JP2010071349A - Fluid-pressure unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect stroke end of a hydraulic cylinder certainly and simply. <P>SOLUTION: The hydraulic cylinder (13) determines to have reached stroke end if both values detected by a pump pressure sensor (S1) and by a rod-side pressure sensor (S2) on hydraulic oil supply side of the hydraulic cylinder (13) range to an axial setting pressure or above and the value detected by a head-side pressure sensor (S3) on back pressure side of the hydraulic cylinder (13) ranges to the level of falling pressure or below. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

    The present invention relates to a fluid pressure unit, and particularly relates to measures for detecting a stroke end of a fluid pressure cylinder.

2. Description of the Related Art Conventionally, a device that drives a fluid pressure cylinder by pumping fluid by a fluid pressure pump is known. For example, in the cylinder driving device disclosed in Patent Document 1, oil is pumped from the leg-side hydraulic pump to the leg-side cylinder, the leg-side cylinder moves forward, and the abutment is pressed against the rail. In this device, pressing detection is performed by detecting that the pressure of the cylinder has become a predetermined value or more. That is, it is detected that the cylinder has reached the target stroke end while ensuring the pressing force of the gold against the rail when the supply pressure of the cylinder rises above a predetermined value.
JP-A-10-180357

    Incidentally, the stroke end detection method of Patent Document 1 has a problem that there is a high possibility of erroneous detection of the stroke end. Specifically, depending on the hydraulic circuit as in Patent Document 1, the pipe length of the pipe returning from the cylinder to the tank is long or the pipe diameter is small, and various valves such as a throttle valve are provided in the return pipe. is there. In such a hydraulic circuit, the flow resistance in the return pipe increases, so that the oil supply pressure increases even during cylinder movement. That is, even when the cylinder moves, a large load pressure acts on the hydraulic pump, and the supply pressure of the cylinder increases. Referring to FIG. 6, the cylinder starts to move at t0 and reaches the stroke end at t1. However, during the movement of the cylinder (t0 to t1), the pump pressure of the hydraulic pump becomes equal to or higher than the shaft setting pressure, and then the supply pressure (shaft pressure) of the cylinder also becomes equal to or higher than the shaft setting pressure. Here, the shaft set pressure is set to a required holding pressure for the cylinder workpiece. As described above, there has been a problem that the supply side pressure becomes equal to or higher than a predetermined value and the target stroke end is erroneously detected although the cylinder has not reached the stroke end.

    The present invention has been made in view of such a point, and an object thereof is to reliably and easily detect the stroke end of a cylinder.

    A first aspect of the present invention is a fluid pressure unit that includes a fluid pressure pump (11) that discharges fluid and supplies the fluid discharged from the fluid pressure pump (11) to a fluid pressure cylinder (13) to advance and retract the cylinder rod. It is assumed. In the fluid pressure unit of the present invention, the pressure in the rod chamber (13b) or the head chamber (13a) on the fluid supply side of the fluid pressure cylinder (13) is equal to or higher than a first set value, and the fluid pressure When the pressure in the head chamber (13a) or rod chamber (13b) on the back pressure side of the cylinder (13) satisfies the condition that it is less than or equal to the second set value, the cylinder rod of the fluid pressure cylinder (13) reaches the stroke end. Stroke end detection means (20) for determining that the fluid pressure pump (11) is stopped and stopping the supply of fluid from the fluid pressure pump (11) to the fluid pressure cylinder (13) is provided.

    In the first invention, when the flow resistance of the back pressure side flow path of the fluid pressure cylinder (13) is large, a relatively large load pressure is generated for the fluid pressure pump (11) during the operation of the fluid pressure cylinder (13). . In this case, during operation (moving) of the fluid pressure cylinder (13), the pressure in the head chamber (13a) or the rod chamber (13b) on the fluid supply side becomes equal to or higher than the first set value, and the rod chamber on the back pressure side. (13b) or the head chamber (13a) also changes at the same pressure. When the fluid pressure cylinder (13) reaches the stroke end, the pressure on the fluid supply side remains at a value equal to or higher than the first set value, and the pressure on the back pressure side decreases to a value equal to or lower than the second set value. Thereby, the stroke end is detected.

    In addition, when the flow resistance of the back pressure side flow path of the fluid pressure cylinder (13) is very small, almost no load pressure is generated for the fluid pressure pump (11) during the operation of the fluid pressure cylinder (13). In this case, during operation (moving) of the fluid pressure cylinder (13), the pressure of the head chamber (13a) or rod chamber (13b) on the fluid supply side and the rod chamber (13b) or head chamber ( The pressure in 13a) remains almost zero. When the fluid pressure cylinder (13) reaches the stroke end, the pressure on the fluid supply side becomes a value equal to or higher than the first set value, and the pressure on the back pressure side remains almost zero (a value equal to or lower than the second set value). . Thereby, the stroke end is detected.

