This invention relates to a hydraulic ride control system for a working vehicle such as a wheel loader.
In digging/loading work by a wheel loader, earth, sand or the like loaded in a bucket is often moved to a predetermined place. When traveling with the load, up and down movements of the vehicle cause a boom to swing up and down due to an increased weight of the bucket, and as a result, amplify vibrations of the vehicle.
With a view to suppressing these vibrations, a bottom pressure chamber of a boom cylinder and an accumulator are brought into communication with each other during traveling to have pressure fluctuations in the bottom pressure chamber absorbed in the accumulator, and during digging work with a bucket, on the other hand, the communication with the accumulator is cut off to prevent the absorption of digging force in the accumulator. As a conventional technique of this sort, reference can be made to JP-A-2000-309953.
During digging work with the bucket, the opening control valve 57 is in the closed position G, so that the bottom pressure chambers 51a of the boom cylinder 51 and the accumulator 58 are kept out of communication to prevent the absorption of digging force, which is applied to the boom cylinders 51, in the accumulator 58.
During traveling, on the other hand, the solenoid valve 59 is switched to bring the opening control valve 57 into the closed position H. The bottom pressure chambers 51a of the boom cylinders 51 are, therefore, brought into communication with the accumulator 58 to have fluctuations in the load on the bottom pressure chambers 51a absorbed in the accumulator 58, so that vibrations of the vehicle can be suppressed.
In the above-described conventional technique, the opening control valve 57 is arranged to selectively bring the bottom pressures 51a of the boom cylinder 51 into communication with the accumulator 58 or to selectively cut off their communication. During the communication, the opening of the opening control valve 57 always remains constant. The weight of a front part, however, varies depending on the material or the like loaded on the bucket, the vehicle class, the front attachment, and the like. When the opening of the opening control valve 57 is excessively small relative to the weight of the front section, fluctuations in the load applied on a boom may not be fully absorbed in the accumulator 58 in some instances, in other words, vibrations may not be suppressed in some instances. When the opening is conversely too large relative to the weight of the front section, the vibrations of the front section may not be sufficiently attenuated so that the body of the working vehicle may be shaken to make it unstable in some instances. Accordingly, the conventional technique may not be able to fully absorb, in some instances, vibrations which take place as a result of a change in the weight of the front section.
An object of the present invention is to provide a hydraulic ride control system for a working vehicle, which irrespective of a variation in the weight of a front section of the vehicle, can suppress vibrations that take place when travelling with a load.
To achieve the above-described object, the present invention provides a hydraulic ride control system for a working vehicle, said system being provided with a hydraulic cylinder, an actuator control valve for controlling a pressure in a pressure chamber of the hydraulic cylinder, an accumulator connected to the pressure chamber of the hydraulic cylinder via a connection line, an opening control valve having a pilot chamber for selectively communicating or cutting off the connection line depending on a pressure in the pilot chamber, and a selector means for selectively feeding a pressure to or draining a pressure from the pilot chamber, wherein the selector means comprises a control means for variably controlling an opening of the opening control valve.
According to the present invention constructed as described above, it is only necessary to perform control by the control means such that the opening of the opening control valve becomes smaller when the weight of the front section is relatively small but becomes larger when the weight of the front section is large. In other words, the opening control valve can be controlled to an optimal opening by the control means in accordance with a change in the weight of the front section, and therefore, vibrations which take place when traveling with a load can be suppressed irrespective of a change in the weight of the front section.
In the above-described invention, the selector means may comprise a solenoid-operated proportional valve for controlling the opening control valve.
In the above-described invention, the hydraulic ride control system may further comprise a load pressure detection means for detecting a load pressure on the hydraulic cylinder and outputting a signal corresponding to the load pressure; and responsive to a signal outputted from the load pressure detection means, the control means may change the opening of the opening control valve.
In the above-described invention, the hydraulic ride control system may further comprise a vehicle speed detection means for detecting a vehicle speed of the working vehicle and outputting a signal corresponding to the vehicle speed; and responsive to a signal outputted from the vehicle speed detection means, the control means may change the opening of the opening control valve.
In the above-described invention, the hydraulic ride control system may further comprise an opening instruction means for outputting, responsive to an input by an operator, a signal that instructs an opening of the opening control valve; and responsive to the signal outputted from the opening instruction means, the control means may change the opening of the opening control valve.
In the above-described invention, the hydraulic ride control system may further comprise a selector valve arranged on a bypass line branching out from the connection line and disposed in parallel with the opening control valve such that the bypass line may normally be maintained in communication but may be cut off when a load pressure on the hydraulic cylinder has increased to at least a predetermined pressure.
