KR101476851B1 - Test device for communication port of machine tool - Google Patents

Abstract

The test apparatus 1000 for a machine tool according to the present invention is used in a machine tool T having a communication port P composed of a plurality of input and output pins for inputting and outputting data and is attached to the communication port of the machine tool, A connector unit 100 having a plurality of input / output pins corresponding to a plurality of input / output pins of the communication port P for testing whether the communication port P is abnormal; A first state in which the test apparatus is electrically connected between a pair of input / output pins selected so as not to overlap among the input / output pins of the connector unit 100 and the test apparatus is connected to the communication port P, And a plurality of LEDs (200) which are turned on or off in different states from a second state in which data is output from the machine tool (T) and a third state in which data is input to the machine tool (T).

Test, machine tool, communication port, RS232C

Description

Technical Field [0001] The present invention relates to a communication port test apparatus for a machine tool,

The present invention relates to an apparatus for testing an abnormality of a communication port in a machine tool having a communication port for data input / output, and more particularly, to a communication port test apparatus for a machine tool having an RS232C communication port.

As work functions of a machine tool have become more sophisticated, communication ports for inputting and outputting machining programs and data to be used in a machine tool that performs functions such as numerical control (NC) have generally been required. As a communication port used for a machine tool, RS232C is mainly used.

As shown in FIG. 1A, a communication port P using RS232C is provided with a plurality of pins for inputting / outputting various signals, and is installed outside the machine tool T. The communication port P is used for inputting and outputting various machining programs to be performed by the machine tool T and data related thereto or for transmitting data communication with the machine tool T for the maintenance of the machine tool T by the customer or the user .

On the other hand, in the production, setup, and maintenance of machine tool equipment, initial faults that can not input the program more frequently than the RS232C communication port frequently occur. In order to prevent this in advance, the RS232C communication It is necessary to test whether the port is abnormal.

In order to confirm whether or not the RS232C communication port is abnormal, conventionally, as shown in FIG. 1B, a user terminal (notebook computer or the like) provided separately before shipment of the machine tool is prepared and the user terminal is connected to the outside of the machine tool T It has been troublesome to connect directly to the prepared communication port P and then to perform a test of directly inputting and outputting data or signals between the machine tool T and the user terminal.

As described above, since the testing process for the communication port P is troublesome, machine tool manufacturers frequently ship machine tools while checking the quality of the communication ports in the quality check (QC) process. After the machine tool is set up in the actual field, there has been a problem in that claims for the communication port defect and service reception frequently occur.

The present invention has been made in order to solve the problems of the conventional art as described above, and it is an object of the present invention to provide a method and a system for testing an RS232C communication port of a machine tool, The objective is to simplify the test method to prevent initial failure and to achieve customer satisfaction.

In order to achieve the above object, a test apparatus 1000 for a machine tool according to the present invention is used in a machine tool T having a communication port P composed of a plurality of input / output pins for data input / output, And a plurality of input / output pins corresponding to a plurality of input / output pins of the communication port (P) for testing whether the communication port (P) is abnormal, attached to the communication port (P) (100); A first state in which the test apparatus 1000 is electrically connected between a pair of input / output pins selected so as not to overlap among the input / output pins of the connector unit 100, and the test apparatus 1000 is connected to the communication port P, And a plurality of LEDs (200) which are turned on or off in a different state from a second state in which data is output from the machine tool (T) and a third state in which data is input to the machine tool (T).

With this configuration, the test apparatus 1000 for a machine tool according to the present invention detects the LED 200 having an abnormality among the plurality of LEDs 200 from the combined state of on / off of the plurality of LEDs 200 , And it is possible to check whether there is an abnormality in the communication port (P) electrically connected to the abnormal LED (200).