    In a second aspect based on the first aspect, the stroke end detection means (20) satisfies the condition that the discharge pressure of the fluid pressure pump (11) is not less than a third set value in addition to the above condition. The cylinder rod of the fluid pressure cylinder (13) is determined to have reached the stroke end, and the supply of fluid from the fluid pressure pump (11) to the fluid pressure cylinder (13) is stopped. Is.

    In the second invention, the pressure in the rod chamber (13b) or the head chamber (13a) on the fluid supply side of the fluid pressure cylinder (13) is equal to or higher than the first set value, and the fluid pressure cylinder (13) In addition to the condition in which the pressure in the head chamber (13a) or the rod chamber (13b) on the back pressure side of the cylinder is lower than the second set value, the stroke when the discharge pressure of the fluid pressure pump (11) exceeds the third set value End is detected.

    According to a third aspect of the present invention, in the first or second aspect, the stroke end detecting means (20) is configured so that the fluid pressure cylinder ( It is configured to stop the supply of fluid to 13).

    In the third aspect, the fluid continues to be supplied from the fluid pressure pump (11) to the fluid pressure cylinder (13) for a predetermined time even if the pressure condition according to the first or second aspect is satisfied. In the case of a fluid pressure cylinder (13) having a so-called cushion mechanism at the stroke end, the above pressure condition may be satisfied before the stroke end. However, the stroke end has not yet been reached at this point. Therefore, in the present invention, since the fluid is continuously supplied to the fluid pressure cylinder (13) for a predetermined time even after the pressure condition is satisfied, the fluid pressure cylinder (13) reliably reaches the stroke end.

    According to a fourth aspect of the present invention, in any one of the first to third aspects, the back pressure side flow connected to the head chamber (13a) or the rod chamber (13b) on the back pressure side of the fluid pressure cylinder (13). The passage (14d) is provided with a throttle means (19) for narrowing the fluid flow path.

    In the fourth aspect of the invention, the flow rate of the fluid flowing through the back pressure side channel (14d) is adjusted by the throttle means (19), and the operating speed of the fluid pressure cylinder (13) is adjusted. In this case, the flow resistance in the throttle means (19) becomes a large load pressure for the fluid pressure pump (11).

    According to a fifth invention, in any one of the first to third inventions, the fluid pressure cylinder (13) is configured so that the cylinder rod is advanced and retracted in the vertical direction, while the fluid pressure cylinder (13) is on the back pressure side. In the back pressure side flow path (14d) connected to a certain head chamber (13a) or rod chamber (13b), when the cylinder rod of the fluid pressure cylinder (13) is lowered, the fluid pressure cylinder (13) Back pressure holding means (21) for holding the pressure on the back pressure side constant is provided.

    In the fifth aspect of the invention, when the fluid pressure cylinder (13) is lowered, the fluid pressure pump (11) is naturally dropped (self-weight drop) in addition to the fluid pressure pump (11) being lowered by the oil pressure. In this state, the fluid pressure cylinder (13) suddenly drops due to the negative pressure on the fluid supply side. However, in the present invention, since the pressure on the back pressure side of the fluid pressure cylinder (13) is kept constant by the back pressure holding means (21), the descending speed is kept constant without suddenly descending. During this lowering operation, the back pressure held by the back pressure holding means (21) becomes a large load pressure for the fluid pressure pump (11).

    In a sixth aspect based on any one of the first to fifth aspects, the drive target of the fluid pressure cylinder is a chuck or a clamp in a machine tool.

    In the sixth invention, the chuck or the clamp is opened and closed by the operation of the fluid pressure cylinder (13). As a result, the workpiece (workpiece) is fixed (gripped) at a predetermined pressure.

    As described above, according to the present invention, at the stroke end, the pressure on the fluid supply side is equal to or higher than the first set value and whether the load pressure is generated or not during operation of the fluid pressure cylinder (13). The pressure side pressure is equal to or lower than the second set value. Therefore, by satisfying the conditions of the pressure on the fluid supply side and the pressure on the back pressure side, the fluid pressure cylinder (13 is maintained while maintaining a predetermined fixing force (gripping force) on the workpiece regardless of whether or not load pressure is generated. ) Stroke end can be reliably and easily detected.