In the above-described invention, a check valve may be arranged on the bypass line to bleed a pressure only from the hydraulic cylinder to the accumulator.
As the present invention can variably control the opening of the opening control valve by the control means depending on the weight of the front section, vibrations which take place when travelling with a load can be suppressed irrespective of the change in the weight of the front section. The present invention, therefore, makes it possible to improve the vibration suppression performance over the conventional technique.
Based on the accompanying drawings, a description will hereinafter be made of best modes for practicing the hydraulic ride control system according to the present invention for the working vehicle.
Referring first to
Referring next to
The branch circuit 24 is equipped with branch lines 9 and 10, which are branching out from the main lines 14 and 15, respectively, and are connectable to an accumulator 7 and the reservoir T, respectively, via an opening control valve 5. It is to be noted that the branch line 9 can connect the bottom pressure chambers 3a of the boom cylinder 3 to the accumulator 7 while the branch line 10 can connect the rod pressure chamber 3b of the boom cylinders 3 to the reservoir T.
The opening control valve 5 is a 4-port-2-position selector valve, and is driven when a pressure is bled from a pressure supply 8 to a pressure chamber 5a via a solenoid-operated proportional valve 12 and a pilot line 13. The other pressure chamber 5b of the opening control valve 5 is connected to the reservoir T via a drain line 11 and the branch line 10. Further, the pressure chamber 5b is provided with a return spring 6.
Normally, the opening control valve 5 is urged by the return spring 6 and remains in a closed position A, so that the branch lines 9,10 are cut off. When a pressure is bled to the pressure chamber 5a, the opening control valve 5 is brought into an open position B so that the branch lines 9, 10 are connected to the accumulator 7 and reservoir T, respectively.
The solenoid-operated proportional valve 12 is opened or closed responsive to an electrical signal from a control means for variably controlling the opening of the opening control valve 5, for example, a controller 21. While the solenoid-operated proportional valve 12 is held neutral, it remains in a position C so that the pressure chamber 5a is connected to the reservoir T via the pilot line 13. Upon receipt of a signal from the controller 21, however, the solenoid-operated proportional valve 12 is brought into a position D responsive to the signal so that a pressure is bled from the pressure supply 8 to the pressure chamber 5a via the pilot line 13. Electrically connected to the controller 21 are a load pressure detection means connected to the bottom pressure chambers 3a of the boom cylinders 3 for detecting a load pressure in the bottom pressure chambers 3a and outputting a signal corresponding to the load pressure, for example, a pressure sensor 18; a vehicle speed detection means for detecting a travelling speed of the wheel loader and outputting a signal corresponding to the travelling speed, for example, a speed sensor 19; and an opening instruction means for outputting, in response to an input by an operator, a signal instructing an opening of the opening control valve 5, for example, an instruction switch 20. To the solenoid-operated proportional valve 12, the controller 21 outputs control signals corresponding to the respective signals.
It is to be noted that the above-mentioned controller 21, solenoid-operated proportional valve 12 and pressure supply 8 make up a selector means for selectively feeding or draining a pilot pressure to or from the pilot chamber 5a of the opening control valve 5.
The branch circuit 24 is also provided with a cock 22 and a relief valve 23, which are arranged in parallel with each other between the accumulator 7 and the reservoir T.
With reference to
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With reference to
Based on the flow chart illustrated in
A description is now made about the computation of a control current. In
Referring
While the wheel loader shown in
While the wheel loader is travelling with a load, a control current corresponding to the load pressure and vehicle speed is outputted, as mentioned above, from the controller 21 to the solenoid-operated proportional valve 12, and corresponding to the output value, a pressure from the pressure supply 8 is controlled and then bled to the pressure chamber 5a of the opening control valve 5. When the pressure applied to the pressure chamber 5a increases to a level sufficient to overcome the preset load on the spring 6, the opening control valve 5 is caused to move through a stroke corresponding to the pressure in the pressure chamber 5a. As a result, the opening control valve 5 is brought into the closed position B, in other words, the branch lines 9 and 10 are brought into connected states, respectively, and during travelling, swings of the boom 1 are absorbed in the accumulator 7 via the boom cylinder 3 and the branch line 9. When the load on the front section of the wheel loader, in other words, the load pressure on the boom cylinder 3 is high, the opening of the opening control valve 5 becomes greater. When the load on the front section is small, on the other hand, the opening of the valve 5 becomes smaller.
