KR20110074041A - Unmanned controlling system of joystick to be applied to machinery - Google Patents

Abstract

PURPOSE: An automatic control system of an operating lever for operating an instrument is provided to prevent neglect accidents and protect a worker against a dangerous working environment by installing a removable operating unit on an operating lever and remote-controlling the removable operating unit. CONSTITUTION: An automatic control system of an operating lever for operating an instrument comprises a removable operating unit(120) and a control unit. The removable operating unit is attached/detached to/from an operating lever(105). The removable operating unit operates the operating lever. The control unit is separated form the instrument. The control unit remote-controls the removable operating unit and controls the operating lever. The removable operating unit comprises a lever coupling unit(130), a driving unit(150) and a support unit(170). The lever coupling unit is removably coupled to the operating lever. The driving unit drives the lever coupling unit. The support unit makes the driving unit remain on the support.

Description

Unmanned controlling system of joystick to be applied to machinery}

The present invention relates to an unmanned steering system of an operation lever for operating an apparatus, and more particularly, by mounting a mounting operation unit to an existing operation lever and remotely controlling the mounting operation unit, an operator has a high risk of working environment. An unmanned steering system of a control lever for operating an apparatus capable of preventing exposure to the apparatus.

In general, heavy construction equipment such as excavators, cranes, etc. are widely used in industrial sites, particularly construction or site. Since the environment in which such heavy construction equipment is used is exposed to many hazards, the person operating the heavy equipment should take special care. This is because the probability of a safety accident is greater than that of other industries unless special care is taken.

Thus, a number of methods for efficiently performing the work while preventing the worker from being subjected to safety accidents during the work are being considered as well as being practiced.

One method that is actually being implemented is to control the operation of such construction equipment from the outside, rather than having the worker take the construction equipment directly. That is, it is a method of unmanned construction heavy equipment.

Conventionally, there are two main methods for unmanned remote control of construction heavy equipment.

The first is a conversion type, in which the existing mechanical hydraulics are replaced with electrohydraulics to enable remote control of the system itself, and various control devices for controlling the electrohydraulics are mounted.

Secondly, the mounting type is equipped with a robot arm type manipulator in the existing construction heavy equipment to operate the control lever or to operate a control lever by riding a robot such as a humanoid robot instead of the manipulator.

However, in the aforementioned first unmanned control method, there is not only the complexity of completely changing the existing mechanical device to the new electro-hydraulic device, but also the existing system cannot be used, and the type and number that can be applied. There is a problem in that there is a limit.

In addition, in the above-described second unmanned control method, the development of a manipulator or a humanoid robot for manipulating the operation lever is not only difficult, but also difficult to mount, and expensive actuators are required to implement such a structure. There is a problem. In addition, there is a problem that the worker is difficult to carry directly.

Accordingly, there is a need for development of a new unmanned steering system that can be applied to an existing system and is easy to carry, and can also accurately perform the operation of the device by remote control from an external device such as heavy equipment.

An object of the present invention, by mounting a mounting operation unit to the existing operation lever and remotely controlling such a mounting operation unit, it is possible to prevent the operator from being exposed to a work environment with a high risk factor, it is not a safety accident occurs It is to provide an unmanned control system of the control lever for operating the device that can be prevented.

In addition, another object of the present invention is to provide an unmanned control system of the operation lever for operating the device that can accurately operate the mounting operation unit mounted on the operation lever such as heavy equipment from the outside, thereby improving the efficiency and accuracy of the operation. It is.

In addition, another object of the present invention, by having a structure to use the mounting operation unit mounted on the existing operation lever can utilize the existing system as it is, according to the unmanned operation lever for operating the device that can implement a cost saving effect To provide a steering system.

In addition, another object of the present invention is to provide an unmanned steering system of the operation lever for operating the device that can be carried by the operator by having a structure that is easy to carry the mounting operation unit and the operation unit control unit for controlling the same.