    Furthermore, according to the second invention, the fact that the discharge pressure of the fluid pressure pump (11) is not less than the third set value is also added to the determination condition for the stroke end. Therefore, erroneous detection of the stroke end can be further prevented. For example, when the shaft pressure increases due to an external force acting on the workpiece, the pressure on the back pressure side has fallen below the step-down level, so that it may be erroneously detected as a stroke end. However, by adding the condition that the discharge pressure of the fluid pressure pump (11) is equal to or higher than the third set value, it is possible to reliably prevent erroneous detection of the stroke end due to the action of at least an external force as described above. . That is, according to the present invention, the stroke end during the operation of the fluid pressure cylinder (13) can be reliably detected by adding the discharge pressure of the fluid pressure pump (11) to the condition.

    Further, according to the third invention, the fluid supply to the fluid pressure cylinder (13) is continued for a predetermined time even after the pressure condition according to the first or second invention is satisfied. Therefore, even the fluid pressure cylinder (13) provided with a cushion mechanism at the stroke end can be reliably operated to the stroke end. Therefore, the reliability of stroke end detection can be improved.

    According to the fourth aspect of the invention, since the throttle means (19) is provided in the back pressure side flow path (14d), the flow rate of the hydraulic oil is adjusted to adjust the operating speed of the fluid pressure cylinder (13). Can do. If the flow regulating valve is provided in the back pressure side flow path (14d) in this way, the flow resistance increases and a large load pressure is generated for the fluid pressure pump (11). Even in this case, the stroke end is reliably detected. be able to.

    According to the fifth aspect of the present invention, the back pressure holding is performed for the fluid pressure cylinder (13) in which the cylinder rod advances and retreats in the vertical direction, and the pressure on the back pressure side is kept constant when the fluid pressure cylinder (13) is lowered. The means (21) is provided in the back pressure side channel (14d). Therefore, the descending speed of the fluid pressure cylinder (13) can be kept constant. In this case, the back pressure held by the back pressure holding means (21) becomes a large load pressure for the fluid pressure pump (11), but even in this case, the stroke end can be reliably detected.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

    As shown in FIG. 1, the hydraulic unit (10) of the present embodiment constitutes a fluid pressure unit according to the present invention. The hydraulic unit (10) is used for machine tools such as a lathe, a polishing machine, a surface finishing machine, a shaving machine, and a machining center. Although not shown, the machine tool has a plurality of fixing devices (drive targets) for fixing a work and a tool, such as a tailstock clamp, a tool post clamp, and a chuck, and these fixing devices are hydraulic units (10 ). Here, it demonstrates as what drives a clamp.

    The hydraulic unit (10) includes a hydraulic pump (11), a motor (12) that drives the hydraulic pump (11), and two drive systems (10A, 10) connected in parallel to the hydraulic pump (11). 10B). The two drive systems (10A, 10B) are a first clamp drive system (10A) and a second clamp drive system (10B).

    The hydraulic pump (11) constitutes a fluid pressure pump that sucks and discharges hydraulic oil as fluid from the oil tank (16). The hydraulic pump (11) is a fixed displacement pump such as a gear pump, a trochoid pump, a vane pump, a piston pump, or the like.

    The motor (12) is a variable speed motor that drives the hydraulic pump (11). The motor (12) detects a rotation speed corresponding to the discharge flow rate of the hydraulic pump (11) by a rotation speed control encoder (not shown) incorporated in the motor (12).

    Each of the drive systems (10A, 10B) includes a direction switching valve (15), two check valves (17, 18), and a variable throttle valve (19). Each drive system (10A, 10B) is connected to a hydraulic cylinder (13) on the machine tool side.

    The hydraulic cylinder (13) has a head chamber (13a) and a rod chamber (13b) defined by a piston, and is driven by hydraulic oil supplied from the hydraulic pump (11). When hydraulic oil is supplied to the head chamber (13a), the cylinder rod (13c) extends (advances) when the hydraulic oil is supplied to the head chamber (13a), and the cylinder rod (13c) when hydraulic oil is supplied to the rod chamber (13b). Contracts (retracts). The hydraulic cylinder (13) includes a cushion mechanism (not shown) at the stroke end. This cushion mechanism alleviates the impact when the cylinder rod (13c) reaches the stroke end.

    The direction switching valve (15) is a 4-port 3-position spring center type electromagnetic switching valve having a first electromagnetic solenoid (15a) and a second electromagnetic solenoid (15b). Each of the directional control valves (15) has a P port of four ports connected to the discharge side of the hydraulic pump (11) by a first pipe (14a), and a T port connected to an oil tank (16) with a second pipe (14b). ), The A port is connected to the head chamber (13a) of the hydraulic cylinder (13) by the fourth pipe (14d), and the B port is connected to the rod chamber (13b) of the hydraulic cylinder (13) to the third pipe (14c). ). Each said piping (14a-14d) comprises the hydraulic piping.

