JP2007152312A - Discharge conveyor control device in crushing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a discharge conveyor control device in a crushing machine capable of preventing breakage of a conveyor belt and a hydraulic motor for a discharge conveyor when the discharge conveyor for conveying stuff crushed by a crushing device is in an overload condition. <P>SOLUTION: The control device has a pressure sensor for detecting the drive pressure of a hydraulic motor 18 for a discharge conveyor, and performs the drive control of the hydraulic motor 18 for the discharge conveyor. The overload of the discharge conveyor is determined based on the drive pressure of the hydraulic motor 18 for the discharge conveyor to be detected by the pressure sensor. If the overload is determined, the overload discharge conveyor stop control for stopping the hydraulic motor 18 for the discharge conveyor is performed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention belongs to the technical field of a carry-out conveyor control device in a crusher for crushing rocks, concrete and the like.

Generally, there are crushers equipped with crushing devices such as jaw crushers, impact crushers, roll crushers, etc., as a machine that finely crushes the objects to be crushed, such as concrete generated at the site of demolition of buildings and rocks generated in civil engineering work. It is known that such crushers include not only a crushing device but also a feeder for supplying the material to be crushed to the crushing device, and a carry-out for carrying out the crushing material crushed by the crushing device to the outside of the machine. Various devices related to crushing work such as conveyors are installed.
By the way, the carry-out conveyor is overloaded when the amount of the crushed processed product to be carried out is too large or the crushed processed product is caught in the middle of carrying out, and the conveyor belt constituting the carry-out conveyor or the carry-out conveyor There is a risk of damage to the hydraulic motor for the carry-out conveyor that is driven.
Therefore, conventionally, when an abnormal stop of the carry-out conveyor is detected, a technique has been proposed in which the operation of the feeder and the crushing device is stopped, thereby preventing breakage of the carry-out conveyor (for example, (See Patent Document 1).
JP-A-7-185387

  However, although the thing of the said patent document 1 can cope after a carrying-out conveyor stops abnormally, even if it is an overload state until a carrying-out conveyor stops, a carrying-out conveyor will continue driving, There is a problem that breakage of the conveyor belt and the hydraulic motor for the carry-out conveyor cannot be surely prevented, and there is a problem to be solved by the present invention.

The present invention has been created in view of the above circumstances and has been created for the purpose of solving these problems. The invention of claim 1 is directed to a crushing device and a crushing product crushed by the crushing device. In a crusher configured to include a carry-out conveyor to be carried out, a hydraulic motor for a carry-out conveyor that drives the carry-out conveyor, and a control device that performs drive control of the hydraulic motor for the carry-out conveyor, the hydraulic motor for the carry-out conveyor When the pressure sensor for detecting the driving pressure is provided, the control device determines an overload of the carry-out conveyor based on the drive pressure of the hydraulic motor for the carry-out conveyor detected by the pressure sensor, and the overload is determined An unloading conveyor control device in a crusher characterized in that the unloading unloading conveyor stop control is performed to stop the unloading conveyor hydraulic motor. A.
And by doing in this way, the trouble that the carry-out conveyor continues to drive in an overloaded state can be surely prevented, and the conveyor belt constituting the carry-out conveyor and the hydraulic motor for the carry-out conveyor are damaged. And damage can be prevented.
The invention according to claim 2 uses a momentary switch that outputs an ON signal to the control device only during operation of the carry-out conveyor operation switch. In addition, the control device stops the switch command for performing the rotation control / stop control of the hydraulic motor for the carry-out conveyor based on the operation of the carry-out conveyor operation switch when performing the carry-out conveyor stop control at the time of overload. It is the structure switched to the control side, It is a carry-out conveyor control apparatus in the crusher of Claim 1 characterized by the above-mentioned.
And by doing in this way, the malfunction that a carry-out conveyor starts unexpectedly as soon as the overload of a carry-out conveyor is eliminated can be avoided.
According to a third aspect of the present invention, there is provided an informing means for notifying an operator that the hydraulic motor for the carry-out conveyor is stopped by the overload carry-out conveyor stop control. The carry-out conveyor in the crusher according to the first or second aspect, It is a control device.
By doing so, it is possible to avoid problems such as the operator continuing the work without noticing the overload of the carry-out conveyor or delaying the work for eliminating the overload of the carry-out conveyor.