The plurality of LEDs 200 may include a first LED 210 configured to be lit when the test apparatus 1000 is connected to the communication port P; A second LED (220) configured to light up when data is output from the machine tool (T); A third LED (230) configured to be turned on when data is input to the machine tool (T); A fourth LED (240) configured to light up both when data is input to the machine tool (T) and when data is output from the machine tool (T); (5) configured to be turned on when data is input to the machine tool (T) and when data is output from the machine tool (T) when the test apparatus (1000) is connected to the communication port And an LED (250).

As described above, according to the present invention, the connector portion 100 of the test apparatus 1000 is connected to the RS232C communication port (P) of the machine tool (T) without preparing a user terminal such as a separate notebook or PC It is possible to easily check in advance whether or not an abnormality of the RS232C communication port (P) of the machine tool (T) is caused by a simple operation.

A plurality of LEDs 200, preferably first to fifth LEDs 210 to 250 are provided in the test apparatus 1000 according to the present invention. (When the test apparatus is initially connected, when data is output, when data is input), the LEDs of the first to fifth LEDs 210 to 250, You can see at a glance whether data pin wiring is abnormal

In addition, the test apparatus 1000 according to the present invention is lighter and easier to carry than an existing PC or a notebook computer, so that it is possible to efficiently check whether communication ports of a plurality of the machine tools 1000 are abnormal.

By such an effect, it is possible to prevent the customer's claim after the field installation, secure the reliability of the customer, prevent serious initial defects, facilitate the A / S response, and contribute to cost reduction by mass production .

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

FIG. 2 is a diagram showing the external appearance of a test apparatus 1000 for a machine tool according to the present invention, and FIG. 3 is a circuit configuration diagram of a test apparatus 1000 according to the present invention.

As shown in the figure, the test apparatus 1000 according to the present invention is a RS232C dummy connector concept. The main signal line of the RS232C communication port of the machine tool is connected to a plurality of LEDs, and the communication port abnormality It is a device that can be checked easily. A test apparatus 1000 according to the present invention includes a connector unit 100 and a plurality of LEDs 200.

The connector unit 100 includes a plurality of input / output pins 1 to 25 corresponding to a plurality of input / output pins of the communication port P of the machine tool T. Preferably, the connector portion 100 is formed to correspond to an RS232C communication port which is mainly used as a communication port for the machine tool T as shown in FIG.

The input / output pins 1 to 25 of the connector 100 shown in FIG. 2 are connected to the corresponding input / output pins of the RS232C communication port P of the machine tool T, respectively. The functions of the main input / output pins among the input / output pins of the connector unit 100 will be described.

The pin 2 is connected to a signal line (TXD - Transmit Data) for serial communication data when an asynchronous serial communication device (machine tool) sends information to an external device.

Pin 3 is connected to a signal line (RXD - Receive Data) for receiving serial communication data input from the external device to the machine tool.

Pin 4 is connected to a signal line (RTS - Ready To Send) indicating that a data terminal equipment (DTE) device (machine tool) such as a computer is ready to receive data to a DCE (Data Circuit Termination Equipment) do.

Pin 5 is connected to a signal line (CTS - Clear To Send) indicating that the DCE device, such as a modem or printer, is ready to receive data to a DTE device (machine tool) such as a computer.

Pin No. 6 is a signal line (DSR - Data Set Ready) that indicates to the computer or terminal (machine tool) that the modem is capable of transmitting and receiving itself. Generally, the DSR signal is transmitted to the modem This signal is output when there is no signal.

The seventh pin is connected to the signal line (GND) connected to the ground.

Pin 8 is a signal line (DCD - Data Carrier Detect) that informs a computer or a terminal (machine tool) that the modem of the opposite modem sends a carrier signal when the modem is connected through a modem and a telephone line, Respectively.

The 20th pin is connected to a signal line (DTR - Data Terminal Ready) indicating that the computer or terminal (machine tool) can transmit and receive data to and from the modem. Generally, the DTR signal is used to initialize the communication port .

The functions of the main pins are summarized in Table 1 below.

