JP2013113035A - Impact prevention control method and impact prevention control device for bucket cylinder of loading shovel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an impact prevention control method and impact prevention control device of the bucket cylinder of a loading shovel for preventing the damage of a link for bucket angle detection due to the influence of sediment.SOLUTION: The impact prevention control device includes an arm angle detector 30 for detecting the arm rotary angle of an arm 12 with respect to a boom 7. A cylinder angle detector 31 for detecting the rotary angle of the bucket cylinder 20 is arranged in the neighborhood of the connection part of the bucket cylinder 20 to the boom 7. From the rotary angle of the bucket cylinder 20 detected by the cylinder angle detector 31, its increase/decrease signal, the arm rotary angle detected by the arm angle detector 30, and a signal showing an operation direction showing which of an extension direction and contraction direction is the bucket cylinder 20 being operated in, the rotary position of the loading bucket 17 is detected.

Description

  The present invention relates to an impact prevention control method and an impact prevention control device at a stroke end of a bucket cylinder of a loading shovel.

  In a loading shovel, in order to prevent an impact at the stroke end of the bucket cylinder and an impact when the loading bucket collides with a stopper provided on the arm, the bucket cylinder is immediately before the stroke end or immediately before the loading bucket collides with the stopper. Control is performed to reduce the expansion / contraction speed to prevent impact. This impact prevention control is performed in order to improve the ride comfort of the operator on the cab and to prevent adverse effects on the structure. In order to perform such impact prevention control, conventionally, as described in Patent Document 1, an angle detector (potentiometer) for detecting a bucket angle is provided on the tip side of the arm, and the arm of this angle detector is mounted. The bucket rotation link is connected to and attached by an angle detection link.

Japanese Utility Model Publication No. 61-35961

  However, since the loading excavator performs excavation by extending the bucket cylinder and rotating the bucket in the tilt direction (the direction in which the bucket front end is lifted), the angle detection link connected to the bucket rotation link is earth and sand. This angle detection link is easily damaged by contact with the surface. If the angle detection link is damaged in this way, the bucket angle cannot be detected, and the impact prevention control function of the bucket cylinder does not work, so the impact cannot be mitigated and the riding comfort becomes worse, or the impact may damage the structure. There was a problem of promoting.

  In view of the above problems, the present invention can prevent damage to a bucket angle detection link due to the influence of earth and sand, and can maintain a bucket angle detection function over a long period of time. An object is to provide an impact prevention control device.

The impact prevention control method for the bucket cylinder of the loading excavator according to claim 1 comprises:
A boom attached to the upper swing body by a boom cylinder so as to be able to move up and down, an arm attached to the tip of the boom to be rotatable, and an arm attached between the boom and the arm to rotate the arm Bucket cylinder of a loading shovel comprising a cylinder, a loading bucket rotatably attached to the tip of the arm, and a bucket cylinder provided between the boom and the loading bucket for rotating the loading bucket In the impact prevention control method of
An arm angle detector for detecting the rotation angle of the arm, and a cylinder angle detector for detecting the rotation angle of the bucket cylinder in the vicinity of the connecting portion of the bucket cylinder to the boom;
The tilt side impact prevention control start angle and the dump side impact prevention control start angle of the loading bucket are stored in correspondence with the arm rotation angle as an angle displayed by an angle detected by the cylinder angle detector. ,
Whether the loading bucket is in the tilt side or the dump side rotation position based on the signal indicating the increase / decrease of the rotation angle of the cylinder detected by the cylinder angle detector and the signal indicating the operation direction of the bucket cylinder. Detect
The cylinder rotation angle detected by the cylinder angle detector and the tilt side or the dump side after the detected rotation position reaches the tilt side or the dump side rotation position to be prepared for the start of impact prevention control. Compare the impact prevention control start angle,
When the rotation angle of the cylinder detected by the cylinder angle detector reaches the impact prevention control start angle, impact prevention control is performed to reduce the expansion speed or contraction speed of the bucket cylinder.