  Next, embodiments of the present invention will be described with reference to the drawings. In FIG. 1, reference numeral 1 denotes a self-propelled crusher. The crusher 1 has a jaw crusher and an impact crusher at a substantially central portion in the front-rear direction of a base frame 3 that is attached to and supported by a crawler type traveling body 2. A crushing device 4 made of a roll crusher or the like is placed. A hopper 5 into which an object to be crushed, such as a concrete lump, is placed is arranged on the upper rear side of the crushing device 4, and the object to be crushed in the hopper 5 is placed below the hopper 5 in the crushing device 4. A feeder 6 for supply is arranged. The feeder 6 sequentially conveys the objects to be crushed put into the hopper 5 to the crushing device 4 side, and drops a small concrete lump, earth and sand, etc. that do not require crushing downward. And the fallen object is configured to be carried out to the left and right outside of the crusher 1 by a side conveyor 7 arranged in a state of projecting left and right from the lower part of the front half side of the feeder 6.

  On the other hand, in front of the crushing device 4, a control unit 8, an engine 9, a power chamber 12 in which first and second hydraulic pumps 10 and 11, which will be described later, are housed, and the like are arranged. Moreover, in the state which the carry-out conveyor 13 for carrying out the crushing processed material crushed by the crushing apparatus 4 reaches the downward direction of the power chamber 12 from the downward direction of the crushing apparatus 4, and further protrudes toward the front upper front of the body. It is arranged. Further, 14 is a magnetic separator disposed above the middle part of the carry-out conveyor 13, and the magnetic separator 14 magnetically attaches a metal material such as a reinforcing bar contained in the concrete lump with a magnet and releases it to the outside. It is configured.

The crushing device 4, the feeder 6, the side conveyor 7, the carry-out conveyor 13, and the magnetic separator 14 are rotated by hydraulic motors 15 to 19 for the crusher, feeder, side conveyor, carry-out conveyor, and magnetic separator. FIG. 2 is a circuit diagram of a hydraulic system of the crusher 1 provided with these hydraulic motors 15 to 19. In FIG. 2, 20 is an oil tank, and 10 is a first hydraulic pump. , 11 is a second hydraulic pump, 21 is a pilot pump, and these pumps 10, 11, 21 are configured to be driven by the power of the engine 9.
Further, in the present embodiment, when the feeder 6, the side conveyor 7, the carry-out conveyor 13, and the magnetic separator 14 are collectively referred to, they are distinguished from the crushing device 4 and are referred to as work devices.
Further, the crusher 1 includes a plurality of hydraulic actuators (for example, left and right traveling hydraulic motors, in addition to the hydraulic motors 15 to 19 for the crushing device, the feeder, the side conveyor, the carry-out conveyor, and the magnetic separator). The crushing device 4 has a crushing particle size adjusting hydraulic cylinder and the like, and the first and second hydraulic pumps 10 and 11 also serve as a hydraulic supply source of these hydraulic actuators. The hydraulic actuator and the hydraulic system related to the hydraulic actuator are omitted.

  The first hydraulic pump 10 is a variable displacement hydraulic pump serving as a hydraulic supply source of the crushing device hydraulic motor 15, and the crushing device is included in the first regulator 10 a that varies the capacity of the first hydraulic pump 10. An electromagnetic proportional valve 22 is connected. The electromagnetic proportional valve 22 for the crushing device is operated by a control signal output from the control device 23 described later, and outputs a control signal pressure to the first regulator 10a. The first regulator 10 a controls the discharge flow rate of the first hydraulic pump 10 based on the control signal pressure output from the crushing device electromagnetic proportional valve 22.

  The second hydraulic pump 11 is a variable displacement hydraulic pump serving as a hydraulic supply source for the hydraulic motors 16 to 19 for feeders, side conveyors, carry-out conveyors, and magnetic separators. An electromagnetic proportional valve 24 for the work device is connected to the second regulator 11a that varies the capacity of the work 11. The work device electromagnetic proportional valve 24 is operated by a control signal output from the control device 23, and outputs a control signal pressure to the second regulator 11a. The second regulator 11 a controls the discharge flow rate of the second hydraulic pump 10 based on the control signal pressure output from the work device electromagnetic proportional valve 24.

  Further, in FIG. 2, reference numeral 25 denotes a crushing device control valve, which comprises a three-position switching valve provided with pilot ports 25a and 25b. The crushing device control valve 25 is located at a neutral position N where no pressure oil is supplied to the crushing device hydraulic motor 15 when no pilot pressure is input to the pilot ports 25a and 25b. When the pilot pressure output from the device normal rotation electromagnetic switching valve 26 is input to the pilot port 25a, the pressure oil supplied from the first hydraulic pump 10 is supplied to the normal rotation side of the crushing device hydraulic motor 15. The pressure oil supplied from the first hydraulic pump 10 is crushed by switching to the forward rotation side operation position X and inputting the pilot pressure output from the crushing device reverse electromagnetic switching valve 27 to the pilot port 25b. The operation is switched to the reverse operation position Y to be supplied to the reverse side of the hydraulic motor 15.