An unmanned steering system of an operating lever for operating a device according to an embodiment of the present invention includes: a mounted operation unit detachably coupled to an operating lever for driving a device to operate the operating lever; And an operation unit control unit arranged to be spaced apart from the device to adjust the operation lever coupled to the mounting operation unit by remotely controlling the mounting operation unit. By mounting the unit and remotely manipulating these mounted operating units, the operator can be prevented from being exposed to high-risk work environments, preventing accidents from occurring and reducing the efficiency and accuracy of the work. Can be improved.

Here, the mounting operation unit, the lever coupling portion detachably coupled to the operation lever; A driving unit driving the lever coupling unit; And a support for supporting the driving unit on a support on which the operation lever is mounted. Such a mounted operation unit is not only detachable to the operation lever but also small in size and easy to carry.

The lever engaging portion, the lever fixing member fixed to the operation lever; A moving shaft coupled to the lever fixing member, wherein a portion coupled to the lever fixing member is rotatably coupled to the lever fixing member; And a portion may be movably coupled to the drive unit, the other portion may include a joint portion for transmitting the driving force generated by the drive unit by the movable shaft is movably coupled to the moving shaft.

The joint part may include a linear bush to which the moving shaft is movably coupled in an axial direction; A first joint coupled to the linear bush to tilt the linear bush in one direction when a driving force is transmitted from the driving unit; And a second joint coupled to the linear bush in the horizontal direction of the first joint and tilting the linear bush in the other direction in the horizontal direction of the one direction when a driving force is transmitted from the driving unit. The moving shaft connected to the lever can be precisely positioned.

The drive unit, the drive body is supported by the support, the joint portion is movably coupled to the inside; A first driving motor mounted to the driving body and generating a driving force for tilting the first joint; A second driving motor mounted to the driving body and generating a driving force for tilting the second joint; A first transmission part transmitting a driving force of the first driving motor to the first joint; And a second transmission unit configured to transfer the driving force of the second driving motor to the second joint, and the driving force of the driving unit may be smoothly transmitted to the lever coupling unit according to this configuration.

The drive body, the drive frame is coupled to the support to form a frame; A rotation reference member coupled to four sides of the driving frame and rotatably coupled to shaft center protrusions protruding from both sides of the first joint and the second joint; And a pair of tilting protrusions respectively coupled to a side of the four side parts of the driving frame in which the first transfer part and the second transfer part are disposed, and protruding from one side of the first joint and the second joint. It may include a coupling plate is formed through holes to be coupled.

The first transmission unit and the second transmission unit, respectively, the pinion gear is coupled to the moving shaft of the first drive motor and the second drive motor; A joint tilting member coupled to the pair of tilting protrusions at an outer side of the coupling plate, wherein a part of the outer side is formed with a gear; And a connecting member having a first transmission gear engaged with the pinion gear and a second transmission gear engaged with the gear of the joint tilting member.

A first encoder coupled to the rotation reference member to measure a tilting degree of the shaft projection of the first joint; A second encoder coupled to the rotation reference member to measure a degree of tilting of the shaft projection of the second joint; And a controller configured to control driving of the first driving motor and the second driving motor based on information from the first encoder and the second encoder. The degree of tilting can be precisely controlled.

The support unit, a support plate on which the drive unit is supported; A detachable coupling member detachably coupled to a support on which the operation lever is mounted; And at least one connection member connecting the support plate and the detachable coupling member.

The removable coupling member has a shape corresponding to the shape of the support to surround at least a portion of the support, the removable coupling member and the support is fixed to each other by a fixing member fixed to the support through the removable coupling member. Can be.

The connection member may include a first connection member coupled to the support plate; A second connection member coupled to the detachable coupling member; And a third connecting member movably coupled along the longitudinal direction of the first connecting member and movably coupled along the longitudinal direction of the second connecting member, whereby height adjustment and width adjustment are possible. .

A photographing camera is mounted to the device and photographs the operation of the device in real time. The operation unit controller may control an operation of the mounted operation unit based on information obtained by the photographing camera.

