The present invention relates to a technical field of a hydraulic control circuit for a work machine such as a hydraulic excavator.
In general, a hydraulic control circuit of a work machine such as a hydraulic excavator is configured to include a hydraulic pump; a hydraulic actuator to which a pressure oil is supplied from the hydraulic pump; a manipulation tool that is manipulated so as to actuate the hydraulic actuator; and a control valve that is connected to a discharge line of the hydraulic pump, and configured to perform oil supply and discharge control to/from the hydraulic actuator in accordance with the manipulation of the manipulation tool; and a main relief valve configured to set a maximum pressure of the discharge line, etc. Furthermore, there are some hydraulic control circuits provided with a bypass oil passage (bleed oil passage) that is formed so as to be branched from the discharge line and reaches an oil tank, in order to adjust the pressure of the discharge line of the hydraulic pump; and a bypass valve (bleed valve) that is disposed in the bypass oil passage, and controls a bypass amount (bleed amount) flowing from the hydraulic pump to the oil tank in response to a control signal that is output from a control device (see, for example, Patent Literatures 1, 2 and 3).
Such a bypass valve is controlled so that the opening area decreases, that is, the bypass amount decreases with an increasing manipulation amount of the manipulation tool. In this case, the hydraulic control circuit disclosed in Patent Literature 1 is configured such that the opening area of the bypass valve is controlled so as to follow a flow rate curve that is set beforehand, as a function of the stroke of the control valve (operation valve). Further, the hydraulic control circuit disclosed In Patent Literature 2 is configured to control a movement stroke of the bypass valve by using a table representing a relationship between a manipulation signal of the manipulation tool and a spool movement stroke of the bypass valve. Further, the hydraulic control circuit disclosed in Patent Literature 3 is configured to cause the opening area of the bypass valve to be proportionally decreased with an increasing manipulation amount.
Meanwhile, in such a hydraulic control circuit as described above, the maximum pressure of the discharge line of the hydraulic pump is set by the main relief valve, while the upper limit pressure of the discharge line is adjusted by controlling the increase and decrease of the opening area of the bypass valve corresponding to the manipulation tool manipulation amount. For this reason, when controlling the opening area of the bypass valve, it is necessary to consider a relationship between a maximum pressure of the discharge line set by the main relief valve and an upper limit pressure of the discharge line adjusted by the bypass valve. However, any of the hydraulic control circuits disclosed in the above Patent Literatures 1 to 3 has not considered the above-described relationship. For this reason, a manipulation tool manipulating region in which the upper limit pressure can be adjusted by the bypass valve might be narrowed, resulting in impairing the operability, and oil might continue to flow from the bypass valve to the oil tank even after the discharge line reaches the maximum pressure, resulting in energy loss.
Furthermore, when the pressure of the discharge line of the hydraulic pump is high, for the bypass valve of a spool type, oil might leak from the bypass valve, depending on an overlapping length between a land portion of the spool of the bypass valve and a sliding contact portion of a housing with which the land part comes into sliding contact, even when the bypass valve is fully closed, and these are problems to be solved by the present invention.
The present invention has been created with an aim of solving these problems in view of the above actual situations. A hydraulic control circuit for a work machine according to Claim 1 of the present invention comprises a hydraulic pump; a hydraulic actuator to which a pressure oil is supplied from the hydraulic pump; a manipulation tool that is manipulated so as to actuate the hydraulic actuator; a control valve that is connected to a discharge line of the hydraulic pump, and configured to perform oil supply and discharge control to/from the hydraulic actuator, in accordance with the manipulation of the manipulation tool; a main relief valve configured to set a maximum pressure of the discharge line; a bypass oil passage that is formed so as to be branched from the discharge line and reaches an oil tank; and a spool type bypass valve disposed on the bypass oil passage, and configured to control a bypass amount flowing from the hydraulic pump to the oil tank in response to a control signal that is output from a control device,
wherein, the bypass valve is configured such that an opening area increases or decreases associated with displacement of the spool, in controlling so that an upper limit pressure of the discharge line becomes a pressure corresponding to a manipulation tool manipulation amount by controlling an increase or decrease of a bypass amount in accordance with a manipulation tool manipulation amount; on the other hand, the control device is provided with a map representing a relationship between a manipulation tool manipulation amount and a spool displacement amount, and controls the spool displacement amount of the bypass valve as a function of the manipulation tool manipulation amount, on the basis of the map; and the map is set such that the upper limit pressure of the discharge line is a pressure corresponding to a spool displacement amount that causes the opening area of the bypass valve to be fully closed by a manipulation amount larger than the manipulation tool manipulation amount at which the maximum pressure of the discharge line is reached.
