JP2001173010A - Twin-arm work machine with control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a work machine for construction work conducting two works individually and concurrently by controlling two work arms with a coupled structure, capable of exerting safe and relatively large force, and adaptable to wide-range work very efficiently by controlling an arm lever. SOLUTION: This twin-arm work machine is provided with a first work machine 11 revolvably mounted with a revolving superstructure 14 on a travel vehicle body 13 and erectably supported with a work arm 8 constituted of a boom 16 and an arm 17 on the revolving superstructure 14, a second work machine 12 arranged adjacently to the first work machine 11 and having nearly the same structure, a coupling body 2 connecting the travel vehicle bodies 13 of the work machines 11, 12 together, and an operation section 7 having operation levers 21 operating the work machines 11, 12 on the right and left. At least one of the operation levers 21 is the arm lever 38 formed into a multi-link shape and outputting link angle states individually, and a control device 76 controlling the movement of the corresponding work arm 8 according to the output of the arm lever 38 is provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a revolving structure in which a revolving body is mounted on a traveling vehicle body via a revolving bearing so as to be revolvable about a longitudinal axis, and the revolving body comprises a boom and an arm at the tip thereof. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a working machine for performing work such as civil engineering work and construction work in which a working arm is supported so as to be able to move up and down, and a control device therefor.

[0002]

2. Description of the Related Art Conventionally, a working machine for construction work of a hydraulic excavator system such as a back hood is operated by an operator operating two operating levers to operate one boom or arm. Excavation and crushing were performed using a special attachment attached to the tip of the arm according to the work.

A hydraulic excavator for performing an excavation operation shown at 10 in FIG. 17 is mounted on a traveling vehicle body 13 so that a revolving body 14 can revolve around a vertical axis (in a direction indicated by r1 in FIG. 17) via a revolving bearing. And the boom 16 is positioned near the revolving axis of the revolving unit 14.
One work arm 8, which can be bent freely, comprising an arm 17 at the tip of the work arm 8 is supported so as to be able to move up and down.

[0004] Attachment (clamping and crushing device) shown at 18 in the figure is attached to the tip of the arm 17 according to the work. Then, the operator 20 operates two operation levers 21 from the seat 22 provided on the revolving unit 14, and expands and contracts through the plurality of hydraulic cylinders 19 attached to the boom 16 and the arm 17. The working arm 8 is operated so as to be freely refracted in the directions indicated by r2 and r4 in the drawing.

Generally, a command is issued to one work arm 8 by two operation levers as shown by 21a and 21b in FIG. 18, and in the figure, the bucket 24 is operated by a right operation lever 21a. Up and down or boom 16
Of the arm 17 is selected by the left operating lever 21b, or one of the left and right swings of the revolving unit 14 is selected. In this way, the work arm 8 is activated in accordance with the commands (directions indicated by r1, r2, r4, and r5 in the drawing) selected one by one by the two left and right operation levers 21.

Further, foot pedals indicated by reference numerals 23a and 23b in FIG. 18 actuate axles provided on the left and right sides of the traveling vehicle body 13 to perform forward / backward traveling or left / right turning traveling via a caterpillar indicated by 26 in FIG. And 2 in FIG.
The pedal indicated by 3a operates the caterpillar 26a on the right side of the traveling vehicle body 13, and the pedal indicated by 23b operates the caterpillar 26b on the left side of the traveling vehicle body 13.

[0007] Here, reference numeral 3 in FIG. 17 denotes a traveling frame of the traveling vehicle body 13 that supports the revolving superstructure 14.

On the other hand, a hydraulic shovel type working machine performs various tasks such as digging, crushing, dismantling, and lifting by replacing the attachment 18, and in recent years, another working arm has been arranged on the working machine. By switching to a work arm equipped with another attachment for each process and performing work,
A configuration has also been proposed that aims to improve work efficiency by eliminating the trouble of replacing attachments.

In the above-mentioned conventional technology, one worker operates one work arm to perform one work according to the attached attachment.

[0010]

In the construction of the conventional working machine such as a hydraulic excavator, various kinds of work such as excavation, crushing, dismantling, and lift are performed by exchanging attachments, but only one work is performed. It has a configuration and is not always efficient in terms of quickly processing work, and has many problems.

That is, for example, in the dismantling work of a hard side wall such as concrete, a spherical iron weight is lifted at the tip of an arm via a rope, and the amplitude is increased while gradually swinging the weight in a repetitive turning operation. It is known to disassemble by hitting the weight against the side wall when it becomes, but the work of shaking the weight involves danger to surrounding objects, and it is difficult to control the amount of energy at the time of collision,
In such an operation, there is a danger that the side wall itself may be collapsed by an impact and fall down, and there is a problem in that the operation can be performed by swinging the weight efficiently.

In addition, when the concrete piece is lifted and moved by the attachment for clamping the broken side wall, the steel frame material embedded in the concrete piece hinders the moving operation. Therefore, the worker moves the concrete piece after waiting for the cutting of the steel frame material. However, there is a problem that the worker must keep the lifted concrete piece until the manual cutting operation is completed. Further, in this case, when the concrete piece is pinched by one work arm, when the center of gravity of the object is different from the pinch point, the moment force acts on the pinch point, and the pinch point tends to slip. It is very dangerous if the object is heavy. For this reason, while the concrete piece must be sandwiched by a large force, the object is easily broken, and especially in the assembly work in which the construction member or the like must be supported to match a predetermined frame, the construction member is opposed to the moment force. Must be kept in the desired position,
In order to prevent slippage, it is necessary to pinch the construction member with strong force, and the construction member is easily crushed or damaged at the holding part,
In addition, there is a problem that when the strength of the construction member is held against the moment, the construction member is cracked around.

Further, in the lifting work, when lifting a heavy object with a rope or the like, if the work arm is extended forward to lift the heavy object, the machine body center of gravity of the working machine is shifted forward, and there is a danger of falling. Further, there is a problem that the work implement itself is easily shaken and fall down due to the swing of the lifted heavy object. Further, if the center of gravity of the aircraft shifts forward, there is a problem that the lift force is reduced and the swing of the lifted heavy object sometimes causes the heavy equipment to fall apart and fall.

Further, in the dismantling work of a building, etc., the dismantling work using a crushing tool at the tip of the arm lifted to a high position includes:
Since there is a risk of falling crushed concrete debris, it is necessary to crush and treat the structure little by little patiently and patiently, but this is a time-consuming and inefficient operation. On the other hand, in order to tear the building material side wall at a desired position, it is difficult to tear the side wall unless the side wall is fixed at the desired position, and there is no other way but to gradually cut the work with a crusher or cutter. In addition, when the building material is not fixed at all, the crusher cannot be crushed unless the tip of the crusher is fitted along the crack, so that there is a problem that the work of holding the building material is not effective and the work is very inefficient.

[0015] As described above, in the conventional configuration, it can be seen in examples of shaking the weight, holding the object, preventing the swing of the lifted object and preventing the body from overturning, or the trouble of the crushing operation. In the dismantling work and the assembling work, the work by the conventional working machine is very inefficient and has many problems in that the work is processed quickly.

On the other hand, Japanese Patent Application Laid-Open No. H4-70452 discloses an apparatus in which one work arm is provided with two types of devices, a digging bucket and a lift device. By operating only one of them, it is intended to switch and use it. However, in such a configuration, for example, it is not possible to prevent the swing of the item lifted by the lift device by sandwiching the swing with the bucket device. This is a structure in which when the work arm is moved, both devices are moved at the same time, and as described above, it is a configuration that can cope with only one work, and does not solve the various problems described above.