    The directional control valve (15) has a neutral position, a first position (right position in FIG. 1), and a second position (by the ON / OFF operation of the first electromagnetic solenoid (15a) and the second electromagnetic solenoid (15b)). 1 to the left side). In the neutral position, the directional control valve (15) communicates with the A port, the B port and the T port and the P port is cut off. In the first position, the P port and the B port communicate with each other and the A port and the T port. In the second position, the P port and the A port communicate with each other, and the B port and the T port communicate with each other.

    The check valve (17, 18) is of a pilot type. The two check valves (17, 18) are provided in the third pipe (14c) and the fourth pipe (14d), respectively.

    The variable throttle valve (19) is provided closer to the direction switching valve (15) than the check valve (18) of the fourth pipe (14d). The variable throttle valve (19) is a flow rate control valve configured such that the flow path area can be changed.

    Each drive system (10A, 10B) is provided with a pump pressure sensor (S1), a rod side pressure sensor (S2), and a head side pressure sensor (S3), which are pressure detection means. The pump pressure sensor (S1) is provided on the discharge side of the hydraulic pump (11) and detects the discharge pressure of the hydraulic pump (11). The rod side pressure sensor (S2) is provided closer to the hydraulic cylinder (13) than the check valve (17) of the third pipe (14c), and detects the pressure in the rod chamber (13b). The head side pressure sensor (S3) is provided closer to the hydraulic cylinder (13) than the check valve (18) of the fourth pipe (14d), and detects the pressure in the head chamber (13a).

    The hydraulic unit (10) is provided with a controller (20). The controller (20) performs drive control of the motor (12) and switching control of the direction switching valve (15). The controller (20) is configured to receive the detected values of the three pressure sensors (S1 to S3) and detect the stroke end of the hydraulic cylinder (13) based on the detected values. Details of the stroke end detection operation will be described later.

-Driving action-
Next, the operation of the hydraulic unit (10) and the detection operation of the stroke end will be described with reference to FIGS.

    The hydraulic unit (10) of the present embodiment independently drives the first clamp and the second clamp. Further, the clamp of the machine tool according to the present embodiment performs a closing operation when the cylinder rod (13c) of the hydraulic cylinder (13) contracts to fix (grip) the workpiece (workpiece).

    The controller (20) controls the closing operation of the clamp based on the flow shown in FIG. First, in step ST1, it is determined whether or not an operation command for the hydraulic cylinder (13) driven from the control panel has been input. Here, it is assumed that an operation command for the hydraulic cylinder (13) of the first clamp drive system (10A) is input.

    When the operation command for the hydraulic cylinder (13) is input, the direction switching valve (15) of the first clamp drive system (10A) is turned on in step ST2. That is, the direction switching valve (15) is switched from the neutral position to the first position. In the subsequent step ST3, the motor (12) is started and the hydraulic pump (11) is driven. Then, the hydraulic oil drawn up from the oil tank (16) by the hydraulic pump (11) is supplied to the rod chamber (13b) of the hydraulic cylinder (13) through the first pipe (14a) and the third pipe (14c). The cylinder rod (13c) of the hydraulic cylinder (13) performs the contracting operation. As the cylinder rod (13c) contracts, hydraulic oil flows from the head chamber (13a) of the hydraulic cylinder (13) to the oil tank (16) via the fourth pipe (14d) and the second pipe (14b). . At this time, the check valve (18) of the fourth pipe (14d) is opened by the pilot pressure. Further, the flow rate of the hydraulic oil is adjusted by the variable throttle valve (19), and the contraction speed (movement speed) of the cylinder rod (13c) is adjusted. The clamp is closed by the operation of the hydraulic cylinder (13).

    When the hydraulic cylinder (13) is contracted, the flow path (second pipe (14b) and fourth pipe (14d)) from the head chamber (13a) to the oil tank (16) is on the back pressure side of the hydraulic cylinder (13). It becomes a flow path. Here, if the flow resistance in the second pipe (14b) and the fourth pipe (14d) is large, the pressure required for the contraction operation of the hydraulic cylinder (13) increases. That is, a load pressure is generated when the hydraulic cylinder (13) is contracted. For example, when the pipe length of the second pipe (14b) or the fourth pipe (14d) is long or the pipe diameter is small, or due to the presence of the variable throttle valve (19), the flow resistance increases and load pressure is generated.