Pin number function Signal name direction 2 Data transmission TXD Print 3 Receive data RXD input 4 Data transmission request RTS Print 5 Data transmission possible CTS input 6 Dataset Ready DSR input 7 ground GND input 8 Carrier detection DCD input 20 Data terminal Ready DTR Print

Next, a plurality of LEDs 200 will be described.

The LED 200 is composed of first to fifth LEDs 210 to 250.

The first LED 210 is electrically connected between the fourth pin and the third pin and is connected in the direction opposite to the flow direction of the data (data output at pin 4 and data input at pin 3). The first LED 210 is normally turned off and is designed to be turned on when the test apparatus 1000 is attached to the communication port P of the machine tool, .

The second LED 220 is electrically connected between pins 2 and 7 and is turned on when data is output from the machine tool T if the connection between the pins 2 and 7 is normal.

The reason why data is transmitted from the No. 2 pin to the No. 7 pin when data is output from the machine tool T is that the data transmission signal TXD is output from the No. 2 pin when data is output from the machine tool T Because it is input to the ground of pin 7.

The third LED 230 is electrically connected between the fourth and fifth pins and is configured to be turned on when data is input to the machine tool T if the connection of the fourth pin and the fifth pin is normal.

When data is input from the machine tool T, data is output from the No. 4 pin and data is input to the No. 5 pin. In the case where data is input from the machine tool T, the reason why the transmission request signal RTS ) Is output to the external DCE device, and the transmit enable signal (CTS) is input from the external DCE device at the 5th pin.

The fourth LED 240 is electrically connected between the 20th pin and the 6th and 8th pins. If the connection of the 20th pin and the 6th and 8th pins is normal, the case where data is input to the machine tool T, (T) are all turned on.

When data is input / output in the machine tool T as described above, data is output from the 20th pin and data is inputted to the 6th and 8th pins.

The reason why data is output from the No. 20 pin when data is input / output from the machine tool T is that the power supply to the machine tool T must precede the data input / output with the machine tool T, The data terminal Ready signal DTR is output to the outside through the 20th pin after the power supply of the data terminal T is applied.

In order to input / output the data, the data set Ready signal (DSR) must be input to the machine tool by pin 6 to inform the machine tool that the external modem is ready to transmit / receive data. In order to input / output data, The signal DCD indicating that the carrier signal transmitted from the opposite modem is detected is input through the No. 8 pin.

The fifth LED 250 is electrically connected between pin 25 and pin 7, and if the connection between pin 7 and pin 25 is normal, data input / output to the machine tool and connection of the test device to the RS232C port of the machine tool All are turned ON.

Meanwhile, according to the preferred embodiment, some or all of the first to fifth LEDs 210 to 250 may be selected as LEDs of different colors to facilitate identification. For example, in the embodiment shown in FIG. 2, the first LED 210 is connected to the green (G), the second LED 220 and the fifth LED 250 to the red (R), the third LED 230 and the fourth And the LED 240 is set to yellow (Y).

Meanwhile, in the illustrated embodiment, it is preferable to provide resistors R1 and R2 between the second LED 220 and the seventh pin, and between the fifth LED 250 and the seventh pin, respectively, in order to adjust an appropriate voltage level .

A process of testing the communication port P of the machine tool T using the test apparatus 1000 according to the present invention will be described.

First, select the mode for testing in the machine tool (T) for initialization and enter parameters if necessary.

When the initialization operation of the machine tool T is completed, the connector unit 100 of the test apparatus 1000 is connected to the communication port P of the machine tool T (first state), and the first to fifth LEDs 210 to 250 are turned on or off.

The first LED 210 and the fifth LED 250 are both turned on and the second, third and fourth LEDs 220, 230, and 240 are turned off in the first state.

If it is not in the above state in the first state, it can be understood that there is a problem in the connection of the LED and the data pin connected thereto. For example, if the first LED 210 is OFF in the first state, it can be seen that there is an abnormality in the connection between the first LED 210 and the fourth and third pins connected thereto.

