JPH1077661A - Control circuit for construction machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To contrive to hold the advancing direction by slowing down the turning responsibility and the speed of a turning controller in the case where an upper turning member is turningly operated. SOLUTION: When a turning hydraulic remote control valve 28 is operated while running, a controller 27 outputs an action command signal to a solenoid proportional pressure reducing valve 24 and a changeover directive signal to a solenoid changeover valve 21. When the valve 21 is changed over, pilot ports 34 and 35 of a changeover valve 9 are communicated by way of an oil passage position (r) with a reducer. A secondary pressure of a pilot from the valve 28 passes through reducers 40 and 41 provided on a pilot pipeline and depressurized by opening of the position (r) so that it may serve the action of the pilot ports 34 and 35 on one hand. At the same time, the valve 24 forces the pilot pressure to act on a regulator. This action drops a gain between a discharge flow rate control of a pump and main spool control of the valve 9, which makes it possible to prevent a lower turning member from being turned in the advancing direction and slow down the turning speed so that an inertial force may be minimized when the turning is put on the brake.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control circuit for an upper swing type construction machine, a work vehicle and the like.

[0002]

2. Description of the Related Art FIG. 8 is a hydraulic circuit diagram disclosed in Japanese Patent Publication No. 1-28174. In the hydraulic circuit shown in FIG. 8, when the turning switching valve 16 is operated while the left and right traveling switching valves 14 and 18 are operated, the communication valve 23 is opened, and a part of the pressure oil of the hydraulic pump 12 is turned. Motor 8
And the amount of pressure oil supplied from the hydraulic pump 12 to the left travel motor 6 is reduced,
Is supplied to the left traveling motor 6 through the communication valve 23, so that the decrease in the speed of the left traveling motor 6 is reduced and the amount of pressure oil supplied to the right traveling motor 7 from the hydraulic pump 13 is reduced. And the speed of the right running motor 7 also decreases. Therefore, the speeds of the left and right traveling motors 6 and 7 become equal, and the traveling curve does not occur.

FIG. 9 is a hydraulic circuit diagram described in Japanese Utility Model Laid-Open No. 1-119457. In the hydraulic circuit shown in FIG. 9, when the left and right traveling valves 14 ', 15' are simultaneously operated, the switching valves 1 in the groups A ', B' are
When at least one of 8 ', 19', and 20 'is switched, the position is switched to the two position of the straight travel valve 31'. The oil discharged from the first pump 12 'passes through an oil passage 46', one of which is supplied to a traveling motor 2 'via an oil passage 47' and a traveling valve 14 ', and the other branches off in the oil passage 46'. , Oil passage 48 ′, two positions of the straight travel valve 31 ′, oil passages 49 ′, 50 ′, travel valve 1
After passing through 5 ', it is supplied to the traveling motor 3'. Thereby, the pressure oil discharged from the first pump 12 'is supplied in parallel to the left and right traveling motors 2', 3 ', and the small excavator can travel straight. In addition, since the swing motor 5 'and the dozer cylinder 11' are separated as a group C 'and an independent circuit having a third pump 33' is formed, the swing motor 5 'and other Even when the hydraulic actuator is operated, it is possible to prevent the small excavator from meandering.

[0004]

In the case of a small excavator, for example, a small excavator among the upper revolving type construction machines, when a vehicle is turned while traveling with a load (earth, sand, rubble, etc.) put in a bucket, FIGS.
Even if the main pressure oil is evenly distributed and supplied to the left and right traveling motors as shown in the hydraulic circuit shown in Figure 7, the upper revolving superstructure has large revolving inertia, and the lower revolving superstructure is rotated during the braking operation to move in the traveling direction. Can be changed. Therefore, turning start and brake operation during running of the small excavator, or running start during turning, is inconvenient in terms of work and is a problem especially in a narrow site. The present invention provides a control circuit configured to control a pump flow rate and a directional control valve for turning such that the responsiveness and speed of turning decrease when a turning operation is performed during a running operation by sensing a driving operation. The purpose is to:

[0005]

In a control circuit according to a first embodiment of the present invention, a plurality of directional control valves for controlling an actuator mounted on a construction machine are divided into two groups A and B. Pressure oil is supplied from separate first and second pumps, respectively, and when the travel motor rotates, a signal that operates another actuator other than the travel motor is used to supply one of the main pumps of the first and second pumps. A traveling linear valve which can be switched to supply the pressure oil from the pumps to the left and right traveling motors and the pressure oil from the other main pump to the other actuators, and the traveling direction valves in the left and right directions with the first and second pumps. In a control circuit interposed between the switching valve and the switching valve, traveling operation detecting means for detecting the operation of the left and right traveling direction switching valves, and detecting the operation of the swing motor control pilot switching valve. A turning operation detecting means is provided, and signals from the traveling operation detecting means and the turning operation detecting means are input to a controller.The turning hydraulic remote control valve and the left and right pilot ports of the turning motor control pilot switching valve are connected to each other. An electromagnetic switching valve is provided between a pair of communicating pilot pipes as a turning pilot pressure reducing valve capable of switching from a shutoff oil passage position to an oil passage position with a throttle, and a pilot derived from the turning hydraulic remote control valve is provided. Secondary pressure, through the throttle section, the swing pilot pressure reducing valve, so as to communicate with the pilot port of the swing motor control pilot switching valve, the controller determines based on the signal from the travel operation detection means, The controller outputs a switching command signal to the electromagnetic switching valve. The regulators of the first and second pumps and the controller communicate with each other via an electromagnetic proportional pressure reducing valve, and the controller makes a determination based on signals from the traveling operation detecting means and the turning operation detecting means. An operation command signal is output to the electromagnetic proportional pressure reducing valve.