  The crushing device normal rotation electromagnetic switching valve 26 and the crushing device reverse rotation electromagnetic switching valve 27 are two-position switching valves connected to the pilot pump 21, and are based on a control signal output from the control device 23. The control port 25 is switched between an OFF position where pilot pressure is not supplied to the pilot ports 25a and 25b of the control valve 25 and an ON position X where pilot pressure is supplied.

  On the other hand, 29 is a control valve for a working device, and is constituted by a three-position switching valve provided with pilot ports 29a and 29b. Here, it is used as a two-position switching valve, and one pilot port 29b is an oil valve. Connected to the tank 20. The work device control valve 29 is located at a neutral position N where no pressure oil is supplied to the work device multiple control valve unit 30 described later in a state where the pilot pressure is not input to the pilot port 29a. However, when the pilot pressure output from the work device electromagnetic switching valve 31 is input to the pilot port 29a, the pressure oil supplied from the second hydraulic pump 11 is supplied to the work device multiple control valve unit 30. The operation position X is switched to.

  The working device electromagnetic switching valve 31 is a two-position switching valve connected to the pilot pump 21, and is piloted to the pilot port 29 a of the working device switching valve 29 based on a control signal output from the control device 23. The position is switched between an OFF position N where no pressure is supplied and an ON position X where the pilot pressure is supplied.

The work device multiple control valve unit 30 is a unit in which control valves 32 to 35 for feeder, side conveyor, unloading conveyor, and magnetic separator are incorporated. Is constituted by an electromagnetic proportional three-position switching valve.
The feeder control valve 32 is used as a two-position switching valve in the present embodiment, and is in a neutral position N where pressure oil is not supplied to the feeder hydraulic motor 16 by a control signal output from the control device 23 to the solenoid 32a. Then, the operation is switched to the normal rotation side operation position X for supplying pressure oil to the normal rotation side of the feeder hydraulic motor 16.
Further, the side conveyor control valve 33, the carry-out conveyor control valve 34, and the magnetic separator control valve 35 are controlled by the control signal output from the control device 23 to the solenoids 33a, 33b, 34a, 34b, 35a, 35b. From the neutral position N where pressure oil is not supplied to the hydraulic motor 17 for the conveyor, the hydraulic motor 18 for the carry-out conveyor, and the hydraulic motor 19 for the magnetic separator, the hydraulic motor 17 for the side conveyor, the hydraulic motor 18 for the carry-out conveyor, and the hydraulic motor 19 for the magnetic separator It is configured to switch to the forward rotation side operation position X for supplying the forward rotation pressure oil or the reverse rotation side operation position Y for supplying the reverse rotation pressure oil.
The opening amounts of the control valves 32 to 35 for the feeder, the side conveyor 33, the carry-out conveyor 34, and the magnetic separator for the forward rotation side operation position X or the reverse rotation side operation position Y are controlled by the control device 23 from the solenoid 32a, It is adjusted by the control signal output to 33a, 33b, 34a, 34b, 35a, 35b.

  Further, 36 is a pressure sensor for detecting the drive pressure on the forward rotation side of the carry-out conveyor hydraulic motor 18, and the pressure sensor 28 extends from the carry-out conveyor control valve 34 to the forward rotation side of the carry-out conveyor hydraulic motor 18. It is arranged in a carry-out conveyor drive oil passage 37 for supplying pressure oil.

  Reference numeral 38 denotes a relief valve disposed in the carry-out conveyor drive oil passage 37. The relief valve 38 has a drive pressure on the forward rotation side of the carry-out conveyor hydraulic motor 18 equal to or higher than a preset set pressure. In this case, the pressure oil in the carry-out conveyor drive oil passage 37 is operated to escape to the oil tank 20.