[0017] Japanese Patent Application Laid-Open No. H5-89543 and Japanese Unexamined Patent Application Publication No. H8-3
Japanese Patent Application Laid-Open No. 11919 is known, but in these publications, a work point is selectively operated by any one of work arms provided before and after, and intermittently. One of the work arms is selected to perform the work in the continuous process. In this configuration, when different identical processes occur continuously, it is possible to save the trouble of replacing the attachment.However, as for each work, the work efficiency is not different from that of the conventional hydraulic excavator. The working machine configuration can handle only one job, and does not solve the various problems described above.

Further, in Japanese Utility Model Laid-Open No. H5-89544, a second work arm having a different shape from one work arm is provided on the work point side. Actual opening H
It is not necessary for the operator to take a posture to a position inverted to a work point by a turning operation as in Japanese Patent Application Laid-Open No. 5-89543, but the above publication structure has a bucket and a breaker as attachments of a work arm. In the same manner as described above, one of the attachments is selectively selected and the hydraulic circuit is switched to perform the operation. Therefore, it cannot be said that the above-mentioned various problems are similarly solved.

That is, Japanese Utility Model Application Laid-Open No. H5-89543, Japanese Patent Application Laid-Open No.
In Japanese Patent Application Publication No. 9544, one working machine is provided with two working arms. However, in one working machine, the hydraulic pressure generated by one engine is limited, and two working arms are used. Cannot be operated simultaneously and efficiently, and only one working arm can be operated by switching the hydraulic circuit. Further, it can be said that it is difficult to arrange the two working arms at a suitable position for working at the same point, because the risk of falling increases due to the position of the center of gravity of the machine body. In addition, the one provided with the above-mentioned two working arms has a problem that the body is difficult to transport in a bulky manner.

On the other hand, as a working machine provided with an arm lever for operating a multi-link working arm by the movement of an arm, Japanese Unexamined Utility Model Publication No. S60-172866 and Japanese Unexamined Patent Publication H3-140525 have been disclosed.
The publication discloses the structure. In any of these, regardless of the state of the link angle of the boom or arm, grasp the tip of the arm lever with a structure that matches the work arm by hand, and operate only the position and posture of the tip of the arm according to the work point. Although it was proposed from the viewpoint of improving work efficiency and preventing erroneous operation, for beginners, the operation method is easy and work efficiency is improved,
Even if only the operation lever is simplified, the skilled worker does not always have a configuration that improves the working efficiency, and does not solve, for example, the various problems described above.

Therefore, as a working machine for civil engineering work or construction work, even in an aging society where there is a concern that there will be a shortage of workers, two workers can work efficiently with one person.
It has been desired to have a configuration in which two operations can be performed individually and simultaneously at the same operation point.

According to the present invention, two work arms in a connected configuration are controlled to perform two works individually and simultaneously, and a relatively large force can be exerted safely. In addition, the arm lever control enables extremely efficient and wide range operation. The purpose of the present invention is to provide a working machine for construction work adapted to various works.

[0023]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems of the prior art, a twin-arm working machine with a control device according to the present invention is arranged such that a revolving body turns around a vertical axis via a revolving bearing on a running vehicle body. A first work machine, which is mounted so as to be capable of being bent, and which is supported on a revolving structure by a revolving work arm comprising a boom and an arm at the tip of the boom, and a first work machine adjacent to the first work machine;
A second working machine having substantially the same structure as the first working machine;
A connecting body that connects the traveling body of the first working machine and the traveling body of the second working machine, an operating lever that operates the working arm of the first working machine, and a working arm of the second working machine. An operation unit having both an operation lever and an operation lever for operating the work arm located on the right side is on the right side of the operation unit, and an operation lever for operating the work arm located on the left side is on the left side of the operation unit. And at least one of the left and right operation levers is configured as an arm lever that is formed in a multi-link shape and individually outputs each link angle state, and according to the output of the arm lever. And a control device for controlling the operation of the corresponding work arm, and arm lever control of the work arm and the attachment provided at the tip thereof.

[0024] The state of the link angle of the arm lever provided in the form of multiple links is captured by the expansion and contraction displacement of the wire mechanism provided in each link, and the work arm and the attachment are controlled, or The arm lever is provided so as to be minutely displaceable in substantially the same bending direction as the working arm, and the state of the minute link angle is determined by the relative voltage value change of the voltage value of the rotation angle detector provided in each link portion. The state of the link angle of the arm lever provided by being able to catch and control the work arm or the attachment, or provided to be able to bend to the same bending angle in substantially the same direction as the boom or the arm of the work arm, and provided in a multi-link shape It is equipped with a rotation angle detector provided at each link and a rotation angle detector provided at each link of the work arm and attachment, which captures the shape of the device by the absolute value of the voltage value. Or formed by controlling in accordance with the deviation of the voltage value of the rotation angle detector of the above two, it is preferable that either.

On the other hand, an operation switch provided separately at the tip of the arm lever so as to be operable with a fingertip is provided, and the operation arm is controlled to stop when the operation switch is operated, regardless of the state of the arm lever. The operation is locked, and an operation switch is provided at the end of the arm lever so that it can be operated with a fingertip.The operation force of the attachment at the end of the work arm is maintained with a constant force regardless of the state of the arm lever. Then, the operation of the attachment of the working arm is continued, so that the operation is safe and easy to operate.

[0026]

FIG. 1 shows an embodiment of the present invention.
This will be briefly described with reference to FIGS.

[0027] Twin arm working machine 1 with control device of the present invention
A revolving unit 14 is mounted on a traveling body 13 so as to be revolvable about a vertical axis via a revolving bearing, and is used for construction work or the like.
7, a first work machine 11 (hydraulic shovel-based work machine), which is supported so as to be able to move freely, and has an attachment 18 at the tip of an arm 17;
A second working machine 12 (a second hydraulic shovel-based working machine) adjacent to the first working machine 11 and having substantially the same structure as the first working machine 11, and a traveling vehicle body of the first working machine 11; 13th and 2nd
A connecting body 2 for connecting the traveling vehicle body 13 of the working machine 12 with
The operating unit 7 disposed on the coupling body 2 having both the operating lever 21 for hydraulically operating the working arm 5 of the first working machine 11 and the operating lever 21 for hydraulically operating the working arm 6 of the second working machine 12. The right operation lever 21a for operating the work arm 5 of the work machine 11 located on the right side with respect to the direction of the operation section 7 is operated by the work machine 12 located on the right side and the left side of the operation section 7. Left operating lever 21 for operating arm 6
b is disposed on the left side of the operation unit 7, and the operation lever 21 is constituted by an arm lever 38 formed in a multi-link shape and individually outputting each link angle state,
A control device 76 for hydraulically controlling the operation of the corresponding work arm 8 according to the output of the arm lever 38 is provided, and the work arm 8 and the attachment 18 disposed at the tip thereof are controlled by the arm lever.

The work arm 8 and the attachment 18 are controlled by capturing the state of the link angle r of the arm lever 38 provided in the form of multiple links by the expansion and contraction displacement of the wire mechanism 46 provided at each link Li. You may. Alternatively, the arm lever 38 is provided so as to be slightly displaceable in substantially the same bending direction as the working arm 8, and the state of the minute link angle is determined by a rotation angle detector VR (potentiometer) provided in each link Li. The work arm 8 and the attachment 18 (hand body shape) may be controlled by capturing the relative change in the voltage value.

