KR102530303B1 - Processing system for cnc lathe using 5-axis robot arm - Google Patents

Abstract

The present invention uses a 5-axis vertical multi-joint robot on a CNC lathe, which is a machine tool that automatically rotates and processes various metal materials through numerical control, to efficiently and automatically move materials to input, process, remove, and load. It relates to a CNC lathe processing system using a 5-axis robot arm with a cover frame having a processing chamber inside and provided with a door to open and close the processing chamber from the outside, and rotation on one side of the inside of the processing chamber of the cover frame. A CNC lathe including a fixed chuck that is installed to be capable of detachably fixing the workpiece to be processed, and a tool post on which a tool for processing the workpiece fixed to the fixed chuck is mounted while moving inside the processing chamber of the cover frame. And, an inlet stocker spaced apart from the front left side of the door of the cover frame and loaded with a plurality of materials to be processed, and spaced apart from the front right side of the door of the cover frame and processed by the CNC lathe. An outlet stocker, through which materials are loaded and ejected, and a 5-axis vertical articulated robot are installed at a distance in front of the door of the cover frame, receive the material to be processed loaded in the inlet stocker, and perform the above process on the fixed chuck of the CNC lathe. It includes a robot arm for injecting the material, removing the processed material from the fixed chuck of the CNC lathe and loading it into the outlet stocker.

Description

CNC lathe processing system using 5-axis robot arm {PROCESSING SYSTEM FOR CNC LATHE USING 5-AXIS ROBOT ARM}

The present invention uses a 5-axis vertical multi-joint robot on a CNC lathe, which is a machine tool that automatically rotates and processes various metal materials through numerical control, to efficiently and automatically move materials to input, process, remove, and load. It is about a CNC lathe processing system using a 5-axis robot arm.

In general, a lathe is a machine tool that rotates various metal materials and cuts them into bytes, and a CNC (Computerized Numerical Control) lathe generates numerical data that selectively indicates processing dimensions, shapes, required tools, feed rates, etc. It is a type of machining center in which a control device is combined with a lathe to automatically determine the position of a cutting tool or perform automatic cutting by connecting the recorded program directly to a computer in real time.

As shown in FIGS. 1 and 2, such a CNC lathe 1 generally has a processing chamber 11 formed therein, and a cover frame provided with a door 12 to open and close the processing chamber 11 from the outside ( 10), a fixing chuck 20 rotatably installed on one side of the inside of the processing chamber 11 of the cover frame 10 and detachably fixing the material M to be processed, and the cover frame ( 10) includes a tool post 30 equipped with a plurality of tools 31 for processing the material M fixed to the fixed chuck 20 while moving inside the processing chamber 11.

The material M, which is the object to be processed of the CNC lathe 1, may be various items, and accordingly, the shape of the fixed chuck 20 or the tool 31 mounted on the tool post 30 may be variously replaced or changed. can However, under the mass production system of a specific item, the size of the cover frame 10 or the shape of the fixed chuck 20 and the type of tool 31 mounted on the tool post 30 may be specified to suit the item. .

Looking at the process of processing the material M using the above-described general CNC lathe 1, after fixing the material M to be processed by biting the fixed chuck 20, the fixed chuck 20 is rotated, and the tool post The machining is completed while the bite of the tool 31 selected by moving the 30 cuts the material M.

At this time, in order to repeatedly process the material M using the CNC lathe 1, the door 12 of the cover frame 10 to fix or take out the material M to the fixed chuck 20 before and after the first machining, respectively. Must be opened and closed, and secondly, in the process, the operator must hold the material (M) by hand and fix it to the fixed chuck (20) or take it out. In this case, if the worker directly grabs and fixes or takes out the material (M) under the automatic mass production system, the worker must always be attached to the CNC lathe (1), which increases labor costs and makes it difficult to guarantee constant continuity of work, thereby reducing productivity. have no choice but to call

In order to replace the manual work of the operator, an articulated robot arm or a gantry-type robot arm that automatically inserts and withdraws the material M to the front of the door 12 of the cover frame 10 is separately installed. That is, the door 12 of the cover frame 10 opens and closes while the gripper grips the material M supplied through the material loading unit or the conveyor instead of the operator's hand and moves or rotates in two or three axes. When closed, the material M is put into or taken out of the processing chamber 11 . For example, as a prior art, there is 'automatic work piece supply and take-out device for C&C lathe' in Patent Registration No. 10-1341118 or 'work piece feed and take-out device for C&C lathe' in Registered Utility Model No. 20-0393854.

Through this, the material (M) is automatically put in and taken out before and after processing of the material (M) without operator intervention through an articulated robot arm or a gantry-type robot arm that can automatically put in and take out the material (M). By doing so, it is possible to reduce labor costs and increase productivity by ensuring work continuity.