In the control circuit according to the first embodiment of the present invention, the switching command signal is not output from the controller to the electromagnetic switching valve, which is a turning pilot pressure reducing valve, when the driving operation is not performed. The switching valve remains at the shutoff oil path position. When the turning hydraulic remote control valve is operated in this state, a pilot secondary pressure derived from the turning hydraulic remote control valve acts on one pilot port of the turning motor control pilot switching valve. The turning in this case is performed in the same state as the turning in the prior art, since the electromagnetic switching valve remains at the shutoff oil path position. Next, when the swing hydraulic remote control valve is operated while the construction machine is running, the straight traveling valve is switched from the single oil passage position to the straight traveling oil passage position, and the hydraulic oil from one main pump is used for controlling the swing motor. It becomes possible to circulate toward the pilot switching valve.
The controller determines based on signals from the traveling operation detecting means and the turning operation detecting means, and issues a switching command signal from the controller to the electromagnetic switching valve, and a switching command signal to the electromagnetic proportional pressure reducing valve communicating with the regulator of the main pump. Each outputs an operation command signal. Since the electromagnetic switching valve switches from the shutoff oil passage position to the oil passage position with the throttle,
The left and right pilot ports of the swing motor control pilot switching valve communicate with each other through the oil passage position with the throttle. Pilot secondary pressure derived from the swing hydraulic remote control valve is opened intermediate pilot pressure to pressure-reduced turning pilot pressure P _S, and the its turning pilot pressure P _S is the turning motor controlled by the oil passage position with the throttle portion Acting on one pilot port of the pilot switching valve. At the same time, the solenoid proportional pressure reducing valve on the main pump side that supplies pressure oil to the swing motor operates to apply pilot pressure to the regulator of the main pump, so that the main spool of the swing motor control pilot switching valve is loosened. And the upper revolving unit can be slowly started to rotate. That is, since the gain of both the discharge flow rate control of the main pump and the main spool control of the swing motor control pilot switching valve can be reduced, it is possible to prevent the traveling direction of the lower traveling body from being rotated by the swing starting force. Can be. In addition, since the turning speed itself also decreases, the inertial force at the time of turning brake becomes small, and the turning of the upper turning body does not continue to turn at the time of braking. Note that the same operation as described above is performed even when the traveling operation is performed during the turning operation.

A control circuit according to a second embodiment of the present invention
As in the case of the control circuit of the embodiment, the electromagnetic switching valve 21, the traveling operation detecting means and the turning operation detecting means are provided, but each of the center bypasses penetrates a plurality of actuator control pilot switching valves in the groups A and B. A foot relief valve and a throttle portion are connected in parallel to the oil passage outlet side, respectively, and the downstream side is communicated with the oil tank, and the negative control generated upstream of the throttle portion when all the pilot switching valves are in the neutral position state. A negative control type (so-called negative control type) hydraulic circuit is configured so that the pressure passes through each regulator of the first and second pumps. Accordingly, when the hydraulic remote control valve for turning is operated during traveling of the hydraulic excavator, the gain of the discharge flow control of the main pump on the turning motor drive side is automatically reduced as the gain of the main spool control of the turning pilot switching valve is reduced. Can be done.

In a control circuit according to a third embodiment of the present invention, a travel operation signal is supplied between a pair of pilot conduits communicating between a turning hydraulic remote control valve and left and right pilot ports of a turning motor control pilot switching valve. A swing pilot pressure reducing valve that can be switched from the shutoff oil passage position to the throttled oil passage position is provided, and a pilot secondary pressure derived from the swing hydraulic remote control valve is provided with the swing pilot pressure reducing valve. Connect the pilot port of the swing motor control pilot switching valve to the pilot port, and connect the left and right pilot ports of the swing motor control pilot switching valve via the shuttle valve, and supply hydraulic oil to the shuttle valve and the rotation motor. And the pilot secondary pressure outlet port of the traveling hydraulic remote control valve Was allowed communication with the pilot port of bets pressure reducing valve.

When the traveling hydraulic remote control valve is not operated in the control circuit of the third embodiment, the traveling pilot pressure does not act on the pilot port of the turning pilot pressure reducing valve. Therefore, when the turning hydraulic remote control valve is operated in a state where the traveling operation is not performed, it is the same as in the first and second embodiments. Next, when the turning hydraulic remote control valve is operated while the hydraulic excavator is traveling, the pilot secondary pressure derived from the traveling hydraulic remote control valve acts on the pilot port of the turning pilot pressure reducing valve.
Since the turning pilot pressure reducing valve is switched from the shutoff oil passage position to the oil passage position with the throttle portion, the left and right pilot ports of the swing motor control pilot switching valve communicate with each other via the oil passage position with the throttle portion. Pilot secondary pressure derived from the swing hydraulic remote control valve is opened intermediate pilot pressure to pressure-reduced turning pilot pressure P _S, and the its turning pilot pressure P _S is the turning motor controlled by the oil passage position with the throttle portion Acting on one pilot port of the pilot switching valve. At the same time, the turning pilot pressure P _S
Of the main pump acts on the regulator of the main pump that supplies pressure oil to the swing motor. Therefore, similarly to the case of the control circuit of the embodiment, the gains of both the discharge flow rate control of the main pump and the main spool control of the swing motor control pilot switching valve can be reduced.

