KR101976410B1 - Power Assistive Modular Robot - Google Patents

Abstract

A power assisted module robot for supporting the operation of the medical assistant is driven by a control device operated by a user and includes a driver for causing the power assisted module robot to perform translational motion, rotational motion and omnidirectional movement of translational rotational motion, To deliver the connected medical aids or to power the medical aids.

Description

Power Assistive Modular Robot

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power-assisted module robot, and more particularly, to a power-assisted module robot for supporting movement, operation, and the like of various medical assistants used in a medical environment such as a hospital.

Generally, in the medical environment such as hospitals, transportation of nursing articles and support for movement of patients are dependent on manpower.

Work by manpower leads to fatigue of the related workforce, and wastes such as increasing the labor cost for the workforce.

In order to avoid work-dependent work, logistic support robots are being developed for logistics transportation in hospitals.

However, the logistics transportation robot according to the related art is mainly designed to automatically run using a stored route map in a hospital.

In order to construct a system for automatic running of the robot, the entire path environment of the hospital should be regenerated so that the robot can move. In addition, the medical infrastructure and medical assistant suitable for the robot should be designed and completely replaced.

In order to apply a logistics transportation robot, which has a limited role as a logistics transportation route, a huge amount of technology and costs are required to construct a system, and thus it is difficult to easily apply it in a small and medium medical environment.

In addition, the logistics transportation robot according to the prior art has a large trajectory required for movement, and accessibility to a narrow place such as a narrow bed is very poor.

U.S. Patent No. 8,204,624

The present invention provides a power-assisted module robot that can be applied at low cost, has excellent mobility, and can effectively support the operation of an existing medical assistant in a medical environment.

According to an aspect of the present invention, there is provided a power assisted module robot for supporting the operation of a medical assistant, the robotic arm being driven by a user-operated steering device, There is provided a power assisted module robot including a driving part for causing movement, and a power supplying part for providing power, for transporting a connected medical assistant or supplying power to a medical assistant.

According to one embodiment, the driving unit includes a first motor and a second motor, and a driving wheel driven by a driving force of the first motor and the second motor, The driving wheels are driven to drive and steer the power-assisted module robots.

According to one embodiment, the driving unit includes a first shaft and a second shaft that are formed to overlap with each other and rotate about a first axis by the first motor and the second motor, A second axis perpendicular to the first axis and a third axis parallel to the second axis and offset from the first axis are defined and the drive wheel is rotated about the third axis, do.

According to one embodiment, the driving unit includes a first cross shaft gear connected to the first shaft, a second cross shaft gear facing the first cross shaft gear and connected to the second shaft, And a second gear portion that is engaged with the first gear portion and is engaged with the second gear portion of the transmission gear, And a driving gear for rotating the driving wheels.

According to one embodiment, the first motor, the first shaft, the second motor, and the second shaft are connected by a timing belt, respectively.

According to one embodiment, the power assisted module robot includes a connection to which a medical assistance device can be connected.

According to one embodiment, the medical assistance device is a nursing car loaded with nursing articles, and the power support module robot includes a vertical body portion and a horizontal horizontal body portion on the vertical body portion, And mounted on the power support module robot.

According to one embodiment, the nursing cart includes a cart handle capable of being held by a user, a measurement sensor capable of sensing a force applied to the cart handle is formed, and a control mode by the control device, When the user holds the cart handle and pushes or pulls the cart handle in a direction in which the cart is desired to move in a steered mode by the cart handle, the force applied to the cart handle The driving unit is driven to move in the direction of the force applied to the cart handle by the power-assisted-module robot.

According to one embodiment, the cart handle is a handrail-type handle formed along the periphery of the upper plate, and the measurement sensor is disposed at the lower center of the upper plate and detects the force transmitted to the upper plate through the cart handle Axis force-torque sensor.

According to one embodiment, the connecting portion is an engaging groove formed at an upper end of the horizontal body portion and capable of being fastened to an engaging projection protruding from a lower portion of the nursing cart, and the engaging groove is formed along the circumference of the engaging projection A spring plunger that can be fastened to the fastening groove is formed.