    In this way, when a load pressure is generated during the contraction operation of the hydraulic cylinder (13), each pressure changes as shown in FIG.

    Specifically, when an axis selection signal (that is, an operation command for the hydraulic cylinder (13)) is input and the operation of the hydraulic pump (11) is started (at time t0 in FIG. 3), the discharge of the hydraulic pump (11) is performed. The pressure (hereinafter referred to as pump pressure) gradually increases, and the contraction speed of the hydraulic cylinder (13) gradually increases. The pump pressure becomes equal to or higher than the shaft set pressure, and thereafter changes at a high value equal to or higher than the shaft set pressure. This is because load pressure is generated. The shaft set pressure is set to a pressure (clamp set pressure) necessary for the clamp to fix (grip) the workpiece.

    Further, the pressure in the rod chamber (13b) of the hydraulic cylinder (13) (hereinafter referred to as the shaft pressure) increases slightly later than the pump pressure and becomes equal to or higher than the shaft set pressure. This shaft pressure also changes at a higher value than the shaft set pressure due to the generation of the load pressure, similarly to the pump pressure. On the other hand, the pressure in the head chamber (13a) of the hydraulic cylinder (13) (hereinafter referred to as the back pressure) also rises at almost the same timing as the shaft pressure due to the generation of the load pressure, and after that it is relatively high and constant. It changes by value.

    Thus, when load pressure is generated during the contracting operation of the hydraulic cylinder (13), the pump pressure, the shaft pressure, and the back pressure change at relatively high values during the contracting operation. The rotational speed of the motor (12) changes in substantially the same manner as the pump pressure.

    When the cylinder rod (13c) of the hydraulic cylinder (13) comes near the stroke end (near side), it receives a cushion action by the cushion mechanism (at time t1 in FIG. 3). In this state, both the pump pressure and the shaft pressure remain at a value equal to or higher than the shaft set pressure. On the other hand, when the cylinder rod (13c) of the hydraulic cylinder (13) receives a cushioning action, the back pressure drops below a predetermined step-down level and finally becomes substantially zero. That is, most of the hydraulic oil is discharged from the head chamber (13a) of the hydraulic cylinder (13), and the pressure of the hydraulic oil in the second pipe (14b) and the fourth pipe (14d) equalizes with the pressure of the oil tank (16). Almost zero.

    In the controller (20), it is determined that both the pump pressure and the shaft pressure are higher than the shaft set pressure (step ST4 and step ST5 in FIG. 2), and it is determined that the back pressure is lower than the step-down level. (Step ST6 in FIG. 2), it is determined that the hydraulic cylinder (13) has reached the stroke end (at time t1 in FIG. 3). However, at this point, the hydraulic cylinder (13) does not actually reach the stroke end. Therefore, after determining that the stroke end has been reached, the controller (20) of the present embodiment continues to operate the hydraulic pump (11) for a certain period of time (step ST7 in FIG. 2). During this fixed time, the hydraulic oil continues to be supplied from the hydraulic pump (11) to the hydraulic cylinder (13), so that the hydraulic cylinder (13) continues to contract. As a result, the hydraulic cylinder (13) reaches the stroke end. When a certain time has elapsed (at time t2 in FIG. 3), the process proceeds to step ST8, and the direction switching valve (15) of the first clamp drive system (10A) is turned off. That is, the direction switching valve (15) is switched from the first position to the neutral position. Thereby, the supply of hydraulic oil from the hydraulic pump (11) to the hydraulic cylinder (13) is stopped. As described above, in the stroke end detection operation of the present embodiment, even if it is determined that the pump pressure and the shaft pressure are higher than the shaft set pressure and the back pressure is lower than the step-down level, the operation to the hydraulic cylinder (13) is immediately performed. The supply of hydraulic oil is continued for a predetermined time (predetermined time) without stopping the supply of hydraulic oil.

    In the present embodiment, the shaft set pressure is used as the first set value and the third set value according to the present invention, and the step-down level is used as the second set value according to the present invention.

    In subsequent step ST9, it is determined whether or not a predetermined waiting time has elapsed since the direction switching valve (15) was switched to the neutral position, and when it has elapsed, the process proceeds to step ST10 and the hydraulic pump (11) is stopped. . Thereby, the closing operation control of the clamp ends. By providing this waiting time, the hydraulic pump (11) can be stopped after the switching of the direction switching valve (15) is completed. That is, this waiting time is a time for the direction switching valve (15) to be completely switched. Since this waiting time is on the order of several tens of milliseconds, the illustration is omitted in FIG. 3 and FIG. 4 described later. That is, in FIGS. 3 and 4, the directional switching valve (15) is turned off (step ST8 in FIG. 2) and the hydraulic pump (11) is stopped (step ST10 in FIG. 2) at the same time. ing.

