JP2020110897A - Tool conveyance device, machining system, and tool conveyance method - Google Patents

Abstract

To improve productivity of a machine tool.SOLUTION: A tool conveyance device 14 attaches/detaches a tool 40 to/from a turning type tool magazine 50 of a machine tool 12. The tool conveyance device 14 includes: a robot 70 which has a multi-joint arm for gripping the tool 40; and a robot control section 74 which controls the robot 70 so as to mount a specified tool in the tool magazine 50 before the machine tool 12 performs machining using the specified tool having prescribed weight or more and controls the robot 70 so as to remove the specified tool from the tool magazine 50 after the machine tool 12 finishes the machining using the specified tool.SELECTED DRAWING: Figure 1

Description

The present invention relates to a tool transfer device for mounting and removing a tool on a machine tool, a machine system, and a tool transfer method.

In a machine tool including a turret that is a swivel type tool magazine as described in Patent Document 1 shown below, the centrifugal speed acting on the tool is taken into consideration in consideration of the centrifugal force acting on the tool. Is described.

JP, 2005-205503, A

As described above, in a machine tool having a swivel type tool magazine, the operation of the machine tool such as the swivel speed of the tool magazine is restricted by the mass of the tool mounted in the tool magazine, especially the maximum weight. It was a factor that hindered the improvement of sex.

Therefore, an object of the present invention is to provide a tool transfer device, a machine system and a tool transfer method capable of improving the productivity of a machine tool.

A first aspect of the present invention is a tool transfer device, which is a tool transfer device for attaching and detaching a tool to and from a swivel tool magazine of a machine tool, the robot having an articulated arm that grips the tool. And the machine tool controls the robot so that the specific tool is mounted in the tool magazine before the machine tool performs the processing using the specific tool having a predetermined weight or more, and the machine tool performs processing using the specific tool. And a robot control unit that controls the robot to remove the specific tool from the tool magazine.

A second aspect of the present invention is a machining system including a tool transfer device and the machine tool.

A third aspect of the present invention is a tool transfer method for a tool transfer device including a robot having a multi-joint arm for holding the tool, the tool being attached to and detached from a swivel type tool magazine of a machine tool, A tool mounting step of controlling the robot to mount the specific tool in the tool magazine before the machine tool performs processing using the specific tool having a predetermined weight or more, and the machine tool uses the specific tool. A tool removing step of controlling the robot to remove the specific tool from the tool magazine after finishing the machining.

According to the present invention, the productivity of machine tools can be improved.

FIG. 1 is an external configuration diagram of a work system according to an embodiment. It is a side view of a machine tool. It is a figure which shows the correspondence of each magazine number and each stocker number which the memory|storage part memorize|stores, and the weight of a tool. It is a figure explaining how a maximum tool weight and an operation mode change according to a processing program. It is a figure explaining the command content of a tool attachment/detachment code. It is a flow chart explaining control of a work system by a tool exchange code. It is a flowchart explaining control of the work system by a tool attachment/detachment code. It is a figure which shows the structure of the machining program concerning the modification 1. It is a figure which shows the tool magazine concerning the modification 1. It is a figure which shows the tool stocker concerning the modification 1.

BEST MODE FOR CARRYING OUT THE INVENTION A tool carrying device, a work system, and a tool carrying method according to the present invention will be described in detail below with reference to the accompanying drawings, with reference to preferred embodiments.

[Embodiment]
FIG. 1 is an external configuration diagram of a work system 10 according to an embodiment. The machine system 10 includes a machine tool 12, a tool transfer device 14, and a tool stocker 16. The machine tool 12 includes a machine tool body 20 and a control device 22 that controls the machine tool body 20. FIG. 2 is a side view of the machine tool 12. In FIG. 2, the structure below the processing object 28 is omitted.

The machine tool main body 20 is provided with a spindle 30, a spindle head 32 that drives the spindle 30 to rotate about a rotation axis (Z axis) that is parallel to the Z direction, and an upright position (+Z direction) from a pedestal 33. And a column 34 for guiding the movement of 32 in the Z-axis direction (vertical direction). Note that the −Z direction is the direction in which gravity acts. The table 46 that supports the workpiece 28 is provided below the spindle head 32 (-Z direction). Illustration of a moving mechanism for moving the table 46 in the X and Y directions is omitted. The X direction, the Y direction, and the Z direction are orthogonal to each other.

A spindle motor 36 for rotating the spindle 30 is provided above the spindle head 32. The tool 40 is attachable to and detachable from the spindle 30. When the tool 40 is mounted on the spindle 30, the tool 40 rotates together with the spindle 30. The machine tool main body 20 includes an automatic tool changing device 48 for automatically changing the tool 40 attached to the spindle 30. The automatic tool changer 48 has a turning type tool magazine 50 and a turning motor 50a for turning the tool magazine 50.

The tool magazine 50 has a plurality of grips 54 provided along the circumferential direction. Each of the grips 54 detachably holds the tool. Each of the plurality of grips 54 is identified by a magazine number. Magazine numbers 1 to 8 are assigned to the tool magazine 50 in FIG.

The tool magazine 50 is supported by a pair of support members 56 extending from the column 34 in the +Y direction. The tool magazine 50 is swingably (rotatably) supported by a swing shaft (rotating shaft) 60 provided at the tip of a pair of supporting members 56. The spindle head 32 and the spindle motor 36 are provided between the pair of support members 56.