According to one embodiment, the medical aids are behavior aids for the patient to support or move the body.

According to one embodiment, the power-assisted module robot includes a vertical body portion and a horizontal horizontal body portion that is horizontal to the vertical body portion, the connection portion extends to an upper end of the horizontal body portion, Which can be fastened.

According to one embodiment, the power-assisted module robot includes a registration of the position of the power-assisted module robot, and a wireless recognition device capable of registering the identity of the connected medical aid or user.

According to one embodiment, the power-assisted module robot adjusts the movement speed according to the position of the power-assisted module robot recognized, and the identity of the connected medical aid or user.

1 is a conceptual diagram of a task support system including a power support module robot according to an embodiment.
2 and 3 are perspective views of a power assisted module robot according to one embodiment.
FIGS. 4 to 6 are views showing the driving unit of the power-assisted module robot from various angles.
7 is a diagram showing translational motion of the power-assisted module robot.
8 is a view showing the rotational motion and the translational rotational motion of the power-assisted module robot.
9 is a perspective view of a nurse cart, which is an example of a medical assistant connected to a power-assisted module robot.
10 is a perspective view of a power assisted module robot and a nursing cart combined.
FIG. 11 is a view showing a connection portion where the power support module robot and the nurse cart are connected.
12 is a view showing a force-torque sensor provided in the nursing car.
13 is a view showing a top plate portion of the nursing car.
14 is a view showing the driving state of the power assisted module robot by the cart handle of the nurse cart.
Fig. 15 is a view showing a connection between a power-assisted module robot and a walking aid, which is another example of a medical assistant.
16 and 17 are views showing a connection portion where the power-assisted module robot and the walking aids are connected.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and action are not limited by this embodiment.

1 is a conceptual diagram of a task support system including a power assisted module robot (hereinafter referred to as " module robot ") 1 according to an embodiment of the present invention.

The modular robot 1 according to the present embodiment receives an operation signal of a steering device 3 directly operated by a related user such as a nurse and transfers the signal to the medical assistant 2 such as the nurse cart 400, And supports the operation of the medical aids by transporting the medical aids 2 or by supplying the necessary power to the medical aids 2.

As used herein, " connection " may include not only physical coupling between components but also electrical signal connections.

The module robot 1 includes a radio frequency identification (RFID) device 6, which is a type of a radio frequency identification device. The user can register the identity of the user who uses the module robot 1 by tagging his or her own ID card 4 to the RFID device 6 and can identify the ID card built in or attached to the medical assistant 2 Can be tagged to the RFID device 6 to register the medical assistant 2 connected to the module robot 1. [

In addition, in addition to the identity of the medical assistant or user connected, the RFID device 6 is also used to identify the current position of the modular robot 1. An ID recognizing device capable of tagging the RFID device 6 is also provided at a position where the module robot 1 is waiting or at a major use base such as a charging station for the module robot 1. [ The user can tag the RFID device 6 and register the position of the module robot 1 when moving the module robot 1 to / from the waiting position.

The position of the module robot 1 to be used and the registration information of the user and / or the medical assistant to the module robot 1 can be transferred to the in-hospital management computer 5 and managed in the control room.

2 and 3 are perspective views of a module robot 1 according to an embodiment of the present invention.

2 and 3, the module robot 1 includes a vertical body portion 10 formed vertically and a horizontal body portion 20 formed vertically from the vertical body portion 10, It has the form of "b".

A monitor 30 is provided at the upper end of the vertical body 10. The monitor 30 is used as a UI device for displaying the operating state of the module robot 1 such as the charging state and the current speed or for inputting the program of the module robot 1. [ However, the monitor 30 is not necessarily provided, and may be replaced with a PC or the like which performs wired / wireless communication with the module robot 1. [

As best shown in FIG. 2, at the lower end of the horizontal body 20 there are two drive units 100. A ball caster 101 is provided near the corner of the horizontal body 20 to provide no separate driving force. The ball caster 101 supports the modular robot 1 so that the modular robot 1 is movable omnidirectionally.

