KR20010003877A - Loading robot having a balancing part - Google Patents

Abstract

PURPOSE: A robot for baggage loading which has a balancing device for compensation of weight maldistribution is provided to prevent the robot from falling over by removing the weight maldistribution even in case of loading of massive baggage, so that the loading work proceeds stably. CONSTITUTION: A robot for baggage(25) loading comprises; a robot body(10); a loading part(40) which consists of a fixing part(30) fixed in the robot body and loading plates which move in between loading place separated from the robot body; a balancing part which is installed to be accessible to or apart from robot body; a driving device which drives so that the balancing part is easy to approach and apart from the robot body; and a controlling device which controls the driving device so that the balancing part moves in the opposite direction of the loading plates when the loading plates move toward loading location, and removing the weight maldistribution by baggage loaded on the loading plates. The driving device comprises; a rack connected to balancing part; a pinion which engages with the rack; and a driving motor which drives the pinion.

Description

Load loading robot with balancing for weight distribution compensation {LOADING ROBOT HAVING A BALANCING PART}

The present invention relates to a load-loading robot, and more particularly, to a load-loading robot having a balancing device capable of compensating the weight unevenness of the load so that the robot does not fall when loading a heavy load.

In the industry, various kinds of baggage loading robots are used to effectively transport the goods necessary for the production of the product. Such a robot generally has a robot body for operation of the robot itself, and a loading plate installed on the robot body to load loads. The loading plate is moved outward from the robot body and placed in a loading position so that an operator can easily carry out the loading work on the robot. In the state that the loading plate is placed in the loading position, the operator loads the load to the loading portion, and when loading of the load is completed, the loading plate is moved to the upper part of the robot body again. The robot carrying the load then moves itself to move the load to the desired position (or moves the loading plate loaded with the load to the desired position by the robot body), and the loading plate as described above for the operator to easily lower the load. Is moved back to the stowed position.

By the way, in the conventional conventional load-loading robot as described above, heavy loads on the loading plate in a state where the loading plate is moved to the loading position, for example, an LCD panel carrier or a flat panel display carrier. When loading a load such as a display carrier, a large moment is applied to the robot by the weight of the load. Therefore, the weight becomes largely ubiquitous toward the loading plate, and the robot may fall over. In particular, in the case of a load-loading robot that can move without being fixed to the ground, such as an unmanned vehicle, the robot is more likely to fall when a large moment is applied.

Therefore, an object of the present invention, by offsetting the ubiquitous of the weight generated when the load is loaded on the loading plate, even when loading a heavy load, the robot can be loaded without loading the load stably load To provide a robot.

1 and 2 are a perspective view of the load loading robot according to the present invention,

3 is a partially enlarged side cross-sectional view of the load-loading robot shown in FIGS. 1 and 2;

4 is a plan sectional view of FIG. 3;

5 is a plan sectional view of a load loading robot according to another embodiment of the present invention, and

6 is a side view illustrating the power transmission part of FIG. 5.

<Description of the code | symbol about the principal part of drawing>

10: robot main body 25: luggage

30: fixed part 40: loading part

45: first rack 53: balance weight

55: second rack 61: first pinion

62: second pinion 73: pulley

75: drive motor

Robot for loading goods according to the present invention for achieving the above object, the robot body; A loading unit having a loading plate capable of moving a position between a fixed part fixed to the robot body and a loading position spaced apart from the robot body; A balancing unit installed to be accessible and spaced apart from the robot body; Driving means for driving the balancing part to approach and to the robot body; And control means for controlling the driving means such that the balancing part is moved in a direction opposite to the moving direction of the loading plate when the loading plate is moved to the loading position, so as to offset the weight ubiquity by the load loaded on the loading plate. Include.

Here, the driving means, the rack connected to the balancing unit; A pinion engaged with the rack; And a drive motor for forward and reverse driving the pinion. Preferably, the loading plate further comprises a loading unit driving means for driving the positional movement between the fixed portion and the loading position, the control unit is linked to the loading unit the driving means and the loading so that the balancing unit is driven Control the secondary drive means.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are perspective views of the load-loading robot according to the present invention. The load-loading robot according to the present invention includes a robot body 10, a loading part 40, and a balancing part 50. 1 and 2 illustrate a state in which the loading part 40 is placed on the robot body 10 and moved outwardly from the robot body 10, respectively.

The robot body 10 serves as a base for supporting the loading unit 40 and has a plurality of wheels 13 at the bottom thereof to facilitate movement. Inside the robot body 10, a power generator for moving the robot and a control device for controlling the operation of the robot are installed. The upper surface of the robot body 10 is provided with a fixing plate 30 which functions as a fixing part for holding and supporting the loading part 40, the loading part 40 is installed on the fixed plate 30 have.

The loading part 40 includes first, second, and third plates 41, 42, and 43 that are sequentially stacked, and each of the plates 41, 42, and 43 has a guide groove formed at a portion in contact with each other. 47) and guide ribs 48 are slidably coupled to each other. Accordingly, the plates 41, 42, and 43 of the loading part 40 are sequentially stacked on the robot body 10 as shown in FIG. 1, and the robot body 10 as shown in FIG. 2. E) outward so that the third plate 43 can be moved between positions moved to a predetermined position (hereinafter referred to as a 'loading position').