The impact prevention control device for the bucket cylinder of the loading shovel according to claim 2 comprises:
A boom attached to the upper swing body by a boom cylinder so as to be able to move up and down, an arm attached to the tip of the boom to be rotatable, and an arm attached between the boom and the arm to rotate the arm Bucket cylinder in a loading shovel comprising a cylinder, a loading bucket rotatably attached to the tip of the arm, and a bucket cylinder provided between the boom and the loading bucket for rotating the loading bucket In the anti-shock control device,
An arm angle detector for detecting a rotation angle of the arm;
A cylinder angle detector provided in the vicinity of the coupling portion of the bucket cylinder to the boom, and detecting a rotation angle of the bucket cylinder;
The tilting side impact prevention control start angle and the dump side impact prevention control start angle of the loading bucket are stored in correspondence with the pivoting angle of the arm as an angle displayed by the pivoting angle detected by the cylinder angle detector. Storage means to keep,
Whether the loading bucket is in the tilt side or the dump side rotation position based on the signal indicating the increase / decrease of the rotation angle of the cylinder detected by the cylinder angle detector and the signal indicating the operation direction of the bucket cylinder. Rotational position detecting means for detecting
After the detected rotation position reaches the tilt side or dump side rotation position to be prepared for the start of impact prevention control, the cylinder rotation angle detected by the cylinder angle detector and the tilt side or dump A comparison means for comparing the side impact prevention control start angle;
The bucket is configured to reduce the expansion speed or the contraction speed of the bucket cylinder when it is determined that the rotation angle of the cylinder detected by the cylinder angle detector has reached the impact prevention control start angle by the comparison means. And a pilot valve control circuit for reducing the operating pressure of the control valve of the cylinder.

  According to the present invention, the rotation position of the loading bucket is obtained from the rotation angle of the bucket cylinder, the arm rotation angle, and the operation signal of the bucket cylinder. For this reason, the bucket angle detector is connected to the front end of the arm. There is no need for side mounting, and the link connected to the bucket angle detector is prevented from being damaged by the excavated soil. For this reason, the angle detection function of the angle detector for detecting the rotation position of the bucket can be maintained over a long period of time. In addition, since the angle detection function of the angle detector can be maintained over a long period of time, the impact prevention control function at the stroke end can be maintained over a long period of time.

It is a side view which shows an example of the loading shovel to which this invention is applied. It is a side view which shows the working front of the loading shovel which is one Embodiment of the impact prevention control apparatus by this invention in the dumping state of a bucket. FIG. 3 is a side view showing a working front of the loading shovel of FIG. 2 in a bucket tilt state. It is a side view which expands and shows the loading bucket of this embodiment. It is a side view which shows the attachment structure of the cylinder angle detector of this embodiment. It is a side view explaining the rotation range of the arm of this embodiment, and the rotation range of a loading bucket with the length of a bucket cylinder. It is a graph which shows the relationship between the rotation angle of an arm, the stroke of a bucket cylinder, etc. in this embodiment. It is an electrohydraulic circuit diagram of the bucket cylinder impact prevention control device of this embodiment. It is a functional block diagram which shows an example of a structure of the apparatus of FIG. In this embodiment, it is a side view which shows the operation | movement range of a cylinder angle detector in case an arm rotation angle is a middle grade. 10 is a flowchart for explaining the operation of the apparatus of FIG. 9.

  FIG. 1 is a side view showing a loading excavator to which the present invention is applied. In FIG. 1, 1 is a crawler type lower traveling body of a construction machine, 2a is a revolving frame installed on the lower traveling body 1 via a revolving device 3, and 4 is an engine, a hydraulic power source, etc. mounted on the revolving frame 2a. The power unit 5 includes a cab mounted on the turning frame 2a. The upper swing body 2 is constituted by the swing frame 2a, the power unit 4, the cab 5, and the like.

