KR20110013040A - Unity servo drive and motor control method - Google Patents

Abstract

PURPOSE: An integrated servo drive and a method for controlling a motor are provided to correspond to the specification change of application with minimum correction by using one servo drive. CONSTITUTION: K input and output ports are connected to a servo motor. The k is an arbitrary natural number. A setting unit(215) sets the type of the motor by recognizing the type of the servo motor. A controller(220) generates a switch control signal according to the set type of the motor. 2k switches activate or inactivate each input and output port. A converter(230) activates m switches according to a switch control signal. The m is 2k or a natural number less than 2k. A communication unit(210) transmits the type of the motor to a servo management device according to the control of the controller.

Description

Unity servo drive and motor control method

The present invention relates to a servo drive, and more particularly, to an integrated servo drive capable of controlling various types of motors.

Recently, various kinds of robots are used in industrial sites. For example, there may be a welding robot for welding various materials such as an iron plate. The industrial robot system controls the operation of the robot through motion control, specifically, position control, speed control, and current control. Direct control of the operation of the robot can be achieved by the servo drive mounted on the robot to perform the servo motor drive operation.

The stator winding structure inside the servo motor is different depending on the type of each servo motor connected to the servo drive. Accordingly, there is a problem that each servo drive for each servo motor should be provided.

The present invention is to provide an integrated type servo drive capable of controlling (or driving) various types of motors.

In addition, the present invention provides an integrated servo drive and motor control method capable of satisfying the changed specifications with minimal modification when changing application specifications (load or speed specifications) by controlling various types of motors using one servo drive. It is to.

According to one aspect of the present invention, an integrated servo drive capable of controlling various types of servo motors is provided.

개의 입출력 포트를 통해 상기 모터 유형에 따라 상이한 명령 펄스를 출력하여 연결된 상기 서보 모터를 제어하며, 상기 명령 펄스는 상기 변환부에 의해 상기 모터 유형에 상응하는 전압으로 변환되어 출력되는 것을 특징으로 하는 통합 서보 드라이브가 제공될 수 있다.According to an embodiment of the present invention, an integrated servo drive capable of controlling a servo motor, comprising: k input / output ports connected to the servo motor; A setting unit configured to recognize a type of a servo motor connected to the integrated servo drive and set a motor type; A controller for generating a switch control signal according to the set motor type; And n (n is 2k) switches for enabling or disabling each input / output port, and converting the m (m is a natural number less than n) switches according to the switch control signal. And a controller, wherein the controller is activated

And outputting different command pulses according to the motor type through two input / output ports to control the connected servo motor, wherein the command pulses are converted into a voltage corresponding to the motor type by the converter and output. Servo drive can be provided.

개의 입출력 포트를 통해 연결된 상기 서보 모터로부터 피드백 데이터를 입력받고, 입력된 상기 피드백 데이터에 상응하여 연결된 상기 서보 모터를 제어할 수 있다.The controller is activated

The controller may receive feedback data from the servo motor connected through two input / output ports, and control the servo motor connected according to the input feedback data.

The communication unit may further include a communication unit for transmitting the motor type, wherein the communication unit may transmit the motor type to a servo management apparatus connected through a network under the control of the controller.

The servo management apparatus receives the motor type, sets the type of the servo motor connected to the integrated servo drive using the received motor type, and transmits a control command according to the set type to the integrated servo drive in real time. have.

The motor type may be any one of an AC servo motor, a DC servo motor, a BLDC servo motor, and a commercial servo drive.

According to another aspect of the present invention, a method is provided in which an integrated servo drive controls various types of servo motors.

개의 입출력 포트가 연결된 상기 서보 모터와 연결되도록 설정하는 단계; 및 상기

개의 입출력 포트를 통해 상기 모터 유형에 따라 상이한 명령 펄스를 연결된 상기 서보 모터로 전송하여 상기 서보 모터를 제어하는 단계를 포함하는 모터 제어 방법이 제공될 수 있다. According to an embodiment of the present invention, a method of controlling a servo motor connected to an integrated servo drive including k (random natural numbers) input / output ports for data transmission and reception with a servo motor, the servo connected to the integrated servo drive Obtaining type information of the motor and setting the motor type according to the type information; Generating a switch control signal according to the set motor type; In response to the switch control signal, m (m is a natural number of 2k or less)

Setting two input / output ports to be connected to the servo motor connected thereto; And said

A method of controlling a motor may be provided by transmitting different command pulses according to the motor type to the connected servo motor through two input / output ports.