A hydraulic control circuit for a work machine according to Claim 2 of the present invention is the hydraulic control circuit according to Claim 1, configured to control the spool displacement amount as a function of the manipulation tool manipulation amount by using the map even in the fully closed state of the bypass valve, in order to control an overlapping length between a land portion of the spool of the bypass valve and a sliding contact portion of a housing with which the land portion comes into sliding contact in the fully closed state of the bypass valve.
A hydraulic control circuit for a work machine according to Claim 3 of the present invention is the hydraulic control circuit according to Claim 2, wherein the control device is configured to vary the overlapping length between the land portion of the spool and the sliding contact portion of the housing in the fully closed state of the bypass valve according to the pressure of the discharge line, by inputting a signal from a pressure detecting means for detecting the pressure of the discharge line of the hydraulic pump and varying the map according to the input pressure of the discharge line.
According to Claim 1 of the present invention, the manipulating region of the hydraulic actuator manipulation tool can be made as wide as possible where the increase or decrease of the upper limit pressure can be controlled by the bypass valve, which can contribute to improvement of operability and reduction of energy loss.
According to Claim 2 of the present invention, it is possible to control an overlapping length between the land portion of the spool in the fully closed state and the sliding contact portion of the housing with which the land portion comes into sliding contact.
According to Claim 3 of the present invention, it is possible to prevent oil leakage from the bypass valve by increasing the overlapping length even when the discharge line is high.
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, a first embodiment of the present invention will be described with reference to
The hydraulic excavator is provided with various types of hydraulic actuators such as a boom cylinder, a stick cylinder, a bucket cylinder, a traveling motor, and a swivel motor, and provided with respective control valves in association with respective hydraulic actuators, besides provided with electromagnetic proportional pressure-reducing valves that output a pilot pressure to operate the respective control valves. In
The control valve 5 is a closed center type spool valve, and is configured to include a first and a second pilot ports 5a, 5b respectively connected to the first and second electromagnetic proportional pressure-reducing valves 6A, 6B; a pump port 5c connected to the discharge line 2 of the hydraulic pump 1; a tank port 5d connected to the oil tank 3; and a pair of actuator ports 5e, 5f respectively connected to respective ports 4a,4b of the hydraulic actuator 4. Further, the control valve 5 is configured such that, in a state where no pilot pressure is input to both the first and second pilot ports 5a, 5b, the spool is located at a neutral position N at which the pump port 5c, the tank port 5d, and the pair of actuator ports 5e, 5f are closed; however, when the pilot pressure is input from the first or second electromagnetic proportional pressure-reducing valve 6A or 6B to the first or second pilot port 5a or 5b, the spool is switched to a first operating position X or a second operating position Y at which a supply flow passage 5g extending from the pump port 5c to one actuator port 5e or 5f, and a discharge flow passage 5h extending from the other actuator port 5f or 5e to the tank port 5d are opened to perform supply flow rate control and discharge flow rate control to/from the hydraulic actuator 4.
In the present embodiment, each of the control valves 5 is connected in parallel with respect to the hydraulic pump 1, and a check valve 9 is disposed in oil passage on an upstream side of the pump port 5c of each of the control valves 5 to hold a load pressure of the hydraulic actuator 4.
Furthermore, in
A hydraulic actuator manipulation tool 21 and a manipulation detecting means 22 for detecting the manipulation (manipulation amount and manipulation direction) of the hydraulic actuator manipulation tool 21 are respectively provided in association with respective hydraulic actuators, but
Furthermore, in
Furthermore, in
Meanwhile, a relationship between a stroke and an opening area of the spool 19c of the bypass valve 19 will be described with reference to
On the other hand, the controller (which corresponds to the control device of the present invention) 15, as illustrated in the block diagram of
The stroke of the spool 19c of the bypass valve 19 is controlled in accordance with a current value applied from the controller 15 to the proportional solenoid 19e as described above. However, the control of the stroke of the bypass valve 19 by the controller 15 will be described. First, before the engine E is started, no electric current is applied from the controller 15 to the proportional solenoid 19e, and the bypass valve 19 is located at the initial position by an urging force of the spring 19d. Furthermore, the opening area of the bypass valve 19 at the initial position is set to an initial opening area Af as described above. The initial opening area Af is set to an opening area (Af<As) smaller than the setting opening area As as described above, which is a minimum opening area necessary for causing the discharge oil of the hydraulic pump 1 to escape into the oil tank 3 immediately after the engine is started, in order to prevent the pump pressure from rapidly rising immediately after the start of the drive of the hydraulic pump 1 associated with the engine start and prevent an excessive load from being applied to the engine E.
