WO2022107494A1 - Controller, boom device, and crane truck - Google Patents
Controller, boom device, and crane truck Download PDFInfo
- Publication number
- WO2022107494A1 WO2022107494A1 PCT/JP2021/037563 JP2021037563W WO2022107494A1 WO 2022107494 A1 WO2022107494 A1 WO 2022107494A1 JP 2021037563 W JP2021037563 W JP 2021037563W WO 2022107494 A1 WO2022107494 A1 WO 2022107494A1
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- WIPO (PCT)
- Prior art keywords
- boom
- wire
- length
- hook
- controller
- Prior art date
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- 238000004804 winding Methods 0.000 claims abstract description 18
- 238000000034 method Methods 0.000 claims description 89
- 230000008569 process Effects 0.000 claims description 89
- 239000010720 hydraulic oil Substances 0.000 claims description 23
- 238000001514 detection method Methods 0.000 claims description 13
- NJPPVKZQTLUDBO-UHFFFAOYSA-N novaluron Chemical compound C1=C(Cl)C(OC(F)(F)C(OC(F)(F)F)F)=CC=C1NC(=O)NC(=O)C1=C(F)C=CC=C1F NJPPVKZQTLUDBO-UHFFFAOYSA-N 0.000 claims description 9
- 238000012937 correction Methods 0.000 claims description 8
- 230000001788 irregular Effects 0.000 abstract description 3
- 230000006870 function Effects 0.000 description 45
- 239000002184 metal Substances 0.000 description 34
- 229910052751 metal Inorganic materials 0.000 description 34
- 230000004048 modification Effects 0.000 description 12
- 238000012986 modification Methods 0.000 description 12
- 238000010586 diagram Methods 0.000 description 10
- 238000012545 processing Methods 0.000 description 10
- 230000007246 mechanism Effects 0.000 description 6
- 230000008859 change Effects 0.000 description 3
- 238000004891 communication Methods 0.000 description 2
- 230000008602 contraction Effects 0.000 description 2
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- 230000007958 sleep Effects 0.000 description 1
- 239000000725 suspension Substances 0.000 description 1
Images
Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66C—CRANES; LOAD-ENGAGING ELEMENTS OR DEVICES FOR CRANES, CAPSTANS, WINCHES, OR TACKLES
- B66C13/00—Other constructional features or details
- B66C13/18—Control systems or devices
- B66C13/22—Control systems or devices for electric drives
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66C—CRANES; LOAD-ENGAGING ELEMENTS OR DEVICES FOR CRANES, CAPSTANS, WINCHES, OR TACKLES
- B66C23/00—Cranes comprising essentially a beam, boom, or triangular structure acting as a cantilever and mounted for translatory of swinging movements in vertical or horizontal planes or a combination of such movements, e.g. jib-cranes, derricks, tower cranes
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66C—CRANES; LOAD-ENGAGING ELEMENTS OR DEVICES FOR CRANES, CAPSTANS, WINCHES, OR TACKLES
- B66C23/00—Cranes comprising essentially a beam, boom, or triangular structure acting as a cantilever and mounted for translatory of swinging movements in vertical or horizontal planes or a combination of such movements, e.g. jib-cranes, derricks, tower cranes
- B66C23/06—Cranes comprising essentially a beam, boom, or triangular structure acting as a cantilever and mounted for translatory of swinging movements in vertical or horizontal planes or a combination of such movements, e.g. jib-cranes, derricks, tower cranes with jibs mounted for jibbing or luffing movements
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66C—CRANES; LOAD-ENGAGING ELEMENTS OR DEVICES FOR CRANES, CAPSTANS, WINCHES, OR TACKLES
- B66C23/00—Cranes comprising essentially a beam, boom, or triangular structure acting as a cantilever and mounted for translatory of swinging movements in vertical or horizontal planes or a combination of such movements, e.g. jib-cranes, derricks, tower cranes
- B66C23/88—Safety gear
Definitions
- the present invention relates to a mobile crane, and more particularly to a boom device mounted on the crane car and a controller for controlling the boom device.
- Crane vehicles are generally equipped with a boom device (see Patent Document 1).
- the boom device disclosed in Patent Document 1 includes a telescopic boom, a boom drive unit, a winch having a wire drum around which a wire is wound, a winch drive unit, a hanging hook provided at the tip of the wire, and a load hook. It has a hook fixing ring.
- the boom is undulatingly supported by the swivel.
- the boom drive unit expands and contracts and undulates the boom.
- the wire is pulled out from the wire drum and wound around the tip of the boom, and a hanging hook is provided at the end of the wire.
- the winch drive unit drives the winch, and the wire is wound on or unwound from the wire drum.
- the hook fixing ring is provided on the swivel base, and the hanging load hook is hung on the hook fixing ring and fixed when the crane is running (during non-working).
- the boom device disclosed in Patent Document 1 includes a control device.
- This control device controls the boom drive unit and the winch drive unit in order to safely perform the boom retracting work at the end of the work and the boom deployment work at the start of the work. For example, when retracting the boom, the operator reduces and erects the boom, and hooks the hanging load on the hook fixing ring. Next, the operator operates the boom drive device to lay down the boom. At this time, the control device controls the boom drive unit and the winch drive unit so that the wire is wound in accordance with the lodging of the boom in order to prevent the wire from loosening.
- control device is based on the wire length S detected by the sensor that detects the wire length and the undulation angle ⁇ of the boom detected by the undulation angle sensor, and these are the ideal correspondence D. That is, the drive of the winch is controlled so that the wire is not too loose and not too tight.
- This ideal correspondence relationship D is obtained by an experiment or simulation using an actual machine, and is stored in advance in the storage unit of the control device.
- a main object of the present invention is to provide a controller that controls the wire so that it is not over-tensioned and not over-slackened before the boom is automatically deployed or retracted.
- the controller according to the present invention is wound around a pedestal, a boom supported by the pedestal and capable of undulating operation between an inverted position and a predetermined standing position, and a wire drum, and wound around the tip of the boom.
- a winch having a hung wire, a hook member having a hanging hook provided on the wire, a first actuator for raising and lowering the boom, a second actuator for driving the winch, and a pedestal provided.
- the controller has the length of the boom, the first designated value according to the position of the locking member with respect to the undulating center of the boom, and the type of the hook member and the type of the locking member. It has a memory for storing the second designated value corresponding to at least one of the above in advance, and the undulation angle of the boom specified from the detection value of the undulation angle sensor, the length of the boom, the first designated value and the above. Based on the second designated value, a generation process for generating an allowable minimum distance and an allowable maximum distance from the boom tip reference position to the hook member, and a hoisting process for winding the wire to the allowable minimum distance. The feeding process of feeding out the wire by the target value corresponding to the difference between the allowable minimum distance and the allowable maximum distance is executed.
- the wire is wound up to the allowable minimum distance before the boom is automatically deployed or retracted, depending on the difference between the allowable minimum distance and the allowable maximum distance.
- the wire is unwound by the target value. Therefore, prior to the automatic expansion or storage, the state of the wire is set so as not to be too tight and not too loose.
- the allowable minimum distance is the distance from the tip of the boom to the hook member in the posture in which the wire is stretched and the hook member is raised, and the allowable maximum distance is the distance when the hook member sleeps. It may be the distance from the tip of the boom to the hook member in the vertical posture.
- the allowable minimum distance is defined when the hook member is in a posture caused by the tension generated in the wire by the hoisting process, and the hook member lays down when the wire is unwound by the feeding process.
- the maximum allowable distance is defined when the posture is reached. Therefore, prior to the automatic deployment or storage, the hook member will change its posture between the raised posture and the sleeping posture, and the wire will surely not be over-tensioned and not too loose. Will be done.
- the boom device further includes a hydraulic pressure supply device that supplies hydraulic oil to the second actuator, and the hydraulic pressure supply device is a relief that reduces the hydraulic oil supplied to the second actuator to less than a predetermined pressure. It may have a relief circuit with a valve. In this case, after the switching process for switching the flow path to the relief circuit is executed, the hoisting process is executed.
- the second designated value may be a value corresponding to the sum of the length of the hook member and the length of the locking member.
- the driving process for driving the first actuator and the second actuator is further performed so that the feeding length of the wire specified from the detection value of the wire sensor maintains the target value. It may be executed.
- the state of the wire is maintained so that it is not too tight and not too loose. That is, the posture of the hook member is maintained so as to be a posture between the raised posture and the sleeping posture. Therefore, in the automatic deployment and storage of the boom, damage to the locking member and occurrence of random winding are surely prevented.
- the acquisition process for acquiring the number of wire hooks and the correction process for correcting the target value based on the number of wire hooks may be further executed.
- the acquisition process and the correction process are executed so that the wire is not over-tensioned and not too loose even if a hook member whose number of wire hooks can be changed is used.
- the boom device includes the controller, the pedestal, the boom, the winch, the hook member, the first actuator, the second actuator, the locking member, the undulation angle sensor, and the undulation angle sensor. It is equipped with a wire sensor.
- the present invention can also be regarded as a boom device.
- the crane vehicle according to the present invention is equipped with the above boom device.
- the present invention can also be regarded as a mobile crane.
- the controller according to the present invention can set the posture of the hook member to an appropriate posture before the boom is automatically deployed or retracted so that the wire is not over-tensioned and not too loose.
- FIG. 1 is a schematic view of a mobile crane 10 according to an embodiment of the present invention.
- FIG. 2 is a schematic view of the mobile crane 10 (boom 32 is in a fully upright posture).
- FIG. 3 is a diagram schematically showing the pulley mechanism 60 of the mobile crane 10.
- FIG. 4 is a diagram schematically showing the structure of the pulley mechanism 60.
- FIG. 5 is a functional block diagram of the mobile crane 10.
- FIG. 6 is a flowchart of the boom deployment process of the mobile crane 10.
- FIG. 7 is a flowchart of the boom retracting process of the mobile crane 10.
- FIG. 8 is a diagram illustrating a function X1 ( ⁇ ) indicating the theoretical extension length of the wire 42.
- FIG. 9 is a diagram illustrating a function X2 ( ⁇ ) indicating the theoretical extension length of the wire 42.
- FIG. 10 is a diagram showing a state in which the hook block 62 is in the intermediate posture.
- FIG. 11 is a diagram illustrating a function X1 ( ⁇ ) according to a modification 1 of the embodiment of the present invention.
- FIG. 12 is an explanatory diagram illustrating a function X2 ( ⁇ ) showing the theoretical extension length of the wire 42 according to the first modification.
- FIG. 13 is a schematic side view of the mobile crane 10 in the modified example 2.
- FIG. 14 is a diagram illustrating a function Y1 ( ⁇ ) indicating the theoretical extension length of the sub wire 89 in the modification 2.
- FIG. 15 is a diagram illustrating a function Y2 ( ⁇ ) indicating the theoretical extension length of the subwire 89 in the modification 2.
- the present embodiment is only one aspect of the present invention, and the embodiments may be changed without changing the gist of the present invention.
- the execution order of each process described later can be appropriately changed without changing the gist of the present invention.
- a part of the processing described later can be omitted as appropriate without changing the gist of the present invention.
- FIG. 1 schematically shows the crane vehicle 10 according to the present embodiment, and shows a state in which the boom 32 is in the inverted position.
- the crane vehicle 10 mainly includes a traveling body 11, a boom device 12 mounted on the traveling body 11, and a cabin 13.
- the traveling body 11 includes a vehicle body 20, an engine 22 mounted on the vehicle body 20, and a battery 23.
- the engine 22 rotationally drives the axles 98 and 99 via a transmission (not shown) or the like.
- the engine 22 drives a hydraulic pump (not shown) included in the hydraulic pressure supply device 24 (see FIG. 5), and the hydraulic pressure supply device 24 generates hydraulic pressure to drive the boom device 12 and the like.
- the cabin 13 is mounted on the swivel table 31 of the boom device 12.
- the cabin 13 has a driving device 14 (see FIG. 5) for operating the mobile crane 10 and a steering device 15 (see FIG. 5) for manipulating the boom device 12. That is, the crane vehicle 10 is a so-called rough terrain crane, and the crane vehicle 10 is operated and the boom device 12 is operated in one cabin 13.
- the mobile crane 10 may be a so-called all-terrain crane.
- the boom device 12 includes a swivel table 31, a boom 32, and a hydraulic pressure supply device 24 (see FIG. 5).
- the swivel table 31 is supported by the vehicle body 20 so as to be swivelable.
- the swivel table 31 corresponds to the "pedestal" described in the claims.
- the boom 32 has a proximal boom 33, a single or plurality of intermediate booms 34, and a tip boom 35.
- the proximal boom 33, the intermediate boom 34, and the distal boom 35 are arranged in a nested manner, which constitute a telescopic.
- the boom device 12 further includes a swivel motor 25, an undulating cylinder 36 for undulating the boom 32, and a telescopic cylinder 37 for expanding and contracting the boom 32.
- the swivel motor 25 is provided on the vehicle body 20 (see FIG. 1).
- the swivel motor 25 receives hydraulic pressure from the hydraulic pressure supply device 24 and rotates to swivel the swivel table 31.
- the undulating cylinder 36 is provided on the swivel table 31.
- the undulating cylinder 36 expands and contracts by receiving hydraulic pressure from the hydraulic pressure supply device 24.
- the undulating cylinder 36 that expands and contracts undulates the boom 32.
- the undulating cylinder 36 corresponds to the "first actuator" described in the claims.
- the telescopic cylinder 37 is provided on the boom 32.
- the telescopic cylinder 37 expands and contracts by receiving hydraulic pressure from the hydraulic pressure supply device 24.
- the telescopic cylinder 37 that expands and contracts expands and contracts the boom 32.
- the boom device 12 further includes a first hydraulic motor 38, a main winch 39, a pulley mechanism 60 (see FIG. 3), and a hanging bracket 41 (see FIG. 1).
- the main winch 39 corresponds to the "winch" described in the claims.
- the main winch 39 is attached to the base end of the boom 32.
- the main winch 39 has a wire drum 44, a winch sheave 43, and a wire 42.
- the wire 42 is wound around the wire drum 44.
- the winch sheave 43 is located above the base end of the boom 32 in a state where the boom 32 is in a horizontal lying position.
- the wire 42 drawn from the wire drum 44 is wound around the winch sheave 43 and then pulled out to the pulley mechanism 60 (see FIG. 3).
- the first hydraulic motor 38 rotates by receiving the supply of hydraulic pressure from the hydraulic pressure supply device 24.
- the rotating first hydraulic motor 38 rotates the wire drum 44.
- the rotating wire drum 44 winds up the wire 42 (winding up) or unwinds the wire 42 (winding down).
- the first hydraulic motor 38 corresponds to the "second actuator" described in the claims.
- the pulley mechanism 60 has a fixed sheave block 61 and a hook block 62.
- the fixed sheave block 61 has one first sheave 63 and three second sheaves 64, 65, 66.
- the first sheave 63 is rotatably supported by a central axis (not shown).
- the second sheaves 64, 65, 66 are supported by a central axis 58 (see FIG. 4).
- the second sheaves 64, 65, 66 have a disk shape and can rotate around the central axis 58.
- the hook block 62 has a frame 45, a hanging hook 40 attached to the frame 45, and three third sheaves 68, 69, 70.
- the third sheaves 68, 69, and 70 are supported by a central axis 59 held by the frame 45, and are arranged side by side in the horizontal direction (width direction of the boom 32).
- the third sheaves 68, 69, and 70 have a disk shape and can rotate around the central axis 59.
- the hook block 62 may have two third sheaves or may have four or more third sheaves.
- the hook block 62 corresponds to the "hook member" described in the claims.
- the hydraulic pressure supply device 24 includes an electromagnetic flow path switching valve (not shown). This flow path switching valve is operated by a drive signal input from the controller 50 described later. By operating the flow path switching valve and changing the hydraulic pressure supply line, the swivel motor 25 and the like are driven. That is, the controller 50 controls the drive of the swivel motor 25 and the like by outputting the drive signal.
- the boom device 12 further includes a boom length sensor 26, an undulation angle sensor 27, and a wire sensor 28.
- the boom length sensor 26 is a sensor that outputs a detection value according to the length of the boom 32.
- the boom length sensor 26 may be a sensor that directly detects the length of the boom 32, or may be a sensor that detects the extension length of the telescopic cylinder 37. That is, the boom length sensor 26 may be a sensor that detects a physical quantity that changes according to the length of the boom 32.
- the undulation angle sensor 27 is a sensor that outputs a detection value according to the undulation angle of the boom 32.
- the undulation angle sensor 27 may be a sensor that directly detects the undulation angle of the boom 32, or may be a sensor that detects the extension length of the undulation cylinder 36. That is, the undulation angle sensor 27 may be a sensor that detects a physical quantity that changes according to the undulation angle of the boom 32.
- the undulation angle sensor 27 is, for example, a tilt sensor or a horizontal sensor that is attached to the boom 32 and outputs an angle with respect to a horizontal plane.
- the wire sensor 28 is, for example, a rotary encoder that detects the amount of rotation of the wire drum 44 (see FIGS. 1 and 2).
- the wire sensor 28 outputs a pulse signal whose voltage value changes according to the rotation of the wire drum 44.
- the wire sensor 28 is connected to the controller 50 by a signal line such as a cable.
- the controller 50 calculates the rotation amount of the wire drum 44 from the number of pulses input from the wire sensor 28, and calculates the feeding length of the wire 42 based on the rotation amount of the wire drum 44 and the radius of the wire drum 44.
- the radius of the wire drum 44 is stored in advance in the memory 52 described later. Any kind of sensor may be used for the wire sensor 28 as long as the controller 50 can acquire the feeding length of the wire 42.
- the CPU 51, the memory 52, the boom length sensor 26, the undulation angle sensor 27, and the wire sensor 28 are connected to a communication bus (not shown) included in the controller 50.
- the control program 54 executed by the CPU 51 reads information and data from the memory 52 or stores the information and data in the memory 52 through the communication bus, and the boom length sensor 26, the undulation angle sensor 27, and the wire sensor 28 are used. Acquire the output detection value.
- the boom length L is, for example, the length of the boom 32 when the boom 32 is fully reduced, and is the length from the base end to the tip end of the boom 32.
- the base end of the boom 32 is the position of the undulating center P (see FIG. 8) of the boom 32.
- the tip of the boom is, for example, the position of the central axis of the second sheaves 64, 65, 66 (see FIG. 1) around which the wire 42 is laid.
- the first designated values A and B indicate the coordinates of the point Q shown in FIG. That is, the coordinates of the point Q are (A, B).
- the point Q indicates the position of one end of the hanging bracket 41 in the two-dimensional coordinate system with the undulation center P as the origin.