The operation unit control unit may be an operation lever corresponding to the operation lever provided in the device, and may be provided in the device substantially the same as the moving direction and the degree of movement of the operation lever provided in the operation unit control unit.

According to the unmanned control system of the operation lever for operating the device according to an embodiment of the present invention, by mounting the mounting operation unit to the existing operation lever and remotely controlling the mounting operation unit, the operator is exposed to a high risk working environment It can prevent the occurrence of safety accidents in advance.

In addition, according to the unmanned control system of the operation lever for operating the device according to an embodiment of the present invention, it is possible to accurately operate the mounted operation unit mounted on the operation lever of the device such as heavy equipment from the outside, thereby improving the efficiency and accuracy of the operation You can.

In addition, according to the unmanned control system of the operation lever for operating the device according to an embodiment of the present invention, by having a structure to use the mounting operation unit mounted on the existing operation lever can use the existing system as it is, thereby reducing costs You can implement the effect.

Further, according to the unmanned steering system of the operation lever for operating the device according to an embodiment of the present invention, the mounting type operation unit and the operation unit control unit for controlling the same has a structure that is easy to carry, it is possible to carry the operator.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the configuration and operation according to an embodiment of the present invention.

The following description is one of several aspects of the patentable invention and the following description forms part of the detailed description of the invention.

Meanwhile, hereinafter, the unmanned steering system of the operation lever mounted on heavy equipment such as an excavator or a crane will be described in detail, but is not limited thereto, and other devices operated by the operation lever, for example, a factory control device or a transportation device. Of course, the unmanned steering system of the present invention may be applied.

1 is a schematic view showing the configuration of an unmanned steering system of the operating lever of the heavy equipment according to an embodiment of the present invention, Figure 2 is a state in which the mounting operation unit shown in Figure 1 is coupled to the operating lever of the heavy equipment 3 is a view illustrating a state in which the lever coupling portion of FIG. 2 is coupled to an operation lever, and FIG. 4 is an enlarged view of an upper portion of the mounted operation unit shown in FIG. 2, and FIG. 5 is FIG. 4. 6 is a perspective view illustrating the moving shaft and the joint part of the lever coupling part shown in FIG. 2, and FIG. 7 is a view showing the lever coupling part operating by the driving part shown in FIG. 4. 8 is a view showing a coupling state of the support of the support and the control lever shown in FIG.

As shown in these figures, the unmanned steering system 100 of the operation lever of the heavy equipment according to an embodiment of the present invention, detachably attached to the operation lever 105 for driving the heavy equipment 103, such as excavators, cranes The operation lever 105 coupled to the mounting operation unit 120 by being remotely controlled by the mounting operation unit 120 coupled to operate the operation lever 105 and the mounting operation unit 120 spaced apart from the heavy equipment 103. It includes a control unit control unit 110 (see Fig. 1).

Due to this configuration, at a point away from the heavy equipment 103, the operator can remotely control the operation unit control unit 110 to control the mounting operation unit 120, and thus the operation lever coupled to the mounting operation unit 120 The 105 can be adjusted, so that the corresponding work of the heavy equipment 103 can be executed, for example, an excavator can carry out an excavation work, and in the case of a crane, a crane work can be performed.

Therefore, the heavy equipment 103 can be remotely controlled, so that the operator may not be exposed to a dangerous work environment, thereby preventing a safety accident from occurring.

First, referring to the configuration of the mounting operation unit 120, the mounting operation unit 120 according to an embodiment of the present invention, as shown in Figure 2, to the operation lever 105 of the heavy equipment 103 The lever engaging portion 130 which is detachably coupled, the driving unit 150 which generates a driving force for manipulating the manipulation lever 105 by moving the lever coupling portion 130, and the eastern portion 150 are operated by the lever 105. It includes a support 170 for supporting the support 107 is mounted.