A cam 62 is provided on the side surface of the spindle head 32, and a cam follower 64 that contacts the cam 62 is provided on the tool magazine 50. The column 34 is provided with a shaft feed motor 34a for moving the spindle head 32 in the axial direction. The shaft feed motor 34a drives the spindle head 32 to move in the axial direction (Z direction) with respect to the column 34, whereby the cam follower 64 moves on the cam 62 along the shape of the cam 62. As a result, the tool magazine 50 swings (rotates) around the swing shaft 60. The cam 62 and the cam follower 64 constitute a swing mechanism that swings the tool magazine 50.

The control device 22 has a processor such as a CPU and a memory, and functions as the control device 22 of the present embodiment by executing a program stored in the memory. The control device 22 includes a motor control unit 24, a communication unit 26, a storage unit 27 that stores a machining program, and an operation mode setting unit 24a that sets an operation mode described later. The motor control unit 24 controls the turning motor 50a to rotate the tool magazine 50 around the rotation shaft 52, and controls the shaft feed motor 34a to move the spindle head 32 in the Z direction.

The tool stocker 16 can store a plurality of tools 40. Here, the location where the tool stocker 16 stores each tool 40 is identified by giving a stocker number. Stocker numbers 1 to 20 are given to the tool stocker 16 in FIG.

The tool transfer device 14 includes a robot 70 having an articulated arm that holds a tool, and a robot controller 72, and performs a tool attaching/detaching operation with respect to the tool magazine 50, that is, an attaching operation and a detaching operation of the tool 40. The robot 70 can take out the tool 40 stored in the tool stocker 16 and store the tool 40 in the tool stocker 16 in addition to the attachment/detachment of the tool 40 to/from the tool magazine 50. The robot control device 72 includes a robot control unit 74 that controls the robot 70, and a communication unit 76 that communicates with the communication unit 26 of the control device 22 of the machine tool 12.

In the machine tool 12, the motor control unit 24 controls the machine tool body 20 (including the shaft feed motor 34a and the swing motor 50a) based on the machining program stored in the storage unit 27, so that the machining object 28 is processed. A predetermined operation such as three-dimensional processing. At this time, the shaft feed motor 34a and the swing motor 50a operate with parameters such as the shaft feed speed and the swing speed according to the operation mode set by the operation mode setting unit 24a. The weight of the tool 40 having the largest weight among the tools 40 attached to the tool magazine 50 is referred to as the maximum tool weight. The operating mode corresponds to the maximum tool weight.

As an example, in the following description, it is assumed that the maximum tool weight is any of 2 kg, 3 kg, and 4 kg, and the operation mode corresponding to these maximum tool weights is one of the high speed mode, the medium speed mode, and the low speed mode. Suppose there is. The high speed mode corresponds to the maximum tool weight=2 kg, the medium speed mode corresponds to the maximum tool weight=3 kg, and the low speed mode corresponds to the maximum tool weight=4 kg. However, the maximum tool weight and the type and number of operation modes are not limited to these. When the maximum tool weight changes, the operation mode can be switched accordingly. Since the maximum tool weight and the operation mode change in this way, the storage unit 27 stores the current maximum tool weight and the current operation mode, respectively.

The storage unit 27 also stores a turning parameter according to each operation mode. The turning parameter is a turning speed, a turning acceleration, or both. Here, it is stored such that the smaller the maximum tool weight corresponding to the operation mode, the larger the value of the turning parameter according to the operation mode, that is, the faster the turning speed or the turning acceleration. Therefore, the motor control unit 24 acquires the turning parameter according to the current operation mode from the storage unit 27, and the turning motor 50a is turned so that the tool magazine 50 turns at the turning speed or the turning acceleration according to the maximum tool weight. Can be controlled. That is, the motor control unit 24 can control the turning motor 50a so that at least one of the turning speed and the turning acceleration becomes faster as the maximum tool weight becomes smaller.

The storage unit 27 also stores the axis feed parameter according to each operation mode. The axis feed parameter is the axis feed speed, the axis feed acceleration, or both. It is stored that the smaller the maximum tool weight corresponding to the operation mode, the larger the value of the axis feed parameter according to the operation mode, that is, the faster the axis feed speed or the axis feed acceleration. Therefore, the motor control unit 24 acquires the axis feed parameter corresponding to the current operation mode from the storage unit 27 so that the spindle head 32 moves at the axis feed speed or the axis feed acceleration corresponding to the maximum tool weight. The shaft feed motor 34a can be controlled. That is, the motor control unit 24 can control the shaft feed motor 34a such that at least one of the shaft feed speed and the shaft feed acceleration becomes faster as the maximum tool weight becomes smaller.

Further, the storage unit 27 stores the type and weight of the tool 40 mounted on the grip 54 of each magazine number of the tool magazine 50, and the type and weight of the tool stored at the location of each stocker number of the tool stocker 16. I remember more. FIG. 3 is a diagram showing a correspondence relationship between each magazine number and each stocker number stored in the storage unit 27 and the weight of the tool. FIG. 3 shows a correspondence relationship between each magazine number and each stocker number stored in the storage unit 27 at a certain time and the weight of the tool. Therefore, when the tool 40 is moved between the tool magazine 50 and the tool stocker 16 by the tool transfer device 14, each magazine number and each stocker number stored in the storage unit 27 are associated with the weight of the tool. Will be updated. In the present embodiment, the predetermined weight is determined in advance, and a tool 40 having a predetermined weight or more is called a specific tool. Here, as an example, the predetermined weight is set to 3 kg. Therefore, the 3 kg and 4 kg tools 40 are specific tools.