  On the other hand, the control device 23 is configured using a microcomputer or the like, and includes a CPU (Central Processing Unit), a memory, and the like. The control device 23 is shown in the block diagram of FIG. As shown, the crushing device operation switch 39, the crushing device reversing switch 40, the feeder operation switch 41, the side conveyor operating switch 42, the side conveyor reversing switch 43, the carry-out conveyor operating switch 44, and the carry-out conveyor reverse switch 45. , A magnetic separator operation switch 46, a magnetic separator reverse switch 47, an accelerator setting operation tool (accelerator dial, accelerator lever, etc.) 48, a signal from the pressure sensor 36 for detecting the drive pressure of the carry-out conveyor hydraulic motor 18 and the like. The electromagnetic proportional valve 22 for the crushing device and the electromagnetic proportional valve 24 for the working device are input based on the input signal. Electromagnetic switching valve 26 for crushing device normal rotation, electromagnetic switching valve 27 for crushing device reverse rotation, electromagnetic switching valve 31 for work device, and control valves 32 to 35 for feeder, side conveyor, carry-out conveyor, magnetic separator, It is configured to output a control signal to the notification means (notification lamp, notification sound, etc.) 49 and the like.

  Here, the operation switches 39, 41, 42, 44, and 46 for the crushing device, feeder, side conveyor, carry-out conveyor, and magnetic separator are respectively used for the crushing device, feeder, side conveyor, and carry-out conveyor. For operating and stopping the crushing device 4, the feeder 6, the side conveyor 7, the carry-out conveyor 13, and the magnetic separator 14 during the normal operation of rotating the hydraulic motors 15 to 19 for the magnetic separator to the forward rotation side. The operation switches 39, 41, 42, 44, and 46 are configured using momentary switches that output an ON signal to the control device 23 only during the push operation. And the control apparatus 23 is comprised so that ON / OFF switching of an operation switch command may be performed, when an ON signal is input from the said operation switch 39,41,42,44,46. That is, when an ON signal is input from the carry-out conveyor operation switch 44, it is switched to “ON” if the immediately preceding carry-out conveyor operation switch command is “OFF”, and to “OFF” if it is “ON”. It has become. Then, as will be described later, the control device 23 uses the crushing device, the feeder 6, the side conveyor 7, the carry-out conveyor 13, and the magnetic separator 14 to operate and stop based on the operation switch command. The rotation control and stop control of the hydraulic motors 15 to 19 for the side conveyor 7, the carry-out conveyor, and the magnetic separator are performed.

  In addition, the reversing switches 40, 43, 45, 47 for the crushing device, the side conveyor, the carry-out conveyor, and the magnetic separator are such that the crushed material is clogged or caught in the crushing device 4 or during the carrying-out. In this case, the operation switch is used to reverse the crushing device 4, the side conveyor 7, the carry-out conveyor 13, and the magnetic separator 14 in order to solve this problem.

  Further, the accelerator setting operation tool 48 is an operation tool for setting the engine speed. In the crusher 1 of the present embodiment, the crusher 1 is for crushing devices, for feeders, for side conveyors, for carry-out conveyors, In order to increase / decrease the rotational speed of each of the hydraulic motors 15-19 for the magnetic separator according to the engine speed, the rotational speed of each of the hydraulic motors 15-19 corresponding to the set value of the accelerator setting operation tool 48 is preset. Yes. That is, the accelerator setting operation tool 48 can set the rotation speeds of the hydraulic motors 15 to 19 for the crushing device, the feeder, the side conveyor, the carry-out conveyor, and the magnetic separator, In order to set the rotational speed of the hydraulic motors 15 to 19 to the speed set by the accelerator setting operation tool 48, the first and second hydraulic pressures are controlled by control signals output to the electromagnetic proportional valve 22 for the crushing device and the electromagnetic proportional valve 24 for the working device. While controlling the discharge flow volume of the pumps 10 and 11, it is comprised so that the opening amount adjustment of each control valve 32-35 for feeders, side conveyors, carry-out conveyors, and magnetic separators may be performed.

  The control device 23 controls the drive of the hydraulic motors 15 to 19 for the crushing device, the feeder, the side conveyor, the carry-out conveyor, and the magnetic separator based on the input signals from the various switches 39 to 47 described above. First, the drive control of the carry-out conveyor hydraulic motor 18 when the carry-out conveyor operation switch 44 is operated will be described with reference to the flowchart shown in FIG. It is determined whether or not the operation switch 44 has been operated, that is, whether or not an ON signal has been input from the carry-out conveyor operation switch 44 (step S1).

  When it is determined “YES” in step S1, that is, when it is determined that the carry-out conveyor operation switch 44 has been operated, the control device 23 switches ON / OFF of the carry-out conveyor switch command. In other words, when the immediately preceding unloading conveyor switch command is “OFF”, it is switched to “ON”, and when it is “ON”, it is switched to “OFF” (step S2). On the other hand, if “NO” in the determination in step S1, that is, if it is determined that the carry-out conveyor operation switch 44 is not operated, the process proceeds to determination in step S3 described later.