As described above, when an articulated robot arm or a gantry-type robot arm capable of automatically inserting and withdrawing the material M is installed, a stocker capable of efficiently loading the material M is also required. As such a stocker, a plurality of loading parts are installed in a chain-sprocket endless track type, such as a 'stocker for material supply' in Registered Utility Model No. 20-0407738 and a 'double-use loading means' in Patent No. 10-2199404, and the loading part It has a structure in which a plurality of materials (M) are mounted by a plurality of vertical rods that are close to or spaced apart from each other according to various diameters of the material (M) while being loaded up and down.

However, in the stocker according to the prior art, first, a plurality of loading parts on which the material M is loaded have a long rectangular structure in a chain-sprocket endless track type, so space utilization is poor, and second, the material to be processed in a floor-fixed type In order to load (M), a large amount of material (M) must be brought to the stocker and loaded with difficulty, and there is a problem in that it is difficult to fix the exact position when the loading part of the third chain-sprocket endless track type moves intermittently.

In particular, in the case of a CNC lathe processing system according to the prior art equipped with a stocker having such a problem, the installation position and application structure of the multi-joint robot arm or gantry robot arm have no choice but to match it, and the material is automatically moved to input, process However, it is not efficient in the process of removing and loading, which inevitably leads to a decrease in productivity and work quality.

An object of the present invention, which was made to solve the above problems, is to simplify the structure of the stocker so that a plurality of loading parts can be moved in an intermittent rotation type, and to achieve accurate positioning during intermittent rotation of the loading part, In particular, it is equipped with a pair of inlet stocker and outlet stocker to load materials for supply and discharge of materials, and an efficient work flow can be established by a 5-axis vertical articulated robot, which can improve productivity and work quality. It is to provide a CNC lathe processing system using an axis robot arm.

Other objects, particular advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments taken in conjunction with the accompanying drawings.

In order to achieve the above object, a CNC lathe processing system using a 5-axis robot arm according to the present invention includes a cover frame having a processing chamber formed therein and having a door to open and close the processing chamber from the outside, and the cover A fixed chuck rotatably installed on one side of the inside of the processing chamber of the frame and detachably fixing the material to be processed, and a tool for processing the material fixed to the fixed chuck while moving inside the processing chamber of the cover frame A CNC lathe including a mounted tool post, an inlet stocker installed at a distance on the front left side of the door of the cover frame and loaded with a plurality of materials to be processed, and a spaced apart installation on the right front side at the front door of the cover frame, An outlet stocker, in which a plurality of materials processed by the CNC lathe are loaded and discharged, and a 5-axis vertical articulated robot are installed at a distance in front of the door of the cover frame and supply the materials loaded on the inlet stocker to be processed. and a robot arm for receiving and inputting the material to the fixed chuck of the CNC lathe, removing the processed material from the fixed chuck of the CNC lathe, and loading the outlet stocker.

In addition, the robot arm includes a base frame, a first axis link frame installed to be vertically movable with respect to the base frame, and one end rotatably installed left and right on the top of the first axis link frame, and the other end The horizontally extended second axis link frame, one end rotatably installed left and right on the upper part of the other end of the second axis link frame, and the third axis link frame having the other end horizontally extended, and one end of the third axis link frame It is installed rotatably left and right at the lower end of the axis link frame, and the other end is horizontally extended, and the fourth axis link frame is installed at an angle of 45 degrees to the lower end of the other end of the fourth axis link frame, and is installed at an angle of 90 degrees. It is characterized by including a fifth axis link frame provided with a pair of first and second grippers rotatably so as to look in vertical and horizontal directions.

In addition, the robot arm waits by holding the material to be processed loaded on the inlet stocker with the first gripper, and when the door of the cover frame is opened, the material processed from the fixed chuck with the second gripper. After gripping and removing, the material to be processed, which is gripped by the first gripper, is put into the fixed chuck, and the material, which is gripped by the second gripper, is repeatedly loaded into the outlet stocker.

In addition, each of the inlet stocker and outlet stocker has a stocker frame, a circular rotating plate rotatably installed on top of the stocker frame, and each is arranged radially at a constant angle with respect to the rotation center of the rotating plate, each A plurality of loading units for vertically stacking a plurality of materials, a rotation operation unit installed inside the stocker frame and intermittently rotating the rotation plate at a predetermined angle, and a rotation operation unit installed inside the stocker frame and operating the rotation It is characterized in that it comprises a position fixing unit for fixing the position of the rotation plate intermittently rotated by the unit at a predetermined angle.

In addition, each of the inlet stocker and the outlet stocker includes a moving wheel installed below the stocker frame to move the stocker frame, and a floor fixing unit installed below the stocker frame and fixing the stocker frame to the floor. It is characterized in that it further comprises.