  Reference numeral 6 denotes a working front of the loading shovel. The front 6 is connected to a boom 7 attached to the revolving frame 2a so as to be raised and lowered, and one end is connected to the revolving frame 2a with a pin 8 and the other end is connected to the boom 7 with a pin 9 A boom cylinder 10 connected to the boom 7, an arm 12 rotatably attached to the boom 7 by a pin 11, an arm cylinder 15 having one end connected to the boom 7 by a pin 13 and the other end connected to the arm 12 by a pin 14. And a loading bucket 17 rotatably attached to the tip of the arm 12 by a pin 16 and a bucket cylinder 20 having one end connected to the boom 7 by a pin 18 and the other end connected to the bucket 17 by a pin 19.

  2 and 3 are side views showing the front 6 in a dumping state and a tilting state of the bucket 17, respectively, and FIG. 4 is an enlarged view of the loading bucket. As shown in FIG. 4, the bucket 17 has a rear bucket 17a and a front bucket 17b coupled to each other by a pin 21 so as to be opened and closed. The rear bucket 17a is connected to the arm 12 and the bucket cylinder 20 by the pins 16 and 19. Is done. Reference numeral 22 denotes a hydraulic cylinder that opens and closes the front bucket 17b with respect to the rear bucket 17a. The hydraulic cylinder 22 has one end connected to the rear bucket 17a by a pin 23 on the left and right sides of the bucket 17 and the other end connected to the front bucket 17b. They are connected by pins 24 and attached. When the hydraulic cylinder 22 is extended, the space between the front bucket 17b and the rear bucket 17a is opened, and the earth and sand in the bucket 17 can be discharged.

  A dump-side stopper 27 that abuts one abutting portion 17 c of the bucket 17 at the dump-side rotation limit position of the bucket 17 is provided on the rear surface of the distal end portion of the arm 12. In addition, a tilt-side stopper 28 that abuts the other abutting portion 17 d of the bucket 17 at the tilt-side rotation limit position of the bucket 17 is provided on the front surface of the distal end portion of the arm 12.

  2 and 3, reference numeral 30 denotes an arm angle detector for detecting the arm rotation angle α, which is a known one. Reference numeral 31 denotes a cylinder angle detector that detects the rotation angle of the boom cylinder 20, and this cylinder angle detector 31 is provided in place of the conventional bucket angle detector that directly detects the angle of the bucket 17.

  FIG. 5 is a side view showing a mounting structure of the cylinder angle detector 31. The cylinder angle detector 31 is attached to the boom 7 in the vicinity of the connecting pin 18 of the cylinder angle detector 31. The angle detection arm 31 a of the cylinder angle detector 31 is connected to a bracket 20 b provided on the outer periphery of the boss 20 a of the bucket cylinder 20 by a link 32 and pins 33 and 34 that are adjustable in length. For this reason, for example, when the bucket cylinder 20 rotates as indicated by the arrow R1, the link 32 is pulled or pushed in the direction of the arrow R2, and the detected rotation angle of the cylinder angle detector 31 changes.

  FIG. 6 shows the relationship between the operating range of the bucket 17 and the lengths of the arm cylinder 15 and the bucket cylinder 20. The state indicated by the solid line of the arm 12 is the state in which the arm cylinder 15 is most contracted (arm rotation angle α = 0), and the length of the arm cylinder 15 at this time is L1. In addition, the state of the arm 12 indicated by a two-dot chain line (the arm rotation angle α is the maximum, and in this embodiment, the arm rotation angle α = 69 degrees) is the most extended arm cylinder 15. The length of the arm cylinder 15 at this time is L2.