The recessed portion 21 is formed at the rear end of the horizontal body portion 20 and the recessed portion 21 is disposed at the rear end of the module robot 1 to facilitate the installation of a movement assistant etc. pulled by the module robot 1. [ It is.

A plurality of connection portions 300 are formed at the upper end of the horizontal body portion 20 so that a plurality of medical assistants can be connected to the module robot 1. [

According to the present embodiment, the first connection part 310 and the second connection part 320, to which two kinds of medical assistants can be connected, are formed.

A power supply unit 200 capable of supplying power to a medical assistant requiring power among the medical assistants connected to the driving unit 100, the monitor 30 and the module robot 1 is formed inside the vertical body unit 10 .

Although not separately shown, the power supply unit 200 includes a rechargeable battery and a terminal capable of electrically connecting the battery and the other device.

A control computer for controlling the motor of the driving unit 100 and for processing signals transmitted from the control unit or the monitor 30 is formed in the vertical body 10.

The modular robot 1 according to the present embodiment is capable of omnidirectional movement of translational motion, rotational motion, and translational rotational motion by the driving unit 100.

4 to 6 are views showing the driving unit 100 from various angles.

The driving unit 100 includes a frame 110 coupled to the horizontal frame 20 and a first motor 121 and a second motor 122 extending vertically at the upper end of the frame 110 and disposed parallel to each other . The first motor 121 and the second motor 122 extend to the vertical frame 10 and are connected to the power supply 200 and the control computer.

The motor shaft 123 of the first motor 121 and the motor shaft 124 of the second motor 122 extend through the frame 110 to the lower end of the frame 110.

The first shaft 141 and the second shaft 142 are rotatably formed with respect to the frame 110 at a position offset from the first motor 121 and the second motor 122 by a predetermined distance.

According to this embodiment, the second shaft 142 has a larger diameter than the first shaft 141 and the first shaft 141 is disposed through the hollow second shaft 142. The first shaft 141 and the second shaft 142 are overlapped with each other and rotate around a first axis A ₁ perpendicular to the frame 110.

The first shaft 141 is longer than the second shaft 142 and both ends of the first shaft 141 are exposed to the outside of the second shaft 142. One end of the first shaft 141 is rotatably fixed to the frame 110 and the second shaft 142 is rotatably fixed to the first shaft 141 and rotatable with respect to the frame 110.

A first rotary drum 151 is formed on the first shaft 141 adjacent to the frame 110 and a second rotary drum 152 is formed on the second shaft 142.

A first timing belt 131 is connected to the rotating shaft 123 of the first motor 121 and the first rotating drum 151. A second timing belt 131 is connected to the rotating shaft 124 of the second motor 122, The second timing belt 132 is connected to the drum 152.

When the first motor 121 rotates and the rotation shaft 123 rotates, the first timing belt 131 transmits the driving force to rotate the first shaft 141 about the first axis A ₁ . When the second motor 122 is driven to rotate the rotation shaft 124, a driving force is transmitted by the second timing belt 132 so that the second shaft 142 rotates about the first axis A ₁ . The rotations of the first shaft 141 and the second shaft 142 are independently performed by the first motor 121 and the second motor 122, respectively.

4, the driving unit 100 includes a connection block 140 fixed to the first shaft 141 and the second shaft 142 to enclose the first shaft 141 and the second shaft 142, And a driving wheel 150 is formed on the connection block 140. [

According to this embodiment, and the second axis (axis) (A ₂₎ defined extending from the first axis (A ₁₎ and to a first axis perpendicular (A _1), while the equilibrium with a second axis (A ₂₎ A third axis A ₃ offset from the first axis A ₁ is defined. According to the present embodiment, the driving wheel 150 is formed to rotate about the third axis A ₃ and has a dual-offset arrangement with the driving transmission shaft.

According to the present embodiment, the driving wheels 150 are driven by the driving forces of the first motor 121 and the second motor 122. At this time, the drive wheel 150 is driven by the differential drive between the first motor 121 and the second motor 122 that are independently driven, and the module robot 1 is driven and steered.