Alternatively, the work arm 8 is provided to be bendable to the same bending angle in the same direction as the boom 16 or the arm 17 of the arm 8,
Link angle r of arm lever 38 provided in a multi-link shape
The shape of the state itself is captured by the absolute value of the voltage value,
A rotation angle detector VR (variable resistor) provided at each link Li, and a rotation angle detector LP (potentiometer) provided at each link of the work arm and the attachment are provided. The control may be performed according to the deviation of the voltage value of the angle detector.

On the other hand, an operation switch 77c separately operable with a fingertip is provided at the tip of the arm lever 38, and the operation arm 8 is forcibly stopped when the operation switch 77c is operated regardless of the state of the arm lever 38. In addition, the operation of the work arm 8 is locked, and an operation switch 77d is provided at the tip of the arm lever 38 so as to be separately operable with a fingertip. The control is performed by forcibly holding the operating force of the attachment 18 at the distal end with a constant force to maintain the operation of the attachment 18 of the working arm 8.

(Operation) With the above configuration, the present invention can perform the following operation. That is, the traveling vehicle body 1
A revolving body 14 is mounted on the revolving body 3 so as to be revolvable, and two working machines 11 and 12 having a revolving body 14 and a working arm 8 composed of a boom 16 and an arm 17 are supported between the revolving body 14 and the connecting body 2. Therefore, a working machine having two working arms 5 and 6 can be realized at a very low development cost, and the stability of the working machine having the connecting structure is
The position of the center of gravity of each working machine is shifted toward the connecting body 2 side,
Supporting each other makes them much safer and much more stable. In this stable structure, the working arm 8 can be provided longer, the working range of the working arm 8 involving turning can be extended, and the long working arm 8 can be used even when there is an obstacle ahead in the traveling direction. By extending the work arm 8 beyond the obstacle to the target point further forward, the work can be performed on the work point at a deeper part. In addition, since each work arm 5, 6 is individually provided on each revolving unit 2, the two work arms 5, 6 can be turned to act on the same work point, or each work arm can be made to act on a different work point. Can be.

A right operating lever 21a for operating the working arm 5 of the working machine 11 located on the right side is provided on the right side of the operating section 7, and a left operating lever 21b for operating the working arm 6 of the working machine 12 located on the left side is provided. Each of the operation levers 21 is provided on the left side of the operation unit 7 and includes an arm lever 38 formed in a multi-link shape and individually outputting each link angle state. In response to the,
A control device 76 for controlling the operation of the corresponding work arm 8 is provided, and the work levers 8 and the attachments 18 provided at their ends are controlled by arm levers, so that the operation levers 21 are respectively disposed on the left and right. Thus, one worker can easily operate the right working arm 5 with the operating lever 21a of the right hand,
By operating each of the left working arms 6 with the left operating lever 21b, both working arms 5, 6 can be controlled individually and simultaneously. Therefore, the loop formed by the two working arms 8 and the connecting body 2 at the time of work can cancel out the reaction force and exert a large working force, and the two connected by the connecting body 2
The work arms 8 can complement each other.

Further, since the operation lever 21 is formed of an arm lever 38 which is formed in a multi-link shape and individually outputs each link angle state, it is possible to operate a plurality of operation levers with both hands. By operating one multi-link lever 38 with one hand, the multi-link angle can be continuously controlled, and the operating lever 21 of the other work arm 8 can be simultaneously controlled with the other hand. .

On the other hand, in such a continuous operation, even if it is a gentle operation, the acceleration is generated to a considerable extent, and the inertia cannot be ignored. Therefore, for example, in the structure of a single working machine in which the center of gravity of the body is close to the base of the boom, the one that causes the reaction force of the inertia of the working arm 8 to be swung in the opposite direction may cause the above-described connection structure. In this case, the distance from the center of gravity to the boom 16 is large, and a stable and safe structure that generates a large torque is provided. In addition, when at least one of the arms performs a continuous operation in accordance with the timing with the arm lever 38, even if the work cannot be fully performed with one working arm, the other arm which is free can be used. Using a corresponding work arm while pressing the ground at a suitable position to cancel the moment, or performing work while supporting it with a fixed object, further increase the distance from the position of the center of gravity of the aircraft, receive the reaction force and A structure is provided between the fixed object, the supporting-side working arm, and the connecting body so as to prevent the occurrence of the wobble. Force can be applied.

That is, the two working arms 5 shown above,
In the configuration provided with the work arm 6, two different works of "performing one work with the work arm 5 and performing another work with the work arm 6" simultaneously and at any work point, This makes it possible to realize a working machine that can control a wide range of work extremely efficiently, which has not been realized with a single work arm conventionally.

If the state of the link angle r of the arm lever 38 provided in the form of multiple links can be captured by the expansion and contraction displacement of the wire mechanism 46 provided at each link Li, for example, hydraulic piping or the like may be drawn. In addition, it is possible to easily manufacture a strong mechanical structure that takes out the displacement of the wire, and is suitable for a part that controls the boom 16 and the arm 17.

Alternatively, the arm lever 38 may be
Is provided so as to be able to be displaced minutely in substantially the same bending direction as that described above, and the state of the minute link angle is determined by the relative voltage value change of the voltage value of the rotation angle detector VR (potentiometer) provided in each link portion Li. As described above, it is possible to cope with the problem by routing the electric wires in the same manner as described above, and it is easy to dispose even a fine link angle, and is suitable for a part such as the attachment 18 where delicate control is required. In addition, it has an electrical structure and can be manufactured at low cost.

Alternatively, the work arm 8 is provided so as to be able to bend to the same bending angle in the same direction as the boom 16 or the arm 17 of the arm 8,
Link angle r of arm lever 38 provided in a multi-link shape
The shape of the state itself is captured by the absolute value of the voltage value,
A rotation angle detector VR provided at each link Li and a rotation angle detector LP provided at each link of the work arm and the attachment are provided in accordance with a deviation between the voltage values of the two rotation angle detectors. If such control is performed, feedback control such as PID control is performed according to, for example, a deviation of the voltage value, so that the link angle difference between the arm lever 38 and the work arm 8 is controlled to be zero. Thus, the work arm 8 can be operated so that the dynamic operation of the arm lever 38, such as swinging or swinging down, follows the operation, and a special effect that can be achieved by a person who has gained a learning effect can be achieved. It is possible to perform control suitable for an application in which the continuous operation of the arm is reflected on the work arm.

As described above, the twin-arm working machine 1 with the control device of the present invention is used as a working machine for civil engineering work or construction work.
Even in an aging society where there is a concern that there will be a shortage of workers, two work machines are connected to each other and two work arms are operated independently, and work can be done efficiently by one person from the operation unit using arm lever control. It is possible to realize a configuration in which two operations are controlled individually and simultaneously.