Next, the data output (second state) and the data input (third state) operation of the machine tool T are performed in a state where the test apparatus 1000 is connected to the communication port P of the machine tool T In each case, the ON / OFF states of the first to fifth LEDs 210 to 250 are checked.

In the second state, only the first LED 210 is turned off and the second, third, fourth, and fifth LEDs 220, 230, 240, and 250 are turned on. In the third state, the first and second LEDs 210 and 220 are OFF and the third, fourth and fifth LEDs 230, 240 and 250 are ON.

If, in the second state, the LED and its connected data pin are not in the above state, an error has occurred. For example, if the second LED 210 is OFF in the second state, it can be understood that there is an abnormality in the connection between the second LED 220 and the second and seventh pins connected thereto.

Likewise, in the third state, an abnormality occurs in the connection of the LED and the data pin connected thereto, which is not the above-described state, and it can be read according to the LED lighting or the lighting-off state.

Table 2 shows LED lighting and lighting conditions in the first and third states when all wiring is normal.

The first LED 210, The second LED (220) The third LED 230, The fourth LED 240 The fifth LED 250, The first state
(When connecting test equipment)
ON
OFF
OFF
OFF
ON Second state
(data
Output)
OFF
ON
ON
ON
ON Third state
(data
Input)
OFF
OFF
ON
ON
ON

Table 3 shows the data pin connections that should be checked when each LED is faulty.

LED that has occurred abnormality Pin connection to check The first LED 210, Pin 3 Pin-4 Pin The second LED (220) 2 < / RTI > The third LED (220) No. 4 pin-5 pin The fourth LED (220) 20-pin-6,8-pinne The fifth LED (220) 7 < / RTI >

Although specific embodiments of the present invention have been described above, it should be understood that the spirit and scope of the present invention is not limited to these specific embodiments, but various modifications and variations may be made without departing from the scope of the present invention. It will be understood by those of ordinary skill in the art to which the present invention belongs.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

1A and 1B are diagrams for explaining a method of testing a machine tool communication port according to the prior art;

2 is a view showing an appearance of a test apparatus 1000 for a machine tool according to the present invention.

3 is a circuit configuration diagram of a test apparatus 1000 according to the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

T: Machine tool P: I / O port

1000: Test apparatus 100: Connector section

1 to 25: I / O pin 200: LED

210: first LED 220: second LED

230: second LED 240: fourth LED

250: fifth LED

Claims (2)

(P) of a machine tool (T) having a communication port (P) composed of a plurality of input / output pins for inputting / outputting data to / from the communication port (P) A test apparatus 1000 for a machine tool, A connector unit (100) having a plurality of input / output pins corresponding to a plurality of input / output pins of the communication port (P); A first state in which the test apparatus 1000 is electrically connected between a pair of input / output pins selected so as not to overlap among the input / output pins of the connector unit 100, and the test apparatus 1000 is connected to the communication port P, A plurality of LEDs (200) that are turned on or off in different states in a second state in which data is output from the machine (T) and in a third state in which data is input to the machine tool (T)  And a controller for detecting the LED 200 having an abnormality among the plurality of LEDs 200 from the combined state of turning on and off the plurality of LEDs 200, And the input / output pin of the port (P). The LED according to claim 1, wherein the plurality of LEDs (200) A first LED (210) configured to be lit only when the test apparatus (1000) connects to the communication port (P); A second LED (220) configured to be lit only when data is output from the machine tool (T); A third LED (230) configured to be lit only when data is input to the machine tool (T); A fourth LED (240) configured to be lit when data is input to the machine tool (T) and when data is output from the machine tool (T); A fifth LED configured to be turned on when data is input to the machine tool T and data is output from the machine tool T when the test apparatus 1000 is connected to the communication port P, (250); (1000) for a machine tool.

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