- the two-dimensional coordinate system is a coordinate system in which the front-rear direction of the crane wheel 10 is the x-axis direction and the vertical direction is the y-axis direction.
- the predetermined standing angle ⁇ is the undulating angle of the boom 32 at the predetermined standing position where the tip of the boom 32 is located directly above the hanging bracket 41.
- the predetermined standing angle ⁇ is used in the boom deployment process (see FIG. 6) to determine whether or not the boom 32 has stood up to a predetermined standing position where the hanging load hook 40 can be safely removed from the hook 41.
- the control program 54 has, for example, a class. That is, the class is stored in the memory 52.
- a class creates an instance (object). Specifically, the class is given the boom length L stored in the memory 52, the first designated value (A, B), and the second designated value K, and as an instance, the function X1 shown in FIG. 8 ( ⁇ ), d / dt ⁇ X1 ( ⁇ ) ⁇ obtained by differentiating the function X1 ( ⁇ ) with respect to time t, the function X2 ( ⁇ ) shown in FIG. 9, and d / dt differentiated with respect to the function X2 ( ⁇ ) with respect to time t. Generate dt ⁇ X2 ( ⁇ ) ⁇ .
- the control program 54 differentiates the generated functions X1 ( ⁇ ) and X2 ( ⁇ ) with respect to time t to generate d / dt ⁇ X1 ( ⁇ ) ⁇ and d / dt ⁇ X2 ( ⁇ ) ⁇ . May be good. Further, the above class is an arithmetic expression that generates X1 ( ⁇ ) and X2 ( ⁇ ) by inputting a boom length L, a first designated value (A, B), and a second designated value K into an input field. There may be.
- the function X1 ( ⁇ ) indicates the theoretical extension length of the wire 42 in a state where the hook block 62 and the hook 41 are aligned in a straight line, as shown in FIG.
- the function X1 ( ⁇ ) indicates the theoretical extension length of the wire 42 when the undulation angle of the boom 32 is ⁇ .
- the function X1 ( ⁇ ) is expressed using A, B, L, K, and ⁇ with ⁇ as a variable and A, B, L, and K as constants.
- the coordinates of the point S indicating the position of the tip of the boom 32 are expressed as (Lcos ⁇ , Lsin ⁇ ).
- the coordinates of the point R indicating the connection position between the wire 42 and the hanging hook 40, that is, the coordinates of the central axis 59 can be expressed as (A + K, B).
- the function X2 ( ⁇ ) is the distance SR between the points S and R, and is represented using A, B, L, K, and ⁇ , as shown in FIG.
- the point R indicates the opposite end of the frame 45 of the hook block 62 on the side where the hanging hook 40 is provided.
- the function X1 ( ⁇ ) corresponds to the “minimum allowable distance” described in the claims.
- the function X2 ( ⁇ ) corresponds to the “maximum allowable distance” described in the claims.
- the control program 54 automatically erects the boom 32 in the laid-down position (see FIG. 1) to the predetermined standing position (see FIG. 2), and automatically lays down the boom 32 in the predetermined standing position to the laid-down position.
- the process executed by the control program 54 is also a process executed by the controller 50.
- the control program 54 executes the boom deployment process. That is, the boom deployment process is executed for the mobile crane 10 to start the work at the work site. Conventionally, this process was manually performed by the operator using the control device 15, but in the present embodiment, the control program 54 automatically performs the work of deploying the boom 32 to a predetermined standing position.
- control program 54 displays an error and booms when the length of the boom 32 detected by the boom length sensor 26 is not “L” stored in the memory 52. You may cancel the execution of the expansion process. This makes it possible to prevent the boom expansion process from being executed in a state where the boom 32 is not reduced.
- the control program 54 switches the flow path of the hydraulic oil from the normal circuit to the first relief circuit 91 via the relief valve 92, and makes the hydraulic pressure supplied to the first hydraulic motor 38 less than a predetermined pressure (S16).
- a predetermined pressure S16
- the tension generated in the wire 42 to be wound becomes smaller, and the hanging metal fitting 41 is moved in the next step S17. It is prevented from being damaged.
- the control program 54 drives the main winch 39 via the first hydraulic motor 38 and winds up the wire 42 (S17).
- the wire 42 is wound up, the hook block 62 is in the posture caused by the wire 42 (see FIG. 8).
- the process of step S16 corresponds to the "switching process” described in the claims.
- the process of step S17 corresponds to the "winding process” described in the claims.
- a tension sensor for detecting the tension applied to the wire 42 is provided, and the control program 54 is based on the fact that the tension detected by the tension sensor reaches a predetermined tension stored in advance in the memory 52. The drive of the winch 39 is stopped.
- the control program 54 drives the main winch 39 via the first hydraulic motor 38, and pays out the wire 42 by the target value determined in step S15 (S19). Specifically, the control program 54 drives the main winch 39, counts the pulse signal output by the wire sensor 28, and is based on the fact that the payout length of the wire 42 indicated by the count value reaches the above target value. Then, the drive of the main winch 39 is stopped.
- the process of step S19 corresponds to the "delivery process" described in the claims.
- the hook block 62 becomes an intermediate posture (see FIG. 10) between the raised posture and the sleeping posture.
- the winding allowance of the wire 42 can be obtained until the hook metal fitting 41 is damaged by the tension generated in the wire 42, and the maneuvering allowance can be obtained until the wire 42 is loosened and irregular winding occurs.
- the random winding means a state in which the wire 42 is irregularly wound around the wire drum 44.
- the control program 54 switches the flow path of the hydraulic oil from the first relief circuit 91 to the normal circuit via the relief valve 92, and sets the hydraulic pressure supplied to the first hydraulic motor 38 to a predetermined pressure (S20).
- the control program 54 generates dX1 ( ⁇ ) / dt and dX2 ( ⁇ ) / dt using the undulation angle ⁇ acquired in step S13 and L, A, B, K, and F read from the memory 52 in step S12. (S21).
- the control program 54 is J ⁇ ⁇ dX obtained by multiplying ⁇ dX ( ⁇ ) / dt + dX2 ( ⁇ ) / dt ⁇ / 2, which is the average value of dX1 ( ⁇ ) / dt and dX2 ( ⁇ ) / dt, by the correction coefficient J. ( ⁇ ) / dt + dX2 ( ⁇ ) / dt ⁇ / 2 is calculated (S22). That is, the control program 54 calculates the feeding speed of the wire 42 in which the hook block 62 maintains the intermediate posture.
- the control program 54 determines that the feed length W is J ⁇ X1 ( ⁇ ) or more and J ⁇ X2 ( ⁇ ) or less (S26: Yes)
- the undulation angle ⁇ acquired in step S13 is stored in the memory 52. It is determined whether or not the predetermined standing angle ⁇ has been reached (S28).
- the control program 54 determines that the undulation angle ⁇ has not reached the predetermined standing angle ⁇ (S28: No)
- the control program 54 executes the processes of steps S131, S141, S211 and S221.
- the processing of steps S131, S141, S211 and S221 is the same as the processing of steps S13, S14, S21 and S22.
- the control program 54 acquires the undulation angle ⁇ again and obtains the function X1 ( ⁇ ), the function X2 ( ⁇ ), dX ( ⁇ ) /. dt, dX2 ( ⁇ ) / dt, J ⁇ ⁇ dX1 ( ⁇ ) / dt + dX2 ( ⁇ ) / dt ⁇ / 2 are generated or calculated.
- the control program 54 repeatedly executes a series of processes of steps S131, S141, S211 and S221 at regular time intervals of, for example, several msec to several tens of msec until the boom 32 reaches a predetermined standing position.
- control program 54 determines that the undulation angle ⁇ has reached the predetermined standing angle ⁇ (S28: Yes)
- the control program 54 stops driving the boom 32 and the main winch 39 via the undulation cylinder 36 and the first hydraulic motor 38 (S29). ), End the boom deployment process.
- the control program 54 executes the processes from steps S11 to S22 described in the boom expansion process. Next, the control program 54 reduces the undulating cylinder 36 at a predetermined speed and causes the boom 32 to lie down at a constant angular velocity F (S31).
- the control program 54 executes the processes of steps S25, S26, and S27.
- step S26 determines in step S26 that the feed length W is J ⁇ X1 ( ⁇ ) or more and J ⁇ X2 ( ⁇ ) or less (S26: Yes)
- the undulation angle ⁇ acquired in step S13 becomes zero. It is determined whether or not it has been reached (S33). That is, the control program 54 determines whether or not the boom 32 has been tilted to the retracted position.
- the control program 54 determines that the undulation angle ⁇ has not reached zero (S33: No)
- the control program 54 executes the processes of steps S131, S141, S211 and S221.
- steps S131, S141, S211 and S221 is the same as the processing of steps S13, S14, S21 and S22. That is, when the boom 32 has not reached the storage position (S33: No), the control program 54 acquires the undulation angle ⁇ again and obtains the function X1 ( ⁇ ), the function X2 ( ⁇ ), and dX ( ⁇ ) / dt. , DX2 ( ⁇ ) / dt, J ⁇ ⁇ dX1 ( ⁇ ) / dt + dX2 ( ⁇ ) / dt ⁇ / 2 is generated or calculated. The control program 54 repeatedly executes a series of processes of steps S131, S141, S211 and S221 at time intervals of, for example, several msec to several tens of msec until the boom 32 reaches the storage position.
- control program 54 determines that the undulation angle ⁇ has reached zero (S33: Yes)
- the control program 54 stops driving the boom 32 and the main winch 39 through the undulation cylinder 36 and the first hydraulic motor 38 (S29), and performs the boom retracting process. To finish.
- the pressure of the hydraulic oil supplied to the first hydraulic motor 38 is set to less than the predetermined value pressure by the process (switching process) of step S16. Therefore, it is possible to prevent the hanging metal fitting 41 from being damaged in the process (winding process) of step S17.
- the wire 42 is unwound (S24) or wound (S32) so that the hook block 62 maintains the above intermediate posture. Therefore, in the automatic deployment and automatic storage of the boom 32, it is possible to surely prevent the hanging metal fitting 41 from being damaged or irregularly wound.
- the boom device 12 includes the second hydraulic motor 81 shown in FIG. 5, the sub winch 82, and the sub wire sensor 80, and the sheaves 85 and 86 shown in FIG. 13, the sub hook member 71, and the hook metal fitting 88. Further prepare. In FIG. 13, the main winch 39, the winch sheave 43, the wire 42, the hook block 62, and the hanging metal fitting 41 are not shown.
- the second hydraulic motor 81 rotates by receiving the supply of hydraulic pressure from the hydraulic pressure supply device 24.
- the second hydraulic motor 81 corresponds to the "second actuator" described in the claims.
- the sub-hook member 71 has a sub-hook main body 72 and a sub-hook 73.
- the sub hook 73 is connected to the sub hook main body 72 and is hung on the hanging metal fitting 88.
- the sub hook member 71 does not have a wire sheave. That is, the number of wires of the sub wire 89 is always "1".
- the sub-hook member 71 corresponds to the "hook member” described in the claims.
- the sub-hook 73 corresponds to the "hanging hook” described in the claims.
- the pressure of the hydraulic oil supplied is set to a predetermined pressure.
- a second relief circuit 93 for relieving the hydraulic oil is provided in order to reduce the amount to less than.
- the second relief circuit 93 has a relief valve 94.
- the relief valve 94 switches the flow path between the normal circuit and the second relief circuit 93 by a drive signal input from the controller 50. That is, the controller 50 can change the pressure of the hydraulic oil supplied to the second hydraulic motor 81 by inputting the drive signal to the relief valve 94.
- the first relief circuit 91 reduces the pressure of the hydraulic oil supplied to the second hydraulic motor 81 in addition to the first hydraulic motor 38 to less than a predetermined pressure
- the second relief circuit 93 may not be provided. good.
- the memory 52 further stores ⁇ and ⁇ indicating the coordinates of the point Q'at one end of the hanging metal fitting 88 as the first designated value.
- the memory 52 further stores the length ⁇ corresponding to the length of the hanging metal fitting 88 and the length of the sub-hook member 71 as the second designated value.
- the coordinates of the point N indicating the position of the sheave 86 when the undulation angle of the boom 32 is ⁇ are It can be expressed as (Mcos ⁇ , Msin ⁇ ).
- the function Y1 ( ⁇ ) which is the theoretical extension length of the subwire 89 in the posture in which the subwire 89 is triggered, is a value obtained by subtracting ⁇ from the distance between the point N and the point Q'. Therefore, the function Y1 ( ⁇ ) can be expressed using the length M of the boom 32, the first designated values ⁇ , ⁇ , and the second designated value ⁇ .
- the control program 54 has a class that generates a function Y1 ( ⁇ ), a function Y2 ( ⁇ ), dY1 ( ⁇ ) / dt, and dY2 ( ⁇ ) / dt.
- the control program 54 has a class that generates a function Y1 ( ⁇ ) and a function Y2 ( ⁇ ), and differentiates the function Y1 ( ⁇ ) and the function Y2 ( ⁇ ) with respect to time t to dY1 ( ⁇ ) / dt. And dY2 ( ⁇ ) / dt may be generated.
- step S16 the control program 54 switches the flow path of the hydraulic oil from the normal circuit to the second relief circuit 93, and the pressure of the hydraulic oil supplied to the second hydraulic motor 81 is set to be less than a predetermined pressure.
- the control program 54 drives the sub winch 82 via the second hydraulic motor 81 so that the sub wire 89 is paid out by the target value in steps S17 and S18. That is, the control program 54 puts the sub-hook member 71 in the intermediate posture in the same manner as the hook block 62.
- step S20 the control program 54 switches the flow path of the hydraulic oil from the first relief circuit 91 and the second relief circuit 93 to the normal circuit.
- the control program 54 further generates dY1 ( ⁇ ) / dt and dY2 ( ⁇ ) / dt in step S21.
- the control program 54 further calculates ⁇ dY1 ( ⁇ ) / dt + dY2 ( ⁇ ) / dt ⁇ / 2 in step S22, and in step S24, the subwire 89 is ⁇ dY1 ( ⁇ ) / dt + dY2 ( ⁇ ) / dt ⁇ / 2.
- the sub-wire drum 83 is rotated at the rotation speed at which the sub-wire drum 83 is fed. That is, the control program 54 drives the sub winch 82 so that the sub hook member 71 maintains the intermediate posture.
- the control program 54 further acquires the feeding length I of the sub wire 89 detected by the sub wire sensor 80 in step S25.
- the control program 54 further determines in step S26 whether or not the acquired payout length I is Y1 ( ⁇ ) or more and Y2 ( ⁇ ) or less.
- the control program 54 determines that Y1 ( ⁇ ) ⁇ I ⁇ Y2 ( ⁇ ) is not (S26: No)
- the control program 54 executes the stop process (S27) and determines that Y1 ( ⁇ ) ⁇ I ⁇ Y2 ( ⁇ ). Then (S26: Yes), the processes after step S28 are executed.
- the mobile crane 10 may have a sub-hook member 71 together with the hook block 62, or may have a sub-hook member 71 instead of the hook block 62.
- the controller 50 controls the drive of the undulating cylinder 36 and the first hydraulic motor 38 so that the feeding length of the wire 42 becomes a target value, and automatically deploys and retracts the boom 32.
- the controller 50 may automatically deploy and retract the boom 32 by other controls. That is, for the processes after step S21, processes other than the processes described in the embodiment may be executed.
- the controller 50 may control the drive of the undulating cylinder 36 and the first hydraulic motor 38 at a predetermined expansion / contraction speed and rotation speed stored in advance in the memory 52 to automatically deploy and retract the boom 32.
- the coordinates of the point S are represented by (Lcos ⁇ , Lsin ⁇ ) using the length L of the boom 32 and the undulation angle ⁇ .
- the function X1 ( ⁇ ) and the function X2 ( ⁇ ) may be generated with the center of the first sheave 63 as (Lcos ⁇ , Lsin ⁇ ) and the coordinates of the point S as (Lcos ⁇ + G1, Lsin ⁇ + G2).
- G1 and “G2" are differences between the center of the first sheave 63 and the center of the second sheave 65, and are stored in advance in the memory 52 as constants.
- the undulating cylinder 36 is expanded and contracted at a predetermined speed so that the boom 32 undulates at a constant angular velocity F.
- the undulating cylinder 36 may be expanded and contracted at a constant speed.
- the angular velocity (d ⁇ / dt) of the boom 32 is calculated from the expansion / contraction speed of the undulating cylinder 36, and the calculated angular velocity is used in place of the above angular velocity F (constant), and dX1 ( ⁇ ) / dt or dX2 ( ⁇ ) / dt is generated or calculated.
- a value corresponding to the average value of the allowable minimum distance X1 ( ⁇ ) and the allowable maximum distance X2 ( ⁇ ) is calculated as the target value.
- the value closer to the X1 ( ⁇ ) side, which is the allowable minimum distance may be set as the target value, or the value closer to the X2 ( ⁇ ) side, which is the allowable maximum distance, may be set as the target value.
- J ⁇ ⁇ X1 ( ⁇ ) + X2 ( ⁇ ) ⁇ ⁇ 2/3 or J ⁇ ⁇ X1 ( ⁇ ) + X2 ( ⁇ ) ⁇ ⁇ 1/3 may be set as the target value.
- the first designated values A and B indicating the coordinates of the point Q are stored in the memory 52.
- the function X1 ( ⁇ ) and the function X2 ( ⁇ ) can be generated, other values may be stored in the memory 52 as the first designated values instead of the first designated values A and B.
- the distance from the point P to the point Q, which is the origin, and a predetermined angle may be stored in the memory 52.
- the predetermined angle is, for example, an angle (depression angle) formed by the straight line PQ with the horizontal plane.
- the hanging metal fitting 41 is rotatably provided on the swivel base 31.
- the hanging metal fitting 41 may be fixed to the swivel base 31.
- the position of the other end of the hanging metal fitting 41 is the point Q
- the second designated value K is the length of the hook block 62. Therefore, even when the hanging metal fitting 41 is fixed to the swivel base 31, the controller 50 can prevent the hanging metal fitting 41 from being damaged or the wire 42 from being randomly wound in the boom expansion process and the boom retracting process. can.
- the hanging metal fitting 41 may be provided in a vehicle body 20, a cabin 13, or the like other than the swivel table 31.
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Abstract
[Problem] To provide a controller making it possible to prevent the occurrence of irregular winding and damage to a latch fitting in automatic deployment and automatic stowing of a boom. [Solution] This controller uses the length L of a boom, an A and B (first designated values) indicating coordinates of a latch fitting, and a length K (second designated value) that is the sum of the length of a hook block and the length of a latch fitting as well as a derricking angle θ of the boom to generate a theoretical wire feed length X1(θ) at an orientation where the hook block is hoisted up and a theoretical wire feed length X2(θ) at an orientation where the hook block is put down (S14). After the wire is wound up and stretched, the controller feeds out wire commensurate with a target value that is the mean value of X1(θ) and X2(θ) (S19), and brings the hook block to an intermediate orientation between the hoisted-up orientation and the put-down orientation. The controller derricks the boom and drives a winch so as to maintain the intermediate orientation.