In addition, each of the loading parts is installed to be able to move up and down on the upper part of the rotating plate, and a circular loading plate for vertically stacking a plurality of materials, and each penetrates the loading plate in the radial direction of the loading plate. It is characterized in that it includes a plurality of mounting rods for mounting the material by contacting the outer circumferential surface of the material while being spaced apart or close to each other.

In addition, each of the inlet stocker and outlet stocker defines a loading position as a position of one loading plate located at a specific angle of the rotating plate, and is installed inside the stocker frame to correspond to the loading position, Further comprising a loading plate lifting unit for lifting and lowering the loading plate in position, and the loading position is defined as a supply loading position in the case of the inlet stocker and a withdrawal loading position in the case of the outlet stocker. .

In addition, the loading plate elevating unit includes an elevating motor that rotates forward and backward, a ball screw that rotates forward and reverse by receiving rotational force from the elevating motor, and an elevating nut that is coupled to the ball screw and moves upward and downward according to the forward and reverse rotation of the ball screw. And, characterized in that it comprises a plurality of lifting rods coupled to the lifting nut and lifting the loading plate up and down while lifting together.

In addition, the rotation operation unit includes a rotation motor rotating in one direction, a main shaft coupled coaxially to the lower portion of the rotation plate and rotating together, and a power transmission means for transmitting rotational force of the rotation motor to the main shaft. to be characterized

In addition, the power transmission means includes a main sprocket coupled to the rotating shaft of the rotary motor and rotating, a driven sprocket coupled coaxially to the main shaft and rotating, and a chain connecting the main sprocket and the driven sprocket. to be characterized

In addition, the rotary plate has a plurality of position fixing grooves formed in the lower portion so as to correspond to each of the loading parts arranged at a predetermined angle, and the position fixing part determines the position of one loading plate located at a specific angle of the rotary plate. Defined as a fixed position, a cylinder fixedly installed inside the stocker frame to correspond to the fixed position, a lifting rod that moves up and down according to the operation of the cylinder, and a lifting rod coupled to the lifting rod to move up and down together to the fixed position It is characterized in that it includes a position fixing protrusion for inserting into the position fixing groove of the corresponding rotation plate and fixing the position.

In addition, the power transmission means includes a Geneva driven wheel in which the center of rotation is coupled to the main shaft in a disk shape and rotates together, and a plurality of driving grooves are formed at a radially constant angle around the outer circumference, and a rotation shaft of the rotary motor in a disk shape. It is coupled to and rotates, and a single driving pin protruding from the center of rotation is inserted into the drive groove of the Geneva driven wheel to intermittently rotate the Geneva driven wheel at a predetermined angle. .

In addition, the position fixing part is a ball plunger that is fixedly installed and spaced apart from the Geneva driving wheel, and an operating ball elastically operated by a spring is inserted into the driving groove of the Geneva driven wheel to fix the position of the Geneva driven wheel. to be

The CNC lathe processing system using a 5-axis robot arm according to the present invention simplifies the structure of the stocker so that a plurality of loading parts can be moved in an intermittent rotation type, and enables accurate position fixation during intermittent rotation of the loading parts, In particular, it is equipped with a pair of inlet stockers and outlet stockers that load materials for supply and discharge of materials, and an efficient work flow can be established by the robot arm, a 5-axis vertical multi-joint robot, which can improve productivity and work quality. There are possible effects.

1 and 2 are perspective views showing a general CNC lathe,
3 is a plan view showing an embodiment of a CNC lathe processing system using a 5-axis robot arm according to the present invention;
4 is a side cross-sectional view showing a robot arm in the embodiment of FIG. 3;
5 is a plan view showing a state in which the robot arm receives the material to be processed from the inlet stocker in the embodiment of FIG. 3;
6 is a side cross-sectional view of main parts sequentially showing the operation process of the first and second grippers of the robot arm to receive the material to be processed from the inlet stocker in correspondence with the embodiment of FIG. 5;
7 is a plan view showing a state in which the robot arm in the embodiment of FIG. 3 removes the processed material from the fixed chuck of the CNC lathe and then inserts the material to be processed;
8 is a main part side showing the operation process of the first and second grippers of the robot arm in order to input the material to be processed after removing the processed material from the fixed chuck of the CNC lathe in correspondence with the embodiment of FIG. 7 is a cross section,
9 is a plan view showing a state in which the robot arm withdraws and loads the processed material in the outlet stocker in the embodiment of FIG. 3;
10 is a side cross-sectional view of main parts sequentially showing the operation process of the first and second grippers of the robot arm to eject and load the processed material in the outlet stocker in correspondence with the embodiment of FIG. 9;
11 is a plan view showing an inlet stocker or an outlet stocker in the embodiment of FIG. 3;
12 is a plan view showing a state in which materials are loaded in the loading unit in the embodiment of FIG. 11;
13 is a planar perspective view showing a first embodiment of a rotation operating unit, a position fixing unit, and a loading plate lifting unit installed inside the stocker frame in the embodiment of FIG. 11;
14 is a cross-sectional side view of the embodiment of FIG. 13 viewed along line A-A';
15 is an enlarged side cross-sectional view of a rotary operation unit in the embodiment of FIG. 14;
16 is a cross-sectional side view of the embodiment of FIG. 13 viewed along line BB';
17 and 18 are side cross-sectional views showing an enlarged operation process of the position fixing unit in the embodiment of FIG. 16;
19 is a planar perspective view showing a second embodiment of a rotary operation unit, a position fixing unit, and a loading plate elevating unit installed inside the stocker frame in the embodiment of FIG. 11;
20 is a cross-sectional side view of the embodiment of FIG. 19 viewed along the line C-C';
21 is an enlarged side cross-sectional view of a rotation operation unit and a position fixing unit in the embodiment of FIG. 20;
FIG. 22 is an enlarged plan view of a position fixing unit together with a Geneva drive wheel and a Geneva driven wheel, which are power transmission means of the rotary operation unit in the embodiment of FIG. 21;
FIG. 23 is a plan view illustrating an operation process of intermittently rotating at a constant angle based on the embodiment of FIG. 22 .