개의 입출력 포트를 통해 연결된 상기 서보 모터로부터 피드백 데이터를 입력받는 단계; 및 상기 피드백 데이터를 분석하고, 분석 결과에 따라 상기 서보 모터로 출력되는 전류를 제어하는 단계를 포함할 수 있다.Activated remind

Receiving feedback data from the servo motor connected through two input / output ports; And analyzing the feedback data and controlling the current output to the servo motor according to the analysis result.

After setting the motor type, the method may further include transmitting the set motor type to a servo management device, wherein the servo management device receives the motor type and uses the received motor type to integrate the servo. Recognizing the type of the motor connected to the drive, it is possible to generate a control command according to the recognized type and transmit it to the integrated servo drive in real time.

By providing the integrated servo drive and the motor control method according to the present invention, there is an advantage that can control (or drive) various types of motors using the integrated servo drive.

In addition, the present invention has the advantage that it is possible to meet the changed specifications through a minimum modification when changing the application specifications (load or speed specifications) by controlling various types of motors using one servo drive.

In addition, the present invention has a very useful advantage in terms of economics / management because it is not necessary to provide a servo drive for each motor individually.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention. In the following description of the present invention, if it is determined that the detailed description of the related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

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

1 is a diagram schematically illustrating a servo system according to an embodiment of the present invention.

Referring to FIG. 1, a servo system according to an exemplary embodiment of the present invention includes a servo management apparatus 110, an integrated servo drive 120, and a plurality of servo motors 130.

As illustrated in FIG. 1, the servo management apparatus 110 and the integrated servo drive 120 are connected through wired or wireless communication. The servo management apparatus 110 may check the state of the integrated servo drive 120 using packet communication in real time, and control the integrated servo drive 120 accordingly. Here, the wired and wireless communication includes all communication capable of packet communication, and may be, for example, Internet communication according to TCP / IP, Ethernet communication, WiBro, WCDMA, or the like.

For example, the servo management apparatus 110 may acquire a motor type from the integrated servo drive 120, and set / store the acquired motor type in the servo management apparatus 110. Here, the motor type is a type of motor connected to the integrated servo drive 120, for example, any one of a direct current (DC) servo motor, an AC servo motor, a brushless direct current (BLDC) servo motor, and a commercial servo drive. Is set.

The servo management device 110 acquires and stores a motor type connected to the integrated servo drive 120 through the integrated servo drive 120, so that the servo management device 110 may be easily changed even if the manager managing the servo management device 110 is changed. It may be possible to recognize the type of the motor connected to 120. Thus, the servo management apparatus 110 may transmit a control signal suitable for a motor connected to the integrated servo drive 120 to the integrated servo drive 120 in real time.

The integrated servo drive 120 is for driving or / or controlling the servo motor 130 and operates under the control of the servo management apparatus 110. The integrated servo drive 120 may control the connected servo motor 130 by activating an input / output port (or an input / output signal line) differently according to the connected motor type. The integrated servo drive 120 may recognize and set the connected motor type by various methods.

For example, assume that an RFID tag is attached to each motor. The integrated servo drive 120 may acquire a tag information through a wired / wireless communication network from another device (not shown) attached to a reader capable of reading tag information of an RFID tag or from a device connected to an externally connected reader. In this case, the integrated servo drive 120 may analyze the obtained tag information to recognize the motor type connected to the integrated servo drive 120 and set the recognized motor type. Of course, when the reader is connected to another device, it is obvious that the integrated servo drive 120 may obtain the motor type from the device and set the obtained motor type.

A method of controlling the connected servo motor 130 by activating the input / output ports differently according to the set motor type will be described in detail with reference to the accompanying drawings.

The servo motor 130 is driven by the control of the integrated servo drive 120 to output feedback data to the integrated servo drive 120. The feedback data depends on the type of servo motor. For example, the feedback data may include one or more of an encoder signal, a hall signal, and pulse data.

For example, in the case of an AC motor, an encoder signal and 2 pulse data are output as feedback data. On the other hand, the DC motor outputs an encoder signal and one pulse data as feedback data. In the case of the BLDC motor, the encoder signal, the hall signal, and one pulse data are output as feedback data.

As such, since different feedback data is output for each motor, the integrated servo motor 130 receives feedback data according to the connected servo motor 130 by activating input / output ports differently depending on the type of motor to be connected. The servo motor 130 may be controlled.

2 is a block diagram schematically illustrating an internal configuration of an integrated servo drive according to an exemplary embodiment of the present invention, and FIG. 3 is a diagram illustrating a winding structure according to a type of a servo motor.