    Next, a case where load pressure is not so much generated during the contraction operation of the hydraulic cylinder (13) will be described. In this case as well, the stroke end detection operation is performed according to the flowchart of FIG. When the piping length of the second pipe (14b) or the fourth pipe (14d) is short, or when the pipe diameter is sufficiently large, the load pressure is hardly generated when the flow resistance of the back pressure side flow path is small. In this case, each pressure changes as shown in FIG.

    Specifically, when the hydraulic pump (11) is driven (at time t0 in FIG. 4), the pump pressure gradually increases due to the pipe resistance, and the contraction speed of the hydraulic cylinder (13) is gradually accelerated. When the hydraulic cylinder (13) accelerates to a predetermined speed, the pump pressure drops to a value considerably lower than the shaft set pressure because no load pressure is generated. Thereafter, the pump pressure changes at a relatively low constant value. On the other hand, since the load pressure is not generated, the shaft pressure and the back pressure are both substantially zero from the start of driving of the hydraulic pump (11).

    As described above, when almost no load pressure is generated during the contraction operation of the hydraulic cylinder (13), the pump pressure, the shaft pressure and the back pressure change at relatively low values or substantially zero during the contraction operation (see FIG. 4 t0 to t1). Note that the rotation speed of the motor (12) changes substantially at a predetermined value, unlike the pump pressure.

    Thereafter, when the hydraulic cylinder (13) is near the stroke end (front side), it receives a cushioning action by the cushion mechanism (at time t1 in FIG. 4). Then, both the pump pressure and the shaft pressure gradually increase and reach the shaft set pressure (at time t2 in FIG. 4). In the meantime, the back pressure does not change and changes in a substantially zero state (t1 to t2 in FIG. 4).

    In the controller (20), it is determined that both the pump pressure and the shaft pressure are higher than the shaft set pressure (step ST4 and step ST5 in FIG. 2), and it is determined that the back pressure is lower than the step-down level. (Step ST6 in FIG. 2), it is determined that the hydraulic cylinder (13) has reached the stroke end. Subsequent steps ST7 and thereafter are the same as when the load pressure described above is generated. In other words, after determining that the stroke end has been reached, the system waits for a certain period of time (t2 to t3 in FIG. 4), and during that time, hydraulic oil continues to be supplied from the hydraulic pump (11) to the hydraulic cylinder (13). As a result, the hydraulic cylinder (13) reaches the stroke end. Then, when waiting for a certain time (t3 in FIG. 4), the direction switching valve (15) is turned OFF, and the hydraulic pump (11) is stopped after the waiting time. As shown in FIG. 4, when almost no load pressure is generated during the contracting operation, the back pressure changes from the start of the contracting operation to the stroke end in a substantially zero state lower than the step-down level.

    In the above description, the operation of the first clamp drive system (10A) has been described. However, during the operation of the first clamp drive system (10A), the second clamp drive system (10B) is operated simultaneously. It is also possible in operation.

-Effect of the embodiment-
As described above, whether or not a load pressure is generated during the operation of the hydraulic cylinder (13), at the stroke end, the shaft pressure is equal to or higher than the shaft set pressure and the back pressure is equal to or lower than the predetermined pressure drop level. Therefore, it is possible to reliably detect the stroke end of the hydraulic cylinder (13) while maintaining a predetermined clamping pressure for the workpiece regardless of whether or not the load pressure is generated.

    Here, if the stroke end is detected only when the shaft pressure is equal to or higher than the shaft set pressure (predetermined pressure), it can be detected when no load pressure is generated (see FIG. 4), but the load pressure is generated. In such a case, it cannot be detected (see FIG. 3). In addition, if it is attempted to detect the stroke end only when the back pressure falls below a predetermined step-down level, it can be detected when load pressure is generated (see FIG. 3), but is detected when load pressure is not generated. It becomes impossible (refer FIG. 4). Accordingly, since the present invention considers both the shaft pressure and the back pressure, the stroke end can be reliably and easily detected without erroneous detection regardless of the presence or absence of the load pressure. Moreover, since the shaft pressure is equal to or higher than the shaft set pressure, it is possible to detect that the stroke end has been reached with the workpiece fixed (gripped) at a predetermined pressure.

