The present invention relates to a control valve for use in both-hand operation, and more particularly to that used in a case of driving a fluid pressure driving device in which both hands of an operator have to be separated off from a dangerous area.
A control valve for use in both-hand operation is hitherto known as that used in a case that dangerousness of injury of hands by accident caused by a movement of the fluid pressure driving device is expected in operators who performs manual operation for the fluid pressure driving device.
That is, the control valve for use in both-hand operation is used in a case that, for example, both hands are required to be separated off from a dangerous area when an air pressure cylinder is started. In the control valve for use in both-hand operation, signal pressure is outputted to an output side, on the basis of both-side pressure of inputs supplied through press button valves when the separate press button valves are respectively operated by both left and right hands at approximately the same time, in concrete terms, within 0.5 second. Further, when a hand(s) is removed from one or both press button valve(s), the signal pressure to the output side is shut off at once, the drive for the air pressure cylinder, or the like in fluid pressure driving device driven by the signal pressure is stopped.
In recent years, simplification and miniaturization of a construction of various types of devices are required, and even in the control valve for use in both-hand operation performing such a movement as described above, the simplification and the miniaturization of a construction of an entire control valve are required. However, for achieving the miniaturization for the control valve for use in both-hand operation, since the control valve is constructed housing a number of valves provided with various functions in a valve body, not only each of the individual valves is required to be miniaturized, but also the valves have to be compactly housed in the valve body.
A technical problem of the present invention is to provide a control valve for use in both-hand operation, entire construction of which is enabled to be simple and miniaturized as well as possible.
Another technical problem of the present invention is to consider the miniaturization of each of the valves in the control valve for use in both-hand operation that is constructed upon housing a number of valves provided with various functions in a valve body, and at the same time, to form a miniaturized and compact-sized control valve for use in both-hand operation by means of an appropriate arrangement of the valves.
Still another technical problem of the present invention is to provide a control valve for use in both-hand operation enabled to manufacture and process the valve body with ease.
To solve the above-described problems, a control valve for use in both-hand operation is characterized in that two manual operation valves to be operated by left and right hands are respectively connected to two main input ports of a valve body, and when the two manual operation valves are operated within a certain time, air pressure is outputted to a fluid pressure driving device from a main output port on the basis of an output of the manual operation valves, and an AND valve and a shuttle valve connected between both of main input ports by respectively connecting one of pairs of input ports to the aforementioned two main input ports, a main switching valve in which a valve input port is connected to an output port of the aforementioned AND valve, and a valve output port is connected to the aforementioned main output port, and a tank connected to an output port of the aforementioned shuttle valve through an aperture, in an inner part of the valve body, and a capacity of the tank is set such that a time until an internal pressure of the tank reaches a certain set pressure by compressed air flowing into the tank through the aforementioned aperture becomes equal to a time difference allowed for operation for the aforementioned two manual operation valves, and the pressure in the tank is applied to a valve member of the main switching valve and a communication between the valve input port of the main switching valve and the valve output port thereof is blocked by the set pressure, in which a cover for forming the aforementioned tank is fixed in an airtight manner at an upper surface of the aforementioned valve body, and the aforementioned AND valve, the shuttle valve, and each valve hole of the main switching valve, are opened from an upper surface of the valve body, and in which a plate for closing the valve holes is fixed to the upper surface of the valve body in an airtight manner, and a continuous hole for introducing the internal pressure of the aforementioned tank into a first pressure-receiving end surface of the valve member in the main switching valve and a continuous hole for allowing a flowing passage from the shuttle valve to communicate with the tank through the aperture are pierced in the plate.