Hereinafter, a preferred embodiment of a CNC lathe processing system using a 5-axis robot arm according to the present invention will be described in detail with reference to the accompanying drawings.

A CNC lathe processing system using a 5-axis robot arm according to the present invention includes a CNC lathe 1, an inlet stocker 2, as shown in FIGS. 3 to 5, 7, 9, and 11 to 14 with reference to FIGS. 1 and 2. ), an outlet stocker (3) and a robot arm (4).

First, the CNC lathe 1 includes a cover frame 10, a fixed chuck 20 and a tool post 30 as shown in FIG. 3 with reference to FIGS. 1 and 2, and the cover frame 10 As an exterior of a machine tool, a processing chamber 11 is formed inside, and a door 12 is provided to open and close the processing chamber 11 from the outside. The fixing chuck 20 is rotatably installed on one side inside the processing chamber 11 of the cover frame 10 and detachably fixes the material M to be processed. In addition, the tool post 30 is equipped with a plurality of tools 31 for processing the material M fixed to the fixed chuck 20 while moving inside the processing chamber 11 of the cover frame 10. . The above-described cover frame 10, fixing chuck 20, and tool post 30 equipped with a plurality of tools 31 are general configurations of the CNC lathe 1, and detailed descriptions of their configurations and functions will be omitted.

Next, to process through the robot arm 4 installed in front of the CNC lathe 1 together with a pair of inlet stockers 2 and outlet stockers 3 installed on the front left and right sides of the CNC lathe 1, respectively. It is possible to automatically move the material (M) to be put into the CNC lathe (1), process, remove and efficiently load it.

Specifically, as shown in FIG. 3, the inlet stocker 2 is spaced apart from the front left side of the door 12 of the cover frame 10, and a plurality of materials M to be processed are loaded and supplied. In addition, the outlet stocker 3 is spaced apart from the front right side of the door 12 of the cover frame 10, and a plurality of materials M processed by the CNC lathe 1 are loaded and discharged.

At this time, the robot arm 4 is installed at a distance in front of the door of the cover frame 10 with a 5-axis vertical multi-joint as shown in FIGS. When the material M is supplied, the material M is put into the fixed chuck 20 of the CNC lathe 1, and the material M processed from the fixed chuck 20 of the CNC lathe 1 It is removed and loaded into the outlet stocker (3).

As shown in FIG. 4, the robot arm 4 includes a base frame 40, a first axis link frame 50 installed to be vertically movable with respect to the base frame 40, and one end of the first The second axis link frame 60 is installed rotatably left and right on the upper part of the one-axis link frame 50, and the other end extends horizontally, and one end is left and right on the upper part of the other end of the second axis link frame 60. A third axis link frame 70 rotatably installed, the other end extending horizontally, and one end rotatably installed left and right at the bottom of the other end of the third axis link frame 70, and the other end horizontally An extended 4th axis link frame 80, and a pair of first and second pairs installed inclined at an angle of 45 degrees to the lower part of the other end of the 4th axis link frame 80 and facing the vertical and horizontal directions at an angle of 90 degrees. The second grippers 91 and 92 include a fifth axis link frame 90 rotatably provided.

Therefore, the robot arm 4 is composed of one axis of the first axis link frame 50 vertically and linearly moving, and four axes of the second to fifth axis link frames 60 to 90 performing relative rotational movement. It becomes a 5-axis by adding the axis, and since the first to fifth axis link frames 50 to 90 are installed vertically based on the base frame 40 fixedly installed on the floor, it becomes a 5-axis vertical articulated robot.

