The present invention relates to a robot and a method of operating the same.
Conventionally, there are known automatic cup-feeding techniques. For example, there is a known technique in which a cup-separating cum is provided such that the cup-separating cum is engaged with a stack of cups, and as a result of the cup-separating cum rotating once, only the bottom one of the cups is separated from the stack, and falls off (see Patent Literature 1, for example).
There is another known technique in which a blade-shaped stopper is inserted between the lips of adjacent paper cups in a paper cup stack, and thereby paper cups are separated from the stack (see Patent Literature 2, for example).
There is yet another known technique in which a claw of an air cylinder is projected, and the top edge of a bottom one of paper cups is pushed down by the projected claw, thereby separating the bottom paper cup from the immediately above paper cup (see Patent Literature 3, for example).
PTL 1: Japanese Laid-Open Patent Application Publication No. 2002-230639 (see, in particular, paragraph [0003] and FIG. 3)
PTL 2: Japanese Laid-Open Patent Application Publication No. H04-078109 (see, in particular, FIG. 1)
PTL 3: Japanese Utility Model Registration No. 3090574 (see, in particular, paragraph [0006] and FIG. 4)
In recent years, in various fields, it has been proposed that a robot and a worker should work together in the same working space in cooperation with each other in order to improve productivity. However, in the above-described conventional techniques, no robot is used for automatic cup feeding. Here, cups are merely one example of containers, and it is preferable to be able to automatically feed the widest possible variety of containers.
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a robot capable of automatically feeding containers by using arms and a method of operating the robot.
In order to solve the above-described problems, a robot according to one aspect of the present invention is a robot for sequentially separating containers from a container stack. Each of the containers has an open top portion, a closed bottom portion, and such a shape that each container gets gradually thinner from the top portion to the bottom portion. The container stack is a stack of the containers that are sequentially stacked such that every two containers adjacent to each other in an upward-downward direction in the stack are arranged in such a manner that an upper one of the two containers is inserted from its bottom portion into an internal space of a lower one of the two containers, such that the top portion of the upper container is exposed. The robot includes: a second arm including a second hand at a distal end thereof, the second hand being operable to grip each of the containers; a first arm including a first hand at a distal end thereof, the first hand being operable to grip each of the containers; and a controller configured to control operations of the first and second arms. The controller is configured to control the first and second arms such that: the second hand of the second arm holds the container stack by gripping the top portion of a bottom one of the containers of the container stack; then, the first hand of the first arm holds the container stack by gripping a portion of the bottom container of the container stack, such that the portion gripped by the first hand is positioned lower than the portion gripped by the second hand; thereafter, the second hand of the second arm releases the top portion of the bottom container, and then holds the container stack by gripping the top portion of a second container from a bottom of the container stack; and subsequently, the first hand of the first arm moves the bottom container downward, and separates the bottom container from the container stack.
According to the above configuration, the first and second arms hold the container stack by the second arm, then re-hold it by the first arm, and thereafter re-hold it by the second arm, sequentially. In a state where the second arm holds the container stack by gripping the top portion of the second container from the bottom of the container stack, the first arm moves the bottom container downward, thereby separating the bottom container from the container stack. In this manner, automatic feeding of each container can be performed by using the arms. In addition, since the feed speed of the containers depends on the operating speed of the arms, by increasing the operating speed of the arms, the feed speed of the containers (i.e., work efficiency) can be improved.
The controller may be configured to control the first and second arms such that: when the second hand of the second arm holds the container stack by gripping the top portion of the bottom container of the container stack, the second hand is positioned at a predetermined height position, and then, the second hand moves upward by a predetermined height before the second hand grips the top portion of the second container from the bottom of the container stack, and the second hand returns to the predetermined height position after the first hand of the first arm has moved the bottom container downward.
According to the above configuration, the operation by the second hand of the second arm to hold the container stack at the predetermined height position is the starting operation of the container separating operation, and the operation by the second hand to return to the predetermined height position after the first hand of the first arm has moved the bottom container downward is the ending operation of the container separating operation. This makes it possible to repeatedly perform the container separating operation.
Each of the first hand and the second hand may be configured to grip each of the containers by applying sandwiching force to the gripped container in a horizontal direction.
According to the above configuration, each of the containers of the container stack, in which the containers are sequentially stacked upward, can be properly gripped.