In the machining system 10 according to the present embodiment, before the machining using the specific tool is executed in the machine tool 12, the tool transporting device 14 attaches the specific tool to the tool magazine 50, and the machining using the specific tool is performed. After the machine tool 12 executes, the tool transfer device 14 is caused to remove the specific tool from the tool magazine 50.

The start of the attachment operation of the specific tool by the tool transfer device 14 means that the robot 70 starts to move to grasp the specific tool stored in the tool stocker 16. The completion of the attaching operation of the specific tool means that the robot 70 moves the specific tool to the retracted position after attaching the specific tool to the tool magazine 50.

The communication unit 76 of the tool transfer device 14 turns on the tool attachment/detachment signal from the start to the completion of the attachment operation of the specific tool, and continues to transmit the tool attachment/detachment signal to the communication unit 26 of the machine tool 12. When the attaching operation of the specific tool is completed, the tool attachment/detachment signal is turned off, and the transmission of the tool attachment/detachment signal to the communication unit 26 is stopped. Thereby, the communication unit 76 notifies the communication unit 26 that the attaching operation of the specific tool is completed. Note that the communication unit 76 may notify the communication unit 26 that the mounting operation of the specific tool has been completed and that a separate completion signal is transmitted.

The start of the removal operation of the specific tool by the tool transfer device 14 is that the robot 70 starts moving to grab the specific tool attached to the tool magazine 50. The completion of the removal operation of the specific tool means that the robot 70 removes the specific tool from the tool magazine 50, stores it in the tool stocker 16, and then moves it to the retracted position.

The communication unit 76 of the tool transfer device 14 turns on the tool attachment/detachment signal from the start to the completion of the removal operation of the specific tool, and continues to transmit the tool attachment/detachment signal to the communication unit 26 of the machine tool 12. When the removal operation of the specific tool is completed, the tool attachment/detachment signal is turned off, and the transmission of the tool attachment/detachment signal to the communication unit 26 is stopped. Accordingly, the communication unit 76 notifies the communication unit 26 that the removal operation of the specific tool is completed. The communication unit 76 may notify the communication unit 26 that the removal operation of the specific tool has been completed by separately transmitting a completion signal.

The robot control unit 74 executes the attaching operation of the specific tool before the machine tool 12 performs the machining using the specific tool. That is, the robot 70 is controlled so that the specific tool is attached to the tool magazine 50. Further, the robot control unit 74 executes the removal operation of the specific tool after the machine tool 12 finishes the machining using the specific tool. That is, the robot 70 is controlled to remove the specific tool from the tool magazine 50. When the robot 70 completes the attachment operation and the removal operation of the specific tool, the communication unit 76 of the robot control device 72 notifies the communication unit 26 of the control device 22 of the completion as described above.

The control device 22 (motor control unit 24) controls the machine tool body 20 in accordance with the machining program to execute the tool replacement of the tool 40 mounted on the spindle 30 and the machining of the machining object 28. Further, in the present embodiment, the control device 22 (communication unit 26) sends a command to the tool transport device 14 based on the machining program, so that the tool transport device 14 performs the tool attaching/detaching operation to/from the tool magazine 50. It FIG. 4 is a diagram for explaining how the maximum tool weight and the operation mode change according to the machining program 80.

“M6T1” to “M6T4” described in the machining program 80 of FIG. 4 are tool exchange codes for instructing the tool exchange of the tool 40 mounted on the spindle 30. “T1” to “T4” indicate the tool 40 having the magazine number 1 to the tool 40 having the magazine number 4 in the tool magazine 50, respectively. Therefore, "M6T1" instructs the tool 40 mounted on the spindle 30 to be replaced with the tool of magazine number 1 in the tool magazine 50.

“M100D2E1” described in the machining program 80 of FIG. 4 is a tool attachment/detachment code for instructing a tool attachment/detachment operation to/from the tool magazine 50 by the tool transfer device 14. “D2” indicates the magazine number 2 of the tool magazine 50, and “E1” indicates the stocker number 1 of the tool stocker 16. Therefore, "M100D2E1" instructs the tool transfer device 14 to attach/detach the tool to/from the tool magazine 50 in order to move the tool between the magazine number 2 of the tool magazine 50 and the stocker number 1 of the tool stocker 16. doing. FIG. 5 is a diagram for explaining the command contents of the tool attachment/detachment code. The broken line arrow in FIG. 5 indicates the instruction content of the tool attachment/detachment code “M100D2E1”.

In the present embodiment, the motor control unit 24 determines that the tool attachment/detachment code “M100D2E1” described in the machining program 80 is based on the arrangement state of the tool 40 shown in FIG. It is possible to determine whether it means the attaching operation or the removing operation of the specific tool. Therefore, when the communication unit 26 notifies the communication unit 76 of a tool attachment/detachment command, which will be described later, it is possible to add the information indicating whether the specific tool is attached or detached.

