JPH0810410B2 - Servo motor system for transportation - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to a servomotor system for transportation, and particularly to a transportation servomotor system in which the amount of movement is determined in advance and the positioning accuracy is 0.1 mm or more for relatively coarse positioning. The present invention relates to a servo motor system.

[Conventional technology]

FIGS. 5 (a) and 5 (b) respectively show a conventional servo motor system for conveyance, in which (1) is an increment value command device, (2) is a counter, (3) is an amplifier,
(4) is a servomotor, (5) is an incremental value system detector represented by an encoder, (6) is an absolute value system command device,
(7) is an absolute value system detector, and (8) is a drive unit.

That is, FIG. 5 (a) shows an incremental value system (incremental) transfer servo motor system, and FIG. 5 (b) shows an absolute value system (absolute) transfer servo motor system. And conventionally, the objective has been achieved by using a servo motor system for conveyance of either system.

[Problems to be solved by the invention]

By the way, the difference between the incremental value system servo system and the absolute value system servo system lies in the following points.

That is, in the incremental value system servo system, a detector (5) that outputs an incremental value indicating only the moving distance of a conveyed object is used, and after returning to the origin of the mechanical system provided at a specific point of the machine, the command device While the coordinate system is set in (1),
The absolute value servo system uses a detector (7) capable of outputting absolute value position data that stores the entire range of motion of the servo motor (4). Read the output from this detector (7). Is to immediately set the coordinate system in the command device (6).

Therefore, in the incremental value system servo system, the operation must be performed after the power is turned on before the home position return operation is performed, whereas in the absolute value system servo system, the current value can be read at any position, so After the turning on, the main work can be started immediately without performing the preparatory operation such as the return to origin.

However, in the absolute value type servo system, the structure of the detector (7) is complicated, the cost of the command device (6) and the amplifier (3) increases due to the increase in signal processing, and the wiring increases. There is a problem that the cost of the entire system increases significantly.

Generally, the basic control of a servomotor is to move the motor (4) according to a command and to follow even a difficult command. Therefore, the feedback information of the position (P), the speed (V), and the current (I) is given to the drive unit (8) that directly affects the operation of the motor (4) every moment, but the command device (1) ), (6), feedback of external information is not performed at every time. For example, in the control of metalworking machines such as NC machine tools, the feed amount per pulse is extremely small at 1.0 to 0.1 μm, and it is fast and minute, so it is common to control the command itself from an external signal. Difficult to do. In the absolute value system servo system shown in FIG. 5 (b),
The absolute value position data from the servo motor (4) is fed back to the command device (6).
It is used only when the coordinates are set after the power is turned on, and is not used thereafter. Therefore, the control of NC machine tool is
This is based on the technique of operating the servo motor (4) essentially as instructed by the incremental value system.

On the other hand, recently, the scope of application of servo motors has expanded significantly after the advent of AC servo motors, and they have come to be widely used for transporting goods. This is because attention has been paid to the fast and accurate driving capability of the servo motor. However, when processing and conveying products whose size is in units of m, the feed accuracy is 0.1 mm or more, and in terms of practical necessity, the unit of mm is often sufficient. That is, even if the accuracy is the same, there is a difference of 10 ³ to 10 ^{4 from} the accuracy of the NC machine tool. Also,
When it comes to safety, this is just as important as in any field, but especially in the servo system for transport, what is carried is large, speedy, and carries far It is more important to know where you are. From this point of view, the absolute value system servo motor system is more strongly required than the incremental value system servo motor system which must always perform the home-return operation once after the power is turned on.

In this way, the conventional servo motor system has both an incremental value system and an absolute value system as a transfer system for which the movement amount is predetermined and the positioning accuracy is 0.1 mm or more for relatively rough positioning. There is a problem that neither is suitable.

The present invention has been made to solve such a problem and has a function equivalent to that of an absolute value system servo system.
Moreover, it is an object of the present invention to obtain a servomotor system for transportation which can be constructed at a cost equal to or less than that of an incremental value type servo system.

[Means for solving problems]

The servo motor system for conveyance according to the present invention is installed at a predetermined distance from the incremental value system position command device, the incremental value system position detector, and the arrival point of the conveyed object, and when the conveyed object is detected, the servo motor system is controlled to be low relative to the servo motor when necessary. A first type external signal device that gives a speed command, and a second command that is installed at the arrival point of the conveyed object and gives a stop command to the servomotor by detecting the conveyed object prior to the command from the incremental value system position command device
Each seed external signal device is provided.