[0040]

Embodiments of the present invention will be described below in detail with reference to the drawings. 1 to 9 show an embodiment of the present invention. FIG. 1 shows an example in which the present invention is applied to a hydraulic excavator used in civil engineering work and construction work.
In the twin-arm working machine indicated by, a revolving body 14 is mounted on a traveling vehicle body 13 via a revolving bearing so as to be revolvable about a vertical axis, and a boom 16 and an arm 17 at the tip thereof are mounted on the revolving body 14.
A first working machine 11 (hydraulic shovel) having an attachment 18 at the end of an arm 17 and a first working machine 11 adjacent to the first working machine 11; A second working machine 12 (a second hydraulic shovel) having substantially the same structure as the first working machine 11;
The connecting body 2 for connecting the traveling body 13 of the working machine 11 to the traveling body 13 of the second working machine 12, the operating lever 21 for hydraulically operating the working arm 5 of the first working machine 11, and the second work Lever 21 for hydraulically operating the work arm 6 of the machine 12
And an operation unit 7 disposed on the connecting body 2 having both of them.

The right operation lever 21a for operating the work arm 5 of the work machine 11 located on the right side with respect to the direction of the operation unit 7 is moved to the right of the seat 22 of the operation unit 7 shown in FIG. The left operation lever 21b for operating the work arm 6 of the work machine 12 located on the left side is operated by the operation unit 7 shown in FIG.
The operation lever 2 is disposed on the left side of the seat 22 of the
Reference numeral 1 denotes an arm lever 38 which is formed in a multi-link shape and outputs each link angle state individually.
Is provided with a control device 76 for hydraulically controlling the operation of the work arm 8, and the arm lever control of the work arm 8 and the attachment 18 disposed at the tip thereof.

Although the control device 76 is omitted for convenience of illustration, it is stored in the operation unit 7. Also, 23 in FIG.
Is a pair of traveling pedals, and 26 is a caterpillar. Further, the bending direction of each link portion of the working arm 8 is pivotally supported so as to be movable only in one axial direction.

Reference numeral 7 in FIG. 1 denotes an operation unit provided in the cabin 15, which is provided on the connecting body 2. And the connecting part 4 is provided at the left and right end positions of the cabin 15,
It is connected so that it can be cut off at two places, slidably at two places, and fixed in a sliding state. In addition, the connection is performed by the connecting frame 4 of the traveling frame 3 of the first working machine 11.
The side surfaces of the second working machine 12 and the traveling frame 3 are connected in a row by the connecting body 2.

In this movable connection structure in a row, even if the traveling frame 3 is connected, the revolving bodies 14a and 14b located above the traveling frame 3 can freely rotate, and can be turned in the front direction of the operation unit 7 (see FIG. (In the direction indicated by X), both of the two working arms 8 can be turned. In addition, since the body is slidably displaced in accordance with the ground, the stability is excellent, and since all the traveling devices 13 are in the same direction (the direction indicated by X in the drawing), the connection structure is highly mobile.

FIG. 2 shows an example in which the row connection in FIG. 1 is changed to the column connection. Therefore, in FIG. 2, the same reference numerals are given to the same parts as those in FIG. 1, and the detailed description will be omitted.

FIG. 2 shows an operation unit 7 provided in the cabin 15, which is provided on the connecting body 2. And the connecting part 4 is provided at the left and right end positions of the cabin 15,
It is connected so that it can be cut off at two places, slidably at two places, and fixed in a sliding state. In addition, the connection is performed by the connecting frame 4 of the traveling frame 3 of the first working machine 11.
The front and rear surfaces of the second working machine 12 and the traveling frame 3 are connected in tandem by a connecting body 2.

In this tandem movable connection structure, even when the traveling frame 3 is connected, the revolving bodies 14a and 14b located above the traveling frame 3 can freely rotate, and can be turned in the front direction of the operation unit 7 (see FIG. (In the direction indicated by X), both of the two working arms 8 can be turned. Moreover, since the body is slid and displaced in accordance with the ground, the stability is excellent, and all the traveling devices 13 are in the same direction (the direction indicated by Y in the drawing). This is a connection structure suitable for applications where a work point exists.

First, the state of the link angle r shown in FIG. 3 of the arm lever 38 provided in a multi-link shape shown in FIG. 9 is captured by the expansion and contraction displacement of the wire mechanism 46 provided at each link Li. A method for controlling the arm 8 and the attachment 18 will be described.

This is because the proportional directional control valve 48 shown in FIG. 4 receives the wire expansion / contraction signal shown in FIG. 3 and generates an oil passage 48a in FIG. The hydraulic cylinder 19 is pushed in the direction of the arrow in FIG. This causes the corresponding link angle Li of the working arm 8 to bend under the load of the hydraulic cylinder 19. On the other hand, when the wire signal 46 on the opposite side to the one 48a in the figure is input, the oil passage direction of the proportional direction switching valve 48 shown on the opposite side to the one 48a in the figure is selected, and the hydraulic cylinder 19 It is movable in the direction opposite to the direction.

The operation lever indicated by reference numeral 21 in FIG. 4 shows another auxiliary hydraulic passage in which the hydraulic cylinder 19 can move in the direction opposite to the direction of the arrow in the drawing, as described above. This is 38 in FIG.
It is shown that the arm lever indicated by the symbol and the operation lever dedicated to the work machine 11 or the work machine 12 are configured to be compatible with each other. M in FIG. 4 indicates an engine motor 50. Also, 51 is a pump, 52 is a filter,
Reference numeral 53 denotes a relief valve for determining the maximum hydraulic pressure.

Next, an arm lever indicated by reference numeral 38 in FIG. 9 is provided so as to be capable of minute displacement in substantially the same bending direction as the working arm 8, and the state of the minute displacement force at the link angle r shown in FIG. The relative voltage change of the voltage value of the rotation angle detector VR (potentiometer) disposed in the
A method for controlling the work arm 8 and the attachment 18 will be described.

This occurs when the proportional directional control valve indicated by 48 in FIG. 6 receives a signal change indicated by VR in FIG. 5 and the signal input indicated by Sb in FIG. Then, the hydraulic cylinder 19 is pushed in the direction of the arrow in the figure by the hydraulic pressure determined by the proportional valve 48. This causes the corresponding link angle Li of the working arm 8 to bend under the load of the hydraulic cylinder 19. On the other hand, when the signal Sc on the opposite side to the signal 48a in the figure is input, the oil passage direction of the proportional direction switching valve 48 shown on the opposite side to the signal 48a in the figure is selected, and the hydraulic cylinder 19 moves in the arrow direction in the figure. It is movable in the opposite direction.

FIG. 6 shows a method of controlling a hydraulic circuit having a configuration similar to that of FIG. 4, and the same parts are denoted by the same reference numerals and detailed description thereof will be omitted.

Next, an arm lever 38 provided in a multi-link shape as shown in FIG. 9 is provided so as to be able to bend to substantially the same direction and the same bending angle as the boom 16 and the arm 17 of the working arm 8.
In the control of (i), the shape of the state of the link angle itself indicated by r in FIG.
And a rotation angle detector VR (variable resistor) disposed on the work arm 8 and the attachment 1
A method for controlling the rotation angle detector LP (potentiometer) provided in each link unit Li and the rotation angle detector LP according to the deviation of the voltage value of both rotation angle detectors will be described.

This corresponds to the arm lever 3 shown by VR in FIG.
8 is input as a command signal,
First, a deviation e between VR and the current rotation angle LP of the link portion corresponding to the work arm 8 is determined. K in the figure is LP
The signal is converted into a signal of the same level as the VR signal (K ·
LP) proportional constant. This deviation e is subjected to PID (proportional P + integral I + differential D) control to obtain a solution indicated by F in FIG.
The signal is amplified by the AMP indicated by A in the figure and output to the port of the proportional valve (hydraulic servo valve) as a current signal i. The hydraulic cylinder 19 provided on the work arm starts to move by receiving hydraulic pressure. As a result, the work arm is movable and outputs LP in accordance with the movement, and controls so that the deviation indicated by e in FIG.