Therefore, “M100D2E1” described first in the machining program 80 instructs to attach the tool 40 stored in the stocker number 1 of the tool stocker 16 to the magazine number 2 of the tool magazine 50. On the other hand, "M100D2E1" described second in the machining program 80 means that the tool attached to the magazine number 2 of the tool magazine 50 is removed and stored in the stocker number 1 of the tool stocker 16. I have an order. FIG. 3 shows a correspondence relationship between each magazine number and each stocker number stored in the storage unit 27 and the weight of the tool before the “M100D2E1” described first in the machining program 80 is executed. ing. Therefore, since the tool 40 is not yet attached to the magazine number 2 of the tool magazine 50 at this point, the corresponding column in FIG. 3 is “none”.

Hereinafter, the operation of the machining system 10 according to the present embodiment will be described by further using the flowcharts of FIGS. 6 and 7 in the order of processing of the machining program 80 of FIG. FIG. 6 is a flowchart for explaining the control of the work system 10 by the tool exchange code. FIG. 7 is a flowchart illustrating control of the work system 10 by the tool attachment/detachment code. 6 shows the control of the machine tool 12, and FIG. 7 shows the control of the machine tool 12 and the control of the tool transfer device 14.

First, since the tool exchange code "M6T1" is described at the beginning of the machining program 80 in FIG. 4 (FIG. 6, step S10), the process proceeds to step S11. In step S11, the motor control unit 24 determines whether the maximum tool weight is smaller than the maximum tool weight corresponding to the operation mode. The maximum tool weight at the start of execution of the machining program 80 in FIG. 4 is 2 kg, and the maximum tool weight corresponding to the operation mode at that time is also 2 kg (high speed mode), and both have the same weight. Therefore, in step S11, since the maximum tool weight is not smaller than the maximum tool weight corresponding to the operation mode (step S11, NO), the process proceeds to step S15. In step S15, the motor controller 24 determines whether the communication unit 26 receives the tool attachment/detachment signal. Since the tool transfer device 14 has not started the tool attachment/detachment operation at this point, the communication section 26 has not received the tool attachment/detachment signal (step S15, NO), and the tool exchange operation by the machine tool main body 20 is executed ( Step S16). That is, according to the tool replacement code “M6T1”, the 2 kg tool 40 of the magazine number 1 of the tool magazine 50 is mounted on the spindle 30.

The first tool attachment/detachment code “M100D2E1” is described in the line next to “M6T1” in the machining program 80 of FIG. 4 (FIG. 7, step S20). The motor control unit 24 that interprets this code causes the communication unit 26 to notify the communication unit 76 of a tool attachment/detachment command (step S21). The tool attachment/detachment command at this time is a command for the mounting operation of the specific tool. Then, the motor control unit 24 determines whether or not the maximum tool weight becomes larger than the current maximum tool weight after the tool 40 is attached to or detached from the tool magazine 50 (step S22). Here, as indicated by the broken line arrow from the column of stocker number 1 to the column of magazine number 2 in FIG. 5, 3 kg of the specific tool of the tool stocker 16 is attached to the tool magazine 50, and the maximum tool weight is from 2 kg. It will change to 3 kg. In this way, when the maximum tool weight increases (step S22, YES), the machine tool main body 20 stops the axis operation (step S23), and the operation mode setting unit 24a stores the operation mode stored in the storage unit 27. Is changed from the high speed mode corresponding to the maximum tool weight=2 kg to the medium speed mode corresponding to the maximum tool weight=3 kg (step S24). Step S24 corresponds to A in FIG.

After step S24, the axis operation by the machine tool body 20 is restarted (step S25). Then, the machining according to the “machining code using the tool of T1” in FIG. 4 is executed by using the 2 kg tool 40 already attached to the spindle 30 by the tool replacement code “M6T1”. At this time, the robot control unit 74, at the latest, finishes the above-described machining using the 2 kg tool 40 mounted on the spindle 30 used by the machine tool 12 one machining before the specific tool, and finishes the 3 kg specific tool. The robot 70 is controlled so that the tool 70 is attached to the tool magazine 50. Then, the determination as to whether the communication unit 26 has stopped receiving the tool attachment/detachment signal from the communication unit 76 (step S26) is repeated by the motor control unit 24 until the tool attachment/detachment signal is not received by the communication unit 26. .. The tool attachment/detachment signal is not received by the communication unit 26 when the tool attachment/detachment operation by the tool transfer device 14 is completed and the communication unit 76 stops transmitting the tool attachment/detachment signal to the communication unit 26. Then, when the tool attachment/detachment signal is not received by the communication unit 26 (step S26, YES), the motor control unit 24 determines whether or not the maximum tool weight has changed due to the tool attachment/detachment operation (step S27). As described above, since the tool conveying device 14 mounts the tool 40 of 3 kg in the tool magazine 50, the maximum tool weight changes from 2 kg to 3 kg (step S27, YES). Therefore, the motor control unit 24 updates the maximum tool weight stored in the storage unit 27 from 2 kg to 3 kg (step S28), and proceeds to the next process (step S29). Step S28 corresponds to B in FIG. In step S28, the motor control unit 24 also indicates the correspondence relationship between each magazine number and each stocker number stored in the storage unit 27 and the weight of the tool, in the column of the magazine number 2 in FIG. Update the column of number 1 to "none".