5 and 6, a first cross shaft gear 143 (e.g., a bevel gear) is connected to the first shaft 141 at the lower end of the first shaft 141, The gear 144 is connected to the second shaft 142 at the lower end of the second shaft 142. The first crossover shaft gear 143 is spaced apart from the second crossover shaft gear 144 by a predetermined distance.

The connection block 140 is provided with a transmission gear 145 that rotates around the second axis A ₂ . The transmission gear 145 is formed to have a double gear of a cross shaft gear portion (for example, a bevel gear) 146 and a parallel shaft gear portion (for example, a spur gear)

5 and 6, the cross shaft gear portion 146 of the transmission gear 145 is simultaneously engaged with the first cross shaft gear 143 and the second cross shaft gear 144 which are arranged in the downward direction .

6, the driving wheel 150 is provided with a driving gear 148 coupled to the driving wheel 150 and rotated together with the driving wheel 150 about the third axis A ₃ do.

The driving gear 148 is a parallel shaft gear, and meshes with the parallel shaft gear portion 147 of the transmission gear 1450.

When rotated in the driving unit 100 in the opposite direction of the motor shaft of the first motor 121 and second motor 122, the first shaft the first shaft 141 and the second shaft (142) (A ₁ In the direction opposite to each other.

When the first shaft 141 and the second shaft 142 rotate in opposite directions, the first cross shaft gear 143 meshes with the second cross shaft gear 144 and the transmission gear 145, The gear 145 rotates about the second axis A ₂ . When the transmission gear 145 rotates, the driving gear 148 and the driving wheel 150 meshed with the transmission gear 145 rotate about the third axis A ₃ .

That is, when the motor shafts of the first motor 121 and the second motor 122 are controlled to rotate in opposite directions, the driving wheels 150 are rotated.

Conversely, when the motor shafts of the first motor 121 and the second motor 122 rotate in the same direction, the first shaft 141 and the second shaft 142 rotate about the first axis A ₁ In the same direction. If the outputs of the first motor 121 and the second motor 122 are the same, the force provided by the first and second intersecting gears 143 and 144 is transmitted to the second axis A ₂ , And the transmission gear 145 does not rotate.

When the first shaft 141 and the second shaft 142 are rotated in the same direction about the first axis A ₁ in a state where the transmission gear 145 is not rotated, Is rotated about the first axis A ₁ together in the rotating direction of the first shaft 141 and the second shaft 142 and the driving wheel 150 fixed to the connecting block 140 rotates about the first axis A ₁ , Steering is performed to rotate around the axis A ₁ .

The first motor 121 and the second motor 122 operate in the same direction and output to drive or steer the drive wheel 150. However, the first motor 121 and the second motor 122, which are independently driven, It will be appreciated that, by appropriately adjusting the motor shaft rotation direction and output of the motor 122, the driving wheels 150 may be controlled so that driving and steering are simultaneously performed.

The module robot 1 according to the present embodiment has two driving units 100 having the same structure as described above on both sides of the horizontal body 20. Through the running and / or steering operation of the two driving parts 100, the module robot 1 is capable of omnidirectional movement of translational motion, rotary motion and translational motion.

7 is a view showing the translational motion of the module robot 1. Fig.

The module robot 1 steers the driving wheels 150 of the two driving units 100 in a desired direction and then travels the vehicle so that the position of the module robot 1 whose front end is directed to the front is maintained, "It is possible.

3, when the motor of each driving unit 100 is controlled so that the driving wheels 150 move in a state in which the driving wheels 150 of the two driving units 100 are disposed to face forward, Move forward or backward.

If the motors of the respective driving parts 100 are controlled so that the driving wheels 150 are driven so that the driving wheels 150 of the two driving parts 100 are laterally directed perpendicular to the state shown in FIG. 3, (1) can move left and right while maintaining the posture.

If the motors of the driving units 100 are controlled such that the driving wheels 150 of the two driving units 100 are diagonally arranged in the same direction and then the driving wheels 150 are driven to travel, And can be diagonally moved.

When the nursing cart 400 is coupled to the module robot 1, for example, it is possible to freely move between the narrow beds without securing a space required for the turning radius, And can be suitably used as an in-hospital operation support device.