  In FIG. 6, in the state of the arm 12 indicated by the solid line A, L3 is the length of the bucket cylinder 20 in the state where the bucket cylinder 20 is most contracted. Thus, when the bucket cylinder 20 is most contracted, the bucket 17 is in the state shown by the solid line B. At this time, the dump side contact portion 17c cannot contact the dump side stopper 27. At this time, the dump side impact prevention control of the bucket cylinder 20 is started immediately before the contraction side stroke end of the bucket cylinder 17. Further, in the state where the arm rotation angle α = 0, when the bucket cylinder 20 is extended to near the maximum stroke, the tilt side abutting portion 17d of the bucket 17 is tilted to the tilt side stopper 28 as indicated by a two-dot chain line C. Abut. The impact prevention control at this time is started immediately before the tilt side contact portion 17d of the bucket 17 contacts the tilt side stopper 28.

  In the state where the arm 12 is advanced to the arm rotation angle α = 69 degrees as indicated by a two-dot chain line D, when the bucket cylinder 20 is contracted, the length of the bucket cylinder 20 contracts to L4 ( This length is longer than the shortest length L3 of the bucket cylinder 20 and L3 <L4.), The bucket 17 is in a state indicated by a two-dot chain line, and the dump side contact portion 17c of the bucket 17 is connected to the dump side stopper 27. Abut. Therefore, the impact prevention control at this time is started immediately before the bucket 17 contacts the dump side stopper 27. On the other hand, when the bucket cylinder 20 is extended, a state indicated by a two-dot chain line F is obtained, and the tilt side contact portion 17d of the bucket 17 contacts the tilt side stopper 28 before the bucket cylinder 20 becomes the longest. Therefore, the impact prevention control at this time is started immediately before the tilt side contact portion 17d of the bucket 17 contacts the tilt side stopper 28.

  FIG. 7 is a diagram showing changes in the stroke length of the bucket cylinder 20 and the impact prevention control start point with respect to the arm rotation angle α. As shown in FIG. 7, in this embodiment, until the arm rotation angle α reaches a predetermined angle (α = 48 degrees), the bucket cylinder 20 contracts to the shortest length, and the dump side contact portion 17 c does not contact the dump stopper 27. On the other hand, in the entire rotation range of the arm 12, on the extension side of the bucket cylinder 20, the tilt side contact portion 17 d of the bucket 17 rotates to a state where it contacts the tilt side stopper 28.

  As shown in FIGS. 2 and 3, as the bucket cylinder 20 expands and contracts, the position of the pin 19 that connects the bucket cylinder 20 to the bucket 17 is an arc shape centering on the pin 16 that attaches the bucket 17 to the arm 12. The locus 29 is drawn. 2 to 4, 29 a is the position of the pin 19 when the bucket cylinder 20 is most contracted, that is, in this case, the dump side contact portion 17 c of the bucket 17 contacts the dump side stopper 27. 29b is the position of the pin 19 when the angle a of the bucket cylinder 20 with respect to the boom 7 is the smallest (the bucket cylinder rotation angle β described later is the maximum). Reference numeral 29c denotes the position of the pin 19 when the bucket cylinder 20 is most extended, that is, in this case, when the tilt side contact portion 17d of the bucket 17 contacts the tilt side stopper 28. For this reason, with the expansion and contraction of the bucket cylinder 20, the inclination angle “a” of the bucket cylinder 20 with respect to the boom 7 changes within the range indicated by the angle “b”.

  Thus, the angle a of the bucket cylinder 20 with respect to the boom 7 changes as the bucket cylinder 20 expands and contracts. However, as can be seen from the locus 29, the rotation angle of the bucket 17 (the degree of extension of the bucket cylinder 20). ) Are different, there is a position where the angle of the bucket cylinder 20 with respect to the boom 7 coincides. For this reason, even if the rotation angle of the arm 2 is known, the position of the pin 19 is in the region (dump position) between the points 29a and 29b only by the rotation angle of the bucket cylinder 20, or the point 29b. It is unclear whether it is in the region (tilt position) between the point 29c and this position needs to be detected. Therefore, in the present invention, as will be described later, it is detected whether or not the angle of the cylinder angle detector 31 is increasing, and the bucket cylinder 20 is operated in the extending direction or operated in the contracting direction. Or the rotation position of the bucket 20 is obtained.