    Furthermore, in the present embodiment, the fact that the pump pressure is equal to or higher than the shaft set pressure (predetermined pressure) is added to the determination condition for the stroke end. Therefore, erroneous detection of the stroke end can be further prevented. For example, when the shaft pressure increases due to the external force acting on the workpiece, the back pressure side pressure is lowered below the step-down level, so that it may be erroneously detected as a stroke end. However, by adding a condition that the pump pressure is equal to or higher than the shaft set pressure, it is possible to reliably prevent erroneous detection of the stroke end due to the action of at least an external force as described above. That is, according to the present invention, the stroke end during the operation of the hydraulic cylinder (13) can be reliably detected by adding the pump pressure to the condition.

    Further, in the present embodiment for the hydraulic cylinder (13) having a cushion mechanism at the stroke end, even if the pump pressure, the shaft pressure and the back pressure satisfy the above-mentioned predetermined pressure conditions, the direction switching valve ( It was made to turn off after waiting for a certain time (predetermined time) without turning off 15). Thereby, the hydraulic cylinder (13) can reliably reach the stroke end. That is, when the direction switching valve (15) is turned off immediately after satisfying the predetermined pressure condition, the hydraulic cylinder (13) stops before the stroke end, but this embodiment can prevent this.

    In the present embodiment, since the variable throttle valve (19) is provided in the fourth pipe (14d), the operating speed of the hydraulic cylinder (13) can be adjusted by adjusting the flow rate of the hydraulic oil. If the flow regulating valve is provided in the back pressure side flow path as described above, the flow resistance increases and the load pressure increases, but even in this case, the stroke end can be reliably detected.

    In this embodiment, the stroke end is detected in the contraction operation of the hydraulic cylinder (13), but the stroke end can be reliably detected even in the extension operation. In that case, the detected value of the head side pressure sensor (S3) is used for the shaft pressure, and the detected value of the rod side pressure sensor (S2) is used for the back pressure.

-Modification of the embodiment-
As shown in FIG. 5, the hydraulic unit (10) according to this modification is obtained by changing the variable throttle valve (19) to the counter balance valve (21) in the above embodiment. Furthermore, this hydraulic unit (10) is intended for the hydraulic cylinder (13) in which the cylinder rod (13c) advances and retreats in the vertical direction. Here, a different point from the said embodiment is demonstrated. In FIG. 5, the hydraulic pump (11) to the direction switching valve (15) are omitted, and A and B in the figure indicate the A port and the B port of the direction switching valve (15).

    Specifically, the counter balance valve (21) is provided closer to the direction switching valve (15) than the check valve (18) in the fourth pipe (14d). The counter balance valve (21) is for maintaining a constant pressure in the fourth pipe (14d) when the hydraulic cylinder (13) is lowered (contracted). That is, the counter balance valve (21) constitutes back pressure holding means for holding the pressure (back pressure) on the back pressure side constant when the hydraulic cylinder (13) is lowered. The counter balance valve (21) has a built-in check valve.

    When lowering the hydraulic cylinder (13), hydraulic oil from the hydraulic pump (11) is supplied to the rod chamber (13b) of the hydraulic cylinder (13). In this downward movement, unlike the upward movement, a force of natural fall (self-weight fall) is applied in addition to the hydraulic pressure by the hydraulic pump (11). For this reason, the pressure in the rod chamber (13b) on the fluid supply side becomes a negative pressure, and the hydraulic cylinder (13) falls rapidly. However, in this modification, the back pressure of the hydraulic cylinder (13) is kept constant by the counter balance valve (21). Therefore, the lowering speed of the hydraulic cylinder (13) is kept constant without suddenly lowering.

    And also in this modification, when the piping length of the 2nd piping (14b) and the 4th piping (14d) is long or when the piping diameter is small, and also by the holding pressure (back pressure) by the counter balance valve (21), The flow resistance increases and a load pressure is generated for the hydraulic pump (11). Even in this case, similarly to the above-described embodiment, it is possible to reliably detect that the hydraulic cylinder (13) has reached the stroke end. In this modification, the same operation and effect can be achieved even with back pressure holding means other than the counter balance valve (21).

<< Other Embodiments >>
About embodiment mentioned above, it is good also as following structures.

    For example, in the above embodiment, the pump pressure is added to the stroke end determination condition, but may be omitted.