Description
この発明は、クレーン車に関し、詳細には、クレーン車に装備されるブーム装置及びブーム装置を制御するコントローラに関するものである。
The present invention relates to a mobile crane, and more particularly to a boom device mounted on the crane car and a controller for controlling the boom device.
クレーン車は、一般にブーム装置を搭載している(特許文献1参照)。特許文献1に開示されたブーム装置は、伸縮可能なブーム、ブーム駆動部、ワイヤが巻回されたワイヤドラムを有するウインチ、ウインチ駆動部、上記ワイヤの先端に設けられた吊荷用フック、及びフック固定環を備えている。ブームは、旋回台に起伏可能に支持されている。ブーム駆動部は、ブームを伸縮及び起伏させる。上記ワイヤは、ワイヤドラムから引き出されてブームの先端に巻き掛けられ、当該ワイヤの端部に吊荷用フックが設けられている。ウインチ駆動部はウインチを駆動し、上記ワイヤは、ワイヤドラムに巻き取られ、或いはワイヤドラムから繰り出される。フック固定環は旋回台に設けられており、上記吊荷用フックは、クレーン走行時(非作業時)にフック固定環に掛けられ、固定される。
Crane vehicles are generally equipped with a boom device (see Patent Document 1). The boom device disclosed in Patent Document 1 includes a telescopic boom, a boom drive unit, a winch having a wire drum around which a wire is wound, a winch drive unit, a hanging hook provided at the tip of the wire, and a load hook. It has a hook fixing ring. The boom is undulatingly supported by the swivel. The boom drive unit expands and contracts and undulates the boom. The wire is pulled out from the wire drum and wound around the tip of the boom, and a hanging hook is provided at the end of the wire. The winch drive unit drives the winch, and the wire is wound on or unwound from the wire drum. The hook fixing ring is provided on the swivel base, and the hanging load hook is hung on the hook fixing ring and fixed when the crane is running (during non-working).
特許文献1に開示されたブーム装置は、制御装置を備える。この制御装置は、作業終了時のブーム格納作業並びに作業開始時のブーム展開作業を安全に行うため、ブーム駆動部及びウインチ駆動部を制御する。たとえばブームの格納作業に際し、作業者は、ブームを縮小且つ起立させ、吊荷用フックをフック固定環に掛ける。次に、作業者は、ブーム駆動装置を操作してブームを倒伏させる。このとき、制御装置は、ワイヤの弛みを防止するため、ブームの倒伏に合わせてワイヤが巻き取られるようにブーム駆動部及びウインチ駆動部を制御する。
The boom device disclosed in Patent Document 1 includes a control device. This control device controls the boom drive unit and the winch drive unit in order to safely perform the boom retracting work at the end of the work and the boom deployment work at the start of the work. For example, when retracting the boom, the operator reduces and erects the boom, and hooks the hanging load on the hook fixing ring. Next, the operator operates the boom drive device to lay down the boom. At this time, the control device controls the boom drive unit and the winch drive unit so that the wire is wound in accordance with the lodging of the boom in order to prevent the wire from loosening.
具体的には、制御装置は、ワイヤの長さを検出するセンサが検出したワイヤ長さSと、起伏角センサが検出したブームの起伏角θとに基づき、これらが理想的な対応関係Dとなるように、すなわち、ワイヤが弛み過ぎず且つ張り過ぎないように、ウインチの駆動を制御する。この理想的な対応関係Dは、実機による実験やシミュレーションによって求められ、予め制御装置の記憶部に記憶される。
Specifically, the control device is based on the wire length S detected by the sensor that detects the wire length and the undulation angle θ of the boom detected by the undulation angle sensor, and these are the ideal correspondence D. That is, the drive of the winch is controlled so that the wire is not too loose and not too tight. This ideal correspondence relationship D is obtained by an experiment or simulation using an actual machine, and is stored in advance in the storage unit of the control device.
ワイヤが張られた状態から上記対応関係Dが維持されるようにウインチ及びブームが駆動されると、制御の揺らぎによって係止部材に想定以上の負荷が加わり、係止部材が破損するおそれが生じる。一方、ワイヤが弛み過ぎた状態から上記対応関係Dが維持されるようにウインチ及びブームが駆動されると、乱巻きが生じるおそれがある。
When the winch and the boom are driven so that the correspondence D is maintained from the state where the wire is stretched, the locking member is subject to an unexpected load due to the fluctuation of the control, and the locking member may be damaged. .. On the other hand, if the winch and the boom are driven so that the correspondence D is maintained from the state where the wire is excessively loosened, random winding may occur.
そこで、本発明の主目的は、ブームの自動展開や自動格納が実行される前に、ワイヤが張り過ぎずかつ弛み過ぎないように制御するコントローラを提供することである。
Therefore, a main object of the present invention is to provide a controller that controls the wire so that it is not over-tensioned and not over-slackened before the boom is automatically deployed or retracted.
(1) 本発明に係るコントローラは、台座と、当該台座に支持され、倒伏位置と所定起立位置との間で起伏動作可能なブームと、ワイヤドラムに巻き取られ、上記ブームの先端部に巻きかけられたワイヤを有するウインチと、上記ワイヤに設けられた吊荷用フックを有するフック部材と、上記ブームを起伏させる第1アクチュエータと、上記ウインチを駆動する第2アクチュエータと、上記台座に設けられ、上記吊荷用フックが係止される係止部材と、上記ブームの起伏角度に応じた検出値を出力する起伏角センサと、上記ワイヤの繰り出し長さに応じた検出値を出力するワイヤセンサと、を備えたブーム装置に搭載される。本発明に係るコントローラは、上記ブームの長さ、上記ブームの起伏中心を基準とする上記係止部材の位置に応じた第1指定値、及び上記フック部材の種別と上記係止部材の種別との少なくとも一方に応じた第2指定値を予め記憶するメモリを有しており、上記起伏角センサの検出値から特定した上記ブームの起伏角度と、上記ブームの長さと、上記第1指定値及び第2指定値と、に基づいて、上記ブームの先端基準位置から上記フック部材までの許容最小距離及び許容最大距離を生成する生成処理と、上記許容最小距離まで上記ワイヤを巻き上げる巻上処理と、上記許容最小距離と上記許容最大距離との差に応じた目標値だけ上記ワイヤを繰り出す繰出処理と、を実行する。
(1) The controller according to the present invention is wound around a pedestal, a boom supported by the pedestal and capable of undulating operation between an inverted position and a predetermined standing position, and a wire drum, and wound around the tip of the boom. A winch having a hung wire, a hook member having a hanging hook provided on the wire, a first actuator for raising and lowering the boom, a second actuator for driving the winch, and a pedestal provided. , The locking member to which the hanging hook is locked, the undulation angle sensor that outputs the detection value according to the undulation angle of the boom, and the wire sensor that outputs the detection value according to the extension length of the wire. And, it is mounted on a boom device equipped with. The controller according to the present invention has the length of the boom, the first designated value according to the position of the locking member with respect to the undulating center of the boom, and the type of the hook member and the type of the locking member. It has a memory for storing the second designated value corresponding to at least one of the above in advance, and the undulation angle of the boom specified from the detection value of the undulation angle sensor, the length of the boom, the first designated value and the above. Based on the second designated value, a generation process for generating an allowable minimum distance and an allowable maximum distance from the boom tip reference position to the hook member, and a hoisting process for winding the wire to the allowable minimum distance. The feeding process of feeding out the wire by the target value corresponding to the difference between the allowable minimum distance and the allowable maximum distance is executed.
この構成によれば、ブームの自動展開や自動格納が実行される前に、ワイヤの繰り出し長さが許容最小距離になるまでワイヤが巻き上げられ、許容最小距離と許容最大距離との差に応じた目標値だけワイヤが繰り出される。したがって、上記自動展開又は自動格納に先立って、ワイヤの状態が張り過ぎずかつ弛み過ぎないように設定される。
According to this configuration, the wire is wound up to the allowable minimum distance before the boom is automatically deployed or retracted, depending on the difference between the allowable minimum distance and the allowable maximum distance. The wire is unwound by the target value. Therefore, prior to the automatic expansion or storage, the state of the wire is set so as not to be too tight and not too loose.
(2) 上記許容最小距離は、上記ワイヤが張られて上記フック部材が引き起こされた姿勢における上記ブームの先端部から上記フック部材までの距離であり、上記許容最大距離は、上記フック部材が寝た姿勢における上記ブームの先端部から上記フック部材までの距離であってもよい。
(2) The allowable minimum distance is the distance from the tip of the boom to the hook member in the posture in which the wire is stretched and the hook member is raised, and the allowable maximum distance is the distance when the hook member sleeps. It may be the distance from the tip of the boom to the hook member in the vertical posture.
この構成では、上記巻上処理によりワイヤに生じた張力によってフック部材が引き起こされた姿勢となったときに上記許容最小距離が定義され、上記繰出処理によりワイヤが繰り出されることによってフック部材が寝た姿勢となったときに上記許容最大距離が定義される。したがって、上記自動展開又は自動格納に先立って、フック部材は、上記引き起こされた姿勢と寝た姿勢との間で姿勢変化することになり、ワイヤは、確実に張り過ぎずかつ弛み過ぎないようにされる。
In this configuration, the allowable minimum distance is defined when the hook member is in a posture caused by the tension generated in the wire by the hoisting process, and the hook member lays down when the wire is unwound by the feeding process. The maximum allowable distance is defined when the posture is reached. Therefore, prior to the automatic deployment or storage, the hook member will change its posture between the raised posture and the sleeping posture, and the wire will surely not be over-tensioned and not too loose. Will be done.
(3) 上記ブーム装置は、上記第2アクチュエータに作動油を供給する油圧供給装置をさらに備えており、上記油圧供給装置は、上記第2アクチュエータに供給する作動油を所定圧力未満に低減するリリーフバルブを備えたリリーフ回路を有していてもよい。この場合、流路を上記リリーフ回路に切り替える切替処理が実行された後、上記巻上処理が実行される。
(3) The boom device further includes a hydraulic pressure supply device that supplies hydraulic oil to the second actuator, and the hydraulic pressure supply device is a relief that reduces the hydraulic oil supplied to the second actuator to less than a predetermined pressure. It may have a relief circuit with a valve. In this case, after the switching process for switching the flow path to the relief circuit is executed, the hoisting process is executed.
この構成では、流路がリリーフ回路に切り替えられると、第2アクチュエータに供給される作動油の圧力が所定圧力未満となるので、巻き上げられるワイヤに生じる張力は小さい。したがって、巻上処理において係止部材が破損することが防止される。
In this configuration, when the flow path is switched to the relief circuit, the pressure of the hydraulic oil supplied to the second actuator becomes less than the predetermined pressure, so the tension generated in the wound wire is small. Therefore, it is possible to prevent the locking member from being damaged in the hoisting process.
(4) 上記第2指定値は、上記フック部材の長さと上記係止部材の長さとの和に応じた値であってもよい。
(4) The second designated value may be a value corresponding to the sum of the length of the hook member and the length of the locking member.
この構成では、どのような種類のフック部材及び係止部材が使用されても、許容最小距離及び許容最大距離が適切に生成される。
In this configuration, the allowable minimum distance and the allowable maximum distance are appropriately generated regardless of the type of hook member and locking member used.
(5) 上記繰出処理の実行後、上記ワイヤセンサの検出値から特定した上記ワイヤの繰り出し長さが上記目標値を維持するように、上記第1アクチュエータ及び第2アクチュエータを駆動させる駆動処理がさらに実行されてもよい。
(5) After the execution of the feeding process, the driving process for driving the first actuator and the second actuator is further performed so that the feeding length of the wire specified from the detection value of the wire sensor maintains the target value. It may be executed.
この構成では、ワイヤの状態が張り過ぎずかつ弛み過ぎないように維持される。すなわち、フック部材の姿勢が上記引き起こされた姿勢と寝た姿勢との間の姿勢となるように維持される。したがって、ブームの自動展開や自動格納において、係止部材の破損や乱巻きの発生が確実に防止される。
In this configuration, the state of the wire is maintained so that it is not too tight and not too loose. That is, the posture of the hook member is maintained so as to be a posture between the raised posture and the sleeping posture. Therefore, in the automatic deployment and storage of the boom, damage to the locking member and occurrence of random winding are surely prevented.
(6) ワイヤ掛数を取得する取得処理と、上記ワイヤ掛数に基いて上記目標値を補正する補正処理とがさらに実行されてもよい。
(6) The acquisition process for acquiring the number of wire hooks and the correction process for correcting the target value based on the number of wire hooks may be further executed.
この構成では、取得処理及び補正処理が実行されることにより、ワイヤ掛数を変更可能なフック部材が使用されていても、ワイヤは、張り過ぎずかつ弛み過ぎないようにされる。
In this configuration, the acquisition process and the correction process are executed so that the wire is not over-tensioned and not too loose even if a hook member whose number of wire hooks can be changed is used.
(7) 本発明に係るブーム装置は、上記コントローラと、上記台座、上記ブーム、上記ウインチ、上記フック部材、上記第1アクチュエータ、上記第2アクチュエータ、上記係止部材、上記起伏角センサ、及び上記ワイヤセンサと、を備える。
(7) The boom device according to the present invention includes the controller, the pedestal, the boom, the winch, the hook member, the first actuator, the second actuator, the locking member, the undulation angle sensor, and the undulation angle sensor. It is equipped with a wire sensor.
本発明は、ブーム装置として捉えることもできる。
The present invention can also be regarded as a boom device.
(8) 本発明に係るクレーン車は、上記ブーム装置を備える。
(8) The crane vehicle according to the present invention is equipped with the above boom device.
本発明は、クレーン車として捉えることもできる。
The present invention can also be regarded as a mobile crane.
本発明に係るコントローラは、ブームの自動展開や自動格納が実行される前に、フック部材の姿勢を適切な姿勢にして、ワイヤが張り過ぎずかつ弛み過ぎないようにすることができる。
The controller according to the present invention can set the posture of the hook member to an appropriate posture before the boom is automatically deployed or retracted so that the wire is not over-tensioned and not too loose.
以下、本発明の好ましい実施形態が、適宜図面が参照されつつ説明される。なお、本実施形態は、本発明の一態様にすぎず、本発明の要旨を変更しない範囲で実施態様が変更されてもよいことは、言うまでもない。例えば、後述する各処理の実行順序は、本発明の要旨を変更しない範囲で適宜変更することができる。或いは、後述の処理の一部は、本発明の要旨を変更しない範囲で適宜省略することができる。
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings as appropriate. Needless to say, the present embodiment is only one aspect of the present invention, and the embodiments may be changed without changing the gist of the present invention. For example, the execution order of each process described later can be appropriately changed without changing the gist of the present invention. Alternatively, a part of the processing described later can be omitted as appropriate without changing the gist of the present invention.
図1は、本実施形態に係るクレーン車10を模式的に示しており、ブーム32が倒伏位置にある状態が示されている。
FIG. 1 schematically shows the crane vehicle 10 according to the present embodiment, and shows a state in which the boom 32 is in the inverted position.
クレーン車10は、走行体11と、走行体11に搭載されたブーム装置12と、キャビン13とを主に備える。走行体11は、車体20と、車体20に搭載されたエンジン22及びバッテリ23とを備える。エンジン22は、不図示のトランスミッション等を介して車軸98、99を回転駆動する。エンジン22は、油圧供給装置24(図5参照)が備える油圧ポンプ(不図示)を駆動させ、油圧供給装置24はブーム装置12等を駆動させる油圧を発生させる。
The crane vehicle 10 mainly includes a traveling body 11, a boom device 12 mounted on the traveling body 11, and a cabin 13. The traveling body 11 includes a vehicle body 20, an engine 22 mounted on the vehicle body 20, and a battery 23. The engine 22 rotationally drives the axles 98 and 99 via a transmission (not shown) or the like. The engine 22 drives a hydraulic pump (not shown) included in the hydraulic pressure supply device 24 (see FIG. 5), and the hydraulic pressure supply device 24 generates hydraulic pressure to drive the boom device 12 and the like.
キャビン13は、ブーム装置12の旋回台31に搭載されている。キャビン13は、クレーン車10の運転を行う運転装置14(図5参照)と、ブーム装置12の操縦を行う操縦装置15(図5参照)とを有する。すなわち、クレーン車10は、いわゆるラフテレーンクレーンであって、クレーン車10の運転及びブーム装置12の操縦が1つのキャビン13にて行われる。但し、クレーン車10は、いわゆるオールテレーンクレーンであってもよい。
The cabin 13 is mounted on the swivel table 31 of the boom device 12. The cabin 13 has a driving device 14 (see FIG. 5) for operating the mobile crane 10 and a steering device 15 (see FIG. 5) for manipulating the boom device 12. That is, the crane vehicle 10 is a so-called rough terrain crane, and the crane vehicle 10 is operated and the boom device 12 is operated in one cabin 13. However, the mobile crane 10 may be a so-called all-terrain crane.
図5が示す操縦装置15は、ブーム装置12を操作する操作レバーや操作ボタン等を有する。操縦装置15は、操作レバーの操作の向きや操作量を示す操作信号や、操作ボタンの操作の有無を示す操作信号を出力する。操縦装置15が出力した操作信号は、コントローラ50に入力される。
The control device 15 shown in FIG. 5 has an operation lever, an operation button, and the like for operating the boom device 12. The control device 15 outputs an operation signal indicating the direction and amount of operation of the operation lever and an operation signal indicating whether or not the operation button is operated. The operation signal output by the control device 15 is input to the controller 50.
キャビン13は、不図示の制御ボックスを有する。この制御ボックスは、制御基板を備える。制御基板は、マイクロコンピュータ、抵抗、コンデンサ、ダイオード、種々のICが実装されており、コントローラ50及び電源回路17を構成している。
The cabin 13 has a control box (not shown). This control box comprises a control board. A microcomputer, a resistor, a capacitor, a diode, and various ICs are mounted on the control board, which constitutes a controller 50 and a power supply circuit 17.