  Further, the rotation angle of the bucket cylinder 20 also changes due to a change in the rotation angle α of the arm 12. Therefore, in the present invention, from the bucket cylinder rotation angle obtained by the cylinder angle detector 31, its increase / decrease signal, the operation direction of the bucket cylinder 20, and the arm rotation angle obtained by the arm angle detector 30. The rotation position for determining whether to prepare for the impact prevention control of the bucket 17, that is, the rotation position on the tilt side or the dump side is detected. Further, when the rotational position of the bucket 17 reaches a position where the impact prevention control should be started, the impact prevention control is started.

  FIG. 8 is an electrohydraulic circuit diagram showing the configuration of an apparatus for carrying out the impact prevention control method according to the present invention based on the detection element described above. In FIG. 8, 35 and 36 are a main hydraulic pump and a pilot hydraulic pump included in the power unit 4, respectively. Reference numeral 37 denotes a controller. The controller 37 receives the output signals of the arm angle detector 30 and the cylinder angle detector 31 and the operation signal of the operation lever 38 of the bucket cylinder 20. Reference numeral 39 denotes a reed-off valve that enables the operation of each hydraulic actuator, and reference numerals 40 and 41 denote relief valves that set the maximum discharge pressure of the main hydraulic pump 35 and the pilot hydraulic pump 36, respectively.

  Reference numeral 42 denotes a control valve for the bucket cylinder 20, and 43 and 44 are proportional solenoid valves that respectively serve as pilot valves for the control valve 42. By adjusting the current from the controller 37 to the solenoids 43 a and 44 a, an operation chamber for the control valve 42 is provided. The pilot oil pressure applied to 42a and 42b is adjusted, and the opening degree of the flow path formed in the control valve can be adjusted. 45 and 46 are relief valves that protect the device by preventing the hydraulic pressure in the secondary side pipe of the control valve 42 from becoming excessive.

  FIG. 9 is a functional block diagram showing an example of a configuration for performing impact prevention control by the controller 37 from output signals of the arm angle detector 30, the cylinder angle detector 31 and the operation lever 38. In FIG. 9, reference numerals 50 to 55 are components realized by the controller 37, and a part thereof is realized by an arithmetic device. The angle increase / decrease detection means 50 monitors the output signal of the cylinder angle detector 31 and determines whether the angle β (see FIG. 10) of the bucket cylinder 20 is in the increasing direction or the decreasing direction based on the magnitude relationship before and after the angle signal. Is detected.

  The operation direction detection means 51 determines whether the operation direction is operated on the tilt side (the expansion side of the bucket cylinder 20) or the dump side (the contraction side of the bucket cylinder 20) from the operation signal generated by the operation of the operation lever 38. It is. From the detection signal from the angle increase / decrease detection means 50 and the detection signal from the operation direction detection means 51, the rotation position detection means 52 detects that the bucket 17 is on the dump side (in FIG. It is determined whether it is on the tilt side (in FIG. 4, the position of the pin 19 is in the range of points 29b to 29c).

  For example, the operation signal of the operation lever 38 detected by the operation direction detection means 51 is to extend the bucket cylinder 20 (tilt direction), and the detection signal from the angle increase / decrease detection means 50 is the rotation angle β of the bucket cylinder 20. Is in the direction of increasing (the direction of arrow R in FIG. 2), it is determined that the bucket 17 is on the dump side. At this time, preparation for impact prevention control is unnecessary.

  On the other hand, the operation signal of the operation lever 38 detected by the operation direction detection means 51 extends the bucket cylinder 20 (tilt direction), and the detection signal from the angle increase / decrease detection means 50 decreases the inclination angle of the bucket cylinder 20. When it is the direction to go (the direction opposite to the arrow R in FIG. 2), it is determined that the bucket 17 is on the tilt side. At this time, preparation for impact prevention control is required.