In a preferred embodiment of the present invention, the control valve for use in both-hand operation is constructed as described below, in which the aforementioned main switching valve is formed of a spool-type valve, and the valve input port to which the compressed air is supplied from the AND valve, the valve output port outputting the compressed air to the aforementioned main output port from the switching valve, and a balancing pressure port for applying pressure of the compressed air in the valve output port to a second pressure-receiving end surface at opposite side of the aforementioned first pressure-receiving end surface of the valve member are opened in the valve hole, and a land for open and close a flowing passage connecting the aforementioned valve input port and the valve output port is provided in the spool-type valve member sliding in the valve hole, and a return spring is housed at the second pressure-receiving end surface side of the valve member in the aforementioned valve hole, and the aforementioned return spring moves the valve member to a tank side in a case that the pressure in the tank does not reach the set value, and thereby the valve member is held at a switching position for allowing the valve input port to communicate with the valve output port, while the valve member is pressed overcoming returning force of the aforementioned return spring, and the valve member is held at a switching position where the valve member blocks the flowing passage connecting the valve input port and the valve output port, when the pressure is accumulated in the tank exceeding the aforementioned set pressure, and is applied to the first pressure-receiving end surface of the valve member.
In this case, it is required for the valve member in the aforementioned spool-type main switching valve to be configured such that a seat diameter of a peripheral surface of each of both ends of the first and second pressure-receiving end surfaces is substantially identical of the seat diameter of the land, and thereby the pressure applied to the valve member in a direction of an axis line is balanced.
In another preferred embodiment of the present invention, the aforementioned two of main input ports are disposed in a manner to be lined in an above and below direction at a position in one-half of one side face of the valve body having approximately rectangular parallelepiped, and the aforementioned main output port, and an exhaust port that exhausts air pressure from the main output port are disposed at a position in the other-half of the one side face in a manner to be lined in an above and below direction, and the aforementioned AND valve and the shuttle valve are disposed at a backside of the aforementioned main input ports, and are allowed to communicate with a flowing passage led to the aforementioned main input ports, and the aforementioned switching vale is disposed to be positioned at a backside of the aforementioned main output port and the aforementioned exhaust port in a manner so as to be lined with the AND valve.
Further, still another preferred embodiment of the present invention is constructed as described below, in which the valve output port of the aforementioned main switching valve is allowed to communicate with the main output port through an exhaust flowing passage of a rapid exhaust valve having a checking function, and the exhaust valve member of the aforementioned rapid exhaust valve is formed of a rubber elastic material, and a checking function portion is provided at a periphery of the exhaust valve member, and seat portions that contact with or separate from an exhaust valve seat led to the aforementioned exhaust port and an exit valve seat led to the valve output port of the aforementioned main switching valve are provided at both end faces of the exhaust valve member, and when output pressure exists in the valve output port of the aforementioned main switching valve, the exhaust valve member is brought to be in contact with an exhaust valve seat side with pressure and one of seat portions thereof closes the exhaust valve seat, and the output of the aforementioned valve output port flows out through the checking function portion, and is outputted to the main output port through the aforementioned exhaust flowing passage, and when the output pressure does not exist in the aforementioned valve output port, the exhaust valve member is brought to be in contact with the exit valve seat side with pressure and the aforementioned exhaust valve seat is released, and the compressed air in the main output port is rapidly exhausted from the exhaust port through the aforementioned exhaust flowing passage.
1 control valve for use in both-hand operation
2
a, 2b manual operation valve
3 air pressure source
5 fluid pressure driving device
6 air pressure cylinder
7
a, 7b speed controller
8 switching valve
9 pressure supplying source
10 valve body
11
a, 11b main input port
12 main output port
13 exhaust port
14 ventilation port
15 tube joint
20 AND valve
20
a input port
20
b output port
21 shuttle valve (OR valve)
21
a input port
21
b output port
23 main switching valve
23
a valve input port
23
b valve output port
23
c residual pressure discharging port
23
d balancing pressure port
25 flowing amount control element
26 aperture
27 check valve
30 tank
31 cover
33 plate
33
a, 33b communication hole
35 valve member
35
a first pressure-receiving end surface
35
b second pressure-receiving end surface
36 valve hole
37
a, 37b land
38 return spring
40 rapid exhaust valve
41 exhaust valve member
41
a checking function portion
41
b, 41c seat portion
42 exhaust flowing passage
43 exhaust valve seat
44 exit valve seat
Hereinbelow, an embodiment of the present invention will be explained in detail on the bases of the drawings.