Each of the containers may be a cup.
According to the above configuration, in a state where the second arm holds the container stack by gripping the top portion of the second container from the bottom of the container stack, the first arm grips and moves the bottom container downward, thereby separating the bottom container from the container stack. Accordingly, even if the container stack is a cup stack in which adjacent cups are closely in contact with each other due to the elasticity of the cups, each of the cups can be properly separated from the cup stack.
A method of operating a robot according to another aspect of the present invention is a method of operating a robot for sequentially separating containers from a container stack. Each of the containers has an open top portion, a closed bottom portion, and such a shape that each container gets gradually thinner from the top portion to the bottom portion. The container stack is a stack of the containers that are sequentially stacked such that every two containers adjacent to each other in an upward-downward direction in the stack are arranged in such a manner that an upper one of the two containers is inserted from its bottom portion into an internal space of a lower one of the two containers, such that the top portion of the upper container is exposed. The robot includes: a second arm including a second hand at a distal end thereof, the second hand being operable to grip each of the containers; and a first arm including a first hand at a distal end thereof, the first hand being operable to grip each of the containers. The method includes: holding the container stack by gripping the top portion of a bottom one of the containers of the container stack by the second hand of the second arm; then, holding the container stack by gripping a portion of the bottom container of the container stack by the first hand of the first arm, such that the portion gripped by the first hand is positioned lower than the portion gripped by the second hand; thereafter, releasing the top portion of the bottom container by the second hand of the second arm; then, holding the container stack by gripping the top portion of a second container from a bottom of the container stack by the second hand of the second arm; and subsequently, moving the bottom container downward and separating the bottom container from the container stack by the first hand of the first arm.
According to the above configuration, the first and second arms hold the container stack by the second arm, then re-hold it by the first arm, and thereafter re-hold it by the second arm, sequentially. In a state where the second arm holds the container stack by gripping the top portion of the second container from the bottom of the container stack, the first arm moves the bottom container downward, thereby separating the bottom container from the container stack. In this manner, automatic feeding of each container can be performed by using the arms. In addition, since the feed speed of the containers depends on the operating speed of the arms, by increasing the operating speed of the arms, the feed speed of the containers (i.e., work efficiency) can be improved.
The present invention has an advantage of being able to provide a robot capable of automatically feeding containers by using arms and a method of operating the robot.
Hereinafter, an embodiment of the present invention is described with reference to the drawings. In the drawings, the same or corresponding elements are denoted by the same reference signs, and repeating the same descriptions is avoided below. The drawings show each component schematically in order to facilitate the understanding thereof. Therefore, some elements that are irrelevant to the present invention may be omitted from the drawings, and there are cases where some of the drawings do not match each other. Also, the dimensions of the elements shown in the drawings are not necessarily precise.
[Configuration]
With reference to
In this example, the arm part 15 is constituted by a first link 15a and a second link 15b. The first link 15a is coupled by a rotary joint J1 to a base shaft 16, which is fixed to the upper surface of the base 12. The first link 15a is rotatable about a rotational axis L1, which extends through the shaft center of the base shaft 16. The second link 15b is coupled to the distal end portion of the first link 15a by a rotary joint J2. The second link 15b is rotatable about a rotational axis L2, which is defined at the distal end portion of the first link 15a.
The wrist part 17 is constituted by a lifting/lowering portion 17a and a rotating portion 17b. The lifting/lowering portion 17a is coupled to the distal end portion of the second link 15b by a prismatic joint J3. The lifting/lowering portion 17a is movable by being lifted/lowered relative to the second link 15b. The rotating portion 17b is coupled to the lower end of the lifting/lowering portion 17a by a rotary joint J4. The rotating portion 17b is rotatable about a rotational axis L3, which is defined at the lower end of the lifting/lowering portion 17a.
The end effectors (18 and 19) are coupled to the rotating portions 17b of the respective right and left wrist parts 17. The end effectors (18 and 19) are provided at the distal ends of the respective right and left arms 13. In this example, each of the end effectors (18 and 19) is configured as a hand. The configurations of the hands will be described below.
Each of the arms 13A and 13B configured as above includes the joints J1 to J4. Each of the arms 13 is provided with, for example: driving servomotors (not shown) corresponding to the respective joints J1 to J4; and encoders (not shown) configured to detect rotation angles of the respective servomotors. The rotational axes L1 of the respective first links 15a of the two arms 13A and 13B are positioned on the same straight line. The first link 15a of one arm 13 and the first link 15a of the other arm 13 are positioned at different heights such that they are displaced from each other in the upward-downward direction.