After that, in the tool exchange code “M6T2” of the machining program 80, the operation mode does not change like the first tool exchange code “M6T1”, and the 3 kg specific tool of the magazine number 2 of the tool magazine 50 is mounted on the spindle 30. It Then, the machining using the specific tool according to the “machining code using the tool of T2” of the machining program 80 is executed.

After that, the operation mode does not change even with the tool replacement code “M6T3” of the machining program 80. Then, the 2 kg tool 40 having the magazine number 3 of the tool magazine 50 is mounted on the spindle 30. That is, a 2 kg tool 40 to be used for machining after the specific tool is mounted on the spindle 30. The second tool attachment/detachment code “M100D2E1” is described in the line next to the tool exchange code “M6T3” in the machining program 80 (FIG. 7, step S20). The motor control unit 24 that interprets this code causes the communication unit 26 to notify the communication unit 76 of a tool attachment/detachment command (step S21). The tool attachment/detachment command at this time is a command for the removal operation of the specific tool. Since the 2 kg tool 40 used for machining after the specific tool is already mounted on the spindle 30, the robot controller 74 mounts the 2 kg tool 40 on the spindle 30 at the earliest. After that, the robot 70 is controlled to remove the specific tool from the tool magazine 50. Further, the motor control unit 24 determines whether or not the maximum tool weight increases after the tool 40 is attached to or detached from the tool magazine 50 (step S22). Here, since the specific tool is removed from the tool magazine 50, the maximum tool weight changes from 3 kg to 2 kg. Thus, if the maximum tool weight does not increase (NO in step S22), the operation mode is not changed as shown in C of FIG. 4 and the process proceeds to step S26 until the tool attachment/detachment signal is not received. The step S26 is repeated by the motor controller 24.

When the motor control unit 24 determines that the tool attachment/detachment signal from the communication unit 76 is no longer received by the communication unit 26 (step S26, YES), the motor control unit 24 determines whether the maximum tool weight has changed due to the tool attachment/detachment. Is determined (step S27). Since the specific tool has been removed from the tool magazine 50 as described above, the maximum tool weight has changed from 3 kg to 2 kg (step S27, YES). Therefore, the motor control unit 24 updates the maximum tool weight stored in the storage unit 27 from 3 kg to 2 kg (step S28), and proceeds to the next process (step S29). Step S28 here corresponds to D in FIG. While the robot control unit 74 controls the robot 70 to remove the specific tool from the tool magazine 50, the 2 kg tool 40 attached to the spindle 30 by the tool replacement code “M6T3” is used, as shown in FIG. Machining according to the "machining code using the tool of T3" is executed. In step S28, the motor control unit 24 updates the correspondence relationship between each magazine number and each stocker number and the weight of the tool stored in the storage unit 27, and returns to the state of FIG.

Here, the control of the tool transfer device 14 when the communication unit 26 of the machine tool 12 notifies the communication unit 76 of the tool transfer device 14 of the tool attachment/detachment command in step S21 will be described. First, the robot controller 74 always determines whether or not there is a tool attachment/detachment command (step S30). When the communication unit 76 receives the tool attachment/detachment command in step S21 (step S30, YES), the robot controller 74 starts the tool attachment/detachment operation based on the command (step S31). That is, the robot control unit 74 controls the robot to attach or detach the specific tool to or from the tool magazine 50. As described above, the tool attachment/detachment command from the communication unit 26 of the machine tool 12 is a command for the tool attachment operation (step S31) that controls the robot 70 to attach the specific tool to the tool magazine 50, or the specific tool is the tool. It is one of the commands for the tool removal operation (step S31) that controls the robot 70 to remove it from the magazine 50. Here, it has been described that the motor control unit 24 determines which of the above two is specified by the tool attachment/detachment code described in the machining program 80.

However, even if the storage unit 27 does not store the information about the arrangement state of the tool 40 in FIG. Alternatively, the communication unit 26 may notify the communication unit 76 of whether the command is the above command. Alternatively, the tool attachment/detachment code described in the machining program 80 may specify which of the above two commands. In addition, which of the above two is instructed when the storage unit (not shown) of the robot controller 72 stores the arrangement state of the tool 40 in FIG. 3 and the communication unit 76 receives the tool attachment/detachment command. May be determined. Alternatively, the robot control unit 74 may simply determine which of the above two commands is given in the order of the tool attachment/detachment command received by the communication unit 76.

When the tool attaching/detaching operation is started, the communication unit 76 turns on the tool attaching/detaching signal and transmits the tool attaching/detaching signal to the communication unit 26. Even during the tool attaching/detaching operation, the robot control unit 74 determines whether or not there is a tool attaching/detaching command, that is, whether or not a new instruction has been sent (step S32). When the communication unit 76 receives a new tool attachment/detachment command during the tool attachment/detachment operation by the tool transfer device 14 (step S32, YES), the instruction is stored in the storage unit (not shown) of the robot controller 72. (Step S33). When the communication unit 76 does not receive a new tool attachment/detachment command (step S32, NO) and after step S33, the robot controller 74 determines whether the tool attachment/detachment operation is completed (step S34). When the robot control unit 74 determines that the tool attachment/detachment operation of the robot 70 under the control of the robot control unit 74 is completed (step S34, YES), the robot control unit 74 turns off the tool attachment/detachment signal to the communication unit 76. The machine tool 12 is notified that the attachment and detachment operations of the specific tool by the robot 70 are completed by, for example, stopping the transmission of the tool attachment/detachment signal to the machine tool 12 (step S35). The control of the machine tool 12 proceeds from step S26 to step S27 based on the notification of the completion of the tool attachment/detachment in which the communication unit 76 stops transmitting the tool attachment/detachment signal to the communication unit 26 in step S35.