  After the processing in step S2, the control device 23 determines whether the carry-out conveyor switch command is “ON” or “OFF” (step S3).

  If it is determined in step S3 that the carry-out conveyor switch command is “ON”, the controller 23 continues to drive the drive pressure on the forward side of the carry-out conveyor hydraulic motor 18 detected by the pressure sensor 36. Is greater than or equal to a preset limit value (step S4). On the other hand, if it is determined in step S3 that the carry-out conveyor switch command is “OFF”, the process proceeds to step S8 described later.

The limit value is the maximum drive pressure on the forward rotation side of the carry-out conveyor hydraulic motor 18 when there is no overload. When the drive pressure of the carry-out conveyor hydraulic motor 18 exceeds the limit value, the carry-out conveyor hydraulic motor 18 Is determined to be overloaded.
The limit value is set lower than the set pressure of the relief valve 38 disposed in the carry-out conveyor drive oil passage 37 described above. Therefore, before the relief valve 38 is operated, the limit value is exceeded in the control device 23. The load is determined.

  If “NO” in the determination in step S4, that is, if the drive pressure of the carry-out conveyor hydraulic motor 18 is less than the limit value, the control device 23 determines that the carry-out conveyor hydraulic motor 18 is not overloaded, and Hydraulic motor rotation control is performed (step S5).

  In the hydraulic control of the carry-out conveyor hydraulic motor in step S5, the control device 23 outputs a control signal to the work device electromagnetic switching valve 31 so as to switch to the ON position X, and to the carry-out conveyor control valve 34. A control signal is output so as to switch to the forward rotation side operation position X. As a result, the pilot pressure is output from the work device electromagnetic switching valve 31 to the pilot port 29a of the work device control valve 29, the work device control valve 29 is switched to the operating position X, and the work device control valve 29 is switched. The discharge pressure oil of the second hydraulic pump 11 is supplied to the work device multiple control valve unit 30 via the control device (note that the control signal of the ON position X is already supplied from the control device 23 to the work device electromagnetic switching valve 31. Is output and the control signal 29 for the work device is located at the operating position X, the control signal is continued). The pressure oil supplied to the work device multiple control valve unit 30 is supplied to the carry-out conveyor hydraulic motor 18 via the carry-out conveyor control valve 34 switched to the forward rotation side operation position X. Thus, the carry-out conveyor hydraulic motor 18 rotates to the forward rotation side.

  Further, in the carry-out conveyor hydraulic motor rotation control in step S5, the control device 23 sets the rotation speed of the carry-out conveyor hydraulic motor 18 to the speed set by the accelerator setting operation tool 48, and the work device electromagnetic proportional valve 24 is used. A control signal is output to control the discharge flow rate of the second hydraulic pump 11 and the opening amount of the carry-out conveyor control valve 34 at the normal rotation side operation position X is adjusted.

Thus, if it is determined in step S4 that the carry-out conveyor hydraulic motor 18 is not overloaded, the carry-out conveyor hydraulic motor 18 is controlled by the accelerator setting operation tool in step S5. It is controlled to rotate at the speed set at 48.
Then, after the process of step S5, the process returns to the determination of step S1.

On the other hand, if the determination in step S4 is “YES”, that is, if the drive pressure of the carry-out conveyor hydraulic motor 18 is equal to or greater than the limit value, the control device 23 determines that the carry-out conveyor hydraulic motor 18 is overloaded, A control signal for operation (lighting of a notification lamp, generation of a notification sound, etc.) is output to the notification means 49 (step S6).
Thereby, the operator can know that the overload carry-out conveyor stop control described later is being executed.

  Further, if “YES” in the determination in step S4, that is, if it is determined that the drive pressure of the carry-out conveyor hydraulic motor 18 is equal to or higher than the limit value and is overloaded, the control device 23 performs a carry-out conveyor switch command. Is switched to “OFF” (step S7).

  After the process of step S7, the control device 23 performs hydraulic motor stop control for the carry-out conveyor (step S8).

  In the carry-out conveyor hydraulic motor stop control in step S8, the control device 23 outputs a control signal to the carry-out conveyor control valve 34 so as to switch to the neutral position N. As a result, the supply of pressure oil to the carry-out conveyor hydraulic motor 18 is cut off, and the carry-out conveyor hydraulic motor 18 stops.