The third plate 43 constitutes a loading plate on which the article 25 is loaded. When the worker loads the load on the loading plate 43 or lowers the load from the loading plate 43, the loading plate 43 is loaded as shown in FIG. 2 to facilitate the loading operation as necessary. The operation may be performed after operating the loading unit 40 to be drawn out to the position.

The balancing unit 50 is composed of a pair of rods 54 supported by the robot body 10 so as to be movable outward thereof, and a balance weight 53 provided at an outer end of the rod 54. The counterweight 53 is made of a material having a large weight to achieve the intended purpose of the present invention. The balancing unit 50 is movable outward in the direction opposite to the loading unit 40 on the same line as the moving line of the loading unit 40. The movement of the balancing unit 50 is controlled by a driving device installed inside the robot body 10, and the balancing unit 50 has a function of compensating for the weight deviation caused by the load on the loading unit 40 as described below. do.

3 and 4 show a driving device for driving the balancing unit 50 and the loading unit 40. The drive device is composed of a pair of racks 45 and 55, a pair of pinions 61 and 62, a pair of belts 71 and 72, and a drive motor 75. The driving device is controlled by a separate control unit (not shown).

The first rack 45 is fixed to the first plate 41 of the loading part 40, and the second rack 55 is connected to the rod 54 of the balancing part 50. The first rack 45 and the second rack 55 are engaged with the first pinion 61 and the second pinion 62, respectively. The first pinion 61 and the second pinion 62 are coaxially arranged. The first pinion 61 and the first pinion 62 are connected to the pulley 75 of the driving motor 75 by the first belt 71 and the second belt 72, respectively. As the drive motor 75, a motor capable of forward and reverse driving is used.

When the user operates an operation unit (not shown) to load the load, the control unit controls the drive motor 75 according to the operated signal. When the driving motor 75 operates, both the first and second pinions 61 and 62 rotate, and thus the first rack 45 and the second rack 55 are moved. Thus, the first plate 41 is moved to the left, and the rod 54 and the counterweight 53 are moved to the right, in contrast.

Although not shown in the figure, each of the plates 41, 42, 43 is connected by a separate mechanical mechanism to move to the telescopic structure. Accordingly, when the first plate 41 is moved to the left side, the second and third plates 42 and 43 are relatively moved to the left side with respect to the plates facing the lower side thereof, respectively, as shown in FIG. 2. Elongate. Thus, the third plate 43 is located at the loading position. In this state, the operator puts the article 25 on the third plate 43. At this time, even if the load of the relatively large load is loaded on the third plate 43, the load of the load is canceled by the counterweight 53 moved to the right, so that the robot does not fall. Therefore, the operation | work which loads the big weight goods can be performed stably. When the loading operation is completed, the driving motor 75 is driven in the reverse direction, and thus the loading plate 43 and the counterweight 53 on which the load 25 is loaded are introduced into the original position.

5 and 6 illustrate another embodiment of the present invention. In the description of the present embodiment, the same reference numerals are given to the same parts as the above-described embodiment.

In the above-described embodiment, the loading unit 40 and the balancing unit 50 are driven at the same time by one driving motor 75. However, in the present embodiment, the loading unit 40 using two motors 85 and 95 is used. ) And the balancing unit 50 are driven separately. That is, the first pinion 61 is connected to the pulley 83 of the first driving motor 85 by the first belt 71, and the second pinion 62 is formed by the second belt 72. It is connected to the pulley 93 of the two-drive motor 95. Therefore, when the first driving motor 85 operates, the loading unit 40 is driven, and when the second driving motor 95 operates, the balancing unit 50 operates. The operator may control the elongation degree of the loading part 40 and the balancing part 50 to be different as needed. In addition, the controller may control the first and second driving motors 83 and 93 simultaneously according to a user's operation so that the balancing unit 50 may be extended in correspondence with the degree of extension of the loading unit 40.

In addition, in the embodiments of the present invention, the driving motor 75 (for the first embodiment) or the first driving motor 85 (both when moving the loading part 40 to the loading position or drawing in from the loading position. In the case of the first embodiment), but to drive, it can be configured to move manually without such a drive motor (75 or 85).

As described above, according to the present invention, when the heavy load is loaded on the loading plate, the weight deviation by the load is compensated by the counterweight, so that the robot does not fall and the loading operation of the load can be performed stably. Will be.

Claims (3)

In the load-loading robot, Robot body; A loading unit having a loading plate capable of moving a position between a fixed part fixed to the robot body and a loading position spaced apart from the robot body; A balancing unit installed to be accessible and spaced apart from the robot body; Driving means for driving the balancing part to approach and to the robot body; And And control means for controlling the driving means such that the balancing part is moved in a direction opposite to the moving direction of the loading plate when the loading plate is moved to the loading position, thereby offsetting the weight ubiquity by the load loaded on the loading plate. A load loading robot, characterized in that. The method of claim 1, The drive means, A rack connected to the balancing unit; A pinion engaged with the rack; And And a drive motor for forward and reverse driving the pinion. The method according to claim 1 or 2, And a loading unit driving means for driving the loading plate to move the position between the fixed portion and the loading position, wherein the control unit is configured to drive the balancing unit in association with the loading unit. Robot for loading loads, characterized in that for controlling.