On the other hand, the arm lever 38 shown in FIG.
An operation switch group 77 separately provided at the tip of the arm so as to be operable with a fingertip is provided, and regardless of the state of the arm lever 38, the operation arm 8 is forcibly stopped when the operation switch 77c shown in FIG. The operation switch 77d shown in FIG. 8B is provided at the tip of the arm lever 38 so as to be operable with a fingertip. Irrespective of this, control is performed by forcibly holding the operating force of the attachment 18 at the distal end of the working arm 8 with a constant force to maintain the operation of the attachment 18 of the working arm 8.
This is because, in response to the forced signal input 77 (operation switch) shown by the dotted line in FIG. 7, the AMP shown in FIG.
This is performed by performing a current output i indicated by. Here, if the forcing signal 77 is a predetermined constant value i, a constant hydraulic pressure proportional to i is output from the proportional valve, while if the forcing signal 77 is a negative signal, i is forcible. And the hydraulic pressure is not output from the proportional valve.

As described above, in the above-described embodiment, by driving the working arm 8 in accordance with the command signal from the arm lever 38, it is possible to perform control to freely operate one working arm with one hand. it can.

In this embodiment, the setting of the signal level of the forcing signal 77 is omitted due to space limitations.
It may be provided so that it can be separately adjusted in the inside, or it may be fixed. Further, the shape of the arm lever is not limited to the shape shown in FIG. Further, the detection of the rotation angle is not limited to the variable resistor VR and the potentiometer LP shown in the embodiment, and may be configured by a trimmer, an encoder, a piezoelectric element, or the like as long as the rotation amount can be obtained as a voltage signal. It does not matter. That is, the present invention is not limited to the above embodiments, and various modifications are possible based on the spirit of the present invention, and these are not excluded from the scope of the present invention.

Next, an application example of the present invention having two working arms in the above-described connection configuration will be described with reference to FIGS.

A1 (first working machine 11), A2 (connecting body 2), A3 (second working machine 1) indicated by a thick dotted line Z in FIG.
2) shows a state where they are connected and fixed to each other. The right working arm 5 is installed on A1 and the left working arm 6 is installed on A3. When the work arms 5 and 6 move in the direction indicated by F1 in the figure (the direction in which the member 75 is contracted), the member 75 gripped by the two work arms changes its reaction (the direction indicated by f in the figure). Will receive it. However, the substantially triangular loop B shown by the right working arm 5-A1-A2-A3-left working arm 6 has a fixed A1-A2-A3, so that the reaction force is not lost and the reaction force is not lost. Cancel the vector and get a large acting force F
1 can be applied to the member 75. Also in the direction indicated by F2 in the figure (direction in which the member 75 is extended), the reaction force is canceled by the substantially triangular loop B and a large force is applied by the two working arms, as in the case of the F1 direction. Can be. Therefore, when compared with a configuration in which two working machines are not connected, for example, a mutual displacement of the body occurs, a reaction force is released, and a large force cannot be applied to an object. Since the relative positions of the working machines are fixed, the working machines can exert a large force without escaping the reaction force.

Further, when a force is applied by the working arms 5 and 6 in the direction indicated by F3 in the drawing (the direction in which the member 75 is bent),
The working arms 5 and 6 can be made to act on substantially the same working point. For example, one of the working arms fixes the member 75 and the other working arm performs the bending process, or both the working arms 5 and 6 In step 6, the bending operation can be performed by applying a bending force. In this way, when the member 75 is in a free state with one working arm, a member that cannot apply a bending force or the like well can be used.
With two working arms, the working force can be easily applied to the working point without escaping.

In a portion indicated by a thick dotted line Z in FIG. 11, a first working machine 11 and a second working machine 12 are fixed by a connecting body 2 shown by oblique lines in the figure, and working arms 5 and 6 are attached thereto. Indicates that each is installed. Here, the bucket 60 lifted by the work arm 5 in the figure is a tool 9 for scooping soil, sand, pebbles, and the like. On the other hand, when the earth and sand in the bucket 60 is heavy, or when the work arm 5 must be fully extended to perform the work, the position of the center of gravity of the body moves forward, and the danger of falling or the bucket 60 shakes. Although there is a risk of spilling earth and sand by tilting, if the structure of the connection structure secures a stable center of gravity, a farther and heavier object can be lifted, and the connection shown in FIG. By holding the bottom side surface of the bucket 60 with the other work arm thus obtained, the lifting operation can be stably performed.

Further, the work arm 6 is provided on a fixed object such as the ground shown by G in the figure, and a fixed loop shown by Y in the figure is formed, so that the center of gravity is fixed, and the object is applied with a large force without danger of falling. You can lift things. This is because, in the case of a normal working machine, a machine that floats when the work arm is extended and hardly obtains a lifting force is supported by a fixed loop indicated by Y in the figure, and a much larger lift is achieved. It produces power. Moreover, since the point indicated by G in the figure is the work arm, it can be provided at any position according to the situation at the work site.

In the portion indicated by the thick dotted line Z in FIG. 12, the first working machine 11 and the second working machine 12 are fixed by a connecting body shown by oblique lines in FIG. 6 indicates that each is installed. Here, one working arm 6 grasps a concrete wall 54 which is a fixed object G, and the other working arm 5 grasps a hammer 55 serving as a breaking tool 9. Here, reference numeral 74 in the figure denotes a rope for preventing the tool 9 from coming off. Therefore, by swinging the boom and the arm, even if the operation is slow, if the swinging operation is performed in a continuous operation as if the snap of the wrist is effective, the tip of the hammer 55 having the elongated handle can be obtained. Can obtain a large acceleration and generate a large destructive force in the direction indicated by the arrow in the figure. This is because the body is not swung in reverse by the reaction of the inertia of the tool 9 and is supported by a fixed loop shown by Z in the drawing because of the connection configuration.
5 is obtained because a large force can be applied to 5. Therefore, the concrete wall 54 hit by the hammer 55 is destroyed, but even if the entire wall is broken and collapses, it does not collapse at once if supported by the work arm 6. Safe work can be performed.

The portion indicated by the thick dotted line Z in FIG. 13 is that the first working machine 11 and the second working machine 12 are fixed by a connecting body shown by oblique lines in the figure, and the working arms 5 and 6 are attached to them. Indicates that each is installed. Here, one working arm 6 grips a concrete piece 56 and the other working arm 5 grips a nipper 58 which is a cutting tool 9. Here, for example, in a building collapsed or dismantled site due to an earthquake disaster, in a work for dismantled material, a steel frame 57 is buried in a concrete piece shown by 56 in the figure, so the work arm 6 is Even if 56 can be lifted in the direction of the arrow in the figure, it is necessary to cut the steel members 57 manually to move them.
Concrete pieces 56 held without human assistance
The steel frame material 57 entangled in the
It can be cut with a nipper 58 using a lever.
Therefore, the work arm 6 can move the concrete piece 56 smoothly and efficiently without interrupting the work.