Here, while adjusting the vertical height by the up and down vertical movement of the first axis link frame 50, the front and back of the robot arm 4 through left and right rotational driving of each of the second to fifth axis link frames 60 to 90. A left and right turning radius is formed and the work area is set. At this time, the fifth axis link frame 90 is provided with a pair of first grippers 91 and second grippers 92 for gripping the material M.

Using this robot arm 4, the operation process through the movement of the material M in relation to the CNC lathe 1, the inlet stocker 2 and the outlet stocker 3 will be looked at with reference to FIGS. 5 to 10. That is, as shown in FIGS. 5 and 6, the robot arm 4 holds the material M to be processed loaded on the inlet stocker 2 with the first gripper 91 and waits. As shown in 7 and 8, when the door 12 of the cover frame 10 is opened, the second gripper 92 grips and removes the material M processed from the fixing chuck 20, and then The workpiece M to be processed held by the first gripper 91 is put into the fixed chuck 20, and as shown in FIGS. 9 and 10, the workpiece held by the second gripper 92 is repeated to load the outlet stocker (3).

As shown in FIGS. 3 to 10, the operation process of the robot arm 4 efficiently rotates the material (M ) can be automatically moved to input, process, remove and load. At this time, each of the inlet stocker 2 and the outlet stocker 3 must be able to efficiently load the material M to be processed and the processed material M, respectively.

To this end, each of the inlet stocker 2 and the outlet stocker 3 includes a stocker frame 100, a rotating plate 200, a plurality of loading parts 300, and a rotating operation unit as shown in FIGS. 3 and 11 to 23 400 and a position fixing part 500, and may further include a loading plate lifting part 600.

As shown in FIGS. 11 to 14 and 16, the stocker frame 100 has an appearance and skeleton, and each component described later is attached and coupled in a hexahedral shape in the drawing. As shown in FIG. 14, the stocker frame 100 has a moving wheel 110 installed at the bottom to be able to move to a desired place along the bottom, and a bottom fixing part 120 is installed at the bottom so that the stocker frame (100) can be fixed to the bottom surface. Through this movable stocker frame 100, it is possible to easily load or remove the material M to be processed in a plurality of loading parts 300 to be described later in a desired work space, and in particular, spaced in front of the CNC lathe 1 When installed, there is an effect that can be easily placed in a desired work space while avoiding interference with other devices.

As shown in FIGS. 11 to 21 , the rotating plate 200 is a circular disc and is rotatably installed on the upper part of the stocker frame 100 . The rotary plate 200 is intermittently rotated at a certain angle by a rotary operating unit 400 to be described later, and a plurality of loading parts 300 on which the material M is loaded are installed on the top and rotated together with the rotary plate 200. do.

As shown in FIGS. 11 to 14, a plurality of loading units 300 are provided, each of which is arranged radially at a constant angle with respect to the center of rotation of the rotating plate 200, and each of the plurality of materials M is placed up and down. load with In the drawing, eight loading units 300 are provided, and each is radially arranged on the top of the rotating plate 200 at an angle of 45 degrees. Accordingly, the rotation plate 200 is intermittently rotated at an angle of 45 degrees by the rotation operation unit 400 to be described later, and the loading unit 300 installed on the top of the rotation plate 200 is also rotated at an angle of 45 degrees together with the rotation plate 200. rotates intermittently.

Specifically, as shown in FIGS. 12 and 14, each of the loading units 300 is installed to be able to move up and down on the top of the rotating plate 200, and a circular stack for vertically loading a plurality of materials M. Plate 310, each penetrating the mounting plate 310, spaced apart or close to each other in the radial direction of the mounting plate 310, contacting the outer circumferential surface of the material (M) to mount the material (M) It includes a plurality of mounting rods 320. Therefore, the plurality of mounting rods 320 can be mounted in contact with the outer circumferential surface of the material M while being spaced apart or close to each other along the radial direction of the mounting plate 310, so that a plurality of The material M can be loaded up and down, and the top of the loaded material M is open, so that the grippers 91 and 92 of the robot arm 4 as shown in FIGS. 3, 5, 6, 9 and 10 ) can easily grip and move the material (M).

At this time, as shown in FIG. 3, the position of one loading plate 310 located at a specific angle of the rotating plate 200 is defined as a loading position, and the inside of the stocker frame 100 corresponds to the loading position It may further include a loading plate elevating unit 600 installed in the loading plate 310 to move up and down the loading plate 310 located at the loading position. The loading position refers to a position where the material M is gripped by the grippers 91 and 92 within the working radius of the grippers 91 and 92 of the robot arm 4 . At this time, the loading position is defined as a supply loading position as shown in FIGS. 5 and 6 in the case of the inlet stocker 2, and an exit loading position as shown in FIGS. 9 and 10 in the case of the outlet stocker 3. can be defined separately.