8 is a view showing the rotational motion and the translational rotational motion of the module robot 1. Fig.

3, when the driving wheels 150 of the two driving units 100 are disposed so as to face forward, and the rotational directions of the driving wheels 150 of the two driving units 100 are reversely controlled, the module robot 1 And rotates about the center axis between the two driving parts 100 to rotate.

In addition, while the modular robot 1 is moving forward or backward, the driving wheels 150 of the two driving units 100 are steered in the same oblique direction while the driving unit 100 positioned outside the rotational center of the modular robot 1 When the motor output is further increased, the module robot 1 performs a translational rotational motion to the left or right with respect to its traveling direction.

Since the driving unit 100 according to the present embodiment operates in conjunction with the outputs of the two motors, a large output required for movement can be obtained even with a small motor output. In addition, by driving the driving wheels with the dual offset structure using the timing belt, it is possible to avoid the size and space limitation of the robot.

In addition, since the module robot 1 can be moved omnidirectionally by a simple control method of a differential drive of the motor, it is possible to construct a work support infrastructure that can support a work while moving freely in a hospital at a relatively low cost.

The maximum moving speed of the module robot 1 by the driving unit 100 is specified in accordance with the position of the module robot 1, the medical assistant to be connected, or the identity of the user and inputted to the controller of the module robot 1. The moving speed of the module robot 1 can be automatically adjusted according to the position of the module robot 1 recognized by the RIFD device 6, the medical assistant connected thereto, or the user's identity.

The modular robot 1 according to the present embodiment has a connection portion 300 to which a medical assistant can be connected to transport a connected medical assistant.

9 is a perspective view of a nurse cart 400 as an example of a medical assistant, and Fig. 10 shows a modular robot 1 to which a nurse cart 400 is coupled.

The nurse cart 400 includes a cart body 410 having a plurality of storage units 411 and capable of loading nursing supplies such as medicine and blood, an upper plate 430 formed at the upper end of the cart body 410, And a lower plate 420 formed at the lower end of the cart body 410.

10, the nurse cart 400 is roughly formed to have a size corresponding to the area of the horizontal monochrome portion 20 of the module robot 1 and is mounted on the horizontal body portion 20, ). A manual lifting device for moving the nurse cart 400 up and down is disposed in the hospital and the module robot 1 is moved to the position of the nurse cart 400 and then the nurse cart 400 is moved to the module robot 1 ).

The upper plate 430 covers an upper plate 432 disposed at the center of the upper plate 430 and a cart handle 433 and a top plate 432 formed on the upper plate 432, And a desk plate 431 on which a variety of objects such as a desk can be placed.

Like the conventional nursing cart, the cart grip 433 is a handrail type handle formed along the periphery of the upper plate 434, although the cart grip 433 may have various shapes.

The lower plate portion 420 is provided with a coupling protrusion 421 which can be fastened to the first coupling portion 310 in the form of a coupling groove formed on the horizontal body portion 20 of the module robot 1, As shown in Fig.

11 shows a connection structure of the first connection portion (coupling groove) 310 and the coupling projection 421. As shown in FIG.

11, a spring plunger 311 is formed in the coupling groove 310 in the circumferential direction of the coupling groove 310 and can be protruded or inserted in the radial direction of the coupling groove 310 have.

Corresponding to this, a coupling groove 422 is formed in the coupling projection 421 so that the spring plunger 311 can be fastened along the circumferential direction.

When the nurse cart 400 is placed on the horizontal body 20 of the module robot 1, the engaging projections 421 are inserted into the engaging grooves 310. In the inserting process, the engaging projections 421 are engaged with the spring plungers 311) to the outside of the radius of the coupling groove (310).

When the engaging protrusion 421 is completely inserted into the engaging groove 310 and the engaging groove 422 is positioned at the position of the spring plunger 311, the spring plunger 311 is urged by the resilient force of the spring, And is fastened to the fastening groove 422.