  On the other hand, the operation signal of the operation lever 38 detected by the operation direction detection means 51 is for contracting the bucket cylinder 20 (dump direction), and the detection signal from the angle increase / decrease detection means 50 is the inclination angle of the bucket cylinder 20. When the direction is an increasing direction (the direction of arrow R in FIG. 2), it is determined that the bucket 17 is on the tilt side. At this time, preparation for impact prevention control is unnecessary.

  On the other hand, the operation signal of the operation lever 38 detected by the operation direction detection means 51 is for contracting the bucket cylinder 20 (dump direction), and the detection signal from the angle increase / decrease detection means 50 is used to decrease the inclination angle of the bucket cylinder 20. If it is the direction to go (the direction opposite to the arrow R in FIG. 2), it is determined that the bucket 17 is on the dump side. At this time, preparation for impact prevention control is required.

  The control start cylinder angle memory 53 receives impacts when the bucket cylinder 20 is operated in the tilt (extension) direction and the dump (contraction) direction for various arm rotation angles α detected by the arm angle detector 30. The angle βs at which the prevention control is started is stored as angle data displayed as the value of the rotation angle β of the bucket cylinder 20.

  Table 1 shows whether the end point of the control in the dumping operation and tilting operation with respect to the arm rotation angle α ends in the most contracted state or the stop contact of the hydraulic cylinder, and detects the dump side and tilt side stroke end angle. An example of the maximum angle and the impact prevention control start angle are shown for a part of the arm rotation angle. Here, the angle detected by the cylinder angle detector 31 refers to the mounting position of the cylinder angle detector 31 shown in FIG. 5, the position of the bracket 20b provided on the boss 20a of the bucket cylinder 20, the orientation of the detection arm 31a, The angle is determined by the length, the length of the link 32, and the like.

  For example, as shown in FIG. 10, when the arm rotation angle α = 40 degrees, the detection angle β of the cylinder angle detector 31 when the direction of the detection arm 31a is on the line 57 is set to 0 degrees. In this case, the detection angle of the cylinder angle detector 31 is indicated by β, and the detected maximum angle (the angle at which the pin 19 is at the position of the point 29b in FIG. 5) is 108.0 degrees, The angle β when the bucket cylinder 20 is most contracted (dump end = an angle at which the position of the pin 19 is at the position of the point 29a) is 96.4 degrees. Further, the angle β when the contact portion 17d of the bucket 17 contacts the tilt side stopper 28 (tilt end = the angle at which the pin 19 is at the position of the point 29c) is 98.9 degrees. Δβ is a change angle from the maximum angle to the dump end angle.

  Note that the arm rotation angle α that changes from the dump end state where the bucket cylinder 20 ends with the shortest length L3 to the dump end state when the bucket contact portion 17c contacts the dump side stopper 27 is the embodiment. In this case, it was 48 degrees as described above. Therefore, when the arm rotation angle α is less than 48 degrees, the control end point on the dump side is the stroke end when the bucket cylinder 20 is most contracted as shown in Table 1, and when the arm rotation angle α is 48 degrees or more, the bucket 17 The state where the dumping side contact portion 17c is in contact with the dumping side stopper 27 is the control end point. Further, the control end point on the tilt side is a state where the tilt side contact portion 17 d of the bucket 17 is in contact with the tilt side stopper 28.

  As shown in Table 1, the control start angle is an angle obtained by adding a slight angle γ to the stroke end angle, and this angle may be changed depending on the magnitude of the arm rotation angle α.