In this way, the mounting operation unit 120 of the present embodiment is coupled to the existing operation lever 105 to realize the unmanned control by adjusting the position of the control lever 105. In addition, as shown in Figure 1, the mounting operation unit 120 has a small size (size) can be easily carried by the operator.

Referring to each configuration, first, the lever engaging portion 130, as shown in Figs. 3 and 6, the lever fixing member 131 fixed to the operation lever 105, and the lever fixing member 131 The coupling part includes a moving shaft 133 coupled to the free rotation, and a joint part 140 coupled to an upper end of the moving shaft 133 to move in various directions by driving of the driving part 150.

First, as shown in FIG. 3, the lever fixing member 131 is coupled to the operation lever 105 but is firmly coupled to the operation lever 105, that is, the lower end of the operation lever 105, that is, the operation lever 105. ) Is fixedly coupled to the shaft portion 106. Therefore, it is possible to prevent the lever fixing member 131 from slipping or detaching from the manipulation lever 105, and thus the movement of the lever coupling unit 130 can be accurately transmitted to the manipulation lever 105.

The moving shaft 133 is a portion which moves the operation lever 105 substantially by the drive of the drive part 150. However, at this time, the lower end of the moving shaft 133 is provided with a spherical rotary hole 134 so that the movement of the moving shaft 133 is not restrained by the lever fixing member 131. The lever fixing member 131 to which the rotating hole 134 is coupled has a holder 132 in which the rotating hole 134 freely rotates so that the movement of the moving shaft 133 is transmitted to the lever fixing member 131 and restrained. You can stop that.

However, the connection structure of the moving shaft 133 and the lever fixing member 131 is not limited to the above-described ball joint connection structure, and other structures, for example, a universal joint structure or a link Of course, it can also be implemented as a structure.

On the other hand, the upper end of the moving shaft 133 is coupled to the joint portion 140. As shown in detail in FIG. 6, the joint part 140 of the present exemplary embodiment includes a linear bush 141 to which the moving shaft 133 is movably coupled in the axial direction, and a driving part coupled to the linear bush 141. When the driving force is transmitted from 150, the first joint 142 tilts the linear bush 141 in the direction of arrow A, and is coupled to the linear bush 141 at an upper portion of the first joint 142 and the driving unit ( And a second joint 145 for tilting the linear bush 141 in the direction of arrow B, which is the horizontal direction in the direction of arrow A, when the driving force is transmitted from 150.

The linear bush 141 is provided in a hollow cylindrical shape, the moving shaft 133 is coupled through but does not have a separate fixing structure so that the moving shaft 133 can move freely in the axial direction. That is, when the first joint 142 and the second joint 145 to be described later are tilted, the moving shaft 133 moves freely in the axial direction, in which the moving shaft 133 is relative to the linear bush 141. It can move, the movement of the moving shaft 133 can be smoothly transmitted to the operation lever 105.

The first joint 142 and the second joint 145 have a substantially similar structure, but are disposed in directions crossing each other in order to change the tilting direction of the moving shaft 133. In other words, when the first joint 142 is tilted by the driving of the driving unit 150, as shown in FIG. 6, the moving shaft 133 may move in the direction of the arrow A, while the second joint When the 145 is tilted by the driving of the driving unit 150, the moving shaft 133 may move in the arrow B direction.

In addition, when the tilting movements of the first joint 142 and the second joint 145 are combined, the moving shaft 133 may move in various directions as well as the arrow A and B directions described above, and thus the operation lever. 105 can be adjusted in position.

Here, the structural features of the first joint 142 and the second joint 145 will be described in more detail. The first joint 142 and the second joint 145 are respectively shown in FIG. 6, as shown in FIG. 6. Axial projections 143 and 146 are formed to protrude from the portion to become the rotation axis, and tilting projections 144 and 147 are formed to protrude from one side of both sides. These configurations will be described later when describing the driving body 151 of the driving unit 150.

Meanwhile, as described above, the lever coupling part 130 directly connected to the operation lever 105 is driven by the driving part 150.