図1が示すように、ブーム装置12は、旋回台31と、ブーム32と、油圧供給装置24(図5参照)とを備える。旋回台31は、車体20に旋回可能に支持されている。旋回台31は、特許請求の範囲に記載された「台座」に相当する。ブーム32は、基端ブーム33、単一又は複数の中間ブーム34、及び先端ブーム35を有する。基端ブーム33、中間ブーム34、及び先端ブーム35は、入れ子状に配置されており、これらはテレスコピックを構成している。基端ブーム33は、旋回台31に起伏可能に支持されており、したがって、ブーム32は、旋回、起伏、及び伸縮可能である。ブーム32は、図1に示される縮小状態と、不図示の拡張状態との間で伸縮すると共に、図1に示される倒伏位置と、図2に示される所定起立位置との間で起伏する。クレーン車10は、ブーム32を縮小状態かつ倒伏位置にした格納状態(図1参照)で走行する。
As shown in FIG. 1, the boom device 12 includes a swivel table 31, a boom 32, and a hydraulic pressure supply device 24 (see FIG. 5). The swivel table 31 is supported by the vehicle body 20 so as to be swivelable. The swivel table 31 corresponds to the "pedestal" described in the claims. The boom 32 has a proximal boom 33, a single or plurality of intermediate booms 34, and a tip boom 35. The proximal boom 33, the intermediate boom 34, and the distal boom 35 are arranged in a nested manner, which constitute a telescopic. The base boom 33 is undulatingly supported by the swivel table 31, and thus the boom 32 is swivelable, undulating, and telescopic. The boom 32 expands and contracts between the contracted state shown in FIG. 1 and the expanded state (not shown), and undulates between the lodging position shown in FIG. 1 and the predetermined standing position shown in FIG. The mobile crane 10 travels in a retracted state (see FIG. 1) with the boom 32 in a contracted state and an inverted position.
図5が示すように、ブーム装置12は、旋回モータ25と、ブーム32を起伏させる起伏シリンダ36と、ブーム32を伸縮させる伸縮シリンダ37とをさらに備える。旋回モータ25は、車体20(図1参照)に設けられている。旋回モータ25は、油圧供給装置24から油圧の供給を受けて回転し、旋回台31を旋回させる。起伏シリンダ36は、旋回台31に設けられている。起伏シリンダ36は、油圧供給装置24から油圧の供給を受けて伸縮する。伸縮する起伏シリンダ36は、ブーム32を起伏させる。起伏シリンダ36は、特許請求の範囲に記載された「第1アクチュエータ」に相当する。伸縮シリンダ37は、ブーム32に設けられている。伸縮シリンダ37は、油圧供給装置24から油圧の供給を受けて伸縮する。伸縮する伸縮シリンダ37は、ブーム32を伸縮させる。
As shown in FIG. 5, the boom device 12 further includes a swivel motor 25, an undulating cylinder 36 for undulating the boom 32, and a telescopic cylinder 37 for expanding and contracting the boom 32. The swivel motor 25 is provided on the vehicle body 20 (see FIG. 1). The swivel motor 25 receives hydraulic pressure from the hydraulic pressure supply device 24 and rotates to swivel the swivel table 31. The undulating cylinder 36 is provided on the swivel table 31. The undulating cylinder 36 expands and contracts by receiving hydraulic pressure from the hydraulic pressure supply device 24. The undulating cylinder 36 that expands and contracts undulates the boom 32. The undulating cylinder 36 corresponds to the "first actuator" described in the claims. The telescopic cylinder 37 is provided on the boom 32. The telescopic cylinder 37 expands and contracts by receiving hydraulic pressure from the hydraulic pressure supply device 24. The telescopic cylinder 37 that expands and contracts expands and contracts the boom 32.
ブーム装置12は、第1油圧モータ38、メインウインチ39、滑車機構60(図3参照)、及び掛け金具41(図1参照)をさらに備える。メインウインチ39は、特許請求の範囲に記載された「ウインチ」に相当する。
The boom device 12 further includes a first hydraulic motor 38, a main winch 39, a pulley mechanism 60 (see FIG. 3), and a hanging bracket 41 (see FIG. 1). The main winch 39 corresponds to the "winch" described in the claims.
メインウインチ39は、ブーム32の基端に取り付けられている。メインウインチ39は、ワイヤドラム44と、ウインチシーブ43と、ワイヤ42とを有する。ワイヤ42は、ワイヤドラム44に巻き付けられている。ウインチシーブ43は、ブーム32が水平方向に沿う倒伏位置にある状態において、ブーム32の基端の上部に位置している。ワイヤドラム44から引き出されたワイヤ42は、ウインチシーブ43に巻き掛けられた後、滑車機構60(図3参照)まで引き出されている。
The main winch 39 is attached to the base end of the boom 32. The main winch 39 has a wire drum 44, a winch sheave 43, and a wire 42. The wire 42 is wound around the wire drum 44. The winch sheave 43 is located above the base end of the boom 32 in a state where the boom 32 is in a horizontal lying position. The wire 42 drawn from the wire drum 44 is wound around the winch sheave 43 and then pulled out to the pulley mechanism 60 (see FIG. 3).
第1油圧モータ38は、油圧供給装置24から油圧の供給を受けて回転する。回転する第1油圧モータ38は、ワイヤドラム44を回転させる。回転するワイヤドラム44は、ワイヤ42を巻き取り(巻上)、或いはワイヤ42を繰り出す(巻下)。第1油圧モータ38は、特許請求の範囲に記載された「第2アクチュエータ」に相当する。
The first hydraulic motor 38 rotates by receiving the supply of hydraulic pressure from the hydraulic pressure supply device 24. The rotating first hydraulic motor 38 rotates the wire drum 44. The rotating wire drum 44 winds up the wire 42 (winding up) or unwinds the wire 42 (winding down). The first hydraulic motor 38 corresponds to the "second actuator" described in the claims.
図3が示すように、滑車機構60は、固定シーブブロック61と、フックブロック62とを有する。
As shown in FIG. 3, the pulley mechanism 60 has a fixed sheave block 61 and a hook block 62.
固定シーブブロック61は、1つの第1シーブ63と、3つの第2シーブ64、65、66とを有している。第1シーブ63は、図示されていない中心軸に回転可能に支持されている。第2シーブ64、65、66は、中心軸58(図4参照)に支持されている。第2シーブ64、65、66は円盤状を呈し、中心軸58を中心として回転可能である。
The fixed sheave block 61 has one first sheave 63 and three second sheaves 64, 65, 66. The first sheave 63 is rotatably supported by a central axis (not shown). The second sheaves 64, 65, 66 are supported by a central axis 58 (see FIG. 4). The second sheaves 64, 65, 66 have a disk shape and can rotate around the central axis 58.
図1が示すように、第1シーブ63は、ブーム32が水平方向に沿う倒伏位置にある状態において、ブーム32の先端の上部に位置している。3つの第2シーブ64、65、66は、倒伏位置において、ブーム32の先端の下部に位置している。図4が示すように、3つの第2シーブ64、65、66は、ブーム32の幅方向に並設されている。なお、本実施形態では、固定シーブブロック61が3つの第2シーブ64、65、66を有する例が示されているが、固定シーブブロック61は、2つの第2シーブを有していてもよいし、4つ以上の第2シーブを有していてもよい。
As shown in FIG. 1, the first sheave 63 is located above the tip of the boom 32 in a state where the boom 32 is in a horizontal lying position. The three second sheaves 64, 65, 66 are located below the tip of the boom 32 in the lodging position. As shown in FIG. 4, the three second sheaves 64, 65, 66 are arranged side by side in the width direction of the boom 32. Although the fixed sheave block 61 has three second sheaves 64, 65, 66 in the present embodiment, the fixed sheave block 61 may have two second sheaves. However, it may have four or more second sheaves.
フックブロック62は、フレーム45と、フレーム45に取り付けられた吊荷用フック40と、3つの第3シーブ68、69、70と、を有している。第3シーブ68、69、70は、フレーム45に保持された中心軸59に支持されており、水平方向(ブーム32の幅方向)に並設されている。第3シーブ68、69、70は円盤状を呈し、上記中心軸59を中心に回転可能である。なお、フックブロック62は、2つの第3シーブを有していてもよいし、4つ以上の第3シーブを有していてもよい。フックブロック62は、特許請求の範囲に記載された「フック部材」に相当する。
The hook block 62 has a frame 45, a hanging hook 40 attached to the frame 45, and three third sheaves 68, 69, 70. The third sheaves 68, 69, and 70 are supported by a central axis 59 held by the frame 45, and are arranged side by side in the horizontal direction (width direction of the boom 32). The third sheaves 68, 69, and 70 have a disk shape and can rotate around the central axis 59. The hook block 62 may have two third sheaves or may have four or more third sheaves. The hook block 62 corresponds to the "hook member" described in the claims.
ウインチシーブ43(図1参照)から引き出されたワイヤ42は、第1シーブ63に掛け回された後、固定シーブブロック61の第2シーブ及びフックブロック62の第3シーブに掛け回される。図4が示す例では、ワイヤ42は、第2シーブ64、第3シーブ68、第2シーブ66、第3シーブ70に掛け回されている。すなわち、ワイヤ42が滑車機構60に掛け回された回数であるワイヤ掛数は、「4」である。ワイヤ掛数が増加されることにより、ブーム装置12の最大吊荷重量が増加する。
The wire 42 drawn from the winch sheave 43 (see FIG. 1) is hung around the first sheave 63 and then hung around the second sheave of the fixed sheave block 61 and the third sheave of the hook block 62. In the example shown in FIG. 4, the wire 42 is hung around the second sheave 64, the third sheave 68, the second sheave 66, and the third sheave 70. That is, the number of wire hooks, which is the number of times the wire 42 is hooked around the pulley mechanism 60, is "4". By increasing the number of wires hooked, the maximum suspension load amount of the boom device 12 increases.
図1が示す掛け金具41は、吊荷用フック40と係合して吊荷用フック40を固定することができる。掛け金具41の一端部は、旋回台31に回動可能に支持されている。吊荷用フック40は、掛け金具41の他端部に引っ掛けられる。掛け金具41は、ブーム32が所定起立位置まで起立され且つ全縮小された状態において、当該ブーム32の先端の直下に位置する。掛け金具41は、クレーン車10の走行中において吊荷用フック40が移動しないように、吊荷用フック40を固定する。掛け金具41は、特許請求の範囲に記載された「係止部材」に相当する。
The hanging bracket 41 shown in FIG. 1 can engage with the hanging load hook 40 to fix the hanging load hook 40. One end of the hanging bracket 41 is rotatably supported by the swivel base 31. The hanging load hook 40 is hooked on the other end of the hanging metal fitting 41. The hanging bracket 41 is located directly below the tip of the boom 32 in a state where the boom 32 is upright to a predetermined upright position and is fully reduced. The hanging metal fitting 41 fixes the hanging load hook 40 so that the hanging load hook 40 does not move while the crane wheel 10 is traveling. The hanging metal fitting 41 corresponds to the "locking member" described in the claims.
図5が示す油圧供給装置24は、走行体11に搭載されている。油圧供給装置24は、所定圧力の作動油を、旋回モータ25、起伏シリンダ36、伸縮シリンダ37、第1油圧モータ38、及びその他のアクチュエータ(以下、旋回モータ25等とも記載する)に供給する。
The hydraulic pressure supply device 24 shown in FIG. 5 is mounted on the traveling body 11. The hydraulic pressure supply device 24 supplies hydraulic oil of a predetermined pressure to the swivel motor 25, the undulating cylinder 36, the telescopic cylinder 37, the first hydraulic motor 38, and other actuators (hereinafter, also referred to as swivel motor 25 and the like).
油圧供給装置24は、不図示の電磁式流路切替弁を備えている。この流路切替弁は、後述のコントローラ50から入力される駆動信号によって作動する。流路切替弁が作動し、油圧供給ラインが変更されることにより、旋回モータ25等が駆動される。すなわち、コントローラ50は、駆動信号を出力することにより、旋回モータ25等の駆動を制御する。
The hydraulic pressure supply device 24 includes an electromagnetic flow path switching valve (not shown). This flow path switching valve is operated by a drive signal input from the controller 50 described later. By operating the flow path switching valve and changing the hydraulic pressure supply line, the swivel motor 25 and the like are driven. That is, the controller 50 controls the drive of the swivel motor 25 and the like by outputting the drive signal.
油圧供給装置24は、第1油圧モータ38に所定圧力の作動油を供給する不図示の通常回路に加え、供給される作動油の圧力を所定圧力未満に低減するために当該作動油をリリーフする第1リリーフ回路91を備える。第1リリーフ回路91は、リリーフバルブ92を有する。リリーフバルブ92は、コントローラ50から入力される駆動信号によって、通常回路と第1リリーフ回路91との間で流路を切り替える。すなわち、コントローラ50は、駆動信号をリリーフバルブ92に入力することにより、第1油圧モータ38に供給される作動油の圧力を変更することができる。コントローラ50は、後述のブーム展開処理(図6参照)及びブーム格納処理(図7参照)において、第1油圧モータ38に供給される作動油の圧力を変更する。
In addition to a normal circuit (not shown) that supplies hydraulic oil at a predetermined pressure to the first hydraulic motor 38, the hydraulic pressure supply device 24 relieves the hydraulic oil to reduce the pressure of the supplied hydraulic oil to less than the predetermined pressure. A first relief circuit 91 is provided. The first relief circuit 91 has a relief valve 92. The relief valve 92 switches the flow path between the normal circuit and the first relief circuit 91 by the drive signal input from the controller 50. That is, the controller 50 can change the pressure of the hydraulic oil supplied to the first hydraulic motor 38 by inputting the drive signal to the relief valve 92. The controller 50 changes the pressure of the hydraulic oil supplied to the first hydraulic motor 38 in the boom expansion process (see FIG. 6) and the boom retracting process (see FIG. 7), which will be described later.
図5が示すように、ブーム装置12は、ブーム長さセンサ26、起伏角センサ27、及びワイヤセンサ28をさらに備える。
As shown in FIG. 5, the boom device 12 further includes a boom length sensor 26, an undulation angle sensor 27, and a wire sensor 28.
ブーム長さセンサ26は、ブーム32の長さに応じた検出値を出力するセンサである。ブーム長さセンサ26は、ブーム32の長さを直接検出するセンサであってもよいし、伸縮シリンダ37の伸長長さを検出するセンサであってもよい。すなわち、ブーム長さセンサ26は、ブーム32の長さに応じて変化する物理量を検出するセンサであればよい。
The boom length sensor 26 is a sensor that outputs a detection value according to the length of the boom 32. The boom length sensor 26 may be a sensor that directly detects the length of the boom 32, or may be a sensor that detects the extension length of the telescopic cylinder 37. That is, the boom length sensor 26 may be a sensor that detects a physical quantity that changes according to the length of the boom 32.
起伏角センサ27は、ブーム32の起伏角度に応じた検出値を出力するセンサである。起伏角センサ27は、ブーム32の起伏角度を直接検出するセンサであってもよいし、起伏シリンダ36の伸長長さを検出するセンサであってもよい。すなわち、起伏角センサ27は、ブーム32の起伏角度に応じて変化する物理量を検出するセンサであればよい。起伏角センサ27は、例えば、ブーム32に取り付けられており、水平面に対する角度を出力する傾斜センサや水平センサである。
The undulation angle sensor 27 is a sensor that outputs a detection value according to the undulation angle of the boom 32. The undulation angle sensor 27 may be a sensor that directly detects the undulation angle of the boom 32, or may be a sensor that detects the extension length of the undulation cylinder 36. That is, the undulation angle sensor 27 may be a sensor that detects a physical quantity that changes according to the undulation angle of the boom 32. The undulation angle sensor 27 is, for example, a tilt sensor or a horizontal sensor that is attached to the boom 32 and outputs an angle with respect to a horizontal plane.
ワイヤセンサ28は、例えば、ワイヤドラム44(図1及び図2参照)の回転量を検出するロータリエンコーダである。ワイヤセンサ28は、ワイヤドラム44の回転に応じて電圧値が変化するパルス信号を出力する。ワイヤセンサ28は、ケーブルなどの信号線によってコントローラ50と接続されている。コントローラ50は、ワイヤセンサ28から入力するパルス数からワイヤドラム44の回転量を算出し、ワイヤドラム44の回転量と、ワイヤドラム44の半径とに基づいてワイヤ42の繰り出し長さを算出する。ワイヤドラム44の半径は、後述のメモリ52に予め記憶される。なお、コントローラ50がワイヤ42の繰り出し長さを取得可能であれば、どのような種類のセンサがワイヤセンサ28に用いられてもよい。
The wire sensor 28 is, for example, a rotary encoder that detects the amount of rotation of the wire drum 44 (see FIGS. 1 and 2). The wire sensor 28 outputs a pulse signal whose voltage value changes according to the rotation of the wire drum 44. The wire sensor 28 is connected to the controller 50 by a signal line such as a cable. The controller 50 calculates the rotation amount of the wire drum 44 from the number of pulses input from the wire sensor 28, and calculates the feeding length of the wire 42 based on the rotation amount of the wire drum 44 and the radius of the wire drum 44. The radius of the wire drum 44 is stored in advance in the memory 52 described later. Any kind of sensor may be used for the wire sensor 28 as long as the controller 50 can acquire the feeding length of the wire 42.
電源回路17は、コントローラ50等に供給する電力を生成する回路である。電源回路17は、例えばDC-DCコンバータである。電源回路17は、バッテリ23から供給された直流電圧を、安定した所定の電圧値の直流電圧に変換して出力する。
The power supply circuit 17 is a circuit that generates electric power to be supplied to the controller 50 and the like. The power supply circuit 17 is, for example, a DC-DC converter. The power supply circuit 17 converts the DC voltage supplied from the battery 23 into a DC voltage having a stable predetermined voltage value and outputs the DC voltage.
コントローラ50は、中央演算処理装置であるCPU51と、メモリ52とを備える。メモリ52は、例えば、ROM、RAM、EEPROM等によって構成されている。
The controller 50 includes a CPU 51, which is a central processing unit, and a memory 52. The memory 52 is composed of, for example, a ROM, a RAM, an EEPROM, or the like.
CPU51、メモリ52、ブーム長さセンサ26、起伏角センサ27、及びワイヤセンサ28は、コントローラ50が有する不図示の通信バスに接続されている。CPU51によって実行される制御プログラム54は、通信バスを通じて、メモリ52から情報やデータを読み出し、或いは情報やデータをメモリ52に記憶させ、ブーム長さセンサ26、起伏角センサ27、及びワイヤセンサ28が出力した検出値を取得する。
The CPU 51, the memory 52, the boom length sensor 26, the undulation angle sensor 27, and the wire sensor 28 are connected to a communication bus (not shown) included in the controller 50. The control program 54 executed by the CPU 51 reads information and data from the memory 52 or stores the information and data in the memory 52 through the communication bus, and the boom length sensor 26, the undulation angle sensor 27, and the wire sensor 28 are used. Acquire the output detection value.