According to the first embodiment constructed as described above, the opening of the opening control valve 5 is variably controlled by the controller 21 depending on the load pressure and vehicle speed. It is, therefore, possible to control the opening control valve 5 to an adequate opening corresponding to the weight of the front section, for example, the existence or non-existence of a load and the vehicle class, the load on the boom cylinders as a result of a change or the like in the front attachment, and the vehicle speed, and to suitably suppress vibrations of the wheel loader during travelling. In other words, excellent vibration suppression performance can be assured.
In the above-described first embodiment, the pressure of the accumulator 7 when the opening control valve 5 is in the closed position A is substantially equal to the pressure in the bottom pressure chambers 3a of the boom cylinder 3 when the opening control valve 5 was in the open position B shortly before its switching into the closed position A. The load pressure on the boom cylinders 3, however, frequently varies depending on the weight of the load, the holding angle of the boom 1, and the like. At the moment that the opening control valve 5 has been switched into the open position B, there is accordingly a difference in pressure between the bottom pressure chambers 3a of the boom cylinders 3 and the accumulator 7. Due to this pressure difference, an undesired motion such as sudden lowering of the boom 1 and as a result, a shock may take place to deleteriously affect the riding comfort.
With reference to the circuit diagram shown in
On the branch line 9 which connects the bottom pressure chambers 3a of the boom cylinders 3 and the accumulator 7 with each other, a bypass line 26 is arranged in parallel with the opening control valve 5, and on the bypass line 26, a restrictor 25 and a selector valve 27 are arranged in this order from the upstream. The selector valve 27 is a 2-port-2-position selector valve. To one of pressure changes of the selector valve 27, that is, a pressure chamber 27a, a pressure on a downstream side of the restrictor 25 is led, and the other pressure chamber, that is, a pressure chamber 27b is connected to the reservoir T via a drain line 31. The selector valve 27 is also equipped with a return spring 28.
Normally, the selector valve 27 remains in an open position E so that the bottom pressure chambers 3a of the boom cylinders 3 and the accumulator 7 are kept connected via the bypass line 26. When the pressure in the bottom pressure chambers 3a of the boom cylinders 3 rises and the pressure in the pressure chamber 27a becomes higher the pressure set by the return spring 28, the selector valve 27 is brought into a closed position F so that the bypass line 27 is cut off.
Further, a check valve 29 is arranged at the open position E of the selector valve 27, and permits only a flow from the bottom pressure chambers 3a of the boom cylinders 3 toward the accumulator 7.
According to the second embodiment constructed as described above, the bottom pressure chambers 3a of the boom cylinder 3 and the accumulator 7 are connected together via the bypass line 26 even when the opening control valve 5 is in the closed position A. The pressure in the accumulator 7 can, therefore, be brought close to the pressure in the bottom pressure chambers 3a of the boom cylinder 3, leading to a reduction in the pressure difference between the accumulator 7 and the bottom pressure chambers 3a of the boom cylinder 3. Even at the moment that the opening control valve 5 has been switched into the open position B, an undesired motion of the boom can be lessened to suppress a shock on the vehicle. Owing to the arrangement of the restrictor 25 on the bypass line 26, it is also possible to suppress the absorption of a digging pressure, which is applied to the boom cylinders 3, in the accumulator 7. Other operations and advantageous effects are as described above with respect to the first embodiment.
It is to be noted that, although the relationships between the load pressure and vehicle speed and the coefficient functions ep,ev are set at the controller 21 in the above-described first and second embodiments, the present invention is not limited to the setting of such relationships and relationships between the load pressure and vehicle speed and the control currents can be set there.
Further, the above-described first and second embodiment can also be constructed such that the controller 21 is provided with a clock means to measure a time from the time point of an input of a signal from the speed sensor 19 into the controller 21, a control signal, in other words, a control current capable of holding the opening of the opening control valve 5 relatively small, for example, during a predetermined time is outputted from the controller 21 to the solenoid-operated proportional valve 12, and a control current capable of gradually increasing the opening of the opening control valve 5 is outputted from the controller 21 to the solenoid-operated proportional valve 12 from a time point beyond the above-mentioned predetermined time.
With the hydraulic ride control systems constructed as described above, the opening of the opening control valve 5 can be smoothly brought from the closed position A into the open position B and further from a small opening position into a large opening position upon initiation of travelling with a load. It is, therefore, possible to avoid the occurrence of an impact on the wheel loader which would otherwise be applied as a result of opening of the opening control valve 5.
This application claims the priority of Japanese Patent Application 2004-331888 filed Nov. 16, 2004, which is incorporated herein by reference.
Number | Date | Country | Kind |
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2004-331888 | Nov 2004 | JP | national |
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Number | Date | Country | |
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20060101815 A1 | May 2006 | US |