  Further, in the hydraulic motor stop control for the carry-out conveyor in step S8, all the hydraulic motors 16, 17, and 19 for feeder, side conveyor, and magnetic separator supplied with pressure oil from the second hydraulic pump 11 are also controlled. When (the hydraulic motor stop control of these hydraulic motors 16, 17, 19 will be described later), the control device 23 switches to the OFF position N with respect to the work device electromagnetic switching valve 31. In addition, a non-actuated control signal is output to the work device electromagnetic proportional valve 24 so as not to output a control signal pressure to the second regulator 11a. As a result, the output of the pilot pressure to the work device control valve 29 is stopped, the work device control valve 29 is switched to the neutral position N, and the supply of pressure oil to the work device multiple control valve unit 30 is cut off. The discharge flow rate of the second hydraulic pump 11 is controlled to be the minimum flow rate.

Thus, when it is determined in step S4 that the carry conveyor hydraulic motor 18 is overloaded, the carry conveyor hydraulic motor 18 is stopped by the carry conveyor hydraulic motor stop control in step S8. Thus, the overload carry-out conveyor stop control according to the present invention is executed.
Then, after the process of step S8, the process returns to the determination of step S1.

Next, the drive control of the crushing device and feeder hydraulic motors 15 and 16 performed by the control device 23 when the crushing device and feeder operation switches 39 and 41 are operated is based on the flowchart shown in FIG. However, since there are many controls similar to the drive control of the carry-out conveyor hydraulic motor 18 described above, a brief description will be given. 5 is used in common for driving control of the hydraulic motors 15 and 16 for the crushing device and the feeder, but the hydraulic motors 15 and 16 are individually controlled.
First, the control device 23 determines whether or not the operation switches 39 and 41 for the crushing device and the feeder are operated (step S1).

  If “YES” is determined in the determination of step S1, that is, if it is determined that the operation switches 39 and 41 for the crushing device and the feeder are operated, the control device 23 turns ON the switch command for the crushing device and the feeder. OFF is switched (step S2). On the other hand, if the determination in step S1 is “NO”, that is, if it is determined that the operation switches 39 and 41 for the crushing device and the feeder are not operated, the process proceeds to the determination in step S3 described later.

  After the process of step S2, the control device 23 determines whether the switch command for the crushing device and the feeder is “ON” or “OFF” (step S3).

  If it is determined in step S3 that the switch command is “ON”, the control device 23 continues to determine that the drive pressure on the forward rotation side of the carry-out conveyor hydraulic motor 18 detected by the pressure sensor 36 is the same as described above. It is determined whether or not the limit value is exceeded (step S4). On the other hand, if it is determined in step S3 that the switch command is “OFF”, the process proceeds to step S7 described later.

  If “NO” in the determination in step S4, that is, if the drive pressure of the carry-out conveyor hydraulic motor 18 is less than the limit value, the control device 23 determines that the carry-out conveyor hydraulic motor 18 is not overloaded, and Then, the feeder hydraulic motor rotation control is performed (step S5).

  First, the crushing device hydraulic motor rotation control will be described. The control device 23 outputs a control signal so that the crushing device normal rotation electromagnetic switching valve 26 is switched to the ON position X. As a result, the pilot pressure is output from the crushing device normal rotation electromagnetic switching valve 26 to the pilot port 25a of the crushing device control valve 25, so that the crushing device control valve 25 is switched to the normal rotation side operating position X, The pressure hydraulic oil discharged from the first hydraulic pump 10 is supplied to the crushing device hydraulic motor 15 via the control valve 25, and thus the crushing device hydraulic motor 15 rotates to the forward rotation side.

  Furthermore, in the crushing device hydraulic motor rotation control, the control device 23 controls the crushing device electromagnetic proportional valve 22 to set the rotation speed of the crushing device hydraulic motor 15 to the speed set by the accelerator setting operation tool 48. A signal is output to control the discharge flow rate of the first hydraulic pump 10.

  Next, the feeder hydraulic motor rotation control will be described. The control device 23 outputs a control signal to the working device electromagnetic switching valve 31 so as to switch to the ON position X, and forwardly rotates with respect to the feeder control valve 32. A control signal is output so as to switch to the side operation position X. As a result, the pilot pressure is output from the work device electromagnetic switching valve 31 to the pilot port 29a of the work device control valve 29, the work device control valve 29 is switched to the operating position X, and the work device control valve 29 is switched. , The discharge hydraulic oil of the second hydraulic pump 11 is supplied to the working device multiple control valve unit 30. Then, the pressure oil supplied to the work device multiple control valve unit 30 is supplied to the feeder hydraulic motor 16 via the feeder control valve 32 switched to the forward rotation side operation position X. Then, the feeder hydraulic motor 16 rotates in the forward direction.