メモリ52は、オペレーティングシステムであるOS53と、ブーム装置12の駆動を制御する制御プログラム54と、ブーム32の長さL(以下、「ブーム長さL」)と、第1指定値A、Bと、第2指定値Kと、角速度定数Fと、所定起立角度φと、を記憶している。OS53及び制御プログラム54は、いわゆるマルチタスク処理により、疑似的に並行してCPU51によって実行される。
The memory 52 includes an operating system OS 53, a control program 54 that controls the drive of the boom device 12, a length L of the boom 32 (hereinafter, “boom length L”), and first designated values A and B. , The second designated value K, the angular velocity constant F, and the predetermined standing angle φ are stored. The OS 53 and the control program 54 are executed by the CPU 51 in a pseudo-parallel manner by so-called multitasking processing.
ブーム長さLは、例えば、ブーム32が全縮小したときのブーム32の長さであって、ブーム32の基端から先端までの長さである。ブーム32の基端は、ブーム32の起伏中心P(図8参照)の位置である。ブームの先端は、例えば、ワイヤ42が架け回された第2シーブ64、65、66(図1参照)の中心軸の位置である。
The boom length L is, for example, the length of the boom 32 when the boom 32 is fully reduced, and is the length from the base end to the tip end of the boom 32. The base end of the boom 32 is the position of the undulating center P (see FIG. 8) of the boom 32. The tip of the boom is, for example, the position of the central axis of the second sheaves 64, 65, 66 (see FIG. 1) around which the wire 42 is laid.
第1指定値A、Bは、図8が示す点Qの座標を示す。すなわち、点Qの座標が(A,B)である。点Qは、起伏中心Pを原点とした2次元座標系における掛け金具41の一端の位置を示す。なお、当該2次元座標系は、クレーン車10の前後方向をx軸方向とし、上下方向をy軸方向とする座標系である。
The first designated values A and B indicate the coordinates of the point Q shown in FIG. That is, the coordinates of the point Q are (A, B). The point Q indicates the position of one end of the hanging bracket 41 in the two-dimensional coordinate system with the undulation center P as the origin. The two-dimensional coordinate system is a coordinate system in which the front-rear direction of the crane wheel 10 is the x-axis direction and the vertical direction is the y-axis direction.
第2指定値Kは、フックブロック62の長さと、掛け金具41の長さとの和である。フックブロックの長さとは、吊荷用フック40の先端から軸59までの距離を意味する。なお、フックブロック62の長さが無視できるほど短い場合、第2指定値Kは、掛け金具41の長さとされ、掛け金具41の長さが無視できるほど短い場合、第2指定値Kは、フックブロック62の長さとされる。すなわち、第2指定値Kは、フックブロック62の種別と、掛け金具41の種別との少なくとも一方に応じた値である。なお、掛け金具41の長さと吊荷用フック40の長さとが別個にメモリ52に記憶されていてもよい。その場合、制御プログラム54は、掛け金具41の長さに吊荷用フック40の長さを加えて第2指定値Kを算出する。
The second designated value K is the sum of the length of the hook block 62 and the length of the hanging metal fitting 41. The length of the hook block means the distance from the tip of the hanging hook 40 to the shaft 59. If the length of the hook block 62 is so short that it can be ignored, the second designated value K is the length of the hanging metal fitting 41, and if the length of the hanging metal fitting 41 is so short that it can be ignored, the second designated value K is. It is the length of the hook block 62. That is, the second designated value K is a value corresponding to at least one of the type of the hook block 62 and the type of the hook 41. The length of the hanging metal fitting 41 and the length of the hanging load hook 40 may be stored separately in the memory 52. In that case, the control program 54 calculates the second designated value K by adding the length of the hanging load hook 40 to the length of the hanging metal fitting 41.
角速度定数Fは、制御プログラム54が後述のブーム展開処理(図6参照)及びブーム格納処理(図7参照)においてブーム32を一定の角速度で起伏させる場合のブーム32の角速度である。すなわち、F=dθ/dtである。
The angular velocity constant F is the angular velocity of the boom 32 when the control program 54 raises and lowers the boom 32 at a constant angular velocity in the boom expansion process (see FIG. 6) and the boom storage process (see FIG. 7) described later. That is, F = dθ / dt.
所定起立角度φは、ブーム32の先端が掛け金具41の真上に位置する所定起立位置でのブーム32の起伏角度である。所定起立角度φは、ブーム展開処理(図6参照)において、吊荷用フック40を掛け金具41から安全に取り外せる所定起立位置までブーム32が起立したか否かの判断に用いられる。
The predetermined standing angle φ is the undulating angle of the boom 32 at the predetermined standing position where the tip of the boom 32 is located directly above the hanging bracket 41. The predetermined standing angle φ is used in the boom deployment process (see FIG. 6) to determine whether or not the boom 32 has stood up to a predetermined standing position where the hanging load hook 40 can be safely removed from the hook 41.
制御プログラム54は、例えばクラスを有する。すなわち、クラスは、メモリ52に記憶されている。クラスは、インスタンス(オブジェクト)を生成するものである。具体的には、クラスは、メモリ52に記憶されたブーム長さLや第1指定値(A,B)や第2指定値Kを与えられることにより、インスタンスとして、図8が示す関数X1(θ)や、関数X1(θ)を時間tで微分したd/dt{X1(θ)}や、図9が示す関数X2(θ)や、関数X2(θ)を時間tで微分したd/dt{X2(θ)}を生成する。なお、制御プログラム54は、生成した関数X1(θ)、関数X2(θ)を時間tで微分してd/dt{X1(θ)}、d/dt{X2(θ)}を生成してもよい。また、上記クラスは、ブーム長さLや第1指定値(A,B)や第2指定値Kが入力フィールドに入力されることによりX1(θ)やX2(θ)を生成する演算式であってもよい。
The control program 54 has, for example, a class. That is, the class is stored in the memory 52. A class creates an instance (object). Specifically, the class is given the boom length L stored in the memory 52, the first designated value (A, B), and the second designated value K, and as an instance, the function X1 shown in FIG. 8 ( θ), d / dt {X1 (θ)} obtained by differentiating the function X1 (θ) with respect to time t, the function X2 (θ) shown in FIG. 9, and d / dt differentiated with respect to the function X2 (θ) with respect to time t. Generate dt {X2 (θ)}. The control program 54 differentiates the generated functions X1 (θ) and X2 (θ) with respect to time t to generate d / dt {X1 (θ)} and d / dt {X2 (θ)}. May be good. Further, the above class is an arithmetic expression that generates X1 (θ) and X2 (θ) by inputting a boom length L, a first designated value (A, B), and a second designated value K into an input field. There may be.
関数X1(θ)は、図8が示すように、フックブロック62と掛け金具41とが一直線上に並んでいる状態におけるワイヤ42の理論上の繰り出し長さを示す。関数X1(θ)は、ブーム32の起伏角度がθである場合のワイヤ42の理論上の繰り出し長さを示す。関数X1(θ)は、θを変数とし、上記A、B、L、Kを定数として、A、B、L、K、θを用いて表される。
The function X1 (θ) indicates the theoretical extension length of the wire 42 in a state where the hook block 62 and the hook 41 are aligned in a straight line, as shown in FIG. The function X1 (θ) indicates the theoretical extension length of the wire 42 when the undulation angle of the boom 32 is θ. The function X1 (θ) is expressed using A, B, L, K, and θ with θ as a variable and A, B, L, and K as constants.
詳しく説明すると、ブーム32の先端の位置を示す点Sの座標は、ブーム32の長さL及びブーム32の起伏角度θを用いて、(Lcosθ,Lsinθ)と表される。したがって、点Sと点Qとの間の距離SQは、図8に示されるように、A、B、L、K、θを用いて表される。そして、関数X1(θ)は、距離SQ-Kとなり、A、B、L、K、θを用いて表される。
More specifically, the coordinates of the point S indicating the position of the tip of the boom 32 are expressed as (Lcos θ, Lsin θ) using the length L of the boom 32 and the undulation angle θ of the boom 32. Therefore, the distance SQ between the points S and Q is expressed using A, B, L, K, and θ, as shown in FIG. Then, the function X1 (θ) becomes the distance SQ—K and is expressed using A, B, L, K, and θ.
関数X2(θ)は、図9が示すように、フックブロック62が寝た姿勢におけるワイヤ42の理論上の繰り出し長さを示す。フックブロック62が寝た姿勢とは、フックブロック62が車体20に支持されて水平方向に沿っている状態である。また、関数X2(θ)は、ブーム32の起伏角度がθである場合のワイヤ42の理論上の繰り出し長さを示す。関数X2(θ)は、θを変数とし、上記A、B、L、Kを定数として、A、B、L、K、θを用いて表される。
The function X2 (θ) indicates the theoretical extension length of the wire 42 in the posture in which the hook block 62 is lying down, as shown in FIG. The posture in which the hook block 62 is lying down is a state in which the hook block 62 is supported by the vehicle body 20 and is aligned in the horizontal direction. Further, the function X2 (θ) indicates the theoretical extension length of the wire 42 when the undulation angle of the boom 32 is θ. The function X2 (θ) is expressed using A, B, L, K, and θ with θ as a variable and A, B, L, and K as constants.
詳しく説明すると、ブーム32の先端の位置を示す点Sの座標は、(Lcosθ,Lsinθ)と表される。ワイヤ42と吊荷用フック40との接続位置を示す点Rの座標、すなわち、中心軸59の座標は、(A+K,B)と表せる。関数X2(θ)は、点Sと点Rとの間の距離SRであり、図9が示すように、A、B、L、K、θを用いて表される。なお、点Rは、フックブロック62のフレーム45における吊荷用フック40が設けられている側の反対側の端を示す。関数X1(θ)は、特許請求の範囲に記載された「許容最小距離」に相当する。関数X2(θ)は、特許請求の範囲に記載された「許容最大距離」に相当する。
More specifically, the coordinates of the point S indicating the position of the tip of the boom 32 are expressed as (Lcosθ, Lsinθ). The coordinates of the point R indicating the connection position between the wire 42 and the hanging hook 40, that is, the coordinates of the central axis 59 can be expressed as (A + K, B). The function X2 (θ) is the distance SR between the points S and R, and is represented using A, B, L, K, and θ, as shown in FIG. The point R indicates the opposite end of the frame 45 of the hook block 62 on the side where the hanging hook 40 is provided. The function X1 (θ) corresponds to the “minimum allowable distance” described in the claims. The function X2 (θ) corresponds to the “maximum allowable distance” described in the claims.
制御プログラム54は、倒伏位置(図1参照)にあるブーム32を所定起立位置(図2参照)まで自動で起立させるブーム展開処理と、所定起立位置にあるブーム32を倒伏位置まで自動で倒伏させるブーム格納処理とを実行する。なお、制御プログラム54が実行する処理は、コントローラ50が実行する処理でもある。
The control program 54 automatically erects the boom 32 in the laid-down position (see FIG. 1) to the predetermined standing position (see FIG. 2), and automatically lays down the boom 32 in the predetermined standing position to the laid-down position. Execute boom storage processing. The process executed by the control program 54 is also a process executed by the controller 50.
クレーン車10が作業現場に到着すると、制御プログラム54は、ブーム展開処理を実行する。すなわち、ブーム展開処理は、作業現場においてクレーン車10が作業を開始するために実行される。この処理は、従来、作業者が操縦装置15を用いて手動で行っていたものであるが、本実施形態では、ブーム32を所定起立位置まで展開する作業を制御プログラム54が自動で行う。
When the mobile crane 10 arrives at the work site, the control program 54 executes the boom deployment process. That is, the boom deployment process is executed for the mobile crane 10 to start the work at the work site. Conventionally, this process was manually performed by the operator using the control device 15, but in the present embodiment, the control program 54 automatically performs the work of deploying the boom 32 to a predetermined standing position.
作業者は、クレーン車10を走行させて作業現場から離れるため、ブーム格納処理を制御プログラム54に実行させる。すなわち、ブーム格納処理は、作業現場においてクレーン車10が作業を終了させるために実行される。この処理は、従来、作業者が操縦装置15を用いて手動で行っていたものであるが、本実施形態では、ブーム32を格納する作業を制御プログラム54が自動で行う。
The worker causes the control program 54 to execute the boom storage process in order to drive the crane vehicle 10 away from the work site. That is, the boom storage process is executed for the mobile crane 10 to finish the work at the work site. Conventionally, this process was manually performed by the operator using the control device 15, but in the present embodiment, the control program 54 automatically performs the operation of storing the boom 32.
以下、ブーム展開処理及びブーム格納処理について、図6及び図7を参照して詳しく説明する。
Hereinafter, the boom expansion process and the boom storage process will be described in detail with reference to FIGS. 6 and 7.
作業者は、クレーン車10が作業現場に到着した後、操縦装置15を用いて、ブーム展開処理の実行を指示する操作を行う。なお、クレーン車10が作業現場に到着した状態において(図1参照)、ブーム32は、上記格納状態であり、かつ、吊荷用フック40は、掛け金具41に固定されている。
After the crane vehicle 10 arrives at the work site, the operator uses the control device 15 to perform an operation instructing the execution of the boom deployment process. When the mobile crane 10 arrives at the work site (see FIG. 1), the boom 32 is in the retracted state, and the hanging load hook 40 is fixed to the hanging metal fitting 41.
制御プログラム54は、操縦装置15から、ブーム展開処理の実行を指示する操作信号が入力されたことに応じて、図6が示すブーム展開処理の実行を開始する。まず、制御プログラム54は、ワイヤ掛数を取得する(S11)。例えば、制御プログラム54は、メモリ52に記憶されたワイヤ掛数を読み出す。或いは、制御プログラム54は、ワイヤ掛数を自動判定する処理を実行して、ワイヤ掛数を取得する。ステップS11の処理は、特許請求の範囲に記載された「取得処理」に相当する。
The control program 54 starts the execution of the boom expansion process shown in FIG. 6 in response to the input of the operation signal instructing the execution of the boom expansion process from the control device 15. First, the control program 54 acquires the number of wires hooked (S11). For example, the control program 54 reads out the number of wires stored in the memory 52. Alternatively, the control program 54 executes a process of automatically determining the number of wire hooks to acquire the number of wire hooks. The process of step S11 corresponds to the "acquisition process" described in the claims.
なお、フローチャートには記載されていないが、制御プログラム54は、ブーム長さセンサ26が検出したブーム32の長さが、メモリ52に記憶された「L」でない場合、エラー表示を行って、ブーム展開処理の実行をキャンセルしてもよい。これにより、ブーム32が縮小されていない状態でブーム展開処理が実行されることを防止することができる。
Although not described in the flowchart, the control program 54 displays an error and booms when the length of the boom 32 detected by the boom length sensor 26 is not “L” stored in the memory 52. You may cancel the execution of the expansion process. This makes it possible to prevent the boom expansion process from being executed in a state where the boom 32 is not reduced.
次に、制御プログラム54は、上記A、B、L、K、Fをメモリ52から読み出す(S12)。また、制御プログラム54は、起伏角センサ27が検出した起伏角度θを取得する(S13)。制御プログラム54は、取得したθ、A、B、L、K、F及び上記クラスを用いて、X1(θ)及びX2(θ)を生成する(S14)。ステップS14の処理は、特許請求の範囲に記載された「生成処理」に相当する。
Next, the control program 54 reads the above A, B, L, K, and F from the memory 52 (S12). Further, the control program 54 acquires the undulation angle θ detected by the undulation angle sensor 27 (S13). The control program 54 uses the acquired θ, A, B, L, K, F and the above class to generate X1 (θ) and X2 (θ) (S14). The process of step S14 corresponds to the "generation process" described in the claims.
制御プログラム54は、生成したX1(θ)及びX2(θ)を用いて、目標値を決定する(S15)。具体的には、制御プログラム54は、目標値として、X1(θ)とX2(θ)との平均値である{X1(θ)+X2(θ)}/2を算出する。制御プログラム54は、算出した目標値に、補正係数Jを乗じて目標値を補正する。補正係数Jは、ステップS11で取得したワイヤ掛数である。例えば、ワイヤ掛数が「4」である場合、J=4である。ステップS15の処理は、特許請求の範囲に記載された「補正処理」に相当する。
The control program 54 determines the target value using the generated X1 (θ) and X2 (θ) (S15). Specifically, the control program 54 calculates {X1 (θ) + X2 (θ)} / 2, which is the average value of X1 (θ) and X2 (θ), as the target value. The control program 54 corrects the target value by multiplying the calculated target value by the correction coefficient J. The correction coefficient J is the number of wires hooked in step S11. For example, when the number of wires hooked is "4", J = 4. The process of step S15 corresponds to the "correction process" described in the claims.
制御プログラム54は、リリーフバルブ92を介して、上記通常回路から第1リリーフ回路91に作動油の流路を切り替えて、第1油圧モータ38に供給する油圧を所定圧力未満にする(S16)。流路がリリーフ回路91に切り替えられ、第1油圧モータ38に供給される作動油の圧力が所定圧力未満となると、巻き上げられるワイヤ42に生じる張力が小さくなり、次のステップS17において掛け金具41が破損することが防止される。
The control program 54 switches the flow path of the hydraulic oil from the normal circuit to the first relief circuit 91 via the relief valve 92, and makes the hydraulic pressure supplied to the first hydraulic motor 38 less than a predetermined pressure (S16). When the flow path is switched to the relief circuit 91 and the pressure of the hydraulic oil supplied to the first hydraulic motor 38 becomes less than a predetermined pressure, the tension generated in the wire 42 to be wound becomes smaller, and the hanging metal fitting 41 is moved in the next step S17. It is prevented from being damaged.
制御プログラム54は、第1油圧モータ38を介してメインウインチ39を駆動し、ワイヤ42を巻き上げる(S17)。ワイヤ42が巻き上げられたことにより、フックブロック62は、ワイヤ42に引き起こされた姿勢になる(図8参照)。ステップS16の処理は、特許請求の範囲に記載された「切替処理」に相当する。ステップS17の処理は、特許請求の範囲に記載された「巻上処理」に相当する。
The control program 54 drives the main winch 39 via the first hydraulic motor 38 and winds up the wire 42 (S17). When the wire 42 is wound up, the hook block 62 is in the posture caused by the wire 42 (see FIG. 8). The process of step S16 corresponds to the "switching process" described in the claims. The process of step S17 corresponds to the "winding process" described in the claims.
