicated, and oil in the main oil chamber 51g is supplied to the first housing hole 81a through the case inner chamber 51s.
When oil is supplied to the main oil chamber 52g of the second actuation valve 52b and the pressure of the main oil chamber 52g rises, oil in the main oil chamber 52g flows through the second hole 52k of the spool 52c to the sub oil chamber 52h, the first hole 52j, and the communication path 51R in that order and further flows into the sub oil chamber 51h of the first actuation valve 51b through the first hole 51j of the first actuation valve 51b.
In the sub oil chamber 51h of the first actuation valve 51b, a rise in pressure causes the actuation valve ball 51d to block communication of the sub oil chamber 51h and the main oil chamber 51g. Accordingly, the spool 51c of the first actuation valve 51b moves to the main oil chamber 51g side. Due to the movement of the spool 51c, the protrusion 51i provided to the spool 51c acts on the valve ball 51p for a push downward against the elastic force of the coil spring 51r, the main oil chamber 51g and the case inner chamber 51s are communicated, and oil returned to the case inner chamber 51s from the first housing hole 81a is returned to the main oil chamber 51g.
The second check valve 52e accommodated in the second check valve chamber 22n is similar in configuration to the first check valve 51e and includes an O-ring 52m, a valve case 52n, a valve ball 52p, a push pin 52q, a coil spring 52r, a spring holder 52o, and an O-ring 52t. The second check valve 52e acts in the same manner as the first check valve 51e, and therefore description is omitted.
In a state where the pump device 20 is fixed to the housing 81 (see
The third relief valve 55 is arranged across the first case 22 and the second case 23. In a similar manner to the up blow valve 53 and the down blow valve 54, the third relief valve 55 includes a valve ball 55d for opening and closing between the cylinder-side and first chamber-side flow path 71A communicating with the case inner chamber 51s of the first check valve 51e and the third open flow path 75, a push pin 55c that contacts the valve ball 55d from above, an adjustment screw 55a that is coaxial with the push pin 55c and screwed and joined to the second case 23 such that an upper section formed with a thread groove 55e protrudes upward from the second case 23, and a coil spring 55b arranged between the push pin 55c and the adjustment screw 55a to cause an elastic force in the axis direction in accordance with the distance between the push pin 55c and the adjustment screw 55a to act with respect to the push pin 55c. The adjustment screw 55a of the third relief valve 55 is also a pressure adjustment mechanism similar to the adjustment screw 53a of the up blow valve 53.
The adjusting action for the working pressure of the third relief valve 55 is the same as the adjusting action by the up blow valve 53 or the down blow valve 54, and therefore description is omitted.
<Action and Effect of Pump Device 20>
With the pump device 20 and the trim tilt device 100 of this embodiment configured in a manner described above, the pressure p1 of oil that acts on the main oil chambers 51g and 52g acts uniformly on the inner surface of the main oil chambers 51g and 52g, as shown in
Thus, in a portion facing the surface 22A of the first case 22, the pressure p1 of the main oil chambers 51g and 52g acts to press the surface 22A of the first case 22. That is, the pressure p1 of the main oil chambers 51g and 52g acts to separate the surface 22A of the first case 22 and the surface 23A of the second case 23 from each other.
Since an area S2 of the main oil chamber 51g facing the surface 22A of the first case 22 is represented as S2=πD22/4, a load F2 that acts in a direction to separate the first case 22 and the second case 23 is represented as F2=p1πD22/4.
Since an area S3 of the main oil chamber 51g facing the surface 22A of the first case 22 in a conventional pump device in which the pressure receiving surface 23s is not formed is represented as S3=πD12/4, a load F3 that acts in a direction to separate the first case 22 and the second case 23 is represented as F3=p1πD12/4. Since D2<D1, F2<F3.
In this manner, the pump device 20 and the trim tilt device 100 of this embodiment can reduce pressure that acts on the stacked surfaces 22A and 23A of the first case 22 and the second case 23 and that is in a direction to separate the first case 22 and the second case 23 from each other, compared to when the pressure receiving surface 23s is not formed.
