DE4235379A1 - Automatic electronic equipment static protection monitor - uses limits check for armband and mat resistances, with audio-visual display - Google Patents

Abstract

The monitor uses a computer (1) connected by interface (9) to monitor circuits (10,11,12,13) via cables (14,15,16). Cable lines include serial input (161), clock (162), control line (163), power and ground (164,165). Each monitor circuit (10..13) has a connection (17,18,19,20) to armband (25) of operative at work area. Connection is via breaker contact (171,181,191,201). Also the work area ground mast is connected (21,22,23,24). Each monitor circuit contains power supply (131) with mains input (132) and protective ground (133). Connections at input are sensed by comparator cct. (134), gating circuit (135) and input to audio-visual display (136). LEDs (148,149,150,151,152,153) indicate mat resistance above or below limits, armband resistance not connected or exceeding 10M or under 1M. In the event of no response to a warning, an audio alarm is raised, and connections to working equipment (145) are broken by relay (143). USE/ADVANTAGE - Continuous monitoring of static protection for assembly/mfr/handling of electronic equipment. Automatic alarm and indicator system with computer record reduces dependence on operator response.

Description

The invention relates to a device for detection the conditions of electrostatic protection Jobs according to the genus of the first patent saying.

Jobs for the production of high-precision electro nical components require precise monitoring grounding of the worker and the work surface. There through the risk of electrostatic discharge diminishes and destroys the very sensitive Components largely avoided.

Such devices are generally mobile, batte rubbed together with a mat and an arm band used. They show optically, through light signals and acoustically, through clearly perceptible warning tones on when certain resistances to be observed exceed or fall below and the risk of an electrostatic charge table discharge occurs. The disadvantage of such Devices can be seen in the fact that they are only individual use a central monitoring not accessible and with them a record of the entire ferti is not possible.

The object of the invention is therefore a device to detect the conditions of the electrostatic Protection of workplaces so that they on the one hand, individual monitoring and correction by the worker and on the other hand a central one Acquisition and evaluation for an entire production enables.  

According to the invention, this object is achieved by the Merk male solved the first claim. To this Way it is possible not just to set up a computer with visual display, but also on similar or similar facilities to connect. So there can be several fiction appropriate facilities in series or parallel summarizes and on a single computer with visual display connected and from this all jobs watches or be logged. Advantageously contains the establishment of a circuit breaker through which the optical and acoustic display means with one Work equipment (consumer, load) are connected and which switches off the tool as soon as a too high or too little resistance for a work surface or the Worker appears. To save electri lines, it is favorable if the last one is in a series of devices a termination plug with the help of which from the facilities originating signals through the interconnected Connection means are routed back to the computer.

The invention is based on a schematic drawing explained in more detail.

A computer 1 with a keyboard 2 , a mouse 3 for moving a cursor 31 in a visual display 4 has an adaptation 5 of the computer 1 to the special task and a connector 6 for a printer 7 and a connector 8 with a signal amplifier 9 to Devices according to the invention (Monito ren) 10 , 11 , 12 , 13 , which are connected to one another via lines 14 , 15 , 16 . The line 16 comprises a wire 161 for the input signal, the serial data input from the previous device, a wire 162 for the clocking for the periods of detection of the conditions for electrostatic protection, a wire 163 as a serial control input for the forwarding of the data , a wire 164 for the power supply from the computer 1 , a wire 165 for connection to the computer ground and a wire 166 for the data return to the computer 1 . The lines 14 , 15 and the connection 8 are designed analogously.

Each device 10 , 11 , 12 , 13 has a connection 17 or 18 or 19 or 20 with a bracelet 25 of a worker and a connection 21 or 22 or 23 or 24 with a mat (work surface) 26 . Switches 171 , 181 , 191 , 201 are inserted into the electrical connections 17 to 20 in order to be able to interrupt the electrical connection.

The internal structure of each device 10 to 13 is explained using the example of the device 13 .

A power supply unit 131 is connected to a voltage source 132 (220 V AC voltage) and connected to protective earth 133 . The power supply 131 supplies a signal detection means 134 , a logic operation 135 and an acoustic-optical display means 136 , in which it applies a voltage (12 V) via a line 137 , 138 , 139 . In addition, there is a ground line 140 , 141 , 142 between the power supply unit 131 on the one hand and the signal detection means 134 , the logical link 135 and the display means 136 on the other hand. The display means 136 is assigned a circuit breaker 143 , which is connected to the power supply 131 via a line 144 (220 V AC voltage) and influences connections 145 to a working medium, not shown.