The fastening force of the spring plunger 311 and the fastening groove 422 prevents the nursing cart 400 from being rolled over from the module robot 1 due to an accident while the module robot 1 is moving. The main clamping force of the nurse cart 400 and the module robot 1 is the force of the nurse cart 400. When the spring plunger 311 and the lock groove 422 are inserted into the nurse cart 400 and the module robot 1, Lt; / RTI > When the nurse cart 400 is lifted from the module robot 1 by using the lifting device, the spring plunger 311 is operated by the shape of the coupling protrusion 421 without any other means, so that the coupling protrusion 421 and the coupling groove 310, Are separated from each other.

The module robot 1 connected to the nurse cart 400 can move the nurse cart 400 by using the control unit 3 in the conventional manner. However, when the control device 3 is used, a user such as a nurse must be skilled in operating the control device 3. [ In addition, since it is required to perform a certain distance away from the nurse cart 400, it may not be possible to intuitively cope with the movement of the nurse cart 400.

When moving a cart with a handrail-type cart handle in the desired direction, the most intuitive way for the user is to push or pull the cart handle by grasping the handle of the cart and applying a force in the direction the cart wants to move. However, such a moving method requires a relatively large amount of force due to the inertia of the cart, thereby causing fatigue of the user.

Fig. 12 is a perspective view of the nursing cart 400, in which the desk plate 431 is not shown, and Fig. 13 is a top view of the nursing cart 400. Fig.

12, according to the present embodiment, a measurement sensor 450, which can sense a force applied to the cart knob 433 so as to enable the manipulation of the module robot 1 by the cart knob 433, .

The measurement sensor 450 according to the present embodiment can measure the forces F _x , F _y and F _{z of} three axes transmitted to the upper plate 432 through the cart knob 433 and the resulting three axis moments M _x and M _y , M _z ) is a relatively low-cost six-axis force-torque sensor.

As shown in Fig. 13, the measurement sensor 450 is disposed below the center of the upper plate 432. [ The pin 434 fixed to the frame to support the desk plate 431 is formed through the upper plate 432 but does not constrain the upper plate 432. [ The cart grip 433 is formed to penetrate the desk plate 431, but the desk plate 431 does not restrict the cart grip 433. Therefore, when the user holds the cart grip 433 and applies a force, the force is transmitted to the measurement sensor 450 and measured.

14 is a view for explaining the concept of a manipulation method of the modular robot 1 by the cart knob.

As shown in Fig. 14, in the control mode by the cart knob 433, the user generally grasps the handrail-type cart knob 433 with two hands as when the cart is moved.

The user intuitively knows how to apply force to the cart handle 433 in order to move the nurse cart 400 in a desired direction of use. When the user holds the cart knob 433 and pushes or pulls the cart knob 433 in a direction in which the nurse cart 400 wants to move, the force F _L , F _R is applied to the cart knob 433 by each hand All. The resultant force F of the forces F _L and F _R by both hands is measured by the measuring sensor 450. The measurement sensor 450, which is a six-axis sensor, can calculate the direction and size of the resultant force F and the resulting moment.

The control unit of the module robot 1 generates a signal for driving the two driving units 100 so that the module robot 1 can move in the direction of the force F corresponding to the force F. [ The two driving portions 100 cause the above-described traveling and steering motion to move the module robot 1 in the direction of the force applied to the cart grip 433.

Since the substantial movement of the nurse cart 400 is performed by the driving unit 100 of the modular robot 1, the user can move the nurse cart 400 with very little force.

According to the present embodiment, anyone who is a general user can move the nurse cart 400 in a manner of pushing or pulling the familiar cart handle, so that a very intuitive and simple manipulation interface is provided.

Of course, the modular robot 1 is configured to be capable of selectively switching between the steered mode by the steering device and the steered mode by the cart handle depending on the user's propensity or location. The switching of the steering mode is performed by operating a mode switching button formed on the modular robot 1 or the steering device 3. [

The electrical / signal connection between the nurse cart 400 and the module robot 1 is carried out by a USB terminal (not shown) formed in both devices. An ID card that can be tagged to the RFID device 6 of the module robot 1 is built in or attached to the nursing car 400. [

The user moves the module robot 1 to a storage place of the nurse cart 400 and then connects the module robots 1 and the USB terminals of the nurse cart 400 to connect both devices. The user tags the ID card of the nurse cart 400 to the RFID device 6 of the module robot 1 to recognize the nurse cart 400 to be connected. Then, the user tags his / her ID card 4 to the RFID device 6 to recognize the identity of the user. The recognized nurse cart 400 and the identity of the user are transferred to the central computer 5 and managed.