In the control circuit according to the fourth embodiment of the present invention, similarly to the control circuit according to the third embodiment, a pair of pilots communicating with the left and right pilot ports of the turning motor control pilot switching valve from the turning hydraulic remote control valve are provided. A turning pilot pressure reducing valve that can be switched from the shutoff oil passage position to the throttled oil passage position by a traveling operation signal is provided between the pipelines, and a signal from the traveling operation detection unit and the rotation operation detection unit is sent to the controller. The output side ports of the electromagnetic proportional pressure reducing valve are connected to the left and right pilot ports of the swing motor control pilot switching valve, respectively, and the pilot secondary pressure derived from the swing hydraulic remote control valve is The traveling operation detecting means and the turning operation detecting means are connected to the turning pilot pressure reducing valve and the input side port of the electromagnetic proportional pressure reducing valve. And the controller determines based on a signal from the means, and to output an actuation command signal from the controller to the solenoid of the solenoid proportional pressure reducing valves. In the above case, the pilot pressure from the electromagnetic proportional pressure reducing valve acting on the pilot port of the swing motor control pilot switching valve is determined by a predetermined coefficient with respect to the traveling pilot pressure value acting on the pilot port of the traveling pilot switching valve. Was set to a pressure value multiplied by.

In the control circuit of the fourth embodiment, when the turning hydraulic remote control valve is operated in a state where the traveling operation is not performed,
The operation signal is input to the controller. The controller makes a determination based on the operation signal and outputs a pilot secondary pressure holding command signal to the electromagnetic proportional pressure reducing valve, so that the electromagnetic proportional pressure reducing valve maintains the pilot secondary pressure conductive state. Therefore, when the turning hydraulic remote control valve is operated in this state, the pilot secondary pressure derived from the turning hydraulic remote control valve passes through the electromagnetic proportional pressure reducing valve in the pilot secondary pressure conducting state, thereby turning the turning motor control pilot switch. Acts on one pilot port of the valve. The turning in this case is the same as the turning in the prior art because the electromagnetic proportional pressure reducing valve maintains the pilot secondary pressure conducting state. Next, when the turning hydraulic remote control valve is operated during traveling of the hydraulic excavator, the controller determines based on the operation signal, and the controller outputs an operation command signal to the solenoid of the electromagnetic proportional pressure reducing valve. The electromagnetic proportional pressure reducing valve performs a pressure reducing operation, but the turning pilot pressure derived from the electromagnetic proportional pressure reducing valve is lower than the pilot secondary pressure derived from the hydraulic turning remote control valve. That is, the coefficient K, which is a ratio at which the turning pilot secondary pressure is reduced, is set so as to decrease as the traveling pilot pressure acting on the pilot port of the traveling pilot switching valve increases. Therefore, when the traveling pilot pressure is increased and the traveling speed is increased, the traveling pilot pressure applied to the pilot port of the pivot motor control pilot switching valve is set to a low pressure, so that the traveling traveling can be smoothly performed.

[0012]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a control circuit diagram of a first embodiment of the present invention. In the drawing, reference numeral 1 denotes a pilot switching valve for controlling the traveling motor 2 on the left side (hereinafter, referred to as traveling pilot switching valve 1), and reference numeral 4 denotes a pilot switching valve for controlling the traveling motor 3 on the right side (hereinafter, traveling pilot switching valve 4). , 9 is a pilot switching valve for controlling the swing motor 5 (hereinafter referred to as a swing pilot switching valve 9), 10 and 11 are pilot switching valves for controlling other hydraulic actuators (not shown), and 15 and 17 are First and second pumps, each of which is a variable displacement main pump, 19 and 20 are regulators of the first pump 15 and the second pump 17, respectively, and 31 is the first pump 15 and the second pump 17 and left and right traveling pilots. A traveling straight valve provided between the switching valves 1 and 4, 21 is an electromagnetic switching valve which is a turning pilot pressure reducing valve, and 22 and 24 are regulators 19 and Solenoid proportional pressure reducing valves that allowed each communicating with 0, 25 pilot pump 26 is a pilot hydraulic source, travel hydraulic remote control valves 27, 28 swing hydraulic remote control valve, 29 _F, 29 _R are traveling pilot change-over valve The pressure sensors 31 _F and 31 _R are driving operation detecting means provided to be connected to the pilot ports 30 _F and 30 _R at both ends of the pilot pilot valve 1. Pilot ports 32 _F and 32 at both ends of the driving pilot switching valve 4 are provided.
_A pressure sensor 33, which is a traveling operation detecting means connected to _R , detects turning pilot pressure acting on the left and right pilot ports 34 or 35 of the turning pilot switching valve 9 via a shuttle valve 36. A pressure sensor as an operation detecting means, 37 is a controller,
A, ro-ro, ho-ho, ha-he, and toe indicate the connections of the pilot lines.