Further, the pressure p1 of the main oil chambers 51g and 52g also acts on the pressure receiving surface 23s formed in each of the first valve chamber 51f and the second valve chamber 52f. The pressure p1 that acts on the pressure receiving surface 23s acts to press the step section 23m to the first case 22 side. Thus, the pressure p1 that acts on the pressure receiving surface 23s acts to push the surface 23A of the second case 23 against the surface 22A of the first case 22. That is, the pressure p1 that acts on the pressure receiving surface 23s acts to inhibit the surfaces 22A and 23A of the first case and the second case 23 from being separated.
Since an area S1 of the pressure receiving surface 23s of the main oil chambers 51g and 52g is represented as S1=π(D1−D2)2/4, a load F1 that inhibits the surfaces 22A and 23A of the first case 22 and the second case 23 from being separated is represented as F1=p1π(D1−D2)2/4.
In this manner, the pump device 20 and the trim tilt device 100 of this embodiment can reduce pressure that acts on the stacked surfaces 22A and 23A of the first case 22 and the second case 23 and that is in a direction to separate the first case 22 and the second case 23 from each other, compared to when the pressure receiving surface 23s is not formed, and cause pressure that inhibits the first case 22 and the second case 23 from separating to act.
Accordingly, leakage of oil at the stacked surfaces 22A and 23A of the first case 22 and the second case 23 can be prevented or suppressed.
In the pump device 20 of this embodiment, the switching valve 51, the up blow valve 53, the down blow valve 54, the third relief valve 55, and the check valves 57 and 58 included in the hydraulic circuit connected to the cylinder device 10 are provided integrally with the pump device 20.
Thus, the performance of the entire hydraulic circuit built in with the switching valve 51, the up blow valve 53, the down blow valve 54, the third relief valve 55, and the check valves 57 and 58 can be measured in a step of measuring the performance such as the oil pressure-feed capability of the gear pump 21 in a state where the pump device 20 is alone before being assembled with the cylinder device 10.
Accordingly, the number of steps for a performance measurement of the pump device 20 and the hydraulic circuit can be reduced.
Due to the switching valve 51, the up blow valve 53, the down blow valve 54, the third relief valve 55, and the check valves 57 and 58 in the hydraulic circuit being provided integrally with the pump device 20, a valve of the hydraulic circuit is not arranged in the housing 81.
Thus, in the housing 81 of this embodiment, the flow path (the cylinder-side and first chamber-side flow path 71A and the cylinder-side and second chamber-side flow path 72A) to be formed can be simplified, compared to a housing of a conventional trim tilt device in which a valve is arranged. As a result, portions connected by intersection of holes that are flow paths can be reduced in the flow path (the cylinder-side and first chamber-side flow path 71A and the cylinder-side and second chamber-side flow path 72A) formed in the housing 81.
In the portion where the holes intersect, there is a tendency that a burr easily remains upon boring and working the hole. By reducing portions where the holes intersect, a burr can be made less likely to remain in the flow path.
The pump device and the hydraulic actuator according to the present invention is not limited to a form in which the switching valve 51, the up blow valve 53, the down blow valve 54, the third relief valve 55, and the check valves 57 and 58 in the hydraulic circuit of the trim tilt device 100 are provided integrally with the pump device 20. A valve may be provided to, for example, the housing 81 separately from the pump device 20.
Note that, when more valves are provided integrally with the pump device 20, more valve chambers for accommodating the valves are formed in the second case 23. Therefore, the rigidity of the second case 23 easily decreases. With a lower rigidity of the second case 23, the stacked surfaces 22A and 23A of the first case 22 and the second case 23 are more easily separated by the pressure of oil that acts on the main oil chamber 51g. Thus, by applying the present invention with respect to the pump device including the second case with such low rigidity, an effect of the present invention that the surfaces 22A and 23A are less likely separated can be exhibited more significantly.