制御プログラム54は、フックブロック62が引き起こされた姿勢、すなわちワイヤ42の繰り出し長さが上記許容最小距離X1(θ)になった後、メインウインチ39の駆動を停止させる(S18)。例えば、制御プログラム54は、ワイヤセンサ28が検出する検出値からワイヤドラム44の回転速度或いはワイヤ42の繰り出し速度を算出し、算出した回転速度や繰り出し速度がゼロになったことに基づいて、フックブロック62が引き起こされた姿勢であると判断し、メインウインチ39の駆動を停止させる。或いは、制御プログラム54は、メインウインチ39を駆動してからの経過時間が、メモリ52に予め記憶された所定時間に達したことに基づいて、メインウインチ39の駆動を停止させる。或いは、ワイヤ42に加わる張力を検出する張力センサが設けられており、制御プログラム54は、当該張力センサが検出した張力が、メモリ52に予め記憶された所定張力に達したことに基づいて、メインウインチ39の駆動を停止させる。
The control program 54 stops driving the main winch 39 after the posture in which the hook block 62 is triggered, that is, the feeding length of the wire 42 reaches the allowable minimum distance X1 (θ). For example, the control program 54 calculates the rotation speed of the wire drum 44 or the feeding speed of the wire 42 from the detection value detected by the wire sensor 28, and hooks based on the calculated rotation speed and the feeding speed becoming zero. It is determined that the block 62 is in the caused posture, and the drive of the main winch 39 is stopped. Alternatively, the control program 54 stops driving the main winch 39 based on the elapsed time from driving the main winch 39 reaching a predetermined time stored in advance in the memory 52. Alternatively, a tension sensor for detecting the tension applied to the wire 42 is provided, and the control program 54 is based on the fact that the tension detected by the tension sensor reaches a predetermined tension stored in advance in the memory 52. The drive of the winch 39 is stopped.
制御プログラム54は、第1油圧モータ38を介してメインウインチ39を駆動し、ステップS15で決定した目標値だけワイヤ42を繰り出す(S19)。具体的には、制御プログラム54は、メインウインチ39を駆動させるとともに、ワイヤセンサ28が出力するパルス信号をカウントし、カウント値が示すワイヤ42の繰り出し長さが上記目標値に達したことに基づいて、メインウインチ39の駆動を停止させる。ステップS19の処理は、特許請求の範囲に記載された「繰出処理」に相当する。
The control program 54 drives the main winch 39 via the first hydraulic motor 38, and pays out the wire 42 by the target value determined in step S15 (S19). Specifically, the control program 54 drives the main winch 39, counts the pulse signal output by the wire sensor 28, and is based on the fact that the payout length of the wire 42 indicated by the count value reaches the above target value. Then, the drive of the main winch 39 is stopped. The process of step S19 corresponds to the "delivery process" described in the claims.
ステップS19が実行されることにより、フックブロック62は、上記引き起こされた姿勢と上記寝た姿勢との間の中間姿勢(図10参照)となる。フックブロック62が中間姿勢にあれば、ワイヤ42に生じる張力により掛け金具41が破損するまでワイヤ42の巻取代ができ、かつワイヤ42が弛んで乱巻きが発生するまで操出代ができる。なお、乱巻きとは、ワイヤ42がワイヤドラム44に不規則に巻き取られた状態などを意味する。
By executing step S19, the hook block 62 becomes an intermediate posture (see FIG. 10) between the raised posture and the sleeping posture. When the hook block 62 is in the intermediate position, the winding allowance of the wire 42 can be obtained until the hook metal fitting 41 is damaged by the tension generated in the wire 42, and the maneuvering allowance can be obtained until the wire 42 is loosened and irregular winding occurs. The random winding means a state in which the wire 42 is irregularly wound around the wire drum 44.
制御プログラム54は、リリーフバルブ92を介して第1リリーフ回路91から上記通常回路に作動油の流路を切り替えて、第1油圧モータ38に供給する油圧を所定圧力にする(S20)。制御プログラム54は、ステップS13で取得した起伏角度θ及びステップS12でメモリ52から読み出したL、A、B、K、Fを用いてdX1(θ)/dt及びdX2(θ)/dtを生成する(S21)。制御プログラム54は、dX1(θ)/dt及びdX2(θ)/dtの平均値である{dX(θ)/dt+dX2(θ)/dt}/2に上記補正係数Jを乗じたJ×{dX(θ)/dt+dX2(θ)/dt}/2を算出する(S22)。すなわち、制御プログラム54は、フックブロック62が上記中間姿勢を維持するワイヤ42の繰り出し速度を算出する。
The control program 54 switches the flow path of the hydraulic oil from the first relief circuit 91 to the normal circuit via the relief valve 92, and sets the hydraulic pressure supplied to the first hydraulic motor 38 to a predetermined pressure (S20). The control program 54 generates dX1 (θ) / dt and dX2 (θ) / dt using the undulation angle θ acquired in step S13 and L, A, B, K, and F read from the memory 52 in step S12. (S21). The control program 54 is J × {dX obtained by multiplying {dX (θ) / dt + dX2 (θ) / dt} / 2, which is the average value of dX1 (θ) / dt and dX2 (θ) / dt, by the correction coefficient J. (Θ) / dt + dX2 (θ) / dt} / 2 is calculated (S22). That is, the control program 54 calculates the feeding speed of the wire 42 in which the hook block 62 maintains the intermediate posture.
制御プログラム54は、ブーム32が一定の角速度Fで起立するように、起伏シリンダ36を所定速度で伸長させる(S23)。制御プログラム54は、ワイヤ42の繰り出し速度が{dX1(θ)/dt+dX2(θ)/dt}/2に上記補正係数Jを乗じたJ×{dX1(θ)/dt+dX2(θ)/dt}/2となるように第1油圧モータ38を介してメインウインチ39を駆動させ(S24)、ワイヤ42を繰り出す。ステップS23、S24の処理は、特許請求の範囲に記載された「駆動処理」に相当する。
The control program 54 extends the undulating cylinder 36 at a predetermined speed so that the boom 32 stands up at a constant angular velocity F (S23). In the control program 54, the feeding speed of the wire 42 is J × {dX1 (θ) / dt + dX2 (θ) / dt} /, which is obtained by multiplying {dX1 (θ) / dt + dX2 (θ) / dt} / 2 by the correction coefficient J. The main winch 39 is driven (S24) via the first hydraulic motor 38 so as to be 2, and the wire 42 is unwound. The processing of steps S23 and S24 corresponds to the "driving processing" described in the claims.
次に、制御プログラム54は、ワイヤセンサ28が検出した検出値からワイヤ42の繰り出し長さWを算出する(S25)。制御プログラム54は、算出した繰り出し長さWがJ×X1(θ)以上J×X2(θ)以下であるか否かを判断する(S26)。すなわち、制御プログラム54は、掛け金具41が破損せず、かつ乱巻きが生じない範囲でワイヤ42が繰り出されているか否かを判断する。
Next, the control program 54 calculates the payout length W of the wire 42 from the detection value detected by the wire sensor 28 (S25). The control program 54 determines whether or not the calculated extension length W is J × X1 (θ) or more and J × X2 (θ) or less (S26). That is, the control program 54 determines whether or not the wire 42 is unwound within a range in which the hanging metal fitting 41 is not damaged and irregular winding does not occur.
制御プログラム54は、繰り出し長さWがJ×X1(θ)以上J×X2(θ)以下でないと判断すると(S26:No)、ブーム32の起立及びメインウインチ39の駆動を停止させる停止処理を実行し(S27)、ブーム展開処理を終了する。なお、フローチャートには示されていないが、制御プログラム54は、停止処理を実行したことに基づいて、エラー報知を行う。エラー報知は、例えば、ブーム展開処理を停止したことを示すエラー画面を不図示のディスプレイに表示させ、或いはエラー音を不図示のスピーカから出力させることによって行われる。
When the control program 54 determines that the extension length W is not J × X1 (θ) or more and J × X2 (θ) or less (S26: No), the control program 54 performs a stop process for stopping the standing of the boom 32 and the driving of the main winch 39. It is executed (S27), and the boom expansion process is terminated. Although not shown in the flowchart, the control program 54 performs error notification based on the execution of the stop process. The error notification is performed, for example, by displaying an error screen indicating that the boom expansion process has been stopped on a display (not shown) or outputting an error sound from a speaker (not shown).
制御プログラム54は、繰り出し長さWがJ×X1(θ)以上J×X2(θ)以下であると判断すると(S26:Yes)、ステップS13で取得した起伏角度θが、メモリ52に記憶された所定起立角度φに到達したか否かを判断する(S28)。制御プログラム54は、起伏角度θが所定起立角度φに到達していないと判断すると(S28:No)、ステップS131、S141、S211、S221の処理を実行する。ステップS131、S141、S211、S221の処理は、ステップS13、S14、S21、S22の処理と同じ処理である。すなわち、制御プログラム54は、ブーム32が所定起立位置に到達していない場合(S28:No)、起伏角度θを再度取得して関数X1(θ)、関数X2(θ)、dX(θ)/dt、dX2(θ)/dt、J×{dX1(θ)/dt+dX2(θ)/dt}/2を生成或いは算出する。制御プログラム54は、ブーム32が所定起立位置に到達するまで、ステップS131、S141、S211、S221の一連の処理を、例えば数m秒から数十m秒の一定の時間間隔で繰り返し実行する。
When the control program 54 determines that the feed length W is J × X1 (θ) or more and J × X2 (θ) or less (S26: Yes), the undulation angle θ acquired in step S13 is stored in the memory 52. It is determined whether or not the predetermined standing angle φ has been reached (S28). When the control program 54 determines that the undulation angle θ has not reached the predetermined standing angle φ (S28: No), the control program 54 executes the processes of steps S131, S141, S211 and S221. The processing of steps S131, S141, S211 and S221 is the same as the processing of steps S13, S14, S21 and S22. That is, when the boom 32 has not reached the predetermined standing position (S28: No), the control program 54 acquires the undulation angle θ again and obtains the function X1 (θ), the function X2 (θ), dX (θ) /. dt, dX2 (θ) / dt, J × {dX1 (θ) / dt + dX2 (θ) / dt} / 2 are generated or calculated. The control program 54 repeatedly executes a series of processes of steps S131, S141, S211 and S221 at regular time intervals of, for example, several msec to several tens of msec until the boom 32 reaches a predetermined standing position.
制御プログラム54は、起伏角度θが所定起立角度φに到達したと判断すると(S28:Yes)、起伏シリンダ36及び第1油圧モータ38を介してブーム32及びメインウインチ39の駆動を停止させ(S29)、ブーム展開処理を終了する。
When the control program 54 determines that the undulation angle θ has reached the predetermined standing angle φ (S28: Yes), the control program 54 stops driving the boom 32 and the main winch 39 via the undulation cylinder 36 and the first hydraulic motor 38 (S29). ), End the boom deployment process.
次に、図7が示すブーム格納処理について説明がされる。なお、ブーム展開処理(図6参照)で説明された処理と同一の処理については、同一の符号を付して説明が省略される。
Next, the boom storage process shown in FIG. 7 will be described. The same processes as those described in the boom expansion process (see FIG. 6) are designated by the same reference numerals and the description thereof will be omitted.
制御プログラム54は、ブーム展開処理で説明されたステップS11からS22までの処理を実行する。次に、制御プログラム54は、起伏シリンダ36を所定速度で縮小し、ブーム32を一定の角速度Fで倒伏させる(S31)。
The control program 54 executes the processes from steps S11 to S22 described in the boom expansion process. Next, the control program 54 reduces the undulating cylinder 36 at a predetermined speed and causes the boom 32 to lie down at a constant angular velocity F (S31).
制御プログラム54は、ワイヤ42の巻き取り速度がJ×{dX1(θ)/dt+dX2(θ)/dt}/2となるように第1油圧モータ38を介してメインウインチ39を駆動させる(S32)。すなわち、制御プログラム54は、フックブロック62が中間姿勢(図10参照)を維持する速度でメインウインチ39にワイヤ42を巻き取らせる。
The control program 54 drives the main winch 39 via the first hydraulic motor 38 so that the winding speed of the wire 42 becomes J × {dX1 (θ) / dt + dX2 (θ) / dt} / 2 (S32). .. That is, the control program 54 causes the main winch 39 to wind the wire 42 at a speed at which the hook block 62 maintains an intermediate posture (see FIG. 10).
制御プログラム54は、上記ステップS25、S26、S27の処理を実行する。制御プログラム54は、ステップS26において繰り出し長さWがJ×X1(θ)以上J×X2(θ)以下であると判断すると(S26:Yes)、ステップS13で取得した起伏角度θが、ゼロに達したか否かを判断する(S33)。すなわち、制御プログラム54は、ブーム32が格納位置まで倒されたか否かを判断する。制御プログラム54は、起伏角度θがゼロに達していないと判断すると(S33:No)、ステップS131、S141、S211、S221の処理を実行する。ステップS131、S141、S211、S221の処理は、ステップS13、S14、S21、S22の処理と同じ処理である。すなわち、制御プログラム54は、ブーム32が格納位置に到達していない場合(S33:No)、起伏角度θを再度取得して関数X1(θ)、関数X2(θ)、dX(θ)/dt、dX2(θ)/dt、J×{dX1(θ)/dt+dX2(θ)/dt}/2を生成或いは算出する。制御プログラム54は、ブーム32が格納位置に到達するまで、ステップS131、S141、S211、S221の一連の処理を、例えば数m秒から数十m秒の時間間隔で繰り返し実行する。
The control program 54 executes the processes of steps S25, S26, and S27. When the control program 54 determines in step S26 that the feed length W is J × X1 (θ) or more and J × X2 (θ) or less (S26: Yes), the undulation angle θ acquired in step S13 becomes zero. It is determined whether or not it has been reached (S33). That is, the control program 54 determines whether or not the boom 32 has been tilted to the retracted position. When the control program 54 determines that the undulation angle θ has not reached zero (S33: No), the control program 54 executes the processes of steps S131, S141, S211 and S221. The processing of steps S131, S141, S211 and S221 is the same as the processing of steps S13, S14, S21 and S22. That is, when the boom 32 has not reached the storage position (S33: No), the control program 54 acquires the undulation angle θ again and obtains the function X1 (θ), the function X2 (θ), and dX (θ) / dt. , DX2 (θ) / dt, J × {dX1 (θ) / dt + dX2 (θ) / dt} / 2 is generated or calculated. The control program 54 repeatedly executes a series of processes of steps S131, S141, S211 and S221 at time intervals of, for example, several msec to several tens of msec until the boom 32 reaches the storage position.
制御プログラム54は、起伏角度θがゼロに達したと判断すると(S33:Yes)、起伏シリンダ36及び第1油圧モータ38を通じてブーム32及びメインウインチ39の駆動を停止させ(S29)、ブーム格納処理を終了する。
When the control program 54 determines that the undulation angle θ has reached zero (S33: Yes), the control program 54 stops driving the boom 32 and the main winch 39 through the undulation cylinder 36 and the first hydraulic motor 38 (S29), and performs the boom retracting process. To finish.
[実施形態の作用効果]
[Action and effect of the embodiment]
ステップS17の処理(巻上処理)が実行されることにより、ワイヤ42の繰り出し長さが許容最小距離であるX1(θ)になるまでワイヤ42が巻き上げられ、ワイヤ42が張られる。そして、生成処理で生成した許容最小距離であるX1(θ)と許容最大距離であるX2(θ)との平均値に応じた長さ(目標値)だけワイヤ42が繰り出されることにより、フックブロック62が上記中間姿勢にされる。その結果、コントローラ50は、ブーム32の自動展開や自動格納が実行される前に、ワイヤ42が張り過ぎずかつ弛み過ぎないようにすることができる。
By executing the process (winding process) of step S17, the wire 42 is wound up until the feeding length of the wire 42 reaches X1 (θ), which is the minimum allowable distance, and the wire 42 is stretched. Then, the wire 42 is unwound by the length (target value) corresponding to the average value of the allowable minimum distance X1 (θ) and the allowable maximum distance X2 (θ) generated in the generation process, thereby causing the hook block. 62 is placed in the above intermediate posture. As a result, the controller 50 can prevent the wire 42 from being over-tensioned and not over-slackened before the boom 32 is automatically deployed or retracted.
また、コントローラ50は、メモリ52に記憶されたブーム32の長さL、第1指定値であるA、B、及び第2指定値であるKに基づいて許容最小距離であるX1(θ)及び許容最大距離であるX2(θ)を生成するから、ブーム32の種類やフックブロック62の種類や掛け金具41の種類に応じた長さL、第1指定値A、B、及び第2指定値Kをメモリ52に記憶させることにより、コントローラ50は、ブーム32の種類やフックブロック62の種類や掛け金具41の種類に拘わりなく、許容最小距離X1(θ)及び許容最大距離(θ)を算出して目標値を設定することができる。したがって、コントローラ50は、ブーム装置12の種類に拘わりなく、ブーム32を安全に自動展開/格納させることができる。すなわち、コントローラ50は、種々のブーム装置に使用することができる。
Further, the controller 50 has X1 (θ) and X1 (θ) which are the minimum allowable distances based on the length L of the boom 32 stored in the memory 52, A and B which are the first designated values, and K which is the second designated value. Since X2 (θ), which is the maximum allowable distance, is generated, the length L, the first designated values A and B, and the second designated value according to the type of the boom 32, the type of the hook block 62, and the type of the hook 41 are generated. By storing K in the memory 52, the controller 50 calculates the allowable minimum distance X1 (θ) and the allowable maximum distance (θ) regardless of the type of the boom 32, the type of the hook block 62, and the type of the hook 41. And the target value can be set. Therefore, the controller 50 can safely automatically deploy / retract the boom 32 regardless of the type of the boom device 12. That is, the controller 50 can be used for various boom devices.
また、ワイヤ42が巻き上げられる前に、ステップS16の処理(切替処理)によって、第1油圧モータ38に供給される作動油の圧力が所定値圧力未満にされる。したがって、ステップS17の処理(巻上処理)において掛け金具41が破損することが防止される。
Further, before the wire 42 is wound up, the pressure of the hydraulic oil supplied to the first hydraulic motor 38 is set to less than the predetermined value pressure by the process (switching process) of step S16. Therefore, it is possible to prevent the hanging metal fitting 41 from being damaged in the process (winding process) of step S17.
また、第2指定値である「K」は、フックブロック62の種類と掛け金具41の種類とに基づいた値であるので、どのような種類のフックブロック62及び掛け金具41が使用されても、許容最小距離X1(θ)及び許容最大距離X2(θ)を適切に生成することができる。
Further, since the second designated value "K" is a value based on the type of the hook block 62 and the type of the hook metal fitting 41, no matter what kind of hook block 62 and the hook metal fitting 41 are used. , The allowable minimum distance X1 (θ) and the allowable maximum distance X2 (θ) can be appropriately generated.