Thereafter, the user selects one of the control mode by the control device and the control mode by the cart knob, and operates the selected control interface to move the module robot 1 to the nursing car 400 Move to the place.

Fig. 15 shows a modular robot 1 to which a walking aid 500, which is a medical assistant 2 according to another example, is connected.

The walking aid 500 is a device for helping a patient with an uncomfortable body to raise or walk.

Generally, the walking aids 500 have a structure in which a vertical frame 520 is installed on a horizontal frame 530 with wheels 531 and an armrest 510 is installed on the vertical frame 520. The patient raises his / her body over the armrest 510 with both arms and straddles the body while supporting the walking aid 500.

The walking aid 500 is a passive device that does not provide any other driving force, except that it has a wheel for movement.

The patient must push the walking aid 500 by himself. However, in the case of a patient who is unable to walk alone while moving the walking aid 500 alone, the movement of the walking aid 500 itself corresponds to labor, and the symptoms may be exacerbated through excessive labor. A driving device can be designed to allow the walking aids 500 to autonomously drive themselves, but this requires a lot of capital and skill.

The modular robot 1 according to the present embodiment is a so-called " behavioral orthosis ", which is a medical assistant for the patient to support or mount the body such as the walking aid 500 (particularly, Thereby assisting the movement of the motion assistant. Behavioral aids include, for example, walking aids, wheelchairs, and patient beds.

And a second connection part 320 for connecting a pull type device such as a behavioral assist device according to the present embodiment. The walking aid 500 can be connected to the module robot 1 by simply adding a connecting device 540 that can be fastened to the second connecting part 320 to the structure of the existing walking aid 500. [

16 and 17 are views showing a connection portion to which the module robot 1 and the walking aid 500 are connected.

16 and 17, the second connection part 320 of the modular robot 1 extends vertically at the upper end of the horizontal body part 20. As shown in FIG.

The second connection portion 320 includes a coupling plate 322 formed in a substantially C shape so as to form a coupling groove 323 and a coupling portion 324 rotated on one end shaft 325 of the coupling plate 322, And a lever 321 that rotates on the other end shaft of the retaining plate 322.

The walking aid 500 is formed with a fastening pin 541 which can be fastened to the fastening groove 323 as a connection part to the second connection part 320. [

The fastening portion 324 is fixed to the fastening plate 322 via a spring. When the fastening pin 541 is pushed into the fastening groove 323, the fastening pin 541 is inserted into the fastening groove 323 while rotating the fastening portion 324. The end of the fastening portion 324 is formed so as to be caught by the end of the lever 321 upon rotation. 17, when the fastening pin 541 is pushed into the fastening groove 323, the fastening portion 324 and the lever 321 fasten the fastening pin 541 inside the fastening groove 322, The walking aid 500 is bound to the second connection portion 320 of the module robot 1. [

When the lever 321 is rotated in the counterclockwise direction, the locking part 324 pushes the locking pin 541 from the second connecting part 320 of the module robot 1 to the walking aid 500, .

In a state in which the walking aid 500 is connected to the modular robot 1, the protector can move the modular robot 1 to the control device 3, thereby helping the patient to walk.

The modular robot 1 according to the present embodiment is connected to various medical assistants (for example, a cleaner, a meal-providing cart, etc.) inside and outside the hospital, which are convenient when the driving force is provided, .

In addition, the module robot 1 according to the present embodiment does not only intend to transport a medical assistant but also transmits power to a medical assistant such as a patient exercise machine having a motor itself, for example, Lt; / RTI > Since the movable module robot 1 can be used for electric power supply, the patient exercise machine or the like can be positioned at various places such as the outdoors without power supply line. The patient exercise machine equipped with the motor in the outdoors such as the outdoor can be used only when the protector carries the module robot 1 so that the patient can prevent an accident that may occur using the exercise machine without the protector.