Next, the configuration of a control circuit according to a first embodiment of the present invention will be described with reference to FIG. First, in the control circuit shown in FIG. 1, a plurality of directional control valves (pilot control valves) for controlling an actuator provided on a hydraulic excavator (not shown) are provided.
Group A (group of pilot switching valve for traveling 1, pilot switching valve 9 for turning, pilot switching valve 10)
And group B (a group of traveling pilot switching valve 4 and pilot switching valve 11), and pressure oil from separate first pump 15 and second pump 17 is supplied to groups A and B, respectively. A pair of traveling pilot switching valves 1 and 4 are arranged on the most upstream side of each of the groups A and B,
In addition, this and another pilot switching valve on the downstream side are connected in parallel, and a traveling straight valve 31 is provided between the first pump 15 and the second pump 17 and the left and right traveling pilot switching valves 1, 4. The first pump 15 of the first pump 15 and the second pump 17 is operated by a signal (a pilot pressure signal in FIG. 1) for operating another actuator (an actuator other than the traveling motors 2 and 3) when the hydraulic remote control valve 27 is operated. Is supplied to the left and right traveling motors 2 and 3 and the pressure oil from the second pump 17 is supplied to the other actuator. According to the present invention, the pressure sensor 29 _F for detecting the operation of the left and right traveling pilot switching valves 1 and 4.
Provided -29 _R, 31 _F -31 _R, the pressure sensor 29
_F -29 _R, 31 _F -31 to a signal from _R to be inputted to the controller 37, also the swing hydraulic remote control valve 2
8 and a pair of pilot pipes (3) communicating the left and right pilot ports 34, 35 of the turning pilot switching valve 9.
_{8 a -38 b -38 c -38 d} ), (39 a, 39 b,
Between 39 _c and 39 _d ), an electromagnetic switching valve 21 is provided as a turning pilot pressure reducing valve capable of switching from the shutoff oil passage position H to the oil passage position with the throttle portion, and is derived from the turning hydraulic remote control valve 28. The pilot secondary pressure is communicated to the electromagnetic switching valve 21 and the pilot port 34 or 35 of the turning pilot switching valve 9 through the throttle section 40 or 41, and the pressure sensor as the traveling operation detecting means is provided. 29
_F -29 _R, 31 _F controller 37 determines on the basis of the -31 signal from _R, and outputs a switch command signal to the electromagnetic switching valve 21 from its controller 37.
And also the first pump 15, and each regulator 19, 20 of the second pump 17, communicates via a solenoid proportional pressure reducing valves 22, 24 and a controller 37, respectively, the pressure sensor 29 _F -29 _R, 31 _F - The controller 37 makes a decision based on the signals from 31 _R and 33, and outputs an operation command signal from the controller 37 to the electromagnetic proportional pressure reducing valves 22 and 24.

Next, the operation of the control circuit according to the first embodiment of the present invention will be described. In the control circuit of the present invention, the switching command signal is not output from the controller 37 to the electromagnetic switching valve 21 which is the turning pilot pressure reducing valve unless the traveling operation is performed, so that the electromagnetic switching valve 21 is shut off. The oil path position remains unchanged. First, the swing hydraulic remote control valve 28 to the single operation as the first case, the pilot secondary pressure derived from the swing hydraulic remote control valve 28 is provided on the pilot conduit _{38 a -38 b, 39 a -39} b Passing through the constricted portion 40 or 41 and the pilot line 38 _c
Via −38 _d or 39 _c −39 _d , it acts on one pilot port 34 or 35 of the turning pilot switching valve 9. The turning in this case is performed in the same state as the turning in the prior art because the electromagnetic switching valve 21 remains at the shutoff oil passage position H.

Next, as the second case, when the turning hydraulic remote control valve 28 is operated while the hydraulic excavator is traveling, the traveling straight traveling valve 31 is switched from the single oil passage position nu to the traveling straight traveling oil passage position. The pressure oil from the two pumps 17 can flow toward the turning pilot switching valve 9. At the same time controller 37 pressure sensor 29 _F -29 _R, 31 _F -3
1 _R and the signal from the pressure sensor 33,
The controller 37 outputs an operation command signal to the electromagnetic proportional pressure reducing valve 24 communicating with the regulator 20 of the second pump 17, and outputs a switching command signal to the electromagnetic switching valve 21. Since the electromagnetic switching valve 21 switches from the shutoff oil passage position H to the oil passage position with throttle, the left and right pilot ports 34-3 of the turning pilot switching valve 9 are switched.
The spaces 5 communicate with each other via the oil passage position with throttle. Swing hydraulic remote control valve 28 pilot secondary pressure derived from its pilot lines _{38 a -38 b, 39 a -39} b
To pass through the throttle portion 40 or 41 is provided, the turning pilot pressure is depressurized to an intermediate pilot pressure by opening dated throttle portion oil passage position Li P _S, and the its turning pilot pressure P _S is turning pilot switching Acts on one pilot port 34 or 35 of the valve 9. At the same time, the solenoid proportional pressure reducing valve 24 on the side of the second pump 17 that supplies pressure oil to the swing motor 5 operates to reduce the pilot pressure to the pressure in the regulator 2.
Act on 0. Thereby, the second pump 17
The gain of both the discharge flow rate control and the main spool control of the turning pilot switching valve 9 can be reduced. That is, the main spool (not shown) of the turning pilot switching valve 9 is gently switched, and the upper turning body (not shown) can be started to turn slowly. FIG.
Is a chart showing the lever operation amount of the swing hydraulic remote control valve 28 (the angle theta) the relationship between the turning pilot pressure P _S. 3, turning the pilot pressure P _S and the main pump (in this embodiment the second pump 17) is a table showing the relationship between the discharge flow rate Q of. In this control circuit, it is possible to prevent the traveling direction of the lower traveling body (not shown) from being turned by the turning start force, and also to reduce the turning speed itself, so that the inertia force at the time of the turning brake is also reduced. The upper revolving superstructure does not rotate continuously during braking. Note that the same operation as described above is performed even when the traveling operation is performed during the turning operation. In the control circuit shown in FIG. 1, a center bypass hydraulic circuit is used for a plurality of actuator control pilot switching valves. However, the present invention is not limited to this, and may be applied to, for example, a closed center hydraulic circuit. is there.