[Action]

In the present invention, an incremental value system position command device and an incremental value system position detector are provided, and basically, the conveyed object is controlled as an incremental value system servo system. Then, when necessary, the external signal from each external signal device is taken in, and the increment value system command is corrected. Therefore, it is possible to obtain a function equivalent to that of the absolute value system servo system, and it is possible to configure the system at a cost equal to or less than that of the incremental value system servo system.

〔Example〕

1 to 3 show an embodiment of the present invention.
In the figure, the same reference numerals as those in FIGS. 5A and 5B indicate the same or corresponding portions. (9) is a first type external signal device installed at a point (A), which is a predetermined distance before the arrival point (B) of the conveyed object (not shown), and the distance between both points (A) and (B) is It is set to a value obtained by adding the distance in which the operation delay of the first type external signal device (9) and the like are included in the distance traveled by the conveyed object during deceleration. (10) is the second installed at the arrival point (B) of the conveyed object
With the seed external signal device, the detection signal thereof is input to the system shown in FIG. 2 together with the first type external signal device (9).

That is, in FIG. 2, (11) is a speed indicator, and when the first type external signal device (9) detects the passage of the conveyed object, the command device (1) changes the speed of the conveyed object. I am supposed to give you instructions. When this instruction is given, the switch (SW ₁ ) between the command device (1) and the speed indicator (11) is switched, and the low speed command is given to the drive section (8) of the servomotor (4). To be given. Further, when the second type external signal device (10) detects the passage of the conveyed object, it instructs the drive unit (8) of the servo motor (4) to forcibly stop the servo motor (4). ing. Specifically, when the second type external signal device (9) detects passage of a conveyed object, the command device (1)
The switch (SW ₂ ) between the drive unit (8) and the drive unit (8) is switched from the input side to the clear side, the command from the command device (1) is cut off, and the position error ( Various expressions such as droop or droop pulse) are cleared and the counter (2) is forcibly set to "0" to give a stop position to the servo motor (4).

In the transport servomotor system configured as described above, the transport object starts from the start point O of the main body and reaches the line speed in a predetermined acceleration time as shown in FIG. Then, when the installation point (A) of the first type external signal device (9) is reached, deceleration is started toward a predetermined low speed, and then the vehicle proceeds at a low speed to reach the arrival point (B). Since the second type external signal device (10) is installed at the arrival point (B), when the conveyed object reaches the arrival point (B), the signal from the second type external signal device (10) is generated. The stop position of the servo motor (4) is forcibly set to the point (B) regardless of the command from the command device (1).
That is, the position error is cleared and the value of the counter (2) is set to "0".
The position error is incremented in the opposite direction, and the position is returned to the stop point (B).

Next, both external signal devices (9) in the actual system,
Explain the use of (10).

FIG. 3A shows the operation of the servomotor (4) or the conveyed object when both the external signal devices (9) and (10) are enabled. As a general rule, this pattern is used when the start position deviates from the original start point O, for example, during the first operation after the power is turned on, or when the position of the conveyed object cannot be known at all due to an emergency stop. Used for.

Now, assuming that the position data set in the command device (1) is the required travel distance, if the start position is a point (X ₁ ) closer to the arrival point (B) than the original start point O, acceleration is performed. Then, the transported object that has reached the line speed is (A)
When the point is reached, deceleration is started, the vehicle advances at low speed, and stops at point (B). Even at this time, the command device (1) continues to issue a command corresponding to the deviation of the start point.

On the contrary, if the start position is a point (X ₂ ) far from the arrival point (B) from the original start point O, the vehicle will stop at the point (X ₃ ) before the arrival point (B). (Of course,
If the position data set in the command device (1) is large enough, it will be the same as the start from the point (X ₁ ). As a system for the entire transportation, when this abnormality is detected by, for example, the second type external signal device (10), the transported object is transported to the arrival point (B) by the sequence function.

FIG. 3B shows a pattern in which the conveyed object starts from the original start point O. In this case, the command device (1) manages the remaining amount movement amount to calculate and set the deceleration point. Stop at the position of the specified position data. Therefore, in this case, it goes without saying that the type 1 external signal device (9) is not necessary, and the type 2 external signal device (10) is not a necessary element. The second type external signal device (10) is shown in FIG. 3 (b) because it is used for confirmation of arrival and for each time arrival, an operation equivalent to the origin return is inserted. When this second type external signal device (10) is to be used for purposes other than this purpose, the position data set in the command device (1) must be made slightly larger than the required feed amount. Will be decided in consideration of the required stop state.

Since the second type external signal device (10) also has a protection function in case of a runaway due to some mistake, if the second type external signal device (10) is used in a disabled state, a separate It is necessary to install the protection function of. FIG. 3B shows the case where a switch (SW ₃ ) is provided.