The portion indicated by the thick dotted line Z in FIG. 14 is that the first working machine 11 and the second working machine 12 are fixed by a connecting body shown by oblique lines in FIG. Indicates that each is installed. Here, one work arm 6 grasps the block 59, and the other work arm 5 assists in assembling the block stack. That is, the work arm 5 has a role of pressing the block 59 assembled in the direction shown by the arrow in the drawing, and prevents the block assembly state from being collapsed, while the work arm 6 supplies the block 59 one after another. Is in charge of Each of them performs two different tasks independently and simultaneously, and the connected working arms move according to the progress of the work and move the work point,
Since the relative positional relationship between the working arms is constant,
The working positional relationship can be easily grasped.

The portion indicated by the thick dotted line Z in FIG. 15 is that the first working machine 11 and the second working machine 12 are fixed by a connecting body shown by oblique lines in FIG. Indicates that each is installed. Here, one of the working arms 6 grasps the dust remover 62 which is the defense tool 9, and the other work arm 5 grasps the nail remover 61 which is the crushing tool 9 to perform work at a high place. Two different tools 9 can be provided on both working arms 5 and 6, and different works can be performed at the same working point. Therefore, the concrete wall 54 located at a high place is dismantled by the nail puller 61 using one of the working arms 5 and dismantled.
The other work arm 6 receives the debris 56 generated by dismantling by the dust collector 62 so as not to fall. Although the treatment of the falling object is an important point related to human life, due to the connection structure, when the work points move one after another to move the dust collector 62 for processing the falling object along the work point, a relative positional relationship is required. Regardless of the traveling movement (in the X direction in the figure), the two working arms 5 and 6 can easily grasp the positional relationship, and can safely and smoothly perform work such as dropping object processing.

The portion indicated by the bold dotted line Z in FIG. 16 shows that the first working machine 11 and the second working machine 12 are fixed by a connecting body shown by oblique lines in FIG. Indicates that each is installed. Here, one work arm 5 grasps the product equipment 63 for building assembling,
The other work arm 6 carries out a lift work while holding the equipment 63 therebetween. If the equipment 63 is to be gripped by only one working arm 5, a rotational moment is generated in the direction indicated by Ri in the figure due to the position of the center of gravity, which makes the equipment 63 slippery. Therefore, it is necessary to pinch the object with a strong force. However, when the product (equipment 63) is likely to be crushed or damaged and the equipment 63 is provided in the Rj direction so as to match the assembling posture, a dotted arrow in FIG. Products shown (Equipment 6
Distortion occurs around the holding position 3), which causes cracks and the like. On the other hand, when supporting the lower side of the equipment 63 with the other work arm 6, the factor of Ri or Ri or the dotted arrow is canceled, and the work arm 63 is preferred with almost no need for the clamping force of the work arm 5. It is possible to maintain the posture. The equipment 63 maintained in the assembling posture maintains the posture until the assembling position (the direction indicated by X in the drawing) because the relative positional relationship between the two working arms 5 and 6 is kept constant in the connection configuration. You can travel and carry.

As described above, in the above-described application example, the two working arms can perform two different kinds of various works by controlling the operation of the connection configuration.

[0070]

According to the present invention, two work arms in a connected configuration are controlled so that two work can be performed individually and simultaneously, and a safe and relatively large force can be exerted. It is possible to provide a work machine for construction work adapted to a wide range of work extremely efficiently.

Further, control for freely operating the two working arms with both hands according to the command signal from the arm lever can be easily realized.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an embodiment of the present invention.

FIG. 2 is a perspective view showing another embodiment.

FIG. 3 is a conceptual diagram showing a wire mechanism.

FIG. 4 is a hydraulic circuit diagram showing the control device.

FIG. 5 is a perspective view showing a method of detecting a link angle.

FIG. 6 is a hydraulic circuit diagram showing the control device.

FIG. 7 is a block diagram showing a control method.

8A is a top view showing a lever switch, and FIG.
FIG.

FIG. 9A is a top view and FIG. 9B is a side view showing an arm lever.

FIG. 10 is a principle view showing an application example.

FIG. 11 is a principle view showing an application example.

FIG. 12 is a principle view showing an application example.

FIG. 13 is a principle view showing an application example.

FIG. 14 is a principle view showing an application example.

FIG. 15 is a principle view showing an application example.

FIG. 16 is a principle view showing an application example.

FIG. 17 is a perspective view showing a conventional example.

FIG. 18 is a perspective view showing the operation unit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Twin arm working machine 2 Connecting body 3 Traveling frame 4 Connecting body 5 First working arm (located on the right side) 6 Second working arm (located on the left side) 7 Operating section 8 Working arm 10 Hydraulic excavator (or backhoe) 11 1st working machine (hydraulic shovel) 12 2nd working machine (hydraulic shovel) 13 traveling vehicle body 14, 14a, 14b revolving unit 15 cabin 16 boom 17 arm 18 attachment 21 operation lever 21a right traveling lever 21b left traveling lever 23 pedal Lever 38 Arm lever 76 Control device

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[Procedure amendment]

[Submission date] March 14, 2001 (2001.3.1.
4)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claim 5

[Correction method] Change

[Correction contents]

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] Claim 6

[Correction method] Change

[Correction contents]

[Procedure amendment 3]

[Document name to be amended] Statement

[Correction target item name] 0004

[Correction method] Change

[Correction contents]

[0004] At the tip of the arm 17, an attachment (holding and crushing device) indicated by 18 in the figure is attached according to the work. The swing body 14 seat seat or al operator 20 provided on the two operating levers 2
By operating 1, the work arm 8 is extended and contracted through a plurality of hydraulic cylinders 19 attached to the boom 16 and the arm 17 so that the work arm 8 can be freely bent in directions indicated by r2 and r4 in the drawing.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0005

[Correction method] Change

[Correction contents]

In general, one working arm 8 is operated by two operating levers as shown by 21a and 21b in FIG.
In the figure, either the vertical movement of the bucket or the vertical movement of the boom 16 is selected by the right operation lever 21a of the seat 22, while the left operation lever 21b is selected. , The vertical movement of the arm 17 or the left and right swing of the swing body 14 is selected. In this way, the work arm 8 is activated in accordance with the commands (directions indicated by r1, r2, r4, and r5 in FIG. 17 ) selected one by one by the two left and right operation levers 21.

[Procedure amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0006

[Correction method] Change

[Correction contents]

[0006] Foot pedals indicated by reference numerals 23a and 23b in FIG. 18 actuate axles provided on the left and right sides of the traveling vehicle body 13 to perform forward / backward traveling or left / right turning traveling via a crawler indicated by 26 in FIG. And 2 in FIG.
The pedal indicated by 3a operates the right crawler 26a of the traveling vehicle body 13, and the pedal indicated by 23b operates the left crawler 26b of the traveling vehicle body 13.

[Procedure amendment 6]

[Document name to be amended] Statement

[Correction target item name] 0016

[Correction method] Change

[Correction contents]

[0016] On the other hand, JP-public H4-70452 (JP-S
Japanese Patent Application Laid-Open No. 63-7427) discloses that one work arm is provided with two types of devices, a digging bucket and a lift device. However, only one of the continuous processes is operated. Then, it is intended to switch and use. However, in such a configuration, for example, it is not possible to prevent the swing of the item lifted by the lift device by sandwiching the swing with the bucket device. This is a structure in which when the work arm is moved, both devices are moved at the same time, and as described above, it is a configuration that can cope with only one work, and does not solve the various problems described above.