FIG. 4 is a control circuit diagram of a second embodiment of the present invention. In the figure, components using the same components as those of the control circuit shown in FIG. The control circuit shown in FIG. 4 includes an electromagnetic switching valve 21, traveling operation detecting means and turning operation detecting means as in the case of the control circuit of the first embodiment, but a plurality of actuators in groups A and B are provided. each center bypass oil passage 43 outlet each side foot relief valve 44 _a, 44 _b and the diaphragm portion 45 _a, 45 _b and a are connected in parallel downstream of the oil tank 47 through a control pilot selector valve allowed communication, all of the pilot the throttle portion when in the neutral position state of the switching valve 45 _a, 45 _b negative control pressure is first pump 15 for generating the upstream side of each pilot to each regulator 19, 20 of the second pump 17 constitute a hydraulic circuit of negatives control scheme so as to communicate via the line 46 _a, 46 _b (the so-called negative control scheme). Therefore, the turning hydraulic remote control valve 28 during traveling of the hydraulic excavator.
Is operated, the controller 37 ′ operates the pressure sensor 29 _F
Judgment is made based on −29 _R , 31 _F −31 _R and the signal from the pressure sensor 33, and the controller 37 ′ outputs a switching command signal to the electromagnetic switching valve 21. Since the electromagnetic switching valve 21 switches from the shutoff oil passage position H to the oil passage position with the throttle portion, the gain of the main spool control of the turning pilot switching valve 9 is reduced as in the control circuit of the first embodiment. Can be. In the above case, in the negative control system of the control circuit of the second embodiment, the gain of the discharge flow rate control of the second pump 17 is automatically reduced with the decrease of the gain of the main spool control of the turning pilot switching valve 9. Can be.

FIG. 5 is a circuit diagram of a main part of a control circuit according to a third embodiment of the present invention. In the figure, components using the same components as those of the control circuit shown in FIG. Although the control circuit of the third embodiment is of the all hydraulic positive control type, the configuration thereof will be described. A swing hydraulic remote control valve 28 in the present invention, a pair of left and right pilot line for communicating the pilot port 34 and 35 of the swing pilot selector valve _{9 (38 a -38 b -38 c} -38 d), (3
9 _a , 39 _b , 39 _c , 39 _d ), there is provided a turning pilot pressure reducing valve 48 which can be switched from the shutoff oil passage position H to the oil passage position with the throttle portion, and the turning hydraulic remote control valve 2 is provided.
The pilot secondary pressure derived from the pilot valve 8 is communicated with the turning pilot pressure reducing valve 48 and the pilot port 34 or 35 of the turning pilot switching valve 9. 34
And 35 are communicated via a shuttle valve 36, and the shuttle valve 36 communicates with the regulator 20 of the second pump 17 that supplies hydraulic oil to the swing motor 5 during traveling operation. 27 pilot secondary-pressure outflow port (Fig. 5, the pilot lines 49 _a, 49 _b,
49c , 49d ₎ is the most downstream shuttle valve 50 for selecting the pilot secondary pressure which is derived to one of the pilot port 49c and 49d.
I was able to communicate with

Next, the operation of the control circuit according to the third embodiment of the present invention will be described. When the traveling hydraulic remote control valve 27 is not operated in the control circuit of the present invention, the traveling pilot pressure does not act on the pilot port 51 of the turning pilot pressure reducing valve 48. Therefore, when the turning hydraulic remote control valve 28 is operated in a state where the traveling operation is not performed, the turning is performed in the same state as the turning in the related art.
Next, while the excavator is running, the turning hydraulic remote control valve 28
Is operated, the pilot secondary pressure derived from the traveling hydraulic remote control valve 27 acts on the pilot port 51 of the turning pilot pressure reducing valve 48. Since the turning pilot pressure reducing valve 48 switches from the shutoff oil passage position H to the oil passage position with throttle, the space between the left and right pilot ports 34 and 35 of the turning pilot switching valve 9 is the oil passage position with throttle. To communicate through. The pilot secondary pressure derived from the turning hydraulic remote control valve 28 is controlled by the pilot line 38 _a -3.
8 _b, 39 _a -39 _b passes through the throttle portion 40 or 41 provided on the swiveling pilot pressure P _S becomes reduced in pressure to an intermediate pilot pressure by the opening of the throttle portion with the oil passage position Li,
Its turning pilot pressure P _S acts on one of the pilot port 34 or 35 of the swing pilot selector valve 9.
Some of the turning pilot pressure P _S therewith which is the reduced pressure at the same time, the shuttle valve 36, via line 52 and 53, acting on the regulator 20 of the second pump 17 supplies pressure oil to the swing motor 5. Therefore, similarly to the case of the control circuits of the first and second embodiments, the gains of both the control of the discharge flow rate of the main pump and the control of the main spool of the turning pilot switching valve 9 can be reduced.