On the other hand, when the engine E starts and the hydraulic pump 1 starts driving accordingly, an electric current is not applied from the controller 15 to the proportional solenoid 19e of the bypass valve 19 and the spool 19c is maintained at the initial position, that is, the opening area of the bypass valve 19 is maintained at the initial opening area Af, until the pump pressure detected by the pump pressure sensor 23 reaches a required pressure Po. This will enable preventing a rapid rise in the pump pressure immediately after the start of the engine drive, and will enable making a pump pressure rising speed until reaching a required pressure Po faster, compared with the case where the opening area of the bypass valve at the time of starting the engine is set to the maximum opening area (for example, a case like the bypass valve 33 in the second embodiment described below). The required pressure Po is a value larger than the pilot primary pressure Pp so that a predetermined pilot primary pressure Pp can be supplied from the hydraulic pump 1 to the pilot primary side oil passage 10, and a small value, for example about 4 Mpa, is desirable from the viewpoint of energy saving.
Then, after the pump pressure reaches the required pressure Po, the controller 15 applies an electric current to the proportional solenoid 19e so that the stroke of the spool 19c reaches a fourth stroke S4, in a state in which a manipulation signal is not input from the manipulation detecting means 22, that is, in a state in which the hydraulic actuator manipulation tool 21 is not manipulated (the manipulation tool is at the neutral position). This will enable the opening area of the bypass valve 19 to reach a setting opening area As. The setting opening area As, however, is an opening area at which the pressure of the discharge line 2 is maintained at a pressure of the order of the required pressure Po, and an opening area larger than the initial opening area Af, in a state in which the discharge amount of the hydraulic pump 1 is of the order of a predetermined amount, and as described above, when the engine speed E is of the order of a predetermined speed (for example, rated speed). Further, until the pump pressure reaches the required pressure Po from the start of the engine E, the controller 15 will not output a control signal of actuation to the first and second electromagnetic proportional pressure-reducing valves 6A, 6B even if the hydraulic actuator manipulation tool 21 is manipulated, so that the control valve 5 is to be held in the neutral position N at which the pressure oil is not supplied to the hydraulic actuator 4. Furthermore, when the manipulation signal is not input from the manipulation detecting means 22 for a predetermined time or more, the controller 15 applies an electric current to the proportional solenoid 19e so that the stroke of the spool 19c becomes the fifth stroke S5, and sets an opening area of the bypass valve 19 to the maximum opening area Am. This will enable reduction of pressure loss of the bypass oil passage 18 in a case where the hydraulic actuator manipulation tool 21 is not manipulated for a predetermined time or longer.
Meanwhile, as described above, it is configured such that the pilot primary pressure Pp acts on the other end side (opposite side of 19d) of the spool 19c of the bypass valve 19 via the introduction oil passage 20 that is formed so as to be branched from the pilot primary side oil passage 10. For this reason, when the pressure of the discharge line 2 is lowered below the required pressure Po and becomes less than the pilot primary pressure Pp, while the hydraulic actuator manipulation tool 21 is not manipulated, the pilot pressure acting on the other end side of the spool 19c of the bypass valve 19 becomes smaller, and the spool 19c moves in a direction in which the stroke decreases from the fourth stroke S4 or the fifth stroke S5. This will enable making adjustment so that the opening area of the bypass valve 19 decreases and the pressure of the discharge line 2 reaches the required pressure Po.
Further, the bypass valve 19, as described above, is located at an initial position by the urging force of the spring 19d, in a state where no electric current is applied to the proportional solenoid 19e from the controller 15, and the opening area of the bypass valve 19 at the initial position is set to the initial opening area Af. As a result, even granted that malfunction occurs in the bypass valve 19 due to certain defects in an electrical system extending from the controller 15 to the proportional solenoid 19e, the bypass oil passage 18 would be opened by the bypass valve 19, and a rapid rise in the pump pressure at the start of the engine or non-startable state of not starting the engine could be avoided, and since the initial opening area Af, which is an opening area of the bypass valve 19 in this case, is an opening area that is smaller than the setting opening area As that is an opening area of the bypass valve 19 when the manipulation tool is at the neutral position, the pressure of the discharge line 2 will also rise above the required pressure Po when the manipulation tool is at the neutral position, and it becomes possible to perform minimum operations necessary for emergency evacuation of the work machine and the like, even if the bypass valve 19 ceases to operate.