Referring to the configuration of the driving unit 150, the driving unit 150 of the present embodiment, as shown in Figs. 4 and 5, is supported by the support unit 170, the inside of the above-described joint portion 140 tilting movement The drive body 151, which is possibly coupled, the first drive motor 156 for generating the driving force for tilting the first joint 142 described above, and the driving force for tilting the second joint 145 described above. Driving force of the second driving motor 157, the first transmission unit 161 transmitting the driving force of the first driving motor 156 to the first joint 142, and the second driving motor 157. And a second transfer part 165 to transfer to the second joint 145.

First, as shown in FIGS. 4 and 5, the driving body 151 is coupled to four sides of the driving frame 152 and the driving frame 152 to form a basic frame coupled to the support 170. Four rotation reference members 153 to which the above-described first and second shafts 143 and 146 of the first joint 142 and the second joint 145 are rotatably coupled, and a first of four sides of the driving frame 152. It includes two coupling plates 154 disposed on two sides on which the transmission unit 161 and the second transmission unit 165 are disposed.

First, the drive frame 152 is a part where many structures are arrange | positioned. The drive frame 152 is coupled to the support unit 170, the lower prime member 152a and the lower prime member 152a having a plate shape on which the first drive motor 156, the second drive motor 157, and the like are mounted. The upper side frame member 152b disposed on the upper side of the upper frame member 152b to which the four rotational reference members 153 are fixedly coupled and coupled to the four corner regions between the upper frame member 152b and the lower prime member 152a. 152c.

The frame members 152a, 152b, and 152c of the drive frame 152 have an advantage of being easy to manufacture because they have a structure that is custom coupled.

As shown in FIG. 6, the rotation reference member 153 is a portion to which the axial projections 143 and 146 of the first joint 142 and the second joint 145 are coupled. The first joint 142 and the second joint 145 rotate relative to the rotation reference member 153 so that the linear bush 141 to which the moving shaft 133 is coupled can accurately tilt.

As shown in part in FIG. 4, the coupling plate 154 is provided with a pair of through holes 154h through which the pair of tilting protrusions 144 and 147 pass. The pair of through holes 154h is formed in an arc shape that is vertically long. This is to limit the tilting range when the tilting protrusions 144 and 147 are tilted.

The first driving motor 156 and the second driving motor 157 may be provided as a DC motor to generate a driving force for driving the first joint 142 and the second joint 145. However, the present invention is not limited thereto, and it is obvious that other types of drive motors, for example, stepper motors capable of precise control may be applied.

The driving force generated from the first driving motor 156 and the second driving motor 157 through the first transmission part 161 and the second transmission part 165, respectively, the first joint 142 and the second joint 145 is passed. However, hereinafter, since the structures of the first transfer unit 161 and the second transfer unit 165 are substantially the same, only the first transfer unit 161 will be described.

As shown in detail in FIG. 7, the first transmission unit 161 includes a pinion gear 162 coupled to the moving shaft 133 of the first drive motor 156 and an outer side of the coupling plate 154 described above. The joint tilting member 163 is coupled to the pair of tilting protrusions 144 of the first joint 142 and the gear 163a is formed at a part of the outer side, and the pinion gear 162 is operated by the joint tilting member ( And a connecting member 164 for transmitting to 163.

Here, the connection member 164, the first transmission gear 164a is engaged with the pinion gear 162, the second transmission gear 164b is engaged with the gear 163a of the joint tilting member 163. Include.

Therefore, as shown in FIG. 7, when the pinion gear 162 coupled to the moving shaft 133 of the first drive motor 156 is rotated in one direction by driving the first drive motor 156, the connection is performed. The first transmission gear 164a and the second transmission gear 164b of the member 164 rotate in the other direction, and the joint tilting member 163 engaged with the second transmission gear 164b is tilted in one direction. The first joint 142 may also move in tilt.