FIG. 6 is a main part circuit diagram of a control circuit according to a fourth embodiment of the present invention. In the figure, components using the same components as those in the control circuit shown in FIG. Reference numeral 33 denotes a pressure sensor as a turning operation detecting means for detecting the operation of the turning pilot switching valve 9, and reference numerals 29 and 31 denote respective pressures as traveling operation detecting means for detecting the operation of the left and right traveling pilot switching valves 1 and 4, respectively. A sensor 54 is a pilot switching valve 56 for controlling another hydraulic actuator 55.
Pressure sensor, which is operation detection means for detecting the operation of
Reference numerals 7 and 58 denote electromagnetic proportional pressure reducing valves, respectively. Next, the configuration of a control circuit according to a fourth embodiment of the present invention will be described with reference to FIG.
In the present invention the third embodiment the control circuit a pair of pilot lines of the case and leads to the right and left of the pilot port 34, 35 of the rotation pilot changeover valve 9 from the swing hydraulic remote control valve 28 similar (38 _a -38 _b - 38 _c -38 _d), (3
9 _a , 39 _b , 39 _c , 39 _d ), a turning pilot pressure reducing valve 48 that can be switched from the shutoff oil passage position H to the oil passage position with the throttle portion by a traveling operation signal is provided, and the turning operation is detected. A pressure sensor 33 as a means and pressure sensors 29 and 31 as traveling operation detecting means are provided, respectively, and signals from the pressure sensors 33, 29 and 31 are sent to a controller 37 ".
The output ports 59 and 60 of the electromagnetic proportional pressure reducing valves 57 and 58 are connected to the left and right pilot ports 34 and 35 of the turning pilot switching valve 9 respectively. The derived pilot secondary pressure is supplied to the turning pilot pressure reducing valve 48 and the input side ports 6 of the electromagnetic proportional pressure reducing valves 57 and 58, respectively.
1 and 62 and the pressure sensors 33 and 2
The controller 37 "determines based on the signals from the controller 9 and the controller 31", and the controller 37 "provides the controller 37" with the signal.
An operation command signal is output to 7 or 58. In the above case, the pilot pressure from the electromagnetic proportional pressure reducing valves 57 and 58 applied to the pilot ports 34 and 35 of the turning pilot switching valve 9 is applied to the pilot ports (30 _F and 30 _F) of the traveling pilot switching valves 1 and 4. _R , 3
And to set the pressure value obtained by multiplying a predetermined coefficient K with respect to the traveling pilot pressure value acting on the 2 _F, 32 _R).
FIG. 7 shows the traveling pilot pressure _Pid acting on the pilot ports of the traveling pilot switching valves 1 and 4, and the turning pilot pressure (specifically, the pilot secondary pressure) value derived from the turning hydraulic remote control valve 28. 6 is a table showing a relationship between the coefficient and a coefficient K to be multiplied.

Next, the operation of the control circuit according to the fourth embodiment of the present invention will be described. According to the present invention, when the turning hydraulic remote control valve 28 is operated in a state where the traveling operation is not performed, the operation signal is input to the controller 37 ″ via the pressure sensor 33. The controller 37 ″ is based on the turning operation signal. Judgment is made and a pilot secondary pressure holding command signal is output to the electromagnetic proportional pressure reducing valves 57 and 58, so that the electromagnetic proportional pressure reducing valves 57 and 58 maintain the pilot secondary pressure conducting state. Therefore, when the turning hydraulic remote control valve 28 is operated in this state, the turning hydraulic remote control valve 28 is operated.
The pilot secondary pressure derived from the pilot secondary pressure is passed through an electromagnetic proportional pressure reducing valve (either one of 57 and 58) in the pilot secondary pressure conducting state, and one pilot port of the turning pilot switching valve 9 ( 34 or 35). The turning in this case is the same as the turning in the prior art because the electromagnetic proportional pressure reducing valves 57 and 58 maintain the pilot secondary pressure conducting state. Next, when the turning hydraulic remote control valve 28 is operated while the hydraulic excavator is traveling, the controller 37 "determines based on the operation signals (the turning operation signal from the pressure sensor 33 and the traveling operation signal from the pressure sensors 29, 31). And the controller 3
7 ", the solenoid 6 of the electromagnetic proportional pressure reducing valves 57, 58
An operation command signal is output to the third and the fourth. The electromagnetic proportional pressure reducing valves 57 and 58 perform a pressure reducing operation, and the pilot pressure P for turning derived from the electromagnetic proportional pressure reducing valves 57 and 58 is used.
_iS is lower than the pilot secondary pressure derived from the turning hydraulic remote control valve 28. That is, as shown in FIG. 7, the coefficient K, which is a ratio at which the turning pilot secondary pressure is reduced, becomes higher as the traveling pilot pressure _PiD acting on the pilot ports of the traveling pilot switching valves 1 and 4 becomes higher. It is set to be smaller. Therefore, when the traveling speed is increased by increasing the traveling pilot pressure _PiD , the pilot port 3 of the turning pilot switching valve 9 is controlled.
4,35 pilot pressure P _iS for turning to act in the low pressure, it is possible to perform a gradual running time of turning. Note in the case of the above, the pilot pressure P _iS for turning to act on the pilot port 34, 35 of the rotation pilot changeover valve 9, the relationship between the pilot secondary pressure P _'S derived from the swing hydraulic remote control valve 28 Is calculated by the controller 37 ″ based on the following equation.