Referring to FIG. 2, the integrated servo drive 120 according to an exemplary embodiment of the present invention includes a communication unit 210, a setting unit 215, a controller 220, a storage unit 225, and a conversion unit 230. It is composed.

The communication unit 210 performs a function of transmitting and receiving data with the servo management apparatus 110 according to a predetermined communication protocol.

For example, the communication unit 210 transmits a motor type set under the control of the controller 220 to the servo management apparatus 110. In addition, the communication unit 210 may receive a control command corresponding to the corresponding motor type from the servo management apparatus 110 and output the control command to the controller 220.

The servo management apparatus 110 may receive the motor type through the communication unit 210, and recognize and set the type of the servo motor connected to the integrated servo drive using the motor type. Accordingly, the servo management apparatus 110 may transmit the control command according to the set type to the integrated servo drive 120 in real time.

The setting unit 215 acquires motor type information connected to the integrated servo drive 120 and sets the motor type according to the obtained motor type information.

For example, the setting unit 215 may set the motor type by the setting of the administrator, or may set the motor type according to the connected servo motor by acquiring motor type information using RFID-based technology. When acquiring motor type information using RFID-based technology, although not illustrated in FIG. 2, the integrated servo drive 120 may use a reader for reading tag information from an electronic tag attached or embedded in the servo motor 130. It may further include. Of course, when the reader is provided in a separate external device, it is natural that the setting unit 215 may obtain tag information (or motor type information) from the corresponding external device through the communication unit 210.

The controller 220 may activate the input / output port differently according to the set motor type. Although the input / output port is not illustrated in FIG. 2, the integrated servo drive according to the present invention includes k input / output ports. Since the number of input / output ports differs depending on the type of servo motor connected (or coupled) to the integrated servo drive 120, the controller 220 connects (or combines) by activating the input / output ports differently according to the set motor type. The feedback data may be appropriately input from the servo motor 130.

In addition, the controller 220 analyzes feedback data of the connected servo motor 130 to generate and output command pulses for controlling the connected servo motor 130. That is, the controller 220 receives a control command for controlling the servo motor 130 from the servo management apparatus 110. The controller 220 receives feedback data from the servo motor 130, analyzes the feedback data, and controls a current to operate the servo motor 130 according to a control command. Since current control using feedback data between the servo drive and the motor is obvious to those skilled in the art, a separate description thereof will be omitted.

The storage unit 225 stores algorithms, programs, and the like necessary for operating the integrated servo drive 120 according to an exemplary embodiment of the present invention.

개의 입출력 포트를 활성화시킨다. 여기서, 각 스위치는 각각의 입출력 포트 활성화(on) 또는 비활성화(off)하는 기능을 수행한다. 즉, 결과적으로 스위치 개수는 입출력 포트의 2배수(즉, 2k)가 된다.The converter 230 includes 2k switches. The conversion unit 230 activates m switches (m is a natural number of 2k or less) according to a switch control signal input from the controller 220.

Active I / O ports. Here, each switch performs a function of enabling or disabling respective input / output ports. That is, as a result, the number of switches is twice the input / output port (that is, 2k).

In addition, the converter 230 converts the command pulse input from the controller 220 into a voltage corresponding to the motor type set by the setting unit and outputs the converted voltage.

For example, assume that the conversion unit 230 includes six switches, and assume that a servo motor connected to the integrated servo drive 120 is a DC motor. Since the DC motor has a two-phase winding structure (refer to FIG. 3A), the conversion unit 230 activates four switches to activate two input / output ports for applying current to the two-phase winding. The operation of the motor can be controlled.

As another example, assume that a servo motor connected to the integrated servo drive 120 is an AC motor. In the case of the AC motor is configured as a three-phase winding structure as illustrated in (b) of FIG. Accordingly, the controller 220 outputs a switch control signal capable of activating six switches for applying current to the three-phase winding to the converter 230. Accordingly, the conversion unit 230 may activate the three input / output ports by activating the six switches, and as a result, the current may be applied through the three input / output ports to operate the AC motor.

Of course, the conversion unit 230 activates the switch differently according to the switch control signal of the servo motor 130 to be connected, activates the input / output port corresponding to the motor type, and then controls the corresponding motor type according to the control of the controller 220. The current may be converted and applied so that a suitable current is applied to the servo motor 130 connected through the input / output port.