With reference to
The second gripper 23, which includes a pair of claws, is formed on the other end of the first portion. The pair of claws is provided such that the claws are able to open and close in the horizontal direction (perpendicular to the rotational axis L3). Groove-shaped recesses that correspond to the shape of a container are formed in the inner surfaces the pair of claws. In this example, each of the groove-shaped recesses has an arc-shaped cross section, such that the groove-shaped recesses form a pillar-like shape extending in the upward-downward direction (parallel to the rotational axis L3). Each of the pair of claws is made of a material such as metal or resin, for example.
Each of the first gripper 22 and the second gripper 23 is configured as, for example, a chuck that is driven to open and close by air or a motor (in this example, air).
In the above configuration, the discharge direction of a discharger 32 gripped by the second gripper 23 of the first hand 18 of the first arm 13A coincides with the direction of the rotational axis L3, and the direction from the bottom portion to the top portion of the container 42 gripped by the first gripper 22 coincides with the direction of the rotational axis L3 (see FIG. 7E). According to this configuration, since the rotational axis L3 coincides with the vertical direction, even when the first arm is not controlled, the container 42 gripped by the first gripper 22 faces in the upward direction, and the discharge direction of the discharger 32 gripped by the second gripper 23 is the downward direction. This makes it possible to readily perform a container placing and food/drink material filling operation.
The second arm 13B includes a second hand 19 as an end effector. The second hand 19 includes a base portion 24 and a gripper 25. The base portion 24 is a flat plate-shaped portion, and one end thereof is fixed to the rotating portion 17b. The gripper 25, which includes a pair of claws, is provided on the other end of the base portion 24. The pair of claws is provided such that the claws are able to open and close in the horizontal direction (perpendicular to the rotational axis L3). Groove-shaped recesses that correspond to the shape of a container are formed in the inner surfaces the pair of claws. In this example, each of the groove-shaped recesses has an arc-shaped cross section, such that the groove-shaped recesses form a pillar-like shape extending in the upward-downward direction (parallel to the rotational axis L3). Each of the pair of claws is constituted by a stiff body portion and an elastic layer covering the inner surface of the body portion. The stiff body portion is made of metal or resin, for example. The elastic layer is made of rubber or hard sponge, for example. Accordingly, when the pair of claws grips a container 42 in a sandwiching manner, the sandwiching force is applied to the container 42 in the horizontal direction, and in this manner, each of the containers 42 of the container stack 41, in which the containers 42 are sequentially stacked upward, can be properly gripped. In addition, when the pair of claws grips the container 42 in the sandwiching manner, the elastic layers of the respective inner surfaces of the pair of claws are depressed, and friction force occurs between the container and the claws due to the elastic force of the elastic layers. As a result, the pair of claws can grip the container 42 without causing the container 42 to slip off the claws.
In the above configuration, the direction from the bottom portion to the top portion of the container 42 of the container stack 41 gripped by the gripper 25 of the second hand 19 of the second arm 13B coincides with the direction of the rotational axis L3 (i.e., the vertical direction) (see
The width (i.e., the dimension in the upward-downward direction) of the gripper 25 of the second arm 13B is greater than the width of the first gripper 22 of the first arm 13A. The reason for this is to allow the gripper 25 of the second arm 13B to stably hold the container stack 41 since the container stack 41 is held mainly by the gripper 25. The gripper 25 of the second arm 13B is configured as, for example, a chuck that is driven to open and close by air or a motor (in this example, air).
The storage unit 14b stores a basic program as a robot controller program and information such as various fixed data. The arithmetic operation unit 14a controls various operations of the dual-arm robot 11 by loading and executing, for example, the basic program stored in the storage unit 14b. Specifically, the arithmetic operation unit 14a generates a control command for the dual-arm robot 11, and outputs the generated control command to the servo control unit 14c. The servo control unit 14c is configured to control the driving of the servomotors corresponding to the joints J1 to J4 of each of the arms 13 of the dual-arm robot 11 based on the control command generated by the arithmetic operation unit 14a. The controller 14 also controls the operations of the first gripper 22 and the second gripper 23 of the first hand 18 and the operations of the gripper 25 of the second hand. Thus, the controller 14 controls the operations of the overall dual-arm robot 1.