[0021]

(Equation 1)

[0022]

According to the control circuit of the present invention, the signals from the traveling operation detecting means and the turning operation detecting means are inputted to the controller, and the left and right pilots of the turning hydraulic remote control valve and the turning motor control pilot switching valve. A turning pilot pressure reducing valve is provided between a pair of pilot lines communicating with the port, the valve being capable of switching from a shutoff oil passage position to an oil passage position with a throttle. Therefore, if the hydraulic excavator is not performing the traveling operation, the switching command signal is not output from the controller to the electromagnetic switching valve serving as the turning pilot pressure reducing valve, so that the electromagnetic switching valve remains in the shutoff oil path position. It is. When the turning hydraulic remote control valve is operated in this state, a pilot secondary pressure derived from the turning hydraulic remote control valve acts on one pilot port of the turning motor control pilot switching valve. The turning in this case is similar to the turning in the prior art, since the electromagnetic switching valve remains at the shutoff oil path position. Next, when the turning hydraulic remote control valve is operated while the construction machine is running, the controller issues a switching command signal to the electromagnetic switching valve and an operation command signal to the electromagnetic proportional pressure reducing valve connected to the regulator of the main pump. Output each. Since the electromagnetic switching valve switches from the shutoff oil passage position to the oil passage position with the throttle,
The left and right pilot ports of the swing motor control pilot switching valve communicate with each other through the oil passage position with the throttle. Pilot secondary pressure derived from the swing hydraulic remote control valve is opened intermediate pilot pressure to pressure-reduced turning pilot pressure P _S, and the its turning pilot pressure P _S is the turning motor controlled by the oil passage position with the throttle portion Acting on one pilot port of the pilot switching valve. At the same time, the solenoid proportional pressure reducing valve on the main pump side that supplies pressure oil to the swing motor operates to apply pilot pressure to the regulator of the main pump, so that the main spool of the swing motor control pilot switching valve is loosened. And the upper revolving unit can be slowly started to rotate. That is, since the gain of both the discharge flow rate control of the main pump and the main spool control of the swing motor control pilot switching valve can be reduced, it is possible to prevent the traveling direction of the lower traveling body from being rotated by the swing starting force. Can be. In addition, since the turning speed itself also decreases, the inertial force at the time of turning brake becomes small, and the turning of the upper turning body does not continue to turn at the time of braking. It should be noted that a control circuit having a turning pilot pressure reducing valve that can be switched by the pilot pressure can also exert the same effect as described above. In addition, the control circuit in which the pilot secondary pressure derived from the turning hydraulic remote control valve is applied to the pilot port of the turning motor control pilot switching valve via the electromagnetic proportional pressure reducing valve turns while the vehicle is not running. When the hydraulic remote control valve is operated, the electromagnetic proportional pressure reducing valve maintains the pilot secondary pressure conducting state. Therefore, the turning in this case is similar to the turning in the case of the prior art. Next, when the turning hydraulic remote control valve is operated during traveling, the electromagnetic proportional pressure reducing valve performs a pressure reducing operation, but the turning pilot pressure derived from the electromagnetic proportional pressure reducing valve is:
The pressure becomes lower than the pilot secondary pressure derived from the turning hydraulic remote control valve. That is, the coefficient K, which is a ratio at which the turning pilot secondary pressure is reduced, is set so as to decrease as the traveling pilot pressure acting on the pilot port of the traveling pilot switching valve increases.
Therefore, when the traveling pilot pressure is increased and the traveling speed is increased, the traveling pilot pressure applied to the pilot port of the pivot motor control pilot switching valve is set to a low pressure, so that the traveling traveling can be smoothly performed.
Therefore, in the upper turning type construction machine equipped with the control circuit of the present invention, when turning operation is performed during traveling, the response and speed of turning can be automatically reduced to prevent the traveling direction from being changed, so that safety during traveling can be reduced. Performance can be improved.

[Brief description of the drawings]

FIG. 1 is a control circuit diagram of a first embodiment of the present invention.

2 is a table showing the relationship between the lever operation amount of the swing hydraulic remote control valve and the swing pilot pressure P _S.

FIG. 3 is a table showing a relationship between a turning pilot pressure P _S and a discharge flow rate of a main pump.

FIG. 4 is a control circuit diagram of a second embodiment of the present invention.

FIG. 5 is a main part circuit diagram of a control circuit according to a third embodiment of the present invention.

FIG. 6 is a main part circuit diagram of a control circuit according to a fourth embodiment of the present invention.

FIG. 7 is a chart showing a relationship between a traveling pilot pressure _Pid acting on a pilot port of a traveling pilot switching valve and a coefficient K multiplied with a turning pilot pressure value derived from a turning hydraulic remote control valve. It is.

FIG. 8 is a hydraulic circuit diagram of one embodiment of the prior art.