As described above, the first transfer unit 161 and the second transfer unit 165 having the same structure as the first transfer unit 161 may use the joints 142 and the driving force of the first drive motor 156 and the second drive motor 157. By transmitting to 145, the tilting of the joints 142 and 145 can be made smoothly.

Meanwhile, in the present exemplary embodiment, the driving motors 156 and 157 which drive the first joint 142 and the second joint 145 are separately provided, whereby the first driving motor 156 and the second driving motor 157 are provided. The tilting degree of the first joint 142 and the second joint 145 generated as a result of the driving of) may be slightly different.

To this end, the mounting operation unit 120 of the present embodiment, as shown in FIGS. 4 and 5, a pair of rotations in which the axial projection 143 and the tilting projection 144 of the first joint 142 are coupled. A pair of first encoder 181 coupled to the reference member 153 to measure the degree of rotation of the axial projection 143 of the first joint 142, axial projection 146 of the second joint 145 and A pair of second encoders 182 coupled to another pair of rotational reference members 153 to which the tilting protrusions 147 are coupled to measure the degree of rotation of the axial projections 146 of the second joint 145; A control unit (not shown) may be further configured to control driving of the first driving motor 156 and the second driving motor 157 based on the measurement information of the first encoder 181 and the second encoder 182. .

With this configuration, the tilting degree of the first joint 142 and the second joint 145 can be precisely controlled, and the moving shaft moves by the tilting movement of the first joint 142 and the second joint 145. It is possible to precisely control the movement of the 133, and thereby it is possible to precisely control the movement of the operation lever 105 operated by the moving shaft 133. That is, the backlash generated due to the gear structures of the first transfer unit 161 and the second transfer unit 165 may be excluded, thereby enabling precise control.

In addition, since the first encoder 181 and the second encoder 182 are provided in pairs, even if one of the pairs fails, the other one may play the above-described role, so that the first joint 142 and the second joint ( There is an advantage that the tilting of the 145 can be accurately controlled.

On the other hand, the support unit 170 is a part for supporting the drive unit 150 for driving the lever coupling unit 130 to the support base 107 on which the operation lever 105 is mounted, as shown in FIGS. 2 and 8. The support plate 171 on which the driving unit 150 is supported, the detachable coupling member 174 detachably coupled to the support base 107 on which the operation lever 105 is mounted, the support plate 171 and the removable coupling member 174 Including four connecting members 177 for connecting.

The detachable coupling member 174 is provided in a shape corresponding to the shape of the support 107 so as to surround the upper end of the support 107 on which the operation lever 105 is mounted. The detachable coupling member 174 is formed with a through hole (not shown) through which a fixing member (not shown) such as a screw passes. Therefore, the fixing member passing through the through-hole presses a part of the support 107, so that the fixing force of the detachable coupling member 174 to the support 107 can be strengthened, thereby impacting from the outside during operation of the heavy equipment 103. Even if this is applied, detachment of the detachable coupling member 174 from the support 107 can be prevented.

And each connection member 177 is provided so that height adjustment is possible. That is, as shown in FIGS. 2 and 8, the connection member 177 may include a first connection member 177a coupled to the support plate 171 and a second connection member coupled to the detachable coupling member 174. 177b and a third connection member 177c movably coupled along the longitudinal direction of the first connection member 177a and movably coupled along the longitudinal direction of the second connection member 177b.

As such, the third connecting member 177c is movably coupled to the second connecting member 177b in the height direction, and the third connecting member 177c is moved in the longitudinal direction of the first connecting member 177a. Possible defects can be appropriately adjusted the overall height of the mounting operation unit 120 according to the present embodiment, there is an advantage that can be flexibly respond to the installation space.

On the other hand, the unmanned control system 100 of the operation lever 105 of the heavy equipment 103 of the present embodiment, the shooting to shoot the operation of the heavy equipment 103 at the work site to operate the heavy equipment 103 in accordance with the work site It further includes a camera (not shown).