また、ワイヤ42は、フックブロック62が上記中間姿勢を維持するように繰り出され(S24)、或いは巻き取られる(S32)。したがって、ブーム32の自動展開や自動格納において、掛け金具41の破損や乱巻きの発生を確実に防止することができる。
Further, the wire 42 is unwound (S24) or wound (S32) so that the hook block 62 maintains the above intermediate posture. Therefore, in the automatic deployment and automatic storage of the boom 32, it is possible to surely prevent the hanging metal fitting 41 from being damaged or irregularly wound.
また、ステップS15において、取得したワイヤ掛数に基づいて目標値が補正されるので、ワイヤ掛数を変更可能なフックブロック62が使用されても、ブーム32の自動展開や自動格納において、掛け金具41の破損や乱巻きの発生を防止することができる。
Further, in step S15, since the target value is corrected based on the acquired wire hooking number, even if the hook block 62 whose wire hooking number can be changed is used, the hook metal fitting is used in the automatic deployment and storage of the boom 32. It is possible to prevent the 41 from being damaged or the occurrence of random winding.
[変形例1]
[Modification 1]
上記実施形態では、第1指定値A、B(起伏中心Pを原点とした2次元座標系における掛け金具41の一端の位置Qの座標)がメモリ52に記憶された例が説明された。本変形例では、図11が示すように、第1指定値A、B、C(起伏中心Pを原点とした3次元座標系における掛け金具41の一端の位置Qの座標)がメモリ52に記憶される。第1指定値Cは、上記3次元座標系におけるz軸に関する座標を示す。z軸は、クレーン車10の幅方向に沿う軸である。
In the above embodiment, an example in which the first designated values A and B (coordinates of the position Q of one end of the hanging metal fitting 41 in the two-dimensional coordinate system with the undulation center P as the origin) are stored in the memory 52 has been described. In this modification, as shown in FIG. 11, the first designated values A, B, and C (coordinates of the position Q at one end of the hanging bracket 41 in the three-dimensional coordinate system with the undulation center P as the origin) are stored in the memory 52. Will be done. The first designated value C indicates the coordinates related to the z-axis in the above three-dimensional coordinate system. The z-axis is an axis along the width direction of the mobile crane 10.
本変形例では、上記点S(ブーム32の先端位置)の座標は、(Lcosθ,Lsinθ,0)と表される。関数X1(θ)は、点Qと点Sとの間の距離SQから第2指定値Kを減じた値であり、L、A、B、C、θ、Kを用いて算出される。同様に、関数X2(θ)は、図12が示すように点R(ワイヤ42と吊荷用フック40との接続位置)と点Sとの間の距離SRであり、L、A、B、C、K、θを用いて算出される。制御プログラム54は、L、A、B、C、K、θが入力されることによって関数X1(θ)及び関数X2(θ)を生成するクラスを有する。制御プログラム54は、L、A、B、C、K、θ、及びFが入力されることによってdX1(θ)/dt及びdX2(θ)/dtを生成するクラスを有する。制御プログラム54は、ステップS14、S21において、L、A、B、C、K、F、θ及び上記クラスを用いて、X1(θ)、X2(θ)、dX1(θ)/dt、及びdX2(θ)/dtを生成する。
In this modification, the coordinates of the point S (tip position of the boom 32) are expressed as (Lcosθ, Lsinθ, 0). The function X1 (θ) is a value obtained by subtracting the second designated value K from the distance SQ between the points Q and S, and is calculated using L, A, B, C, θ, and K. Similarly, the function X2 (θ) is the distance SR between the point R (the connection position between the wire 42 and the hanging hook 40) and the point S as shown in FIG. 12, L, A, B, and so on. Calculated using C, K, θ. The control program 54 has a class that generates a function X1 (θ) and a function X2 (θ) by inputting L, A, B, C, K, and θ. The control program 54 has a class that generates dX1 (θ) / dt and dX2 (θ) / dt by inputting L, A, B, C, K, θ, and F. The control program 54 uses L, A, B, C, K, F, θ and the above class in steps S14 and S21 to X1 (θ), X2 (θ), dX1 (θ) / dt, and dX2. Generate (θ) / dt.
本変形例では、ブーム32の先端位置と掛け金具41の位置とがクレーン車10の幅方向にずれていても、正確なX1(θ)、X2(θ)、dX1(θ)/dt、及びdX2(θ)/dtを生成することができる。その結果、ブーム32の先端及び掛け金具41の位置がクレーン車10の幅方向にずれていても、掛け金具41の破損や乱巻きの発生を防止することができる。
In this modification, accurate X1 (θ), X2 (θ), dX1 (θ) / dt, and even if the tip position of the boom 32 and the position of the hanging bracket 41 are displaced in the width direction of the crane wheel 10. dX2 (θ) / dt can be generated. As a result, even if the tip of the boom 32 and the position of the hanging metal fitting 41 are displaced in the width direction of the crane wheel 10, it is possible to prevent the hanging metal fitting 41 from being damaged or the occurrence of random winding.
[変形例2]
[Modification 2]
本変形例では、ブーム装置12は、図5が示す第2油圧モータ81、サブウインチ82、及びサブワイヤセンサ80と、図13が示すシーブ85、86、サブフック部材71、及び掛け金具88とをさらに備える。なお、図13では、メインウインチ39、ウインチシーブ43、ワイヤ42、フックブロック62、及び掛け金具41の図示が省略されている。
In this modification, the boom device 12 includes the second hydraulic motor 81 shown in FIG. 5, the sub winch 82, and the sub wire sensor 80, and the sheaves 85 and 86 shown in FIG. 13, the sub hook member 71, and the hook metal fitting 88. Further prepare. In FIG. 13, the main winch 39, the winch sheave 43, the wire 42, the hook block 62, and the hanging metal fitting 41 are not shown.
第2油圧モータ81は、油圧供給装置24から油圧の供給を受けて回転する。第2油圧モータ81は、特許請求の範囲に記載された「第2アクチュエータ」に相当する。
The second hydraulic motor 81 rotates by receiving the supply of hydraulic pressure from the hydraulic pressure supply device 24. The second hydraulic motor 81 corresponds to the "second actuator" described in the claims.
図5が示すように、サブウインチ82は、第2油圧モータ81によって回転されるサブワイヤドラム83と、サブワイヤドラム83に巻き取られたサブワイヤ89と、サブウインチシーブ84とを有する。サブワイヤドラム83から引き出されたサブワイヤ89は、サブウインチシーブ84に巻き掛けられた後、シーブ85に巻き掛けられる。サブウインチ82は、特許請求の範囲に記載された「ウインチ」に相当する。サブワイヤドラム83は、特許請求の範囲に記載された「ワイヤドラム」に相当する。
As shown in FIG. 5, the sub winch 82 has a sub wire drum 83 rotated by a second hydraulic motor 81, a sub wire 89 wound around the sub wire drum 83, and a sub winch sheave 84. The sub-wire 89 drawn from the sub-wire drum 83 is wound around the sub-winch sheave 84 and then around the sheave 85. The sub winch 82 corresponds to the "winch" described in the claims. The sub-wire drum 83 corresponds to the "wire drum" described in the claims.
シーブ85は、第1シーブ63(図1参照)と水平方向に並んでブーム32の先端部に設けられている。シーブ86は、シーブ85と離間してブーム32の先端部に設けられている。シーブ85に巻き掛けられたサブワイヤ89は、シーブ86に巻き掛けられた後、サブフック部材71に繋がれている。
The sheave 85 is provided at the tip of the boom 32 so as to be horizontally aligned with the first sheave 63 (see FIG. 1). The sheave 86 is provided at the tip of the boom 32 apart from the sheave 85. The sub wire 89 wound around the sheave 85 is wound around the sheave 86 and then connected to the sub hook member 71.
サブフック部材71は、サブフック本体72と、サブフック73と、を有する。サブフック73は、サブフック本体72と連結されており、掛け金具88に掛けられる。
The sub-hook member 71 has a sub-hook main body 72 and a sub-hook 73. The sub hook 73 is connected to the sub hook main body 72 and is hung on the hanging metal fitting 88.
サブフック部材71は、ワイヤシーブを有していない。すなわち、サブワイヤ89のワイヤ掛数は常に「1」である。サブフック部材71は、特許請求の範囲に記載された「フック部材」に相当する。サブフック73は、特許請求の範囲に記載された「吊荷用フック」に相当する。
The sub hook member 71 does not have a wire sheave. That is, the number of wires of the sub wire 89 is always "1". The sub-hook member 71 corresponds to the "hook member" described in the claims. The sub-hook 73 corresponds to the "hanging hook" described in the claims.
掛け金具88は、掛け金具41(図1参照)と水平方向に並んで配置されている。掛け金具88の一端は、旋回台31に回動可能に支持されている。サブフック73は、掛け金具88の他端に引っ掛けられる。掛け金具88は、特許請求の範囲に記載された「係止部材」に相当する。
The hanging bracket 88 is arranged side by side with the hanging bracket 41 (see FIG. 1) in the horizontal direction. One end of the hanging bracket 88 is rotatably supported by the swivel base 31. The sub hook 73 is hooked on the other end of the hanging metal fitting 88. The hanging bracket 88 corresponds to the "locking member" described in the claims.
サブワイヤセンサ80(図5参照)は、例えば、サブワイヤドラム83の回転量を検出するロータリエンコーダである。サブワイヤセンサ80は、サブワイヤドラム83の回転に応じて電圧値が変化するパルス信号を出力する。サブワイヤセンサ80は、ケーブルなどの信号線によってコントローラ50と接続されている。コントローラ50は、サブワイヤセンサ80から入力するパルス数からサブワイヤドラム83の回転量を算出し、サブワイヤドラム83の回転量と、サブワイヤドラム83の半径とに基づいてサブワイヤ89の繰り出し長さを算出する。サブワイヤドラム83の半径は、メモリ52に予め記憶される。なお、コントローラ50がサブワイヤ89の繰り出し長さを取得可能であれば、どのような種類のセンサがサブワイヤセンサ80に用いられてもよい。サブワイヤセンサ80は、特許請求の範囲に記載された「ワイヤセンサ」に相当する。
The sub-wire sensor 80 (see FIG. 5) is, for example, a rotary encoder that detects the amount of rotation of the sub-wire drum 83. The sub-wire sensor 80 outputs a pulse signal whose voltage value changes according to the rotation of the sub-wire drum 83. The sub-wire sensor 80 is connected to the controller 50 by a signal line such as a cable. The controller 50 calculates the rotation amount of the sub-wire drum 83 from the number of pulses input from the sub-wire sensor 80, and the feeding length of the sub-wire 89 is based on the rotation amount of the sub-wire drum 83 and the radius of the sub-wire drum 83. Is calculated. The radius of the sub wire drum 83 is stored in the memory 52 in advance. Any kind of sensor may be used for the sub-wire sensor 80 as long as the controller 50 can acquire the feeding length of the sub-wire 89. The sub-wire sensor 80 corresponds to the "wire sensor" described in the claims.
本変形例では、図5が示すように、油圧供給装置24は、第2油圧モータ81に所定圧力の作動油を供給する不図示の通常回路に加え、供給される作動油の圧力を所定圧力未満に低減するために当該作動油をリリーフする第2リリーフ回路93を備える。第2リリーフ回路93は、リリーフバルブ94を有する。リリーフバルブ94は、コントローラ50から入力される駆動信号によって上記通常回路と第2リリーフ回路93との間で流路を切り替える。すなわち、コントローラ50は、駆動信号をリリーフバルブ94に入力することにより、第2油圧モータ81に供給される作動油の圧力を変更することができる。なお、第1リリーフ回路91が、第1油圧モータ38に加え第2油圧モータ81に供給される作動油の圧力を所定圧力未満に低減する場合、第2リリーフ回路93は設けられていなくてもよい。
In this modification, as shown in FIG. 5, in the hydraulic pressure supply device 24, in addition to a normal circuit (not shown) that supplies hydraulic oil at a predetermined pressure to the second hydraulic motor 81, the pressure of the hydraulic oil supplied is set to a predetermined pressure. A second relief circuit 93 for relieving the hydraulic oil is provided in order to reduce the amount to less than. The second relief circuit 93 has a relief valve 94. The relief valve 94 switches the flow path between the normal circuit and the second relief circuit 93 by a drive signal input from the controller 50. That is, the controller 50 can change the pressure of the hydraulic oil supplied to the second hydraulic motor 81 by inputting the drive signal to the relief valve 94. When the first relief circuit 91 reduces the pressure of the hydraulic oil supplied to the second hydraulic motor 81 in addition to the first hydraulic motor 38 to less than a predetermined pressure, the second relief circuit 93 may not be provided. good.
メモリ52は、掛け金具88の一端の点Q’の座標を示すα及びβを第1指定値としてさらに記憶する。メモリ52は、掛け金具88の長さとサブフック部材71の長さとに応じた長さηを第2指定値としてさらに記憶する。
The memory 52 further stores α and β indicating the coordinates of the point Q'at one end of the hanging metal fitting 88 as the first designated value. The memory 52 further stores the length η corresponding to the length of the hanging metal fitting 88 and the length of the sub-hook member 71 as the second designated value.
図14が示すように、ブーム32の基端からシーブ86までの長さをブーム長さMとすると、ブーム32の起伏角度がθである場合のシーブ86の位置を示す点Nの座標は、(Mcosθ,Msinθ)と表せる。一方、サブワイヤ89が引き起こされた姿勢におけるサブワイヤ89の理論上の繰り出し長さである関数Y1(θ)は、点Nと点Q’との間の距離からηを減じた値である。したがって、関数Y1(θ)は、ブーム32の長さM、第1指定値α、β、及び第2指定値ηを用いて表すことができる。
As shown in FIG. 14, where the length from the base end of the boom 32 to the sheave 86 is the boom length M, the coordinates of the point N indicating the position of the sheave 86 when the undulation angle of the boom 32 is θ are It can be expressed as (Mcosθ, Msinθ). On the other hand, the function Y1 (θ), which is the theoretical extension length of the subwire 89 in the posture in which the subwire 89 is triggered, is a value obtained by subtracting η from the distance between the point N and the point Q'. Therefore, the function Y1 (θ) can be expressed using the length M of the boom 32, the first designated values α, β, and the second designated value η.
図15が示すように、サブワイヤ89が寝た姿勢におけるサブワイヤ89の理論上の繰り出し長さである関数Y2(θ)は、点Nと点R’との間の距離である。したがって、関数Y2(θ)は、ブーム長さM、第1指定値α、β、及び第2指定値ηを用いて表すことができる。なお、ブーム長さMがブーム長さLとほぼ同じである場合は、ブーム長さMに代えてブーム長さLが用いられてもよい。
As shown in FIG. 15, the function Y2 (θ), which is the theoretical extension length of the subwire 89 in the lying position, is the distance between the point N and the point R'. Therefore, the function Y2 (θ) can be expressed using the boom length M, the first designated values α, β, and the second designated value η. When the boom length M is substantially the same as the boom length L, the boom length L may be used instead of the boom length M.
制御プログラム54は、関数Y1(θ)、関数Y2(θ)、dY1(θ)/dt、及びdY2(θ)/dtを生成するクラスを有する。なお、制御プログラム54は、関数Y1(θ)及び関数Y2(θ)を生成するクラスを有し、関数Y1(θ)及び関数Y2(θ)を時間tで微分してdY1(θ)/dt及びdY2(θ)/dtを生成してもよい。
The control program 54 has a class that generates a function Y1 (θ), a function Y2 (θ), dY1 (θ) / dt, and dY2 (θ) / dt. The control program 54 has a class that generates a function Y1 (θ) and a function Y2 (θ), and differentiates the function Y1 (θ) and the function Y2 (θ) with respect to time t to dY1 (θ) / dt. And dY2 (θ) / dt may be generated.
制御プログラム54は、ステップS12(図6参照)において、ブーム長さM、第1指定値α、β、及び第2指定値ηをメモリ52からさらに読み出す。制御プログラム54は、ステップS12で読み出したM、α、β、η、Fと、ステップS13で取得した起伏角度θと、上記クラスとを用いてY1(θ)及びY2(θ)をさらに生成する。そして、制御プログラム54は、ステップS15において、目標値としてY1(θ)及びY2(θ)の平均値を算出する。
The control program 54 further reads the boom length M, the first designated values α, β, and the second designated value η from the memory 52 in step S12 (see FIG. 6). The control program 54 further generates Y1 (θ) and Y2 (θ) using the M, α, β, η, F read in step S12, the undulation angle θ acquired in step S13, and the above class. .. Then, the control program 54 calculates the average value of Y1 (θ) and Y2 (θ) as the target value in step S15.
制御プログラム54は、ステップS16において、上記通常回路から第2リリーフ回路93に作動油の流路を切り替え、第2油圧モータ81に供給される作動油の圧力が所定圧力未満に設定される。制御プログラム54は、ステップS17、S18において、目標値だけサブワイヤ89が繰り出されるように第2油圧モータ81を介してサブウインチ82を駆動させる。すなわち、制御プログラム54は、フックブロック62と同様にして、サブフック部材71を中間姿勢にする。制御プログラム54は、ステップS20において、第1リリーフ回路91及び第2リリーフ回路93から上記通常回路に作動油の流路を切り替える。
In step S16, the control program 54 switches the flow path of the hydraulic oil from the normal circuit to the second relief circuit 93, and the pressure of the hydraulic oil supplied to the second hydraulic motor 81 is set to be less than a predetermined pressure. The control program 54 drives the sub winch 82 via the second hydraulic motor 81 so that the sub wire 89 is paid out by the target value in steps S17 and S18. That is, the control program 54 puts the sub-hook member 71 in the intermediate posture in the same manner as the hook block 62. In step S20, the control program 54 switches the flow path of the hydraulic oil from the first relief circuit 91 and the second relief circuit 93 to the normal circuit.
制御プログラム54は、ステップS21において、dY1(θ)/dt及びdY2(θ)/dtをさらに生成する。制御プログラム54は、ステップS22において{dY1(θ)/dt+dY2(θ)/dt}/2をさらに算出し、ステップS24において、{dY1(θ)/dt+dY2(θ)/dt}/2でサブワイヤ89が繰り出される回転速度でサブワイヤドラム83を回転させる。すなわち、制御プログラム54は、サブフック部材71が中間姿勢を維持するようにサブウインチ82を駆動させる。
The control program 54 further generates dY1 (θ) / dt and dY2 (θ) / dt in step S21. The control program 54 further calculates {dY1 (θ) / dt + dY2 (θ) / dt} / 2 in step S22, and in step S24, the subwire 89 is {dY1 (θ) / dt + dY2 (θ) / dt} / 2. The sub-wire drum 83 is rotated at the rotation speed at which the sub-wire drum 83 is fed. That is, the control program 54 drives the sub winch 82 so that the sub hook member 71 maintains the intermediate posture.