Further, in the feeder hydraulic motor rotation control, the control device 23 outputs a control signal to the work device electromagnetic proportional valve 24 so that the rotation speed of the feeder hydraulic motor 16 is set to the speed set by the accelerator setting operation tool 48. Thus, the discharge flow rate of the second hydraulic pump 11 is controlled, and the opening amount of the feeder control valve 32 at the forward rotation side operation position X is adjusted.
Thus, if it is determined in step S4 that the carry-out conveyor hydraulic motor 18 is not overloaded, the crushing device and feeder hydraulic motor rotation control in step S5 controls the crushing device and feeder hydraulic pressure. The motors 15 and 16 are controlled to rotate at a speed set by the accelerator setting operation tool 48.
Then, after the process of step S5, the process returns to the determination of step S1.

  On the other hand, if the determination in step S4 is “YES”, that is, if the drive pressure of the carry-out conveyor hydraulic motor 18 is equal to or greater than the limit value, the control device 23 determines that the carry-out conveyor hydraulic motor 18 is overloaded, The switch command for the crusher and feeder is switched to “OFF” (step S6).

  After the process of step S6, the control device 23 performs hydraulic motor stop control for the crushing device and the feeder (step S7).

  First, the crushing device hydraulic motor stop control will be described. The control device 23 outputs a control signal so as to switch the crushing device normal rotation electromagnetic switching valve 26 to the OFF position N. As a result, the output of the pilot pressure to the crushing device control valve 25 is stopped, the crushing device control valve 25 is switched to the neutral position N, and the pressure oil supply to the crushing device hydraulic motor 15 is cut off. Then, the hydraulic motor 15 for the crushing device stops.

  Further, in the crushing device hydraulic motor stop control, the control device 23 outputs a non-operational control signal to the crushing device electromagnetic proportional valve 22 so as not to output the control signal pressure to the first regulator 10a. Thereby, the discharge flow rate of the first hydraulic pump 10 is controlled to be the minimum flow rate.

  Next, the feeder hydraulic motor stop control will be described. The control device 23 outputs a control signal to the feeder control valve 32 so as to switch to the neutral position N. Thereby, the pressure oil supply to the feeder hydraulic motor 16 is cut off, and the feeder hydraulic motor 16 stops.

  Further, in the feeder hydraulic motor stop control, all of the hydraulic motors 16, 17, 19, 18 for the feeder, side conveyor, magnetic separator, and carry-out conveyor supplied with pressure oil from the second hydraulic pump 11 are used. When the stop control is being performed, the control device 23 outputs a control signal so as to switch the work device electromagnetic switching valve 31 to the OFF position N, and to the work device electromagnetic proportional valve 24. The non-operational control signal is output so as not to output the control signal pressure to the second regulator 11a. As a result, the output of the pilot pressure to the work device control valve 29 is stopped, the work device control valve 29 is switched to the neutral position N, and the supply of pressure oil to the work device multiple control valve unit 30 is cut off. The discharge flow rate of the second hydraulic pump 11 is controlled to be the minimum flow rate.

Thus, if it is determined in step S4 that the carry conveyor hydraulic motor 18 is overloaded, the crushing device and feeder hydraulic motor 15 is controlled by the crushing device and feeder hydraulic motor stop control in step S7. , 16 are also controlled to stop, so that the crushing device and feeder hydraulic motors 15, 16 are also stopped when the above-described overload carry-out conveyor stop control is executed. .
Then, after the process of step S7, the process returns to the determination of step S1.

  Furthermore, the control device 23 also performs rotation control and stop control of the hydraulic motors 17 and 19 for the side conveyor and the magnetic separator based on the operation of the operation switches 42 and 46 for the side conveyor and the magnetic separator. Although description of these controls is omitted, the hydraulic motors 17 and 19 for the side conveyor and the magnetic separator are configured not to stop even when the above-described carry-out conveyor stop control is performed during overload.