  FIG. 11 is a flowchart for explaining the operations and operations shown in FIGS. In FIG. 11, when the loading excavator is in an operating state, it is in a state of waiting for the operation of the operation lever 38 (S1). When the operation lever 38 is operated, the operation direction detecting means 51 shown in FIG. If a tilt operation is detected, the solenoid 43a of the proportional solenoid valve 43 is energized in the circuit diagram of FIG. 7, and the proportional solenoid valve 43 is switched to the left position, so that the control chamber of the control valve 42 is operated. Since the pilot pressure oil from the pilot hydraulic pump 36 is supplied to 42a and the control valve 42 is switched to the right position, the pressure oil from the main hydraulic pump 35 is supplied to the bottom chamber 20c of the bucket cylinder 20, and the bucket cylinder 20 Elongate. In such an operation of extending the bucket cylinder 20, the cylinder angle β is detected by the cylinder angle detector 31 (S4). The angle increase / decrease detecting means 50 detects whether or not the cylinder angle β is decreasing (S5).

  If the output signal of the angle increase / decrease detection means 50 indicates that the cylinder angle β is increasing based on the fact that the output signal of the operation direction detection means 51 is a tilt operation, the rotational position detection means 52 is shown in FIG. The bucket rotation position is determined to be at a position (dump position) where the position of the pin 19 is between 29a and 29b, and the process returns to step S2. On the other hand, if it indicates that the cylinder angle β is decreasing, the rotation position of the bucket in FIG. 4 is determined as a position (tilt position) where the position of the pin 19 is between 29b and 29c. Prepare for impact prevention control.

  Thus, when the bucket 17 is in the tilt position in the tilt operation, the arm rotation angle α is detected by the arm angle detector 30 (S6), and the impact prevention stored in the memory 53 in advance corresponding to the arm rotation angle α. The angle βs at which the control is to be started (= angle + γ as the control end point) is extracted, and the detected angle β of the bucket cylinder is compared with the angle βs at which the impact prevention control is to be started by the comparison means 54 (S8). If the detected angle β of the bucket cylinder does not reach the angle βs at which the impact prevention control should be started (β> βs), the process returns to step S2.

  Conversely, if the detected angle β of the bucket cylinder has reached the angle βs at which the impact prevention control should be started (β ≦ βs), the comparison means 54 sends a control signal to the pilot valve control circuit 55, and this pilot valve control circuit 55 suppresses the operation signal of the operation lever 38, reduces the current supplied to the solenoid 43a of the proportional solenoid valve 43 to lower the secondary pilot hydraulic pressure of the proportional solenoid valve 43 (S9), and the flow rate of the control valve 42 Is reduced, the extension speed of the bucket cylinder 20 is reduced, and the impact when the contact portion 17d of the bucket 17 contacts the tilt side stopper 28 is mitigated.

  When the operation lever 38 is operated to the dump side, the controller 37 energizes the solenoid 44 a of the proportional solenoid valve 44, pilot pressure oil is supplied to the operation chamber 42 b of the control valve 42, and the rod chamber 20 c of the bucket cylinder 20. Pressure oil is supplied to the bucket cylinder 20 to contract. In this case, the same control as the impact prevention control on the tilt side is performed in steps S10 to S15 in FIG.

  According to this embodiment, the rotation position of the bucket 17 is obtained from the rotation angle of the bucket cylinder 20, the arm rotation angle, and the operation signal of the bucket cylinder 20. The link 32 connected to the angle detector 31 is prevented from being damaged by excavated earth and sand. For this reason, the angle detection function of the angle detector for detecting the rotation position of the bucket can be maintained over a long period of time. In addition, since the angle detection function of the angle detector can be maintained over a long period of time, the impact prevention control function at the stroke end can be maintained over a long period of time.

  Although the present invention has been described above by the embodiment, the present invention relates to an arm link that connects the bucket cylinder 20 and the arm 12 between the bucket cylinder 20 and the bucket 17, and the bucket cylinder 20 and the bucket 17. The present invention can also be applied to a loading excavator configured to include bucket links that connect the two. In addition, when implementing this invention, not only the said embodiment but a various change and addition are possible in the range which does not deviate from the summary of this invention.