[Procedure amendment 7]

[Document name to be amended] Statement

[Correction target item name] 0019

[Correction method] Change

[Correction contents]

That is, Japanese Utility Model Application Laid-Open No. H5-89543, Japanese Patent Application Laid-Open No.
In Japanese Patent Application Publication No. 9544, one working machine is provided with two working arms. However, in one working machine, the hydraulic pressure generated by one engine is limited, and two working arms are used. Cannot be operated simultaneously and efficiently, and only one working arm can be operated by switching the hydraulic circuit. Moreover, the work by placement into a suitable position for working the two working arms at the same point that said to be a difficult construction since the risk of falling in view of the center of gravity of the aircraft is increased.

[Procedure amendment 8]

[Document name to be amended] Statement

[Correction target item name] 0031

[Correction method] Change

[Correction contents]

(Operation) The present invention has the following structure
The following actions can be performed. That is, the revolving unit 14 is mounted on the traveling vehicle body 13 so as to be revolvable, and the revolving unit 1
Since two work machines 11 and 12 each having a work arm 8 composed of a boom 16 and an arm 17 supported on the connection body 4, the two work arms 5 and 6 are connected. It is possible to realize a working machine having a configuration with very low development costs, and furthermore, the stability of the working machine having the connection structure is such that the positions of the centers of gravity of the working machines are shifted toward the connecting body 2 side and supported by each other. Fitting makes it safer and much more stable. In this stable structure, the working arm 8 can be provided longer, the working range of the working arm 8 involving turning can be extended, and the long working arm 8 can be used even when there is an obstacle ahead in the traveling direction. By extending the work arm 8 beyond the obstacle to the target point further forward, the work can be performed on the work point at a deeper part. In addition, since each work arm 5, 6 is individually provided on each revolving unit 14 , the work arms 5, 6 can be turned so as to act on the same work point, or each work arm can be acted on a different work point. Can be.

[Procedure amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0034

[Correction method] Change

[Correction contents]

On the other hand, in such a continuous operation,
Even if the operation is gradual, an acceleration is generated to some extent, and the influence of the reaction cannot be ignored. Therefore, for example, in the structure of a single working machine in which the center of gravity of the body is close to the base of the boom, the one that causes the reaction force from the working arm 8 to be swung in reverse has the above-described connection structure. In this case, the distance between the boom 16 and the center of gravity is large, and the boom 16 has a stable and safe structure that generates a large torque. In addition, when at least one of the arms performs a continuous operation in accordance with the timing with the arm lever 38, even if the work cannot be fully performed with one working arm, the other arm which is free can be used. Using a corresponding work arm while pressing the ground at a suitable position to cancel the moment, or performing work while supporting it with a fixed object, further increase the distance from the position of the center of gravity of the aircraft, receive the reaction force and A structure is provided between the fixed object, the supporting-side working arm, and the connecting body so as to prevent the occurrence of the wobble. Force can be applied.

[Procedure amendment 10]

[Document name to be amended] Statement

[Correction target item name] 0042

[Correction method] Change

[Correction contents]

Although the control device 76 is omitted for the sake of illustration, it is stored in the operation unit 7. In addition, FIG.
3 is a pair of travel pedals, 26 is a crawler . Further, the bending direction of each link portion of the working arm 8 is pivotally supported so as to be movable only in one axial direction.

[Procedure amendment 11]

[Document name to be amended] Statement

[Correction target item name] 0060

[Correction method] Change

[Correction contents]

[0060] indicated by a thick point line in FIG. 10 A1 (first work
) , A2 (connecting body) , and A3 (second working machine) are connected and fixed to each other, and the right working arm 5 is installed on A1 and the left working arm 6 is installed on A3. ing. When the work arms 5 and 6 move in the direction indicated by F1 in the figure (the direction in which the member 75 is contracted), the member 75 gripped by the two work arms changes its reaction (the direction indicated by f in the figure). Will receive it. However, the substantially triangular loop B shown by the right working arm 5-A1-A2-A3-left working arm 6 is fixed between A1-A2-A3, so that the reaction force is not lost and the reaction force is not lost. The combined vector is canceled and a large acting force F1 is applied to the member 75.
Is a structure that can be applied to The direction indicated by F2 in the figure (the direction in which the member 75 is extended) is also changed to the above F1.
As in the case of the direction, the reaction force is canceled by the substantially triangular loop B, and a large force can be applied by the two working arms. Thus, for example, no connection 2
Compared to the configuration with a single work machine, the mutual displacement of the body occurs and the reaction force escapes, so that a large force can not be applied to the object, but the relative positions of the work machines of the connection structure are fixed Therefore, a large force can be exerted without losing the reaction force.

[Procedure amendment 12]

[Document name to be amended] Statement

[Correction target item name] 0062

[Correction method] Change

[Correction contents]

A portion indicated by a thick dotted line Z in FIG.
And the second working machine are fixed by a connecting body indicated by hatching in the figure, and the working arms 5 and 6 are respectively installed on them. Here, the work arm 5 shown in FIG.
The bucket 60 is a tool 9 for scooping soil, sand, pebbles and the like. On the other hand, when the earth and sand in the bucket 60 is heavy, or when the work arm 5 must be fully extended to perform the work, the position of the center of gravity of the body moves forward, and the danger of falling or the bucket 60 shakes. Although there is a risk of spilling earth and sand by tilting, if the structure of the connection structure secures a stable center of gravity, a farther and heavier object can be lifted, and the connection shown in FIG. By holding the bottom side surface of the bucket 60 with the other work arm thus obtained, the lifting operation can be stably performed.

[Procedure amendment 13]

[Document name to be amended] Statement

[Correction target item name] 0064

[Correction method] Change

[Correction contents]

A portion indicated by a thick dotted line Z in FIG.
This indicates that the working machine and the second working machine are fixed by a connecting body indicated by hatched portions in the figure, and that the working arms 5 and 6 are respectively installed on them. Here, one working arm 6 grasps the concrete wall 54 which is the fixed object G,
The other working arm 5 holds a hammer 55 serving as the destruction tool 9. Here, reference numeral 74 in the figure denotes a rope for preventing the tool 9 from coming off. Therefore, by swinging the boom and the arm, even if the operation is slow, if the swinging operation is performed in a continuous operation as if the snap of the wrist is effective, the tip of the hammer 55 having the elongated handle can be obtained. Can obtain a large acceleration and generate a large destructive force in the direction indicated by the arrow in the figure. This is, of reaction from the tool 9
This is obtained because the body is not swung in the reverse direction due to the influence, and is supported by the fixed loop indicated by Y in FIG. The concrete wall 54 hit with a hammer 55
However, even if the entire wall is broken and collapses, if it is supported by the work arm 6, it is possible to perform a safe operation that does not collapse at once.

[Procedure amendment 14]

[Document name to be amended] Statement

[Correction target item name] 0065

[Correction method] Change

[Correction contents]

The portion indicated by the bold dotted line Z in FIG. 13 is such that the first working machine and the second working machine are fixed by a connecting body shown by oblique lines in the figure, and the working arms 5 and 6 are respectively attached thereto. It indicates that it is installed. Here, one working arm 6 grips a concrete piece 56 and the other working arm 5 grips a nipper 58 which is a cutting tool 9.
Here, for example, in a building collapsed or dismantled site due to an earthquake disaster, in a work for dismantled material, a steel frame 57 is buried in a concrete piece shown by 56 in the figure, so the work arm 6 is Even if 56 can be lifted in the direction of the arrow in the figure, the steel members 57 must be cut by hand to move them, but the steel members entangled with the held concrete pieces 56 without human assistance 57 can be cut by another working arm 5 with a nipper 58 using a lever. Therefore, the work arm 6 can move the concrete piece 56 smoothly and efficiently without interrupting the work.