The module robot 1 according to the present embodiment can be directly applied to the medical infrastructure by simply modifying the existing medical infrastructure and there is no need to construct a separate automation system.

In addition, the module robot 1 is capable of omnidirectional movement, and thus can be effectively used in facilities and people-like spaces such as hospitals.

Claims (14)

As a power-assisted modular robot that supports the operation of medical assistants,
A driving unit that is driven by a manipulator operated by a user and causes the power support module robot to perform omni-directional movement of translational motion, rotational motion, and translational rotational motion;
A power supply unit for supplying electric power; And
And a connection portion to which the medical assistant can be connected,
Wherein the medical assistant is connected to the medical assist device, and the medical assistant is connected to the medical assist device. The method according to claim 1,
The driving unit includes:
A first motor and a second motor; And a driving wheel driven by a driving force of the first motor and the second motor,
Wherein the driving wheels are driven by differential operation between the first motor and the second motor to drive and steer the power assisted module robot. 3. The method of claim 2,
Wherein the driving unit includes a first shaft and a second shaft that are overlapped with each other and rotate about a first axis by the first motor and the second motor,
A second axis perpendicular to the first axis and a third axis parallel to the second axis and offset from the first axis are defined,
And the drive wheel rotates about a third axis. The method of claim 3,
The driving unit includes:
A first cross shaft gear connected to the first shaft;
A second cross shaft gear facing the first cross shaft gear and connected to the second shaft;
A transmission gear having a first axis of rotation and a second axis of rotation; a transmission gear having a first axis of rotation and a second axis of rotation;
And a driving gear engaged with the parallel shaft gear portion of the transmission gear and engaged with the driving wheel to rotate the driving wheel. The method of claim 3,
Wherein the first motor, the first shaft, the second motor, and the second shaft are connected by a timing belt, respectively. delete The method according to claim 1,
Wherein the medical assistant is a nursing car loaded with nursing care articles,
Wherein the power assistance module robot includes a vertical body and a horizontal body horizontal to the vertical body,
Wherein the nursing cart is mounted on the horizontal supporting body and mounted on the power support module robot. 8. The method of claim 7,
The nursing care cart includes a cart handle that can be held by a user,
A measurement sensor capable of sensing a force applied to the cart handle is formed,
The mode can be switched to the steering mode by the steering device and the steering mode by the cart handle,
When the user holds the cart handle and pushes or pulls the cart handle in a direction in which the cart wants to move, the driver is driven in response to the direction of the force applied to the cart handle, Wherein the power support module robot moves in the direction of the force applied to the cart handle. 9. The method of claim 8,
The cart handle is a handrail type handle formed along the periphery of the upper plate,
Wherein the measurement sensor is a six-axis force-torque sensor disposed at a lower center of the upper plate and sensing a force transmitted to the upper plate through the cart handle. The method according to claim 1,
Wherein the medical assistant is a nursing car loaded with nursing care articles,
Wherein the power assistance module robot includes a vertical body and a horizontal body horizontal to the vertical body,
The connecting portion
And an engaging groove formed at an upper end of the horizontal body portion and engageable with an engaging projection protruding from a lower portion of the nursing cart,
Wherein the coupling groove is formed with a spring plunger that can be fastened to the coupling groove formed along the circumference of the coupling protrusion. The method according to claim 1,
Wherein the medical assistant is a behavior assistant for supporting a patient or supporting the body. 12. The method of claim 11,
Wherein the power assistance module robot includes a vertical body and a horizontal body horizontal to the vertical body,
Wherein the connecting portion is a hooking groove extending from an upper end of the horizontal body portion and capable of engaging with a fastening pin formed on the walking aiding device. The method according to claim 1,
And a wireless recognition device capable of registering the position of the power-assisted module robot, and registering the connected medical assistant or the user's identity. 14. The method of claim 13,
Wherein the movement speed is controlled according to the position of the power support module robot recognized, the medical assistant to be connected, and the user's identity.

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