As the aforementioned fluid pressure driving device 5, an air pressure cylinder 6 that drives various types of devices, a pair of speed controller, 7a and 7b, which controls driving speed of a reciprocating movement of the air pressure cylinder 6, a switching valve 8 driven by air pressure, which controls driving operation of the aforementioned air pressure cylinder 6 on the basis of output of the aforementioned control valve 1 for use in both-hand operation, a pressure supplying source 9 that supplies compressed air to the air pressure cylinder 6 through the switching valve 8 are shown here. The switching valve 8 is constructed as a five-port valve that drives the air pressure cylinder 6 in a direction where dangerousness exists during the time the output pressure of the control valve 1 for use in both-hand operation, serving as pilot fluid pressure, is supplied, and when the output pressure of the control valve 1 is reduced, returns the air pressure cylinder 6 to a side of safeness. However, the switching valve 8 is not limited to have such a construction, and various types of structures that appropriately drives the fluid pressure driving device 5 and stops the device at once at the side of safeness when the output pressure of the control valve 1 is reduced can be adopted.
The aforementioned control valve 1 for use in both-hand operation is provided with two main input ports, 11a and 11b, for individually connecting the aforementioned two three-port manual operation valves, 2a and 2b, in a valve body 10, as shown in
Further, at a position in the other-half of the one side face of the aforementioned valve body 10 where the aforementioned main input ports, 11a and 11b, are disposed, a main output port 12 that outputs signal pressure (air pressure) to the switching valve 8 of the fluid pressure driving device 5, and an exhaust port 13 that exhausts air pressure that is being supplied to the switching valve 8 are disposed in a manner to be lined in an above and below direction, as is clear from
The aforementioned main output port 12 is a port which outputs air pressure as pilot fluid pressure to the switching valve 8 of the fluid pressure driving device 5, when compressed air is supplied to both the main input ports, 11a and 11b, from both of the operation valves, 2a and 2b, approximately at the same time. The aforementioned exhaust port 13 is a port which discharges the air pressure that is being supplied to the switching valve 8, when the compressed air is not supplied to the main input ports from at least one of both the manual operation valves, 2a and 2b, namely both of the main input ports, 11a and 11b, are brought to a state that the compressed air is not supplied thereto.
When the construction of the aforementioned control valve 1 in se for use in both-hand operation is further concretely explained, firstly, as shown in
The aforementioned AND valve 20 and the OR valve 21 are disposed at a backside of the main input ports, 11a and 11b, connected to the aforementioned manual operation valves, 2a and 2b, at one side face of the valve body 10, facing each of axis lines in a direction in which the main input ports, 11a and 11b, are disposed, namely in a condition in parallel with an above and below direction of the drawing, and are allowed to communicate with the flowing passage led to the aforementioned main input ports, 11a and 11b. More in concrete, a valve hole is pierced from an upper surface of the valve body 10 at a backside position of the aforementioned main input ports, 11a and 11b, and valve mechanisms of the AND valve 20 and that of the shuttle valve 21 are housed in the valve hole. A connecting operation for each of the pair of input ports, 20a and 20a, in the AND valve 20, and the pair of input ports, 21a and 21a, in the shuttle valve 21, and the aforementioned main input ports, 11a and 11b, are performed by means of allowing a hole pierced in an inner back of the main input ports, 11a and 11b, to communicate with valve holes of the aforementioned AND valve 20 and the shuttle valve 21.