Next, an application example (usage example) of the dual-arm robot 11 configured as above is described with reference to
<Working Site>
With reference to
Meanwhile, a container stand 35 is disposed in front of the conveying body 51 near the first arm of the dual-arm robot 11. A plurality of container stacks 41 are arranged on the container stand 35 at their predetermined positions.
<Container Stack>
Each of the containers 42 is required to have an open top portion, a closed bottom portion, and such a shape that each container 42 gets gradually thinner from the top portion to the bottom portion. In this example, each container 42 is a cup.
Each of the container stacks 41 is a stack of the containers that are sequentially stacked such that every two containers adjacent to each other in the upward-downward direction in the stack are arranged in such a manner that the upper one of the two containers is inserted from its bottom portion into the internal space of the lower one of the two containers, such that the top portion of the upper container is exposed. In other words, each container stack 41 is formed by stacking the containers 42 in a non-inverted manner. The “non-inverted” stacking herein is the opposite of “inverted” stacking, and the “non-inverted” stacking means that each container 42 in the stack is in such an orientation that the direction from the bottom portion to the top portion of the container 42 is the upward direction.
Next, operations of the dual-arm robot configured as above are described based on
As shown in
Next, as shown in
Next, as shown in
Next, as shown in
Next, as shown in
Next, as shown in
Then, the second hand 19 (gripper 25) of the second arm 13B holds the container stack 41 (step S5).
Next, as shown in
Next, as shown in
In step S4, if no container 42 is present above the bottom container 42, i.e., if the container 42 currently gripped by the first hand 18 (first gripper 22) of the first arm is the top container (i.e., the last container) of the container stack 41, then the try to grip the second container from the bottom of the container stack 41 fails (NO in step S4). In this case, in the container separating operation, the first hand 18 (first gripper 22) of the first arm moves the bottom container 42 downward, separates the bottom container 42 from the container stack 41, and places and releases the bottom container 42 on the conveying body 51 (step S9). Thereafter, returning to step S1, the second hand (gripper 25) grips the next container stack 41, and is positioned at the separating position.
After step S7, the controller 14 determines whether or not to end the container separating operation (step S8). If the controller 14 determines not to end the container separating operation (NO in step S8), the controller 14 returns to step S2. If the controller 14 determines to end the container separating operation (YES in step S8), the controller 14 ends the container separating operation.
Concurrently with the container separating operation, the food/drink filling operation is performed in a manner described below.
With reference to
As described above, according to the present embodiment, the first and second arms 13A and 13B hold the container stack 41 by the second arm 13B, then re-hold it by the first arm 13A, and thereafter re-hold it by the second arm 13B, sequentially. In a state where the second arm 13B holds the container stack 41 by gripping the top portion of the second container from the bottom of the container stack 41, the first arm 13A moves the bottom container downward, thereby separating the bottom container 42 from the container stack 41. In this manner, automatic feeding of each container 42 can be performed by using the arms 13A and 13B. In addition, since the feed speed of the containers 42 depends on the operating speed of the arms 13A and 13B, by increasing the operating speed of the arms 13A and 13B, the feed speed of the containers 42 (i.e., work efficiency) can be improved.
[Variations]
According to the dual-arm robot 11 of the present embodiment, also when the container stack is the above-described tea bowl stack 41, the container separating operation can be properly performed, and thereby automatic feeding of the tea bowls 42 can be performed.
The containers are not limited to the above-described examples, but may be trays, bowls, dishes, etc.
The working site is not limited to a working site relating to food products, but may be a different kind of working site, so long as the working site is a site where a robot and a worker work together in the same working space in cooperation with each other.
From the foregoing description, numerous modifications and other embodiments of the present invention are obvious to a person skilled in the art. Therefore, the foregoing description should be interpreted only as an example and is provided for the purpose of teaching the best mode for carrying out the present invention to a person skilled in the art. The structural and/or functional details may be substantially altered without departing from the spirit of the present invention.
The robot and the method of operating the same according to the present invention are useful as a robot capable of automatically feeding containers by using arms and a method of operating the robot.
Number | Date | Country | Kind |
---|---|---|---|
2017-074060 | Apr 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2018/013573 | 3/30/2018 | WO | 00 |