1: crawler type lower traveling body, 2a: turning frame, 3: turning device, 4: power unit, 5: cab, 6: front for work, 7: boom, 10: boom cylinder, 12: arm, 15: arm cylinder , 17: loading bucket, 17c: dump side contact portion, 17d: tilt side contact portion, 18, 19: pin, 20: bucket cylinder, 20a: boss, 20b: bracket, 21: pin, 22: hydraulic cylinder, 27: Dump side stopper, 28: Tilt side stopper, 29: Trajectory of pin 19, 30: Arm angle detector, 31: Cylinder angle detector, 31a: Angle detection arm, 32: Link, 35: Main hydraulic pump, 36 : Pilot hydraulic pump, 37: Controller, 38: Operation lever, 42: Control valve, 43, 44: Proportional solenoid valve, 43a, 44a Solenoid

Claims (2)

A boom attached to the upper swing body by a boom cylinder so as to be able to move up and down, an arm attached to the tip of the boom to be rotatable, and an arm attached between the boom and the arm to rotate the arm Bucket cylinder of a loading shovel comprising a cylinder, a loading bucket rotatably attached to the tip of the arm, and a bucket cylinder provided between the boom and the loading bucket for rotating the loading bucket In the impact prevention control method of
An arm angle detector for detecting the rotation angle of the arm, and a cylinder angle detector for detecting the rotation angle of the bucket cylinder in the vicinity of the connecting portion of the bucket cylinder to the boom;
The tilt side impact prevention control start angle and the dump side impact prevention control start angle of the loading bucket are stored in correspondence with the arm rotation angle as an angle displayed by an angle detected by the cylinder angle detector. ,
Whether the loading bucket is in the tilt side or the dump side rotation position based on the signal indicating the increase / decrease of the rotation angle of the cylinder detected by the cylinder angle detector and the signal indicating the operation direction of the bucket cylinder. Detect
The cylinder rotation angle detected by the cylinder angle detector and the tilt side or the dump side after the detected rotation position reaches the tilt side or the dump side rotation position to be prepared for the start of impact prevention control. Compare the impact prevention control start angle,
A bucket of a loading shovel, wherein impact prevention control is performed to reduce the expansion speed or contraction speed of the bucket cylinder when the cylinder rotation angle detected by the cylinder angle detector reaches the impact prevention control start angle. Cylinder impact prevention control method. A boom attached to the upper swing body by a boom cylinder so as to be able to move up and down, an arm attached to the tip of the boom to be rotatable, and an arm attached between the boom and the arm to rotate the arm Bucket cylinder of a loading shovel comprising a cylinder, a loading bucket rotatably attached to the tip of the arm, and a bucket cylinder provided between the boom and the loading bucket for rotating the loading bucket In the anti-shock control device,
An arm angle detector for detecting a rotation angle of the arm;
A cylinder angle detector provided in the vicinity of the coupling portion of the bucket cylinder to the boom, and detecting a rotation angle of the bucket cylinder;
The tilting side impact prevention control start angle and the dump side impact prevention control start angle of the loading bucket are stored in correspondence with the pivoting angle of the arm as an angle displayed by the pivoting angle detected by the cylinder angle detector. Storage means to keep,
Whether the loading bucket is in the tilt side or the dump side rotation position based on the signal indicating the increase / decrease of the rotation angle of the cylinder detected by the cylinder angle detector and the signal indicating the operation direction of the bucket cylinder. Rotational position detecting means for detecting
After the detected rotation position reaches the tilt side or dump side rotation position to be prepared for the start of impact prevention control, the cylinder rotation angle detected by the cylinder angle detector and the tilt side or dump A comparison means for comparing the side impact prevention control start angle;
The bucket is configured to reduce the expansion speed or the contraction speed of the bucket cylinder when it is determined that the rotation angle of the cylinder detected by the cylinder angle detector has reached the impact prevention control start angle by the comparison means. An impact prevention control device for a bucket cylinder of a loading excavator, comprising a pilot valve control circuit for reducing an operation pressure of a control valve of the cylinder.

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