Further, the output port 20b of the aforementioned AND valve 20 is connected to a valve input port 23a of the main switching valve 23, as shown in
The tank 30 is a tank whose capacity is set such that a time for internal pressure of the tank 30 to reach a certain pressure by the compressed air that flows therein through the aforementioned flowing amount control element 25 equals a time difference allowed for the operation for two of the manual operation valves, 2a and 2b performed with both hands. The pressure in the tank 30 is configured to be applied to a first pressure-receiving end surface 35a of a valve member 35 so that the valve member (spool valve) 35 in a spool-type main switching valve 23 is driven, as shown in
The aforementioned spool-type main switching valve 23 is constructed by piercing a valve hole 36 from an upper surface of the valve body 10 to be positioned in parallel with the AND valve 20 at the backside of the aforementioned main output port 12 and the aforementioned exhaust port 13, and by inserting the aforementioned valve member 35 of a spool type into the valve hole 36, as is clear from
The aforementioned tank 30 is a tank formed by means of joining a cover 31 on the valve body 10 therein, as is clear from
In the aforementioned spool-type main switching valve 23, as clearly shown in
Furthermore, a return spring 38 is housed at side of the second pressure-receiving end surface 35b of the valve member 35 in the aforementioned valve hole 36, and repulsion force of the return spring 38 is applied to the valve member 35. A strength of the repulsion force of the return spring 38 is configured such that the valve member 35 is pressed overcoming repulsion force of the aforementioned return spring 28 when the pressure is accumulated in the aforementioned tank 30 exceeding a certain set pressure and applied to the pressure-receiving end surface 35a of the valve member 35, the valve member 35 is held at a position where the land 37a blocks an area between the valve input port 23a and the valve output port 23b, while the valve member 35 is held in a condition to be moved to a side of the tank 30, in a case that the compressed air is not filled in the tank 30 through the aforementioned aperture 26, or that the pressure of the compressed air does not reach a certain set pressure, and thereby the valve member 35 is held at a switching position of
The valve member 35 in the aforementioned spool-type main switching valve 23 is configured such that a seat diameter of a peripheral surface of the sides of the pressure-receiving end surfaces 35a and 35b at both sides of the valve member 35, and the seat diameters of the lands, 37a and 37b, are formed to be substantially the same so as for the valve member 35 to be moved while balancing the pressure to be applied thereto in a direction of an axis line. However, when the spool-type main switching valve 23 having the valve member 35 with thus balanced pressure is used, the valve hole 36 can be miniaturized compared to a case using a switching valve, such as, for example, a poppet valve, or the like that is hard to balance the pressure, and as a result, the valve body 10 can be miniaturized. Specifically, the miniaturization for the aforementioned valve hole 36 is effective for the miniaturization for the valve body 10 in a case that each of the valve holes of the AND valve 20, shuttle valve 21, and the main switching valve 23, is pierced in a parallel manner from the upper surface of the valve body 10, as in the aforementioned control valve 1 for use in both-hand operation.
As shown in
In more concrete explanation, an exhaust valve member 41 of the rapid exhaust valve 40 is formed of a rubber elastic material, and includes a fin-like checking function portion 41a around a periphery thereof, and seat portions, 41b and 41c at both faces. In the seat portions, 41b and 41c, the seat portion 41b contacts with or separates from the exhaust valve seat 43 positioned inside the aforementioned exhaust port 13, and similarly, the seat portion 41c contacts with or separates from an exit valve seat 44 positioned at an outside of the valve output port 23b of the aforementioned main switching valve 23b and facing the aforementioned exhaust valve seat 43.
Accordingly, when the output pressure exists in the valve output port 23b of the aforementioned main switching valve 23, the exhaust valve member 41 is thereby brought to be in contact with the exhaust valve seat 43 side with pressure, and the seat portion 41b closes the exhaust valve seat 43, and the output of the aforementioned valve output port 23b presses the checking function portion 41a at the periphery of the exhaust valve member 41 and flows out therefrom, and further, outputted to the main output port 12 passing through the exhaust flowing passage 42. Furthermore, when the output pressure does not exist in the aforementioned valve output port 23b, and compressed air exists at the main output port 12 side, the exhaust valve member 41 is brought to be in contact with the exit valve seat 44 side with pressure. Thereby, the aforementioned exhaust valve seat 43 is opened and at the same time, the output valve seat 44 is closed by the seat portion 41c of the exhaust valve member 41. As a result, the compressed air in the main output port 12 is rapidly exhausted from the exhaust port 13 through the aforementioned exhaust flowing passage 42.