Returning to the machining program 80 of FIG. 4, since the tool replacement code “M6T4” is described (FIG. 6, step S10), the process proceeds to step S11. At this point, the maximum tool weight is 2 kg, and the maximum tool weight corresponding to the operation mode is 3 kg (medium speed mode). That is, in step S11, the motor control unit 24 determines that the maximum tool weight is smaller than the maximum tool weight corresponding to the operation mode (step S11, YES), so the machine tool main body 20 stops the axis operation (step S12). .. Then, the operation mode setting unit 24a changes the operation mode stored in the storage unit 27 from the medium speed mode corresponding to the maximum tool weight=3 kg to the high speed mode corresponding to the maximum tool weight=2 kg (step S13). Step S13 here corresponds to E in FIG.

After step S13, the axis operation by the machine tool main body 20 is restarted (step S14), and the process proceeds to step S15. Since the tool attaching/detaching operation has already been completed, the motor control section 24 determines that the communication section 26 has not received the tool attaching/detaching signal (step S15, NO), and the tool exchanging operation by the machine tool body 20 is executed ( Step S16). That is, the 2 kg tool 40 having the magazine number 4 of the tool magazine 50 is mounted on the spindle 30. Then, the machining according to the “machining code using the tool of T4” in FIG. 4 is executed by using the 2 kg tool 40 already attached to the spindle 30 by the tool replacement code “M6T4”.

This is the end of the execution of the machining program 80. However, in step S15, the tool transfer device 14 starts the tool attaching/detaching operation by the tool attaching/detaching code which is not shown in FIG. When the motor control unit 24 determines that 26 has been received (step S15, YES), the machine tool main body 20 stops the axis operation (step S17), and the motor control unit 24 causes the communication unit 26 to receive the tool attachment/detachment signal. It waits until it stops (step S18, NO). When the communication section 26 no longer receives the tool attachment/detachment signal (step S18, NO), the tool attachment/detachment operation is completed, so the machine tool body 20 restarts the axis operation (step S19), and the tool exchange by the machine tool body 20 is performed. The operation is executed (step S16). As a result, the 2 kg tool 40 having the magazine number 4 of the tool magazine 50 is mounted on the spindle 30. That is, it becomes possible to perform the tool exchanging operation after the completion of the tool attaching/detaching operation of the specific tool. In this way, the robot control device 72 includes the communication unit 76, and when the tool attaching/detaching operation of the specific tool is completed, by notifying the communication unit 26 of the completion, the machine tool main body 20 by two operations Interference with the robot 70 can be avoided.

As described above, before the machine tool 12 executes the machining using the specific tool, the state in which the specific tool is not attached to the tool magazine 50 is maintained. The tool transfer device 14 attaches the specific tool to the tool magazine 50 immediately before the machine tool 12 uses the specific tool for machining. Then, the tool transfer device 14 immediately removes the specific tool from the tool magazine 50 after the machine tool 12 finishes the processing using the specific tool. As a result, when the machine tool 12 does not use the specific tool for machining, it is possible to reduce the maximum tool weight by leaving the specific tool in the tool magazine 50. As a result, the operation mode of the machine tool 12 can be set to the high speed mode in the state where the tool magazine 50 removes the specific tool.

Therefore, when the specific tool is removed from the tool magazine 50, the motor control unit 24 sets at least one of the turning speed and the turning acceleration of the tool magazine 50 faster than when the specific tool is attached to the tool magazine 50. Can be controlled. As a result, the operating speed of the machine tool 12 can be increased and the cycle time can be shortened, so that productivity can be improved. Similarly, in the state where the specific tool is removed from the tool magazine 50, the motor control unit 24 causes the spindle head 32 to move in the axial direction by at least one of the axis feed speed and the axis feed acceleration, and further, the tool magazine 50 swings. The moving speed can be controlled faster than when the specific tool is attached to the tool magazine 50. As a result, the operating speed of the machine tool 12 can be increased and the cycle time can be shortened, so that productivity can be improved.

The turning parameter may include the turning jerk or time constant of the tool magazine 50. In this case, the smaller the maximum tool weight corresponding to the operation mode, the larger the turning jerk corresponding to the operation mode, and the smaller the time constant corresponding to the operation mode. The axis feed parameter may include the axis feed jerk or time constant of the spindle head 32. In this case, the smaller the maximum tool weight corresponding to the operation mode, the larger the axial feed jerk corresponding to the operation mode, and the smaller the time constant corresponding to the operation mode.

Further, in the above description, the storage unit 27 has been described as storing both the turning parameter and the axis feed parameter according to each operation mode, but only one of them is determined according to each operation mode. It doesn't matter if you do so.

[Modification]
The above embodiment may be modified as follows.