制御プログラム54は、ステップS25において、サブワイヤセンサ80が検出したサブワイヤ89の繰り出し長さIをさらに取得する。制御プログラム54は、ステップS26において、取得した繰り出し長さIがY1(θ)以上Y2(θ)以下であるか否かをさらに判断する。制御プログラム54は、Y1(θ)≦I≦Y2(θ)でないと判断すると(S26:No)、停止処理(S27)を実行し、Y1(θ)≦I≦Y2(θ)であると判断すると(S26:Yes)、ステップS28以降の処理を実行する。
The control program 54 further acquires the feeding length I of the sub wire 89 detected by the sub wire sensor 80 in step S25. The control program 54 further determines in step S26 whether or not the acquired payout length I is Y1 (θ) or more and Y2 (θ) or less. When the control program 54 determines that Y1 (θ) ≦ I ≦ Y2 (θ) is not (S26: No), the control program 54 executes the stop process (S27) and determines that Y1 (θ) ≦ I ≦ Y2 (θ). Then (S26: Yes), the processes after step S28 are executed.
本変形例では、いわゆるメインフックであるフックブロック62とサブフック部材71とを備えるクレーン車10であっても、メインウインチ39及びサブウインチ82の両方のウインチにおいて乱巻きの発生を防止でき、かつ、掛け金具41、88の破損を防止することができる。
In this modification, even in the mobile crane 10 provided with the hook block 62 which is a so-called main hook and the sub hook member 71, it is possible to prevent the occurrence of random winding in both the main winch 39 and the sub winch 82, and It is possible to prevent the hanging metal fittings 41 and 88 from being damaged.
なお、クレーン車10は、フックブロック62とともにサブフック部材71を有していてもよいし、フックブロック62に代えてサブフック部材71を有していてもよい。
The mobile crane 10 may have a sub-hook member 71 together with the hook block 62, or may have a sub-hook member 71 instead of the hook block 62.
[その他の変形例]
[Other variants]
上記実施形態では、コントローラ50は、ワイヤ42の繰り出し長さが目標値となるように起伏シリンダ36及び第1油圧モータ38の駆動を制御してブーム32の自動展開及び自動格納を行う。しかしながら、コントローラ50は、他の制御によって、ブーム32の自動展開及び自動格納を行ってもよい。すなわち、ステップS21以降の処理については、実施形態で説明した処理以外の処理が実行されてもよい。例えば、コントローラ50は、メモリ52に予め記憶された所定の伸縮速度及び回転速度で起伏シリンダ36及び第1油圧モータ38の駆動を制御してブーム32の自動展開及び自動格納を行ってもよい。
In the above embodiment, the controller 50 controls the drive of the undulating cylinder 36 and the first hydraulic motor 38 so that the feeding length of the wire 42 becomes a target value, and automatically deploys and retracts the boom 32. However, the controller 50 may automatically deploy and retract the boom 32 by other controls. That is, for the processes after step S21, processes other than the processes described in the embodiment may be executed. For example, the controller 50 may control the drive of the undulating cylinder 36 and the first hydraulic motor 38 at a predetermined expansion / contraction speed and rotation speed stored in advance in the memory 52 to automatically deploy and retract the boom 32.
上記実施形態では、上記点Sの座標は、ブーム32の長さLと起伏角度θとを用いて(Lcosθ,Lsinθ)で表された。ただし、第1シーブ63の中心を(Lcosθ,Lsinθ)として、点Sの座標を(Lcosθ+G1,Lsinθ+G2)として関数X1(θ)及び関数X2(θ)が生成されてもよい。ここで、「G1」及び「G2」は、第1シーブ63の中心と第2シーブ65の中心との差分であり、定数としてメモリ52に予め記憶される。
In the above embodiment, the coordinates of the point S are represented by (Lcos θ, Lsin θ) using the length L of the boom 32 and the undulation angle θ. However, the function X1 (θ) and the function X2 (θ) may be generated with the center of the first sheave 63 as (Lcosθ, Lsinθ) and the coordinates of the point S as (Lcosθ + G1, Lsinθ + G2). Here, "G1" and "G2" are differences between the center of the first sheave 63 and the center of the second sheave 65, and are stored in advance in the memory 52 as constants.
上記実施形態では、ステップS23、S31において、ブーム32が一定の角速度Fで起伏するように起伏シリンダ36が所定速度で伸縮される。ただし、起伏シリンダ36が一定の速度で伸縮されてもよい。その場合、起伏シリンダ36の伸縮の速度からブーム32の角速度(dθ/dt)が算出され、算出された角速度が上記角速度F(定数)に代えて用いられ、dX1(θ)/dtやdX2(θ)/dtが生成或いは算出される。
In the above embodiment, in steps S23 and S31, the undulating cylinder 36 is expanded and contracted at a predetermined speed so that the boom 32 undulates at a constant angular velocity F. However, the undulating cylinder 36 may be expanded and contracted at a constant speed. In that case, the angular velocity (dθ / dt) of the boom 32 is calculated from the expansion / contraction speed of the undulating cylinder 36, and the calculated angular velocity is used in place of the above angular velocity F (constant), and dX1 (θ) / dt or dX2 ( θ) / dt is generated or calculated.
また、ステップS23、S31において、ブーム32は、オペレータが操作する操縦装置15によって起伏されてもよい。その場合、制御プログラム54は、操縦装置15から入力する信号であって、オペレータの操作量に応じた信号に基づいた起伏速度(角速度)で起伏シリンダ36を起伏させる。この角速度(dθ/dt)が上記角速度Fに代えて用いられて、dX1(θ)/dtやdX2(θ)/dtを生成或いは算出する。
Further, in steps S23 and S31, the boom 32 may be undulated by the control device 15 operated by the operator. In that case, the control program 54 undulates the undulating cylinder 36 at an undulating speed (angular velocity) based on the signal input from the control device 15 and corresponding to the operation amount of the operator. This angular velocity (dθ / dt) is used in place of the above angular velocity F to generate or calculate dX1 (θ) / dt and dX2 (θ) / dt.
上記実施形態では、許容最小距離であるX1(θ)及び許容最大距離であるX2(θ)の平均値に応じた値が目標値として算出される。しかしながら、許容最小距離であるX1(θ)側に寄った値が目標値とされてもよいし、許容最大距離であるX2(θ)側に寄った値が目標値とされてもよい。例えば、J×{X1(θ)+X2(θ)}×2/3やJ×{X1(θ)+X2(θ)}×1/3が目標値とされてもよい。
In the above embodiment, a value corresponding to the average value of the allowable minimum distance X1 (θ) and the allowable maximum distance X2 (θ) is calculated as the target value. However, the value closer to the X1 (θ) side, which is the allowable minimum distance, may be set as the target value, or the value closer to the X2 (θ) side, which is the allowable maximum distance, may be set as the target value. For example, J × {X1 (θ) + X2 (θ)} × 2/3 or J × {X1 (θ) + X2 (θ)} × 1/3 may be set as the target value.
上記実施形態では、上記点Qの座標を示す第1指定値A、Bがメモリ52に記憶される。ただし、関数X1(θ)及び関数X2(θ)を生成可能であれば、第1指定値A、Bに代えて他の値が第1指定値としてメモリ52に記憶されていてもよい。例えば、原点である点Pから点Qまでの距離及び所定角度がメモリ52に記憶されていてもよい。ここで、所定角度とは、例えば、直線PQが水平面となす角度(俯角)である。
In the above embodiment, the first designated values A and B indicating the coordinates of the point Q are stored in the memory 52. However, if the function X1 (θ) and the function X2 (θ) can be generated, other values may be stored in the memory 52 as the first designated values instead of the first designated values A and B. For example, the distance from the point P to the point Q, which is the origin, and a predetermined angle may be stored in the memory 52. Here, the predetermined angle is, for example, an angle (depression angle) formed by the straight line PQ with the horizontal plane.
上記実施形態では、掛け金具41は、回動可能に旋回台31に設けられている。ただし、掛け金具41は、旋回台31に固定されていてもよい。この場合、掛け金具41の他端の位置が点Qとされ、第2指定値Kは、フックブロック62の長さとされる。したがって、掛け金具41が旋回台31に固定される場合であっても、コントローラ50は、ブーム展開処理及びブーム格納処理において、掛け金具41の破損やワイヤ42の乱巻きの発生を防止することができる。
In the above embodiment, the hanging metal fitting 41 is rotatably provided on the swivel base 31. However, the hanging metal fitting 41 may be fixed to the swivel base 31. In this case, the position of the other end of the hanging metal fitting 41 is the point Q, and the second designated value K is the length of the hook block 62. Therefore, even when the hanging metal fitting 41 is fixed to the swivel base 31, the controller 50 can prevent the hanging metal fitting 41 from being damaged or the wire 42 from being randomly wound in the boom expansion process and the boom retracting process. can.
また、掛け金具41は、車体20やキャビン13など、旋回台31以外に設けられていてもよい。
Further, the hanging metal fitting 41 may be provided in a vehicle body 20, a cabin 13, or the like other than the swivel table 31.
また、フックブロック62は、掛け金具41を用いずに、旋回台31や車体20やキャビン13等に設けられたバーなどに直接掛けられて係止されてもよい。その場合、当該バーの位置が点Qとされ、かつ第2指定値K=0として関数X1(θ)や関数X2(θ)等が算出される。
Further, the hook block 62 may be locked by being directly hung on a bar provided on the swivel table 31, the vehicle body 20, the cabin 13, or the like without using the hanging metal fitting 41. In that case, the position of the bar is set to the point Q, and the function X1 (θ), the function X2 (θ), and the like are calculated with the second designated value K = 0.
10・・・クレーン車
12・・・ブーム装置
24・・・油圧供給装置
26・・・ブーム長さセンサ
27・・・起伏角センサ
28・・・ワイヤセンサ
31・・・旋回台
32・・・ブーム
36・・・起伏シリンダ
38・・・第1油圧モータ
39・・・メインウインチ
40・・・吊荷用フック
41・・・掛け金具
42・・・ワイヤ
43・・・ウインチシーブ
44・・・ワイヤドラム
50・・・コントローラ
52・・・メモリ
54・・・制御プログラム
71・・・サブフック部材
73・・・サブフック
80・・・サブワイヤセンサ
81・・・第2油圧モータ
82・・・サブウインチ
83・・・サブワイヤドラム
88・・・掛け金具
89・・・サブワイヤ
91・・・第1リリーフ回路
92・・・リリーフバルブ
93・・・第2リリーフ回路
94・・・リリーフバルブ 10 ...Crane wheel 12 ... Boom device 24 ... Hydraulic supply device 26 ... Boom length sensor 27 ... Rough angle sensor 28 ... Wire sensor 31 ... Swing table 32 ... Boom 36 ... Undulating cylinder 38 ... First hydraulic motor 39 ... Main winch 40 ... Crane hook 41 ... Hanging bracket 42 ... Wire 43 ... Winch sheave 44 ... Wire drum 50 ... Controller 52 ... Memory 54 ... Control program 71 ... Sub hook member 73 ... Sub hook 80 ... Sub wire sensor 81 ... Second hydraulic motor 82 ... Sub winch 83 ... Sub-wire drum 88 ... Hanging bracket 89 ... Sub-wire 91 ... First relief circuit 92 ... Relief valve 93 ... Second relief circuit 94 ... Relief valve
12・・・ブーム装置
24・・・油圧供給装置
26・・・ブーム長さセンサ
27・・・起伏角センサ
28・・・ワイヤセンサ
31・・・旋回台
32・・・ブーム
36・・・起伏シリンダ
38・・・第1油圧モータ
39・・・メインウインチ
40・・・吊荷用フック
41・・・掛け金具
42・・・ワイヤ
43・・・ウインチシーブ
44・・・ワイヤドラム
50・・・コントローラ
52・・・メモリ
54・・・制御プログラム
71・・・サブフック部材
73・・・サブフック
80・・・サブワイヤセンサ
81・・・第2油圧モータ
82・・・サブウインチ
83・・・サブワイヤドラム
88・・・掛け金具
89・・・サブワイヤ
91・・・第1リリーフ回路
92・・・リリーフバルブ
93・・・第2リリーフ回路
94・・・リリーフバルブ 10 ...
Claims (8)
- 台座と、
当該台座に支持され、倒伏位置と所定起立位置との間で起伏動作可能なブームと、
ワイヤドラムに巻き取られ、上記ブームの先端部に巻きかけられたワイヤを有するウインチと、
上記ワイヤに設けられた吊荷用フックを有するフック部材と、
上記ブームを起伏させる第1アクチュエータと、
上記ウインチを駆動する第2アクチュエータと、
上記台座に設けられ、上記吊荷用フックが係止される係止部材と、
上記ブームの起伏角度に応じた検出値を出力する起伏角センサと、
上記ワイヤの繰り出し長さに応じた検出値を出力するワイヤセンサと、を備えたブーム装置に搭載されるコントローラであって、
上記ブームの長さ、上記ブームの起伏中心を基準とする上記係止部材の位置に応じた第1指定値、及び上記フック部材の種別と上記係止部材の種別との少なくとも一方に応じた第2指定値を予め記憶するメモリを有しており、
上記起伏角センサの検出値から特定した上記ブームの起伏角度と、上記ブームの長さと、上記第1指定値及び第2指定値と、に基づいて、上記ブームの先端基準位置から上記フック部材までの許容最小距離及び許容最大距離を生成する生成処理と、
上記許容最小距離まで上記ワイヤを巻き上げる巻上処理と、
上記許容最小距離と上記許容最大距離との差に応じた目標値だけ上記ワイヤを繰り出す繰出処理と、を実行する、コントローラ。 With the pedestal
A boom that is supported by the pedestal and can be undulated between the laid-down position and the predetermined standing position,
A winch with a wire wound around a wire drum and wound around the tip of the boom.
A hook member having a hanging hook provided on the wire, and
The first actuator that raises and lowers the boom,
The second actuator that drives the winch and
A locking member provided on the pedestal to which the hanging hook is locked, and
An undulation angle sensor that outputs a detection value according to the undulation angle of the boom, and
A controller mounted on a boom device equipped with a wire sensor that outputs a detection value according to the wire feeding length.
The length of the boom, the first designated value according to the position of the locking member with respect to the undulating center of the boom, and the first according to at least one of the type of the hook member and the type of the locking member. 2 It has a memory to store the specified value in advance,
From the tip reference position of the boom to the hook member based on the undulation angle of the boom specified from the detection value of the undulation angle sensor, the length of the boom, and the first designated value and the second designated value. And the generation process to generate the allowable minimum distance and the allowable maximum distance of
The hoisting process for winding the wire up to the minimum allowable distance and
A controller that executes a feeding process of feeding out the wire by a target value according to the difference between the allowable minimum distance and the allowable maximum distance. - 上記許容最小距離は、上記ワイヤが張られて上記フック部材が起こされた姿勢における上記ブームの先端部から上記フック部材までの距離であり、
上記許容最大距離は、上記フック部材が寝た姿勢における上記ブームの先端部から上記フック部材までの距離である、請求項1に記載のコントローラ。 The allowable minimum distance is the distance from the tip of the boom to the hook member in the posture in which the wire is stretched and the hook member is raised.
The controller according to claim 1, wherein the allowable maximum distance is a distance from the tip end portion of the boom to the hook member in a posture in which the hook member is lying down. - 上記ブーム装置は、
上記第2アクチュエータに作動油を供給する油圧供給装置をさらに備えており、
上記油圧供給装置は、上記第2アクチュエータに供給する作動油を所定圧力未満に低減するリリーフバルブを備えたリリーフ回路を有しており、
流路を上記リリーフ回路に切り替える切替処理を実行した後、上記巻上処理を実行する、請求項1または2に記載のコントローラ。 The boom device is
It is further equipped with a hydraulic pressure supply device that supplies hydraulic oil to the second actuator.
The hydraulic pressure supply device has a relief circuit provided with a relief valve that reduces the hydraulic oil supplied to the second actuator to less than a predetermined pressure.
The controller according to claim 1 or 2, wherein the hoisting process is executed after the switching process of switching the flow path to the relief circuit is executed. - 上記第2指定値は、上記フック部材の長さと上記係止部材の長さとの和に応じた値である、請求項1から3のいずれかに記載のコントローラ。 The controller according to any one of claims 1 to 3, wherein the second designated value is a value corresponding to the sum of the length of the hook member and the length of the locking member.
- 上記繰出処理の実行後、上記ワイヤセンサの検出値から特定した上記ワイヤの繰り出し長さが上記目標値を維持するように、上記第1アクチュエータ及び第2アクチュエータを駆動させる駆動処理をさらに実行する、請求項1から4のいずれかに記載のコントローラ。 After executing the feeding process, a driving process for driving the first actuator and the second actuator is further executed so that the feeding length of the wire specified from the detection value of the wire sensor maintains the target value. The controller according to any one of claims 1 to 4.
- ワイヤ掛数を取得する取得処理と、
上記ワイヤ掛数に基いて上記目標値を補正する補正処理と、をさらに実行する、請求項1から5のいずれかに記載のコントローラ。 The acquisition process to acquire the number of wires, and
The controller according to any one of claims 1 to 5, further performing a correction process for correcting the target value based on the number of wires. - 請求項1から6のいずれかに記載のコントローラと、上記台座、上記ブーム、上記ウインチ、上記フック部材、上記第1アクチュエータ、上記第2アクチュエータ、上記係止部材、上記起伏角センサ、及び上記ワイヤセンサと、を備えたブーム装置。 The controller according to any one of claims 1 to 6, the pedestal, the boom, the winch, the hook member, the first actuator, the second actuator, the locking member, the undulation angle sensor, and the wire. A boom device with a sensor.
- 請求項7に記載のブーム装置を備えたクレーン車。 A mobile crane equipped with the boom device according to claim 7.
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JP2020191734A JP7533156B2 (en) | 2020-11-18 | 2020-11-18 | Controller, boom device, and crane vehicle |
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Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS49101453U (en) * | 1972-12-22 | 1974-08-31 | ||
JPH07172775A (en) * | 1993-12-17 | 1995-07-11 | Komatsu Ltd | Boom storage and expansion device of crane |
WO2020027335A1 (en) * | 2018-08-02 | 2020-02-06 | 株式会社タダノ | Operation assistance module, image generation application, and work machine |
-
2020
- 2020-11-18 JP JP2020191734A patent/JP7533156B2/en active Active
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2021
- 2021-10-11 WO PCT/JP2021/037563 patent/WO2022107494A1/en active Application Filing
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS49101453U (en) * | 1972-12-22 | 1974-08-31 | ||
JPH07172775A (en) * | 1993-12-17 | 1995-07-11 | Komatsu Ltd | Boom storage and expansion device of crane |
WO2020027335A1 (en) * | 2018-08-02 | 2020-02-06 | 株式会社タダノ | Operation assistance module, image generation application, and work machine |
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