[Procedure amendment 15]

[Document name to be amended] Statement

[Correction target item name] 0066

[Correction method] Change

[Correction contents]

In the part shown by the thick dotted line Z in FIG. 14, the first working machine and the second working machine are fixed by a connection body shown by oblique lines in the figure, and the working arms 5 and 6 are respectively attached to them. It indicates that it is installed. Here, one working arm 6 grasps the block 59 and the other working arm 5
Provides assistance in assembling blocks. That is, the work arm 5 plays a role of pressing the block 59 assembled in the direction indicated by the arrow in the figure, and prevents the assembled state of the block from collapsing.
Is in charge of supplying the blocks 59 one after another.
Each of them performs two different tasks independently and at the same time, and the relative positions of the working arms are constant even when the connected working arms travel and move the working point according to the work progress. Therefore, the working positional relationship can be easily grasped.

[Procedure amendment 16]

[Document name to be amended] Statement

[Correction target item name] 0067

[Correction method] Change

[Correction contents]

In the portion indicated by the thick dotted line Z in FIG. 15, the first working machine and the second working machine are fixed by a connecting body shown by oblique lines in the figure, and the working arms 5 and 6 are respectively attached thereto. It indicates that it is installed. Here, one of the working arms 6 grasps the dust remover 62 which is the defense tool 9, and the other work arm 5 grasps the nail remover 61 which is the crushing tool 9 to perform work at a high place. Two different tools 9 can be provided on both working arms 5 and 6, and different works can be performed at the same working point. Therefore, the concrete wall 54 located at a high place is broken by one nail 61 and dismantled by one working arm 5, and the debris 56 generated by the dismantling is received by a dust collector 62 so as not to drop by the other working arm 6. I have. The treatment of this falling object is an important point related to human life, but because of the connection structure,
When the work points move one after another and the dust collector 62 for processing the falling object is moved along the work point, the two work arms 5 and 6 in a relative positional relationship are moved regardless of the traveling movement (the X direction in the drawing). It is easy to grasp the positional relationship, and it is possible to safely and smoothly perform operations such as handling of falling objects.

[Procedure amendment 17]

[Document name to be amended] Statement

[Correction target item name]

[Correction method] Change

[Correction contents]

In the portion indicated by the thick dotted line Z in FIG. 16, the first working machine and the second working machine are fixed by a connecting body shown by oblique lines in FIG. It indicates that it is installed. Here, one work arm 5 holds the product equipment 63 for building assembling, and the other work arm 6 carries out the lift work while holding the equipment 63. If the equipment 63 is to be gripped by only one working arm 5, a rotational moment is generated in the direction indicated by Ri in the figure due to the position of the center of gravity, which makes the equipment 63 slippery. Therefore, it is necessary to pinch the object with a strong force. However, when the product (equipment 63) is likely to be crushed or damaged and the equipment 63 is provided in the Rj direction so as to match the assembling posture, a dotted arrow in FIG. Distortion occurs around the pinching position of the indicated product (equipment 63), causing cracks and the like. On the other hand, when supporting the lower side of the equipment 63 with the other work arm 6, the factor of Ri or Ri or the dotted arrow is canceled, and the work arm 63 is preferred with almost no need for the clamping force of the work arm 5. It is possible to maintain the posture. The equipment 63 maintained in the assembling posture maintains the posture until the assembling position (the direction indicated by X in the drawing) because the relative positional relationship between the two working arms 5 and 6 is kept constant in the connection configuration. You can travel and carry.

[Procedure amendment 18]

[Document name to be amended] Statement

[Correction target item name] Explanation of sign

[Correction method] Change

[Correction contents]

[Description of Signs] 1 Twin arm working machine 2 Connected body 3 Traveling frame 4 Connecting section 5 First working arm (located on the right) 6 Second working arm (located on the left) 7 Operating section 8 Working arm 10 Hydraulic excavator (Or backhoe) 11 first working machine (hydraulic shovel) 12 second working machine (hydraulic shovel) 13 traveling vehicle body 14, 14a, 14b revolving unit 15 cabin 16 boom 17 arm 18 attachment 21 operating lever 21a right operating lever 21b Left operation lever 23 Pedal lever 38 Arm lever 76 Control device

[Procedure amendment 19]

[Document name to be amended] Drawing

[Correction target item name] FIG.

[Correction method] Change

[Correction contents]

FIG.

 ──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Toshihiko Shimizu 1-115-16-305 Egawa, Shimamoto-cho, Mishima-gun, Osaka F-term (reference) 2D003 AA01 AB03 AB04 BA07 BB10 CA02 DA04 DB04 DC02 EA04 2D012 FA00 2E176 DD01 DD06 DD07

Claims (6)

[Claims] A revolving body is mounted on a traveling vehicle body via a revolving bearing so as to be revolvable about a vertical axis, and a revolving work arm comprising a boom and an arm at the tip of the revolving body is raised and lowered on the revolving body. A first working machine that is supported, a second working machine that is adjacent to the first working machine and that has substantially the same structure as the first working machine, a traveling body of the first working machine, and a second working machine. A connecting body for connecting a traveling vehicle body of the first working machine; an operating lever for operating a working arm of the first working machine;
An operating unit having both an operating lever for operating the working arm of the working machine of the first embodiment, wherein the operating lever for operating the operating arm located on the right side operates the operating arm located on the right side and the left side of the operating unit. Operating lever is disposed on the left side of the operating unit, and at least one of the left and right operating levers is formed as an arm lever that is formed in a multi-link shape and outputs each link angle state individually. A control device for controlling the operation of a corresponding work arm in accordance with the output of the arm lever, wherein the control device controls the work arm and the attachment disposed at the tip thereof by the arm lever. Arm working machine. 2. A work arm and an attachment are controlled by capturing a state of a link angle of an arm lever provided in a multi-link shape by an expansion and contraction displacement of a wire mechanism provided at each link portion. The twin arm working machine with the control device described in the above. 3. An arm lever is provided so as to be minutely displaceable in substantially the same bending direction as the work arm, and a state of a minute link angle is determined by a relative value of a voltage value of a rotation angle detector provided at each link portion. 2. The twin-arm working machine with a control device according to claim 1, wherein the working arm and the attachment are controlled by detecting the voltage value change. 4. The shape of a link angle state of a multi-link arm lever, which is provided so as to be able to bend to substantially the same direction and the same bending angle as a boom or an arm of a working arm, is represented by an absolute value of a voltage value. It comprises a rotation angle detector provided at each link, and a rotation angle detector provided at each link of the work arm and the attachment, according to a deviation between the voltage values of the two rotation angle detectors. The twin-arm working machine with a control device according to claim 1, wherein the twin-arm working machine is controlled by a control. 5. An operation switch provided at the tip of the arm lever so as to be separately operable with a fingertip. The operation switch is controlled to stop when the operation switch is operated, regardless of the state of the arm lever. 5. The twin-arm working machine with a control device according to claim 1, wherein the operation is locked. 6. An operation switch provided at the tip of the arm lever so as to be separately operable with a fingertip, and maintains the operating force of the attachment at the tip of the working arm with a constant force regardless of the state of the arm lever. 6. The operation of the attachment of the working arm is continued.
The twin arm working machine with the control device described in the above.