4 is a flowchart illustrating a method in which an integrated servo drive controls various types of servo motors according to an embodiment of the present invention. Each step described below is performed by each internal configuration of the integrated servo drive 120, but will be collectively described as an integrated servo drive for the convenience of understanding and explanation.

In operation 410, the integrated servo drive 120 acquires motor type information of the connected servo motor 130, recognizes the motor type, and sets the recognized motor type.

When the connected motor type is recognized, the integrated servo drive 120 may transmit information about the recognized motor type to the servo management apparatus 110. Accordingly, the servo management apparatus 110 may recognize the servo motor 130 connected (or coupled) to the integrated servo drive 120, and then, even if the user changes, the type of the servo motor 130 connected separately. There is an advantage in that it does not need to perform a separate process to recognize. The servo management apparatus 110 may generate a control command according to the received motor type and transmit the generated control command to the integrated servo drive 120.

In operation 415, the integrated servo drive 120 generates a switch control signal according to the set motor type.

For example, when the integrated servo drive 120 includes 2 k switches (k is the natural number of input / output ports), the switch control signal may be a control signal for activating or deactivating m switches. Here m is a natural number of 2k or less. In the present invention, the number of switches included in the integrated servo drive 120 may be configured differently according to the number of input / output ports. That is, the number of switches may be configured by twice the input / output port.

In the present specification, the input / output port is an interface connected to the electrical winding of the stator required for driving the servo motor 130. That is, a current is applied to the internal winding of the servo motor 130 through the input / output port.

개의 입출력 포트를 활성화시킨다.In step 420, the integrated servo drive 120 activates m switches according to a switch control signal.

Active I / O ports.

개의 입출력 포트를 통해 서보 모터(130)로 인가하여 구동되도록 제어한다.In step 425, the integrated servo drive 120 generates a command pulse according to the motor type, and converts the command pulse into a current corresponding to the motor type to activate it.

It is controlled to be driven by being applied to the servo motor 130 through two input / output ports.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

1 schematically illustrates a servo system according to an embodiment of the invention.

2 is a block diagram schematically showing an internal configuration of an integrated servo motor according to an embodiment of the present invention.

3 illustrates a winding structure according to a type of servo motor.

4 is a flow chart illustrating a method in which an integrated servo drive controls various types of servo motors according to an embodiment of the present invention.

Claims (8)

In the integrated servo drive that can control the servo motor, K (random natural numbers) input / output ports connected to the servo motor; A setting unit configured to recognize a type of a servo motor connected to the integrated servo drive and set a motor type; A controller for generating a switch control signal according to the set motor type; And It includes 2k switches for each input port on (on) or off (off), and includes a conversion unit for activating m (m is a natural number less than 2k) according to the switch control signal, The controller is activated

Outputs different command pulses according to the motor type through two input / output ports to control the connected servo motor, And the command pulse is converted into a voltage corresponding to the motor type by the converter and outputted. According to claim 1, The controller is activated

And receiving feedback data from the servo motor connected through two input / output ports, and controlling the servo motor connected according to the input feedback data. According to claim 1, Further comprising a communication unit for transmitting the motor type, And the communication unit transmits the motor type to a servo management apparatus connected through a network under the control of the controller. The method of claim 2, The servo management apparatus receives the motor type, sets the type of the servo motor connected to the integrated servo drive using the received motor type, and transmits a control command according to the set type to the integrated servo drive in real time. Integrated servo drive, characterized in that. According to claim 1, The motor type is any one of an AC servo motor, a DC servo motor, a BLDC servo motor, and a commercial servo drive. A method of controlling a servo motor connected to an integrated servo drive including k (random natural numbers) input / output ports for transmitting and receiving data with a servo motor, the method comprising: Acquiring type information of the servo motor connected to the integrated servo drive and setting a motor type according to the type information; Generating a switch control signal according to the set motor type; In response to the switch control signal, m (m is a natural number of 2k or less)

Setting two input / output ports to be connected to the servo motor connected thereto; And remind

And transmitting different command pulses according to the motor type to the connected servo motor through two input / output ports to control the servo motor. The method according to claim 6, Activated remind

Receiving feedback data from the servo motor connected through two input / output ports; And Analyzing the feedback data and controlling a current output to the servo motor according to an analysis result. After setting the motor type, The method may further include transmitting the set motor type to a servo management apparatus. The servo management apparatus receives the motor type, recognizes the type of the motor connected to the integrated servo drive by using the received motor type, generates a control command according to the recognized type, and transmits the control type to the integrated servo drive in real time. Motor control method characterized in that the transmission.

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