Through this, whenever a plurality of materials M loaded on the loading plate 310 located at the loading position are supplied to the CNC lathe 1 one by one through the grippers 91 and 92 of the robot arm 4, the loading plate By pushing the material 310 upward as much as the height of the material M, it is possible to more easily grip the next material M.

Specifically, as shown in FIGS. 13 and 14, the lifting plate lifting unit 600 includes a lifting motor 610 that rotates forward and backward, and a ball screw 620 that rotates forward and backward by receiving rotational force from the lifting motor 610. And, the lifting nut 630 coupled to the ball screw 620 and moving up and down according to the forward and reverse rotation of the ball screw 620, and the mounting plate 310 coupled to the lifting nut 630 while moving up and down together ) includes a plurality of lifting rods 640 for lifting up and down. Although separate reference numerals are not shown, a height sensor capable of detecting the lifting height of the mounting plate 310 and the lifting position of the lifting nut 630 may be provided.

As shown in FIGS. 13 to 15 , the rotation operation unit 400 is installed inside the stocker frame 100 and intermittently rotates the rotation plate 200 at a predetermined angle. Specifically, the rotation operation unit 400 includes a rotation motor 410 rotating in one direction, a main shaft 420 coaxially coupled to the lower portion of the rotation plate 200 and rotating together, and the rotation motor 410. It includes a power transmission means 430 for transmitting rotational force to the main shaft 420.

At this time, as shown in 14 and 15, the power transmission means 430 is coupled to the rotation shaft of the rotation motor 410 and rotates, and the main shaft 420 is coupled to the main shaft 420 to rotate. A driven sprocket 432 and a chain 433 connecting the driven sprocket 431 and the driven sprocket 432 may be included. That is, the rotation of the rotation motor 410 causes the main sprocket 431 to rotate, and the driven sprocket 432 to rotate through the chain 433, so that the rotation plate 200 rotates together with the main shaft 420. .

At this time, in order for the rotary plate 200 to rotate intermittently at a certain angle, for example, at an angle of 45 degrees in the drawing, the rotation of the rotary motor 410 is controlled to rotate the rotary plate 200 only by an angle of 45 degrees and then stop. However, even if precise rotation control of the rotary motor 410 can be achieved, errors in design or assembly, errors in operation due to wear or sagging due to long use inevitably occur. Therefore, even if a slight error occurs after the rotating plate 200 is rotated at a certain angle, for example, an angle of 45 degrees in the drawing, the position fixing unit 500 is required to accurately fix the position.

That is, the position fixing part 500 is installed inside the stocker frame 100 as shown in FIGS. 13 and 16 to 18, and the rotating plate 200 rotated intermittently by the rotary operation part 400 is fixed at a certain angle.

Specifically, the rotary plate 200 is formed with a plurality of position fixing grooves 210 recessed at the bottom so as to correspond to each of the mounting parts 300 arranged at a certain angle, and at this time, the position fixing part 500 is a cylinder ( 510), the position fixing protrusion 530, which is coupled to the lifting rod 520 that moves up and down, is inserted into the position fixing groove 210 to fix the position of the rotary plate 200.

That is, as shown in FIGS. 13 and 16, the cylinder 510 defines the position of one loading plate 310 located at a specific angle of the rotating plate 200 as a fixed position, and the position corresponding to the fixed position. It is fixedly installed inside the stocker frame 100. At this time, as shown in FIGS. 17 and 18, the lifting rod 520 moves up and down according to the operation of the cylinder 510, and the position fixing protrusion 530 is coupled to the lifting rod 520 and moves up and down together. It is inserted into the position fixing groove 210 of the rotation plate 200 corresponding to the fixing position to fix the position.

In this case, in order to facilitate insertion between the position fixing protrusion 530 and the position fixing groove 210, the position fixing protrusion 530 has a truncated cone shape and is inserted into the position fixing groove 210. Therefore, even if a slight error occurs after the rotary plate 200 is rotated at a certain angle, for example, an angle of 45 degrees in the drawing, the position fixing protrusion 530 of the position fixing part 500 is the position fixing groove of the rotary plate 200 ( 210), it is possible to correct minute errors of the rotating plate 200.

On the other hand, when the power transmission means 430 of the rotary operation unit 400 adopts the above-described chain-sprocket structure, minute errors inevitably occur during the intermittent rotation of the rotary plate 200, and the cylinder type as described above The configuration of the position fixing groove 210 and the position fixing protrusion 530 is required. Therefore, another power transmission means 430 is proposed so that the intermittent rotation of the rotating plate 200 can be more accurately and intermittently fixed in a simple configuration.

That is, as shown in FIGS. 19 to 23, the power transmission means 430 may include a Geneva driven wheel 434 and a Geneva driving wheel 435, and in this case, the position fixing part 500 is a ball plunger ( 540).