Therefore, the operation unit controller 110 may control the operation of the mounted operation unit 120 based on the information obtained by the photographing camera.

The operation unit controller 110 is provided in a shape corresponding to the operation lever 105 installed in the heavy equipment 103. That is, the operation unit control unit 110 is also provided in the shape of the operation lever. Therefore, the operation unit controller 110 drives the mounted operation unit 120 so that the movement corresponding to the movement direction and the degree of movement of the operation unit controller 110 can be made in the operation lever 105 of the heavy equipment 103. Serves to control.

Hereinafter, a driving process of the mounted operation unit 120 having such a configuration will be described with reference to FIG. 8. However, a case in which the first joint 142 is tilted by the first driving motor 156 will be described.

First, the operator remotely controls the operation unit controller 110 based on information captured in real time from a photographing camera mounted on the heavy equipment 103.

For example, when the operation lever 105 needs to be moved to the right with reference to FIG. 8, when the operation unit controller 110 is moved to the right, the first driving motor 156 of the mounted operation unit 120 generates a driving force. The driving force is transmitted to the first joint 142 through the first transmission unit 161. Then, the first joint 142 moves the moving shaft 133 by tilting in the direction of the arrow C, and thus the manipulation lever 105 may be moved to the right.

That is, the position of the manipulation lever 105 is precisely adjusted by the control of the manipulation unit controller 110.

As such, according to one embodiment of the present invention, by mounting the mounting operation unit 120 to the existing operation lever 105 and by controlling the mounting operation unit 120 remotely by the operation unit control unit 110, Workers can be prevented from being exposed to high-risk work environments, preventing accidents from occurring and improving the efficiency and accuracy of operations due to remote control.

In addition, by having a structure using the mounting operation unit 120 mounted on the existing operation lever 105, it is possible to utilize the existing system as it is, thereby implementing a cost-saving effect, and also the mounting operation unit 120 And it has an advantage that the operation unit control unit 110 for controlling it has an easy structure to carry,

In the above-described embodiment, the movement of the moving shaft is controlled by the joint part provided with the universal joint structure, but the present invention is not limited thereto, and it is natural that the position of the moving shaft may be adjusted by another driving method.

 As described above, the present invention has been described by specific embodiments such as specific components and the like. For those skilled in the art to which the present invention pertains, various modifications and variations are possible. Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

1 is a schematic diagram showing the configuration of an unmanned steering system of the operation lever of the heavy equipment according to an embodiment of the present invention.

Figure 2 is a perspective view showing a state in which the mounting operation unit shown in Figure 1 is coupled to the operation lever of the heavy equipment.

FIG. 3 is a view illustrating a state in which the lever coupling unit of FIG. 2 is coupled to the operation lever.

4 is an enlarged view of an upper portion of the mounted operation unit illustrated in FIG. 2.

FIG. 5 is a view of FIG. 4 viewed from the rear.

6 is a perspective view illustrating a moving shaft and a joint part of the lever coupling part illustrated in FIG. 2.

FIG. 7 is a view illustrating that the lever coupling unit operates by the driving unit illustrated in FIG. 4.

8 is a view showing a coupling state of the support of the support and the control lever shown in FIG.

<Explanation of symbols for the main parts of the drawings>

100: unmanned steering system of the control lever of heavy equipment

103: heavy equipment 105: operation lever

110: control unit control unit 120: mounting type operation unit

130: lever engaging portion 131: lever portion fixing member

133: moving shaft 140: joint portion

141: linear bush 142: first joint

145: second joint 150: drive unit

156: first drive motor 157: second drive motor

161: first delivery unit 165: second delivery unit

170: support portion 171: support plate

174: detachable coupling member 177: connecting member

181: first encoder 182: second encoder

Claims (13)