FIG. 9 is a hydraulic circuit diagram of another example of the related art.

[Explanation of symbols]

1,4 Traveling motor control pilot switching valve 2,2 ', 3,3', 6,7 Traveling motor 5,8 Swing motor 9 Swing motor control pilot switching valve 12 ', 15 First pump 13', 17 2 pumps 19, 20 regulator 21 electromagnetic switching valve (turning pilot pressure reducing valve) 22,24,57,58 electromagnetic proportional pressure reducing valve 27 traveling hydraulic remote control valve 28 swing hydraulic remote control valve 29,29 _F, 29 _R, 31 , 31 _F , 31 _R , 33,
54 Pressure sensor 31, 31 'Straight travel valve 37, 37', 37 "Controller 40, 41 Throttle section 48 Valve for turning pilot pressure reduction

Claims (7)

[Claims] 1. A plurality of directional control valves for controlling an actuator mounted on a construction machine are divided into two groups A and B,
Pressurized oil from separate first and second pumps is supplied to the groups A and B, respectively, and the first and second pumps are operated by signals that operate other actuators other than the traveling motor when the traveling motor rotates. A traveling linear valve that can be switched to supply hydraulic oil from one main pump to the left and right traveling motors and hydraulic oil from the other main pump to the other actuator; A driving circuit detecting means for detecting the operation of the left and right traveling direction switching valves and a control circuit interposed between the right and left traveling direction switching valves and the operation of the turning motor control pilot switching valve. Turning operation detecting means for inputting signals from the traveling operation detecting means and the turning operation detecting means to a controller, a turning remote control valve for turning, and a turning motor. Between a pair of pilot lines for communicating the pilot port of the left and right patronage pilot switching valve,
A control circuit for a construction machine, comprising a swing pilot pressure reducing valve capable of switching from a shutoff oil passage position to a throttled oil passage position. 2. The control circuit for a construction machine according to claim 1, wherein the pilot secondary pressure derived from the turning hydraulic remote control valve is passed through a throttle to reduce the turning pilot pressure. And a control circuit for a construction machine, wherein the control circuit communicates with a pilot port of a swing motor control pilot switching valve. 3. The control circuit for a construction machine according to claim 1, wherein said turning pilot pressure reducing valve is set to an electromagnetic switching valve, and based on a signal from said traveling operation detecting means. A control circuit for a construction machine, wherein the controller determines and outputs a switching command signal to the electromagnetic switching valve from the controller. 4. The control circuit for a construction machine according to claim 1, wherein each of the regulators of the first and second pumps and a controller are respectively communicated via an electromagnetic proportional pressure reducing valve, and the travel operation is performed. A control circuit for a construction machine, wherein the controller determines based on signals from the detecting means and the turning operation detecting means, and outputs an operation command signal to the electromagnetic proportional pressure reducing valve from the controller. 5. A plurality of directional control valves for controlling an actuator mounted on a construction machine are divided into two groups A and B,
Pressurized oil from separate first and second pumps is supplied to the groups A and B, respectively, and the first and second pumps are operated by signals that operate other actuators other than the traveling motor when the traveling motor rotates. A traveling linear valve that can be switched to supply hydraulic oil from one main pump to the left and right traveling motors and hydraulic oil from the other main pump to the other actuator; And a control circuit interposed between the left and right traveling direction switching valves, a pair of pilot pipelines communicating the turning hydraulic remote control valve and the left and right pilot ports of the turning motor control pilot switching valve. A swing pilot pressure reducing valve switchable from a shutoff oil passage position to a throttle member oil passage position, and a pilot secondary pressure derived from the swing hydraulic remote control valve. The throttle pilot pressure reducing valve and the pilot port of the swing motor control pilot switching valve are connected to each other through a throttle unit, and the left and right pilot ports of the swing motor control pilot switching valve are connected via a shuttle valve. The shuttle valve communicates with the regulator of the main pump that supplies pressure oil to the swing motor, and the pilot secondary pressure derivation port of the traveling hydraulic remote control valve is connected to the pilot port of the swing pilot pressure reducing valve. A control circuit for a construction machine, wherein the control circuit is in communication with the construction machine. 6. A control circuit for a construction machine according to claim 5, wherein a traveling operation detecting means for detecting an operation of said traveling direction switching valve, and an operation of a swing motor controlling pilot switching valve. A turning operation detecting means is provided, and signals from the traveling operation detecting means and the turning operation detecting means are input to a controller. Outputs of the electromagnetic proportional pressure reducing valves are respectively provided to left and right pilot ports of the turning motor control pilot switching valve. Side port, so that the pilot secondary pressure derived from the turning hydraulic remote control valve passes through the turning pilot pressure reducing valve and the input side port of the electromagnetic proportional pressure reducing valve. The controller makes a determination based on a signal from the turning operation detecting means, and the controller issues an operation command signal to the electromagnetic proportional pressure reducing valve. A control circuit for a construction machine, wherein the control circuit outputs a signal. 7. The control circuit for a construction machine according to claim 6, wherein a pilot pressure from said electromagnetic proportional pressure reducing valve acting on a pilot port of said swing motor control pilot switching valve is used for traveling pilot switching. A control circuit for a construction machine, wherein a pressure value obtained by multiplying a traveling pilot pressure value acting on a pilot port of a valve by a predetermined coefficient is set.