Specifically, the Geneva driven wheel 434 has a disk shape, and the center of rotation is coupled to the main shaft 420 to rotate together, and a plurality of drive grooves 434a are formed around the outer circumference at a radially constant angle. In addition, the Geneva drive wheel 435 has a disc shape and is coupled to the rotation shaft of the rotation motor 410 to rotate, and a single drive pin 435a protruding away from the rotation center drives the Geneva driven wheel 434. It is inserted into the groove 434a to intermittently rotate the Geneva driven wheel 434 at a constant angle. As shown in the drawing, eight driving grooves 434a of the Geneva driven wheel 434 are formed at an angle of 45 degrees to intermittently rotate at a constant angle, that is, at an angle of 45 degrees.

That is, the Geneva driven wheel 434 and the Geneva driving wheel 435 are a Geneva mechanism, which is an intermittent rotation mechanism by the mutual driving groove 434a and the driving pin 435a. The rotation motor 410 rotates the Geneva driving wheel 435 in a certain direction. Therefore, the drive pin 435a rotates when the Geneva drive wheel 435 receives the one-way rotational force of the rotation motor 410, and the drive pin 435a is inserted into the drive groove 434a of the Geneva drive wheel 434. Intermittent movement of the Geneva driven wheel 434 by the repeated operation of rotating the Geneva driven wheel 434 and then being inserted into the next driving groove 434a of the Geneva driven wheel 434 while coming out of it and rotating the Geneva driven wheel 434. make a rotation The intermittent rotation of the Geneva driven wheel 434 leads to the intermittent rotation of the main shaft 420 and the rotating plate 200, and the plurality of loading parts 300 radially arranged on the top of the rotating plate 200 intermittently rotate and transfer at a constant angle. It will be.

By driving the above-described rotation operation unit 400, the rotation plate 200 and the plurality of loading units 300 are intermittently rotated and transferred, and each loading unit 300 repeats rotation transfer and stopping operations. At this time, the rotation plate ( 200), the position of the Geneva driven wheel 434 can be fixed with a simple structure through the ball plunger 540, which is the position fixing part 500, to fix the position of the Geneva driven wheel 434.

That is, the position fixing part 500 is fixedly installed at a distance from the Geneva driving wheel 435, and the actuating ball 542 elastically operated by the spring 541 is the drive groove of the Geneva driven wheel 434 ( 434a) to fix the position of the Geneva driven wheel 434. Accordingly, the main shaft 420 and the rotary plate 200 coupled to the Geneva driven wheel 434 and rotating together are also fixed in position, and the loading part 300 installed on the upper part of the rotary plate 200 is also rotated at an accurate angle to position to be fixed

As described above, the CNC lathe processing system using the 5-axis robot arm according to the present invention simplifies the structure of the stockers 2 and 3 so that the plurality of loading parts 300 can be moved in an intermittent rotation type, and the loading During the intermittent rotation of the part 300, it is possible to achieve accurate position fixation, and in particular, a pair of inlet stocker (2) and outlet stocker (3) for loading the material (M) for supply and discharge of the material (M) While having a 5-axis vertical multi-joint robot arm 4, it is possible to build an efficient work line, thereby improving productivity and work quality.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can improve and change the technical spirit of the present invention in various forms. Therefore, such improvements and changes will fall within the protection scope of the present invention as long as they are obvious to those skilled in the art.

M: material
1: CNC lathe 2: Inlet stocker
3: Outlet Stalker 4: Robot Arm
10: cover frame 11: processing chamber
12: door 20: fixed chuck
30: tool stand 31: tool
40: base frame 50: first axis link frame
60: 2nd axis link frame 70: 3rd axis link frame
80: 4th axis link frame 90: 5th axis link frame
91: first gripper 92: second gripper
100: stalker frame
110: moving wheel 120: floor fixing part
200: rotary plate 210: position fixing groove
300: loading part
310: loading plate 320: mounting rod
400: rotation operation unit
410: rotation motor 420: main shaft
430: power transmission means 431: driving sprocket
432: driven sprocket 433: chain
434: Geneva driven wheel 434a: driving groove
435: Geneva drive wheel 435a: drive pin
500: position fixing part 510: cylinder
520: lifting rod 530: position fixing protrusion
540: ball plunger
541: spring 542: operating ball
600: loading plate lifting part
610: lifting motor 620: ball screw
630: lifting nut 640: lifting bar

Claims (13)