(Modification 1)
FIG. 8 is a diagram showing the configuration of the machining program 90 according to the first modification. FIG. 9 is a diagram showing a tool magazine 50 according to the first modification. FIG. 10 is a diagram showing the tool stocker 16 according to the first modification. In the machining program 90 according to the first modification, the tool replacement code “M6T2” is followed by the tool attachment/detachment codes “M100D1E1” and “M100D3E3”. That is, a 3 kg specific tool stored in the magazine number 1 of the tool magazine 50 and the stocker number 1 of the tool stocker 16 during machining with the 2 kg tool 40b attached to the magazine number 2 of the tool magazine 50. The tool 40a is attached, and the tool 40c which is a specific tool attached to the magazine number 3 of the tool magazine 50 is removed and stored in the stocker number 3 of the tool stocker 16. In this way, the productivity of the machine tool 12 can be further improved by continuously executing the tool attaching/detaching operation during machining with the single tool 40b. If the tool attachment/detachment codes are continuous in this way, as described in step S33 of FIG. 7, the tool attachment/detachment command by the subsequent tool attachment/detachment code is stored in the storage unit (not shown) of the robot controller 72. By doing so, it becomes possible to sequentially process the tool attaching/detaching operation.

[Invention Obtained from Embodiment]
The invention that can be understood from the above-described embodiment will be described below.

(First invention)
The tool transfer device (14) attaches and detaches the tool (40) to and from the swivel type tool magazine (50) of the machine tool (12). The tool transfer device (14) includes a robot (70) having an articulated arm that grips the tool (40) and a specific tool before the machine tool (12) uses the specific tool having a predetermined weight or more. The robot (70) is controlled so as to be attached to the tool magazine (50), and after the machine tool (12) finishes machining with the specific tool, the robot (70 is removed to remove the specific tool from the tool magazine (50). ) Is controlled by the robot controller (74).

As a result, when the specific tool is not used for machining, the specific tool can be removed from the tool magazine (50), and the operating speed of the machine tool (12) can be increased to improve productivity.

The robot control unit (74) attaches the specific tool to the tool magazine (50) by the time the machining using the tool (40) used by the machine tool (12) before the specific tool is finished at the latest. The robot (70) may be controlled as described above. The robot control section (74) mounts the specific tool on the spindle (30) of the machine tool (12) at least as soon as possible after mounting the tool (40) used for machining after the specific tool. ), the robot (70) may be controlled to be removed from the robot.

The robot controller (74) may control the attachment and detachment of the specific tool to and from the tool magazine (50) by the robot (70) based on a command from the machine tool (12).

The tool transfer device (14) may include a communication unit (76) for notifying the machine tool (12) of the completion of the attaching and detaching operations of the specific tool by the robot (70). Thereby, the interference between the machine tool body (20) and the robot (70) can be avoided.

(Second invention)
A machine system (10) includes the above-described tool transfer device (14) and a machine tool (12).

This makes it possible to improve the productivity of the machine tool (12).

The machine tool (12) has a turning motor (50a) for turning the tool magazine (50) and the weight of the heaviest tool (40) of the tools (40) attached to the tool magazine (50). And a motor control unit (24) for controlling the turning motor (50a) so that the tool magazine (50) turns at a turning speed or a turning acceleration according to the maximum tool weight.

The motor control unit (24) may control the swing motor (50a) such that at least one of the swing speed and the swing acceleration becomes faster as the maximum tool weight becomes smaller. Thereby, the operating speed of the machine tool (12) can be increased and the productivity can be improved.

The machine tool (12) includes a spindle (30), a spindle head (32) that rotationally drives the spindle (30), a shaft feed motor (34a) that moves the spindle head (32) in the axial direction, and a spindle head ( 32) may swing the tool magazine (50) when it moves along the axial direction. The motor control unit (24) may control the shaft feed motor (34a) so that the spindle head (32) moves at the shaft feed speed or the shaft feed acceleration according to the maximum tool weight.

The machine tool (12) includes a spindle (30), a spindle head (32) that rotationally drives the spindle (30), a shaft feed motor (34a) that moves the spindle head (32) in the axial direction, and a spindle head ( The swinging mechanism that swings the tool magazine (50) when the tool 32 (32) moves along the axial direction, and the tool (40) having the largest weight among the tools (40) attached to the tool magazine (50) A motor control unit (24) for controlling the shaft feed motor (34a) so that the spindle head (32) moves at the shaft feed speed or the shaft feed acceleration corresponding to the maximum tool weight, which is the weight of Good.

The motor controller (24) may control the shaft feed motor (34a) such that at least one of the shaft feed speed and the shaft feed acceleration becomes faster as the maximum tool weight of the tool (40) becomes smaller. Thereby, the operating speed of the machine tool (12) can be increased and the productivity can be improved.

(Third invention)
A tool carrying method includes a robot (70) having an articulated arm that holds a tool (40) for attaching and detaching the tool (40) to and from a swivel type tool magazine (50) of a machine tool (12). A method for carrying a tool of a carrying device (14), wherein a robot (70) is attached to a tool magazine (50) before the machine tool (12) performs processing using the particular tool having a predetermined weight or more. ) Controlling the robot (70) so as to remove the specific tool from the tool magazine (50) after the machine tool (12) finishes machining with the specific tool. Have.

As a result, when the specific tool is not used for machining, the specific tool can be removed from the tool magazine (50), and the operating speed of the machine tool (12) can be increased to improve productivity.