    Further, in the above embodiment, the hydraulic cylinder (13) having a cushion mechanism at the stroke end is targeted. However, when the hydraulic cylinder not having the cushion mechanism is targeted, step ST7 in FIG. Can be omitted. That is, since the cushion action does not occur in the hydraulic cylinder (13), the pump pressure, the shaft pressure, and the back pressure satisfy the predetermined pressure conditions (steps ST4 to ST6 in FIG. 2) only after reaching the stroke end. Become. In other words, when the pump pressure or the like satisfies the above-described predetermined pressure condition, the hydraulic cylinder (13) has reached the stroke end (at time t1 in FIG. 3 and at time t2 in FIG. 4). Therefore, the controller (20) determines that the stroke end has been reached if the pump pressure or the like satisfies the predetermined pressure condition in steps ST4 to ST6 in FIG. 2, and immediately switches the direction switching valve (15) to OFF (step ST8). Thereby, the supply of hydraulic oil from the hydraulic pump (11) to the hydraulic cylinder (13) is stopped. The subsequent operation is the same as in the above embodiment.

    In the above embodiment, the hydraulic unit (10) for driving the two clamp drive systems (10A, 10B) has been described. However, the present invention is not limited to this, and a drive system in which a clamp and a chuck are mixed, or a drive system dedicated to the chuck is provided. Similar effects can be obtained even with a hydraulic unit that is driven.

    Further, the present invention can be similarly applied to a device other than a machine tool or a fluid pressure unit using a fluid other than hydraulic oil.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a fluid pressure unit that drives a fluid pressure cylinder.

FIG. 1 is a hydraulic circuit diagram showing an overall configuration of a hydraulic unit according to the embodiment. FIG. 2 is a flowchart showing the stroke end detection operation by the controller. FIG. 3 is a graph showing changes in pump pressure, shaft pressure, and back pressure. FIG. 4 is a graph showing changes in pump pressure, shaft pressure, and back pressure. FIG. 5 is a hydraulic circuit diagram illustrating a hydraulic unit according to a modification of the embodiment with a part thereof omitted. FIG. 6 is a diagram for explaining a conventional stroke end detection operation.

Explanation of symbols

10 Hydraulic unit (fluid pressure unit)
11 Hydraulic pump (fluid pressure pump)
13 Hydraulic cylinder (fluid pressure cylinder)
13a Head chamber
13b Rod chamber
14 Fourth piping (back pressure side flow path)
19 Variable throttle valve (throttle means)
20 Controller (Stroke end detection means)
21 Counter balance valve (back pressure holding means)

Claims (6)

A fluid pressure unit comprising a fluid pressure pump (11) for discharging fluid, and supplying the fluid discharged from the fluid pressure pump (11) to a fluid pressure cylinder (13) to advance and retract the cylinder rod,
The pressure in the rod chamber (13b) or the head chamber (13a) on the fluid supply side of the fluid pressure cylinder (13) is not less than the first set value, and the head is on the back pressure side of the fluid pressure cylinder (13). If the condition that the pressure in the chamber (13a) or the rod chamber (13b) is equal to or lower than the second set value is satisfied, it is determined that the cylinder rod of the fluid pressure cylinder (13) has reached the stroke end, and the fluid pressure pump ( A fluid pressure unit comprising stroke end detection means (20) for stopping the supply of fluid from 11) to the fluid pressure cylinder (13). In claim 1,
In addition to the above conditions, the stroke end detection means (20) may cause the cylinder rod of the fluid pressure cylinder (13) to perform a stroke when the discharge pressure of the fluid pressure pump (11) satisfies a condition that exceeds a third set value. A fluid pressure unit configured to stop the supply of fluid from the fluid pressure pump (11) to the fluid pressure cylinder (13) by determining that the end has been reached. In claim 1 or 2,
The stroke end detection means (20) is configured to stop the supply of fluid from the fluid pressure pump (11) to the fluid pressure cylinder (13) after a predetermined time has elapsed after satisfying the above conditions. A fluid pressure unit characterized by that. In any one of Claims 1 thru | or 3,
The back pressure side flow path (14d) connected to the head chamber (13a) or the rod chamber (13b) on the back pressure side of the fluid pressure cylinder (13) has a throttle means (19) for restricting the fluid flow path. A fluid pressure unit is provided. In any one of Claims 1 thru | or 3,
The fluid pressure cylinder (13) has a cylinder rod that moves up and down in the vertical direction.
The cylinder rod of the fluid pressure cylinder (13) is lowered in the back pressure side flow path (14d) connected to the head chamber (13a) or the rod chamber (13b) on the back pressure side of the fluid pressure cylinder (13). The fluid pressure unit is provided with a back pressure holding means (21) for holding the pressure on the back pressure side of the fluid pressure cylinder (13) constant when the fluid pressure cylinder (13) is used. In any one of Claims 1 thru | or 5,
A fluid pressure unit, wherein the fluid pressure cylinder is driven by a chuck or a clamp in a machine tool.

Images