A detachable operation unit detachably coupled to an operation lever for operating a device to operate the operation lever; And An operation unit control unit arranged to be spaced apart from the device to adjust the operation lever coupled to the mounting operation unit by remotely controlling the mounting operation unit; Unmanned control system of the operation lever for operating the appliance comprising a. The method of claim 1, The mounted operation unit, A lever coupling part detachably coupled to the operation lever; A driving unit driving the lever coupling unit; And And a support for supporting the drive unit on a support on which the operation lever is mounted. The method of claim 2, The lever coupling portion, A lever fixing member fixed to the operation lever; A moving shaft coupled to the lever fixing member, wherein a portion coupled to the lever fixing member is rotatably coupled to the lever fixing member; And A portion is movably coupled to the drive portion, and the other portion is an unmanned steering system for operating a lever for operating a device including a joint portion for transmitting the driving force generated by the drive portion to the movable shaft by movably engaging the movable shaft. . The method of claim 3, wherein The joint part, A linear bush to which the moving shaft is movably coupled in an axial direction; A first joint coupled to the linear bush to tilt the linear bush in one direction when a driving force is transmitted from the driving unit; And Unmanned operation lever of the operation lever including a second joint coupled to the linear bush in the horizontal direction of the first joint to tilt the linear bush in the other direction in the horizontal direction of the one direction when the driving force is transmitted from the drive unit Steering system. The method according to any one of claims 1 to 4, The driving unit includes: A driving body which is supported by the support part and in which the joint part is movably coupled; A first driving motor mounted to the driving body and generating a driving force for tilting the first joint; A second driving motor mounted to the driving body and generating a driving force for tilting the second joint; A first transmission part transmitting a driving force of the first driving motor to the first joint; And And a second transmission part for transmitting a driving force of the second drive motor to the second joint. The method of claim 5, The drive body, A drive frame coupled to the support to form a frame; A rotation reference member coupled to four sides of the driving frame and rotatably coupled to shaft center protrusions protruding from both sides of the first joint and the second joint; And A pair of tilting protrusions respectively coupled to the side portions of the first transmission part and the second transmission part of the four sides of the driving frame, the protrusions protruding from one side of the first joint and the second joint, respectively. Unmanned control system of the operating lever for operating the device including a coupling plate is formed through holes. The method of claim 6, The first transfer unit and the second transfer unit, respectively, A pinion gear coupled to the moving shafts of the first drive motor and the second drive motor; A joint tilting member coupled to the pair of tilting protrusions at an outer side of the coupling plate, wherein a part of the outer side is formed with a gear; And And a connecting member having a first transmission gear engaged with the pinion gear and a second transmission gear engaged with the gear of the joint tilting member. The method of claim 6, A first encoder coupled to the rotation reference member to measure a tilting degree of the shaft projection of the first joint; A second encoder coupled to the rotation reference member to measure a degree of tilting of the shaft projection of the second joint; And And a control unit for controlling the driving of the first drive motor and the second drive motor based on information from the first encoder and the second encoder. The method of claim 2, The support portion A support plate on which the driving unit is supported; A detachable coupling member detachably coupled to a support on which the operation lever is mounted; And And an at least one connecting member connecting the support plate and the detachable coupling member. 10. The method of claim 9, The detachable coupling member has a shape corresponding to the shape of the support to surround at least a portion of the support, And the detachable coupling member and the support are mutually fixed by a fixing member fixed to the support by passing through the detachable coupling member. 10. The method of claim 9, The connecting member, A first connection member coupled to the support plate; A second connection member coupled to the detachable coupling member; And And a third connection member movably coupled along the length direction of the first connection member and movably coupled along the length direction of the second connection member. The method of claim 1, It is mounted to the device is equipped with a shooting camera for shooting the operation of the device in real time, And the operation unit controller controls the operation of the mounted operation unit based on the information obtained by the photographing camera. The method of claim 1, The operation unit controller is an operation lever corresponding to the operation lever provided in the device, and the operation lever of the operation lever provided in the device is substantially the same as the moving direction and the degree of movement of the operation lever provided in the operation unit controller. Unmanned steering system of control lever for actuating machine operation.

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