Next, the control of the bypass valve 19 in a case where the hydraulic actuator manipulation tool 21 is manipulated after the engine E is started and the pump pressure reaches the required pressure Po will be described. In this case, the controller 15 controls the stroke of the spool 19c by using a bypass valve control map 25, which will be described below.
The bypass valve control map 25, as illustrated in
It may be better to perform special control in some cases, for example, to control the upper limit pump pressure so as to be lower than the system pressure at boom lowering of the hydraulic excavator. In such a case, the opening area of the bypass valve 19 is set so as to avoid “0” even when the manipulation tool manipulation amount is maximal.
When the control of the bypass valve 19 by the controller 15 using the bypass valve control map 25 is described with reference to
The stroke of the spool 19c when the opening area of the bypass valve 19 becomes “0”, that is, an electric current value applied to the proportional solenoid 19e corresponding to the position of the third stroke S3 is desirably corrected by calibration or the like.
Further, in an interlocking operation in which a plurality of hydraulic actuators 4 are simultaneously operated, the stroke of the spool 19c of the bypass valve 19 is calculated on the basis of the manipulation amounts of respective hydraulic actuator manipulation tools 21 that is input from the manipulation detecting means 22 and the bypass valve control maps 25 for respective hydraulic actuators.
Meanwhile, the control of the stroke of the spool 19c after the opening area of the bypass valve 19 becomes “0” will be described with reference to a partial enlarged view of the bypass valve control map 25 illustrated in
On the other hand, when the pump pressure that is input from the pump pressure sensor 23 becomes lower than the setting pressure, the bypass valve control map 25 is changed so that the displacement in a direction from the third stroke S3 toward the second stroke S2 after the opening area of the bypass valve 19 has become “0”, decreases as the pump pressure becomes low, and is set so that, when the pump pressure is sufficiently low (for example, 5 MPa), the spool 19c is located at the third stroke S3, even when the manipulation tool manipulation amount reaches a maximum manipulation amount Lm, as illustrated by the dotted line in
In the present embodiment configured as described above, the hydraulic control circuit of the hydraulic excavator is configured to include a hydraulic pump 1; a hydraulic actuator 4 to which a pressure oil is supplied from the hydraulic pump 1; a hydraulic actuator manipulation tool 21 manipulated in order to actuate the hydraulic actuator 4; a control valve 5 connected to the discharge line 2 of the hydraulic pump 1, and configured to perform oil supply/discharge control to/from the hydraulic actuator 4, in accordance with the manipulation of the hydraulic actuator manipulation tool 21; a main relief valve 17 configured to set a maximum pressure of the discharge line 2; a bypass oil passage 18 that is formed so as to be branched from the discharge line 2 and reaches an oil tank 3; a spool type bypass valve 19 disposed on the bypass oil passage 18, and configured to control a bypass amount flowing from the hydraulic pump 1 to the oil tank 3 in response to a control signal that is output from the controller 15, and so on. In this hydraulic control circuit, the bypass valve 19 is configured such that the opening area increases or decreases associated with the displacement of the spool 19c, in controlling so that the upper limit pressure of the discharge line 2 becomes a pressure corresponding to the manipulation tool manipulation amount, by controlling increase or decrease of the bypass amount as a function of the manipulation amount of the hydraulic actuator manipulation tool 21; on the other hand, the controller 15 is provided with a bypass valve control map 25 representing a relationship between a manipulation tool manipulation amount and a spool stroke (displacement amount of the spool 19c), and controls the spool stroke of the bypass valve 19 as a function of the manipulation tool manipulation amount, on the basis of bypass valve control map 25; and in the bypass valve control map 25, the upper limit pressure of the discharge line 2 is set to become a pressure corresponding to the spool stroke (the third stroke S3 in the first embodiment) at which the opening area of the bypass valve 19 is fully closed by a second manipulation amount L2 which is a manipulation amount larger than a first manipulation amount L1 at which the maximum pressure of the discharge line 2 is reached.
Therefore, the displacement amount of the spool 19c of the bypass valve 19 is controlled in accordance with the manipulation tool manipulation amount by using the bypass valve control map 25. The upper limit pressure of the discharge line 2 will be controlled to become a pressure corresponding to the manipulation amount of the hydraulic actuator manipulation tool 21, in accordance with the increase or decrease of the opening area of the bypass valve 19 associated with the displacement of the spool 19c; in this case, however, the upper limit pressure of the discharge line 2 will be controlled so that the opening area of the bypass valve 19 is fully closed at the second manipulation amount L2 which is a larger manipulation amount than the first manipulation amount L1 at which the maximum pressure of the discharge line 2 is reached. As a result, until the upper limit pressure of the discharge line 2 reaches the maximum pressure of the discharge line 2, the upper limit pressure of the discharge line 2 will be able to be controlled to become a pressure corresponding to the manipulation tool manipulation amount, by controlling the increase/decrease of the opening area of the bypass valve 19, and the manipulating region of the hydraulic actuator manipulation tool 21 can be made as wide as possible where the increase or decrease of the upper limit pressure can be controlled by the bypass valve 19, which can greatly contribute to the improvement of operability. On the other hand, when the upper limit pressure of the discharge line 2 is controlled so that the bypass valve 19 is fully closed when the manipulation amount becomes larger than when the maximum pressure of the discharge line 2 is reached, thereby attaining the reduction of energy loss.