The tool mounting step is performed by the robot so that the specific tool is mounted in the tool magazine (50) at the latest by the time the machining using the tool (40) used by the machine tool (12) before the specific tool is completed. (70) may be controlled. The tool removing step removes the specific tool from the tool magazine (50) after the tool (40) used for machining is mounted on the spindle (30) of the machine tool (12) at least one after the specific tool. The robot (70) may be controlled as described above.

The tool mounting step may control mounting of the specific tool to the tool magazine (50) by the robot (70) based on a command from the machine tool (12). The tool removing step may control the removal of the specific tool from the tool magazine (50) by the robot (70) based on a command from the machine tool (12).

10... Machine system 12... Machine tool 14... Tool transport device 16... Tool stocker 20... Machine tool body 22... Control device 24... Motor control unit 24a... Operation mode setting unit 26, 76... Communication unit 28... Workpiece 30... Spindle 32... Spindle head 34... Column 34a... Shaft feed motor 36... Spindle motor 40, 40a, 40b, 40c... Tool 46... Table 48... Automatic tool changer 50... Tool magazine 50a... Rotation motor 52... Rotating shaft 54... Grip 56... Support member 60... Oscillation shaft 62... Cam 64... Cam follower 70... Robot 72... Robot control device 74... Robot control unit 80, 90... Machining program

Claims (13)

A tool transfer device for attaching and detaching a tool to and from a swivel type tool magazine of a machine tool,
A robot having an articulated arm that holds the tool;
Before the machine tool performs processing using a specific tool having a predetermined weight or more, the robot is controlled to attach the specific tool to the tool magazine, and the machine tool finishes the processing using the specific tool. After that, a robot control unit that controls the robot to remove the specific tool from the tool magazine,
A tool transfer device. The tool transfer device according to claim 1, wherein
The robot control unit controls the robot so that the specific tool is attached to the tool magazine by the time the processing using the tool used by the machine tool before the specific tool is completed at the latest. However, the robot is controlled so as to remove the specific tool from the tool magazine after the tool used for machining is mounted on the spindle of the machine tool at least as soon as one of the specific tools. apparatus. The tool transfer device according to claim 1 or 2, wherein
The said robot control part is a tool conveyance apparatus which performs the control of attachment and detachment of the said specific tool by the said robot to the said tool magazine based on the command from the said machine tool. The tool transfer device according to any one of claims 1 to 3,
A tool transfer device comprising a communication unit for notifying the machine tool of the completion of the attachment operation and the removal operation of the specific tool by the robot. A tool carrier according to any one of claims 1 to 4,
The machine tool,
A work system equipped with. The work system according to claim 5,
The machine tool is
A rotation motor for rotating the tool magazine,
Motor control for controlling the swing motor so that the tool magazine swings at a swing speed or a swing acceleration according to the maximum tool weight, which is the weight of the heaviest tool among the tools attached to the tool magazine. Department,
A work system. The work system according to claim 6,
The motor control unit controls the turning motor such that at least one of the turning speed and the turning acceleration becomes faster as the maximum tool weight becomes smaller. The work system according to claim 6 or 7, wherein
The machine tool is
Spindle and
A spindle head for rotationally driving the spindle,
A shaft feed motor for moving the spindle head in the axial direction,
A swing mechanism that swings the tool magazine when the spindle head moves along the axial direction,
Have
The motor control unit controls the shaft feed motor so that the spindle head moves at a shaft feed speed or a shaft feed acceleration corresponding to the maximum tool weight. The work system according to claim 5,
The machine tool is
Spindle and
A spindle head for rotationally driving the spindle,
A shaft feed motor for moving the spindle head in the axial direction,
A swing mechanism that swings the tool magazine when the spindle head moves along the axial direction,
The spindle feed motor is controlled so that the spindle head moves at the spindle feed speed or the spindle feed acceleration according to the maximum tool weight, which is the weight of the heaviest tool among the tools attached to the tool magazine. A motor control unit for
A work system. The work system according to claim 8 or 9, wherein
The machine control system, wherein the motor control unit controls the axial feed motor such that at least one of the axial feed speed and the axial feed acceleration becomes faster as the maximum tool weight becomes smaller. A tool transfer method for a tool transfer device comprising a robot having an articulated arm for gripping the tool, wherein the tool is attached to and detached from a swivel type tool magazine of a machine tool,
A tool attaching step of controlling the robot to attach the specific tool to the tool magazine before the machine tool is machined using the specific tool having a predetermined weight or more;
A tool removing step of controlling the robot to remove the specific tool from the tool magazine after the machine tool finishes machining with the specific tool;
A method of transporting a tool, comprising: It is a tool conveyance method of Claim 11, Comprising:
The tool attaching step controls the robot to attach the specific tool to the tool magazine by the time the machining using the tool used by the machine tool before the specific tool for machining is completed at the latest. Then
The tool removing step controls the robot to remove the specific tool from the tool magazine after the tool used for machining is mounted on the spindle of the machine tool at least one after the specific tool. Yes, the tool transportation method. The tool transfer method according to claim 11 or 12, wherein
The tool attachment step executes control of attachment of the specific tool to the tool magazine by the robot based on a command from the machine tool,
The tool removal method, wherein the tool removal step executes control of removal of the specific tool from the tool magazine by the robot based on a command from the machine tool.

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