In the present embodiment configured as described, the carry-out conveyor 13 is driven by the rotation of the carry-out conveyor hydraulic motor 18 to carry out the crushed material, but the amount of the crushed material to be carried out is too large. If the crushed material is caught in the middle of unloading, the unloading conveyor 13 may be overloaded. In such a case, the control device 23 determines whether or not the carry-out conveyor 13 is overloaded based on the driving pressure of the carry-out conveyor hydraulic motor 18 detected by the pressure sensor 36 and is overloaded. If it is determined, the overloading carry-out conveyor stop control for stopping the carry-out conveyor 13 is performed.
As a result, a problem that the carry-out conveyor 13 continues to be driven while being in an overload state can be reliably prevented, and a conveyor belt (not shown) constituting the carry-out conveyor 13 and a hydraulic motor 18 for the carry-out conveyor are included. Can prevent damage and breakage.

  Furthermore, as described above, the overload of the carry-out conveyor 13 is determined by determining whether the drive pressure of the carry-out conveyor hydraulic motor 18 is equal to or higher than the limit value. Is set lower than the set pressure of the relief valve 38 arranged in the carry-out conveyor drive oil passage 37, and therefore, the control device 23 judges the overload before the relief valve 38 operates. Thus, it can be determined early that the carry-out conveyor 13 is overloaded.

  Further, in this case, a momentary switch that outputs an ON signal to the control device 23 only while the carry-out conveyor operation switch 44 is being pressed is used as the carry-out conveyor operation switch 44 that operates and stops the carry-out conveyor 13. The control device 23 performs rotation control-stop control of the carry-out conveyor hydraulic motor 13 based on the operation of the carry-out conveyor operation switch 44 when carrying out the overload carry-out conveyor stop control. Since the switch command is switched to “OFF”, that is, the stop control side, the carry-out conveyor 13 is stopped due to an overload, for example, when a carry-out conveyor operation switch is configured using a toggle switch. As soon as the overload was resolved because the operation switch for the carry-out conveyor was kept ON Suddenly a problem, such as carry-out conveyor 13 will start moving, it can be avoided.

  Moreover, in the present embodiment, when the overload carry-out conveyor stop control is executed, the crushing device 4 and the feeder 6 are also stopped. Can be avoided. Furthermore, since the momentary switch is used for the crushing device operation switch 39 and the feeder operation switch 41 in the same manner as the carry-out conveyor operation switch 44, the crushing device 4 is instantly released after the overload of the carry-out conveyor 13 is eliminated. It is also possible to avoid a problem that the feeder 6 moves unexpectedly.

  Further, the stop of the carry-out conveyor 13 by the overload carry-out conveyor stop control is notified to the operator by the notification means 49, so that the operator continues to supply the crushed object to the hopper 5 without noticing the stop of the carry-out conveyor 13. Or a problem that the overload elimination work of the carry-out conveyor 13 is delayed can be avoided.

It is a side view of a crusher. It is a circuit diagram which shows the hydraulic system of a crusher. It is a block diagram which shows the input / output of a control apparatus. It is a flowchart figure which shows drive control of the hydraulic motor for carry-out conveyors. It is a flowchart figure which shows drive control of the hydraulic motor for crushing apparatuses and feeders.

Explanation of symbols

DESCRIPTION OF SYMBOLS 4 Crushing device 13 Unloading conveyor 18 Unloading conveyer hydraulic motor 23 Control device 36 Pressure sensor 44 Unloading conveyor operation switch 49 Notification means

Claims (3)

  A crushing device, a carry-out conveyor for carrying out a crushed product crushed by the crushing device, a hydraulic motor for a carry-out conveyor that drives the carry-out conveyor, and a control device that performs drive control of the hydraulic motor for the carry-out conveyor In the crusher configured as described above, a pressure sensor for detecting the driving pressure of the hydraulic motor for the carry-out conveyor is provided, while the control device is configured to carry out the carry-out conveyor based on the drive pressure of the hydraulic motor for the carry-out conveyor detected by the pressure sensor. An unloading conveyor control device for a crusher, wherein the unloading conveyer stop control is performed to stop the unloading hydraulic motor when the overload is determined.   The carry-out conveyor operation switch for performing the operation-stop of the carry-out conveyor is configured using a momentary switch that outputs an ON signal to the control device only while operating the carry-out conveyor operation switch. Is a configuration for switching a switch command to the stop control side to perform rotation control / stop control of the hydraulic motor for the carry-out conveyor based on the operation of the carry-out conveyor operation switch when carrying out the carry-over conveyor stop control at the time of overload. The carry-out conveyor control apparatus in the crusher of Claim 1 characterized by the above-mentioned.   The unloading conveyor control device for a crusher according to claim 1 or 2, further comprising a notification means for notifying an operator of a stop of the unloading conveyor hydraulic motor by an unloading unloading conveyor stop control.

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