Furthermore, in this the hydraulic control circuit, it is configured such that the stroke of the spool 19c with respect to the manipulation tool manipulation amount is controlled by the bypass valve control map 25 even in a state where the bypass valve 19 is fully closed, thereby enabling the control of the overlapping length between the land portion of the spool 19c (in a state where the bypass valve 19 is fully closed) and the sliding contact portion of the housing with which the land portion comes into sliding contact. In this case, it is configured such that a signal from the pump pressure sensor 23 that detects the pressure of the discharge line 2 of the hydraulic pump 1 is input to the controller 15, and the overlapping length is changed in accordance with the pressure of the discharge line 2, by changing the bypass valve control map 25 in accordance with the input pressure of the discharge line 2. This will enable preventing oil leakage from the bypass valve 19 by increasing the overlapping length even when the discharge line 2 has a high pressure, resulting in contribution to the reduction of energy loss.
Next, the second embodiment of the present invention will be described with reference to
Furthermore, in
Meanwhile, the relationship between the stroke of the spool 33c of the bypass valve 33 and the opening area in the second embodiment will be described with reference to
The stroke of the spool 33c of the bypass valve 33 is controlled in accordance with a current value applied from the controller 15 to the proportional solenoid 33e, but the control of the stroke of the bypass valve 33 by the controller 15 will be described. First, no electric current is applied to the proportional solenoid 33e from the controller 15, before the engine E is started, and the bypass valve 33 is located at an initial position by the urging force of the spring 33d. Furthermore, the opening area of the bypass valve 33 at the initial position is set to the maximum opening area Am as described above.
Furthermore, when the hydraulic actuator manipulation tool 21 is not manipulated, after the engine E is started, no electric current is applied to the proportional solenoid 33e from the controller 15, and the bypass valve 33 is maintained at the initial position, that is, the maximum opening area Am by the urging force of the spring 33d. On the other hand, when the hydraulic actuator manipulation tool 21 is manipulated, the controller 15 controls the stroke of the spool 33c of the bypass valve 33 by using a bypass control map 34 of the second embodiment.
The bypass valve control map 34, as illustrated in
The control of the bypass valve 33 by the controller 15 using the bypass valve control map 34 will be described with reference to
Meanwhile, the control of the stroke of the spool 33c after the opening area of the bypass valve 33 has become “0” will be described with reference to a partial enlarged view of the bypass valve control map 34 illustrated in
On the other hand, when the pump pressure that is input from the pump pressure sensor 23 becomes lower than the setting pressure, the bypass valve control map 34 is changed so that the displacement in a direction from the second stroke S2 toward the maximum stroke Sm after the opening area of the bypass valve 33 has become″0″, decreases as the pump pressure becomes low, and is set so that, when the pump pressure is sufficiently low (for example, 5 MPa), the spool 33c is located at the second stroke S2, even when the manipulation tool manipulation amount reaches a maximum manipulation amount Lm, as illustrated by the dotted line in
Therefore, the bypass valve 33 of the second embodiment adopts a configuration in which the opening area decreases with an increase of the stroke of the spool 33c, and the spool stroke of the bypass valve 33 increases as the manipulation amount of the hydraulic actuator manipulation tool 21 increases. Although the spool stroke is configured to increase, even in the second embodiment in which the bypass valve 33 configured in this way is used, the upper limit pressure of the discharge line 2 will be controlled so that the opening area of the bypass valve 19 is fully closed, at the second manipulation amount L2 which is larger than the first manipulation amount L1 at which the discharge line 2 reaches the maximum pressure, which will exhibit the same action and effect as those of the first embodiment, thereby contributing to the improvement of operability and the reduction of energy loss.
The present invention can be utilized to control a bypass valve provided in a hydraulic control circuit of a work machine such as a hydraulic excavator.
Number | Date | Country | Kind |
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2020-080129 | Apr 2020 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2021/025145 | 4/19/2021 | WO |