A processing chamber is formed inside, a cover frame equipped with a door to open and close the processing chamber from the outside, and rotatably installed on one side of the inside of the processing chamber of the cover frame and detachably fixing the material to be processed A CNC lathe including a fixed chuck and a tool post equipped with a tool for processing the material fixed to the fixed chuck while moving inside the processing chamber of the cover frame;
An inlet stocker installed at a distance from the front left side of the door of the cover frame and loading and supplying a plurality of materials to be processed;
An outlet stocker installed at a distance from the front right side of the door of the cover frame and loading and ejecting a plurality of materials processed by the CNC lathe;
It is a 5-axis vertical multi-joint robot installed at a distance in front of the door of the cover frame, receives the material to be processed loaded in the inlet stocker, puts the material into the fixed chuck of the CNC lathe, and fixes the CNC lathe. A 5-axis robot arm comprising a robot arm for removing the processed material from the chuck and loading it into the outlet stocker,
Each of the inlet stocker and outlet stocker,
A stocker frame, a circular rotating plate rotatably installed on the upper part of the stocker frame, each of which is radially arranged at a constant angle with respect to the center of rotation of the rotating plate, and a plurality of stacks for vertically stacking a plurality of materials A rotation operation unit installed inside the stocker frame and intermittently rotating the rotation plate at a constant angle, and a rotation operation unit installed inside the stocker frame and rotated intermittently by the rotation operation unit to a constant Including a position fixing unit for fixing the position for each angle,
The rotating operation part,
A rotary motor rotating in one direction, a main shaft coaxially coupled to the lower portion of the rotary plate and rotating together, and a power transmission means for transmitting rotational force of the rotary motor to the main shaft,
The power transmission means,
A Geneva driven wheel in a disc shape with a center of rotation coupled to the main shaft to rotate together, and a plurality of drive grooves formed at a radially constant angle around the outer circumference;
A Geneva drive that rotates by being coupled to the rotation shaft of the rotation motor in a disk shape, and a single driving pin protruding from the center of rotation is inserted into the driving groove of the Geneva driven wheel to intermittently rotate the Geneva driven wheel at a certain angle. including wheels,
The position fixing unit,
A 5-axis robot arm, characterized in that a ball plunger that is fixedly installed at a distance from the Geneva driving wheel and has an actuating ball elastically operated by a spring inserted into the driving groove of the Geneva driven wheel to fix the position of the Geneva driven wheel Used CNC lathe processing system.
According to claim 1,
The robot arm,
base frame,
A first axis link frame installed to be vertically movable with respect to the base frame;
A second axis link frame having one end rotatably installed left and right on the top of the first axis link frame and the other end extending horizontally;
A third axis link frame having one end rotatably installed left and right on the upper part of the other end of the second axis link frame and the other end extending horizontally;
A fourth axis link frame having one end rotatably installed in the lower part of the other end of the third axis link frame and the other end extending horizontally;
A 5th axis link frame installed at an angle below the other end of the 4th axis link frame at an angle of 45 degrees and having a pair of first and second grippers rotatably provided so as to face vertical and horizontal directions at an angle of 90 degrees A CNC lathe processing system using a 5-axis robot arm, characterized in that it comprises.
According to claim 2,
The robot arm,
The first gripper grips and waits for the material to be processed loaded on the inlet stocker, and when the door of the cover frame is opened, the second gripper grips and removes the material processed from the fixed chuck, and then the A CNC lathe using a 5-axis robot arm, characterized in that the workpiece to be processed, which is gripped by the first gripper, is put into the fixed chuck, and the workpiece, which is gripped by the second gripper, is repeatedly loaded into the outlet stocker. processing system.
delete According to claim 1,
Each of the inlet stocker and outlet stocker,
A moving wheel installed below the stocker frame to move the stocker frame;
The CNC lathe processing system using a 5-axis robot arm, characterized in that it further comprises a floor fixing part installed at the bottom of the stocker frame and fixing the stocker frame to the floor surface.
According to claim 1,
Each of the loading parts,
A circular loading plate installed on the upper part of the rotating plate to be able to move up and down and vertically loading a plurality of materials;
CNC using a 5-axis robot arm, characterized in that each includes a plurality of mounting rods for holding the material by contacting the outer circumferential surface of the material while being spaced apart or close to each other in the radial direction of the mounting plate through the mounting plate. lathe processing system.
According to claim 6,
Each of the inlet stocker and outlet stocker,
The position of any one loading plate located at a specific angle of the rotating plate is defined as a loading position, and is installed inside the stocker frame to correspond to the loading position to raise and lower the loading plate located at the loading position. Including further trial elevation,
The loading position is
A CNC lathe processing system using a 5-axis robot arm, characterized in that the inlet stocker is defined as a supply loading position and the outlet stocker is defined as an exit loading position.
According to claim 7,
The loading plate lifting part,
An elevating motor that rotates forward and backward;
A ball screw that receives rotational force from the lifting motor and rotates forward and backward;
a lifting nut coupled to the ball screw and moving up and down according to forward and reverse rotation of the ball screw;
The CNC lathe processing system using a 5-axis robot arm, characterized in that it includes a plurality of lifting rods coupled to the lifting nut and lifting the stacking plate up and down while lifting together.
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