In the pump device 20 of this embodiment, the first valve chamber 51f and the second valve chamber 52f are formed with the opening 23x on the opposite side of the first case 22. Thus, even if the pressure receiving surface 23s is formed by the step section 23m or the like on the first case 22 side in the first valve chamber 51f and the second valve chamber 52f, the first actuation valve 51b can be accommodated in the first valve chamber 51f from the opening 23x side, and the second actuation valve 52b can be accommodated in the second valve chamber 52f from the opening 23x side.
In the pump device 20 of this embodiment, the first valve chamber 51f and the second valve chamber 52f are open on the opposite side of the first case 22, the openings 23x are closed by the cover plate 24, and the cover plate 24 is fixed integrally with the first case 22 and the second case 23 by the fastening members 28a to 28e. Thus, even if the rigidity of the second case 23 decreases due to the opening of the first valve chamber 51f and the second valve chamber 52f being formed, the decreased rigidity can be improved by the cover plate 24.
In the pump device 20 and the trim tilt device 100 of the embodiment described above, two relief valves that are the up blow valve 53 and the third relief valve 55 are provided in the first chamber-side flow path 71 communicating with the first chamber Y1 of the cylinder device 10, as shown in
In the pump device 20 and the trim tilt device 100 of this embodiment, the cover plate 24 that is an iron plate or the like is applied as the covering member that covers the respective openings 23x of the first valve chamber 51f and the second valve chamber 52f, as shown in
<<Embodiment 2>>
In the pump device 20 and the trim tilt device 100 of Embodiment 1, the pressure receiving surface 23s is formed by the step section 23m. However, the pump device and the trim tilt device according to the present invention are not limited to this form.
On the first case 22 side in the main oil chamber 51g in Embodiment 2, an inclined surface 23n inclined from the inner circumferential surface of the main oil chamber 51g toward the surface 22A of the first case 22 is formed.
The inclined surface 23n is inclined with respect to the surface 22A of the first case 22, but the pressure pl that acts on the pressure receiving surface 23s has a component orthogonal to the surface 22A of the first case 22. Thus, the inclined surface 23n forms the pressure receiving surface 23s such that the pressure p1 of oil that acts on the main oil chamber 51g acts toward the first case 22.
By the inclined surface 23n being formed, the area of the surface of the main oil chamber 51g facing the surface 22A of the first case 22 is smaller than when the inclined surface 23n is not formed.
Since the pressure p1 acts uniformly on the inner surface of the main oil chamber 51g, the load of the pressure p1 of the oil in the main oil chamber 51g that acts on the surface 22A of the first case 22 to separate the surface 22A of the first case 22 and the surface 23A of the second case 23 from each other is smaller than when the pressure receiving surface 23s is not formed.
The pressure p1 of oil in the main oil chamber 51g also acts on the pressure receiving surface 23s, and the pressure that acts on the pressure receiving surface 23s acts as a load to push the surface 23A of the second case 23 against the surface 22A of the first case 22. That is, the pressure p1 that acts on the pressure receiving surface 23s acts to inhibit the surfaces 22A and 23A of the first case 22 and the second case 23 from separating.
In this manner, the pump device 20 and the trim tilt device 100 of this embodiment can reduce pressure in a direction to separate the first case 22 and the second case 23 from each other, and cause pressure that inhibits the first case 22 and the second case 23 from separating to act.
Accordingly, leakage of oil at the stacked surfaces 22A and 23A of the first case 22 and the second case 23 can be prevented or suppressed.
The pressure receiving surface 23s is not limited to those of Embodiments 1 and 2 described above. In short, the surface may be in any form as long as the surface is formed in a valve chamber that accommodates an actuation valve of a second case and causes the pressure of hydraulic fluid that acts on the valve chamber to act toward a first case.
In the respective embodiments described above, the trim tilt device is applied as one example of the hydraulic actuator. However, the hydraulic actuator of the present invention is not limited to such trim tilt devices.
Number | Date | Country | Kind |
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2014-062716 | Mar 2014 | JP | national |
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Entry |
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Office Action dated Oct. 10, 2017 for the corresponding Chinese Patent Application No. 201410594901.8. |
Number | Date | Country | |
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20150275929 A1 | Oct 2015 | US |