In the control valve 1 for use in both-hand operation, when the operator takes off his or her hand from at least one of the manual operation valves, the compressed air that is being outputted from the main output port 12 is required to be rapidly exhausted so that the fluid pressure driving device 5 is stopped at once or is brought to a safe condition. However, since the exhaust port 13 is provided in the positional relationship described above, the same can be formed to have a large diameter. However, the valve body 10 is not caused to be large-sized resulting from forming the exhaust port 13 to have a large diameter.
Next, the operation of the control valve 1 for use in both-hand operation having the construction described above will be explained.
In the aforementioned control valve 1 for use in both-hand operation, when one of the manual operation valves 2a or 2b in
When the other of the manual operation valves, 2b or 2a, is pressed before the internal pressure of the aforementioned tank 30 reaches the set pressure, the compressed air flows into both the input ports, 20a and 20a, of the AND valve 20, and thereby an output is generated at the output port 20b of the AND valve 20 and reaches the valve input port 23a of the main switching valve 23. On the other hand, since the internal pressure of the aforementioned tank 30 has not reached until the set pressure at this moment, the main switching valve 23 is at a switching position shown in
Incidentally, even when the output from the shuttle valve 21 is accumulated to the tank 30 through the aperture 26, and reaches a set pressure, the valve member 35 cannot be switched by the pressure in the aforementioned tank 30. This is because, when the compressed air reaches the valve output port 23b from the valve input port 23a of the main switching valve 23, the compressed air flows into the balancing pressure port 23d and is applied to the second pressure-receiving end surface 35b of the valve member 35.
In a case that the aforementioned other of the manual operation valve is not pressed until the internal pressure of the aforementioned tank 30 reaches the set pressure, the internal pressure of the tank 30 is applied to the first pressure-receiving end surface 35a of the valve member 35 in the main switching valve 23, and the valve member 35 is switched by overcoming the returning force of the return spring 38 at the other end of the valve member 35. As a result, since the switching condition is configured such that the communication of the valve input port 23a of the switching valve 23 with the valve output port 23b thereof is blocked, even when the manual operation valve is pressed thereafter, the compressed air cannot be outputted to the fluid pressure driving device 5 through the main switching valve 23.
Further, when at least one of the aforementioned manual operation valves, 2a and 2b, is released by taking off the hand therefrom in a condition that the compressed air is supplied to the fluid pressure driving device 5 by pressing both the manual operation valves, 2a and 2b, the output from the AND valve disappears. Therefore, the pressure applied to the second pressure-receiving end surface 35b of the valve member 35 through the balancing pressure port 23d at the spool-type main switching valve 23 is reduced. In addition, since sufficient pressure is accumulated in the tank 30 at that moment, the valve member 35 of the main switching valve 23 is switched, and the communication between the valve input port 23a of the switching valve 23 and the valve output port 23b thereof is blocked.
Further, when the hands are taken off from both of the aforementioned manual operation valves, 2a and 2b, the compressed air from the air pressure source 3 is blocked at these valves. On the other hand, the compressed air accumulated in the tank 30 is discharged from either one of the manual operation valves, 2a and 2b, through the check valve 27 and the shuttle valve 21.
Number | Date | Country | Kind |
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2004-199545 | Jul 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2005/012302 | 7/4/2005 | WO | 00 | 1/5/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/004079 | 1/12/2006 | WO | A |
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Number | Date | Country | |
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20070256741 A1 | Nov 2007 | US |