By the way, there are many processing steps, the length of the transfer line is structurally long, and there is a problem of extension due to temperature difference,
Alternatively, there are relatively many cases where it is desired to configure one line with a plurality of servo motors because it is better to use a plurality of servo motors having a small capacity separately. FIG. 4 shows a system constructed on the basis of such a request.

FIG. 4 shows a case where three servo motors (4) are used. Since the operations of the three servo motors (4) need to be synchronized, each drive unit (8) is controlled by the same command. As described above, it is possible to control a plurality of servo motors (4) with one command device (1) by using the incremental value system command device (1) and by using two types of external signal devices (9). ), (10) so that the conveyed object can be guided to the arrival point (B). Then, the reduction in the required number of command devices (1) improves reliability and reduces the cost, and a greater effect can be obtained by increasing the number of servo motors (4).

However, the required accuracy is 0 due to the combination of the incremental value system servo system and the two types of external signal devices (9) and (10).
In the case of a sufficient transportation application with 1 mm, the same performance as the absolute value system servo system can be obtained, and the system can be configured at the same cost as the incremental value system servo system. And in a line that uses a plurality of servo motors (4) per line, the strength of the incremental value system is exerted, and the command device (1)
Can be performed with one unit. This enhances the required synchronism due to the nature of the line, eliminates the need for interlocking between command devices, improves the reliability by simplifying the system, and provides an inexpensive system.

In the present invention, the terms "incremental value system" and "absolute value system" are used for convenience of description, but the "absolute value system" means an absolute value that stores the length of all steps covered by the servo motor. This means setting the coordinate system with the output data of the detector. The "incremental value system" mainly means a type that requires a return to origin, and two methods of giving a movement command value, an incremental value system and an absolute value system, are included in this "incremental value system". .

Further, in the above embodiment, the case where one type 1 external signal device (9) is provided is shown, but a plurality of type 1 external signal devices (9) may be provided. Further, the speed command device (1) and the counter (2) may be incorporated in the command device (1). The position command may be data or a pulse train.

〔The invention's effect〕

As described above, the present invention basically controls an article as an incremental value system servo system, and corrects the incremental value system command by an external signal from an external signal device at a necessary time. Position accuracy is 0.1m
In the transfer system for relatively coarse positioning of m or more, the same function as the absolute value system servo system can be obtained, and the system can be configured at the same cost as or less than the incremental value system servo system. And so on.

[Brief description of drawings]

FIG. 1 is an explanatory view showing the relationship between the installation position of an external signal device and the speed of a servomotor or a conveyed object in a conveying servomotor system according to an embodiment of the present invention, and FIG. 2 shows a similar system configuration. A block diagram and FIG. 3A are explanatory diagrams showing a change in speed of a servomotor or a conveyed object when starting from a point other than an original start point in which both external signal devices are effective in one embodiment of the present invention, Figure (b)
Is an explanatory view showing the speed change of the servo motor or the conveyed object when only the second type external signal device is enabled and starting from the original start point, and FIG. 4 is a command device for controlling a plurality of servo motors. FIG. 5 (a) is a block diagram showing a conventional incremental value system transfer servo motor system, and FIG. 5 (b) is a conventional absolute value system transfer servo motor system. It is a block diagram. (1) ... Command device, (2) ... Counter, (3) ...
Amplifier, (4) …… Servo motor, (5) …… Detector,
(8) …… Drive unit, (9) …… First type external signal device, (1
0) ... Type 2 external signal device. In the drawings, the same reference numerals indicate the same or corresponding parts.

Front Page Continuation (72) Inventor Akira Shima Aichi Prefecture, Nagoya City Higashi-ku 5-1-14 Yada Minami Mitsubishi Electric Corporation Nagoya Works (56) Reference JP-A-59-99508 (JP, A) JP-A- 59-88239 (JP, A) JP-A-55-131454 (JP, A) JP-A-60-44248 (JP, A) Practical application Sho-62-158507 (JP, U)

Claims (2)

[Claims] 1. An incremental value system position command device of a system in which a coordinate system is set by returning to a predetermined origin of a machine, and an incremental value system position detector for detecting only a moving distance of a conveyed object, It is installed a predetermined distance before the arrival point of the conveyed object, at least during the first operation after the power is turned on and during the first operation when the conveyed object is stopped at a place other than the arrival point for some reason. In the first type external signal device that gives a low speed command to the servo motor upon detection of the conveyed object, and at the arrival point of the conveyed object, the incremental value system position command device is transmitted to the servo motor upon detection of the conveyed object. And a second type external signal device that gives a stop command in preference to the command of 1. 2. A position command from the incremental value system position command device,
The first command pulse is applied to a plurality of servomotors, and the first command pulse is claimed.
The servo motor system for conveyance according to the item.