The signal detection means 134 contains comparators, two of which 146 , 147 are shown, which compare the signals coming from the wristband 25 or the mat 26 with reference signals coming from reference signal formers 186 , 187 and the result of their comparison via the logic link 135 to the display means 136 forward. There are six LEDs 148 to 153 on the display means 136 , which light up or go out in accordance with the signals. The signals come about when an upper (H) or a lower (L) resistance value is exceeded or undershot when determining the resistance value of the mat 26 or the bracelet 25 to earth, or that the bracelet is removed (P) will or that the resistance values are within the specified limits. The LEDs indicate the following signals:

• - LED 148 lights up red when an upper resistance value (5.7 megohms) is exceeded in mat 26 .
• - LED 149 lights up yellow when a lower resistance value (1 megohm) is undercut in mat 26 .
• - LED 150 lights up red if, after putting on the bracelet 25, the resistance belonging to the worker (10 megohms) is exceeded or the bracelet 25 is not put on after the connection 20 has been established.
• - LED 151 lights up yellow when the resistance value belonging to the worker (1 megohm) falls below.
• - LED 152 lights up yellow when the electrical connection 20 opens with the help of the switch 201 ge, so if the worker interrupted the device 20 , a break is made.
• - LED 153 lights up green if none of the LEDs 148 to 150 lights up when operating device 13 , that is if the values are OK.

When one of the LED 148 to 150 of on, so, if the worker does not respond, the failure does not arise from, sec in a signal transmitter 154 15 an acoustic signal delays generated and the terminal 145 is interrupted by means of the Lei stungsschalters 143 for working medium.

In the device 13 there is also a connection means 155 which is connected via a line 27 to the display means 136 and via line 16 to the preceding device 12 . From a connector 28 is arranged at the outputs 29 of the connection by means of 155 .

The multi-wire line 27 transmits an error signal on a wire 271 if the resistance value of the mat 26 is outside the range between 1 and 5.7 megohms, on an wire 272 an error signal if the resistance value of the worker is above 10 megohms, on one wire 273 the pause display and on a wire 274 the OK display. A core 275 is the ground line. A 12 V supply line 276 exists between the mains connection 131 and the connection means 155 . The terminating connector 28 allows on the one hand the inclusion of the signals transmitted through the outputs 29 from the individual devices 10 to 13 and on the other hand their return through the line 166 to the central computer 1 , which it shows on its display 4 and prints out with its printer 7 .

With the device 13 according to the invention, the mat 26 and the grounding of the device 13 itself can be monitored and all the values determined can be transmitted to the central station, the computer 1 . The required resistance determination is carried out using direct current in the microampere range. The current flow from the device 13 , specifically from signal detection means 134 , via the connection (sensor cable) 24 to a corner of the mat (work surface) 26 , through the mat 26 to an earth cable 30 of the mat at a diametrical corner, to the earth and back to ground 133 of device 13 . The monitoring of the mat 26 is activated when the device 13 is connected to the voltage source 132 .

When monitoring the work surface 26 and a directional earthing, the resistance R _{M of} the mat 26 to earth is determined. Exceeding the permissible resistance values 1 Megaohm R _M 5, 7 Megaohm is recorded as an error. If R _{M is} greater than 5.7 megohms, LED 148 lights up and LED 153 goes out. The acoustic signal from the signal generator 154 sounds with a delay of 15 seconds. An error message is sent to control center 1 via connection part 155 . The power supply to the work equipment on the stop 145 is interrupted with the help of the circuit breaker 143 . If R _{M is} less than 1 megohm, LED 149 lights up. The LED 153 then goes out and, after a delay of 15 seconds, an acoustic signal sounds when a jumper (not shown) contained in the logic combination 135 is inserted. In this case, an error message is also forwarded to the computer 1 and the power supply to the work equipment is interrupted using the circuit breaker 143 .

If the conductive mat 26 is missing, the sensor line 24 is connected directly to earth (but at a different earth point than the earth line of the device 13 ). The jumper is removed. The device 13 thus only monitors its own invention, only the LED 149 lights up.

When switch 201 is open, device 13 is in the parked state. LED 152 lights up and LED 153 goes out. There is a parking message to computer 1 . The acoustic signal does not sound. The power supply to the working medium is interrupted by the circuit breaker 143 .

With the device 13 according to the invention, however, the earthing of a worker can also be monitored with the aid of the bracelet 25 to be firmly attached by him; the resistance values he averaged can be transmitted to the computer 1 via the connection means 155 . The resistance determination is carried out with the aid of a very small, pulsed measuring current (<5 µA). During the measurement, the direct current flows e.g. B. 0.2 sec and is then switched off for 2 sec before the next measurement begins. The monitoring of the wristband 25 does not start until the switch 201 is switched on. The current then runs from the device 13 via the resistive special cable 20 to the bracelet 25 , the skin of the worker, the special cable 20 to the earth of the device 13 .

If the resistance is greater than 10 megohms, LED 150 lights up and LED 153 goes out. The acoustic signal sounds after 15 seconds. The error is reported to the computer 1 via the connection means 155 . The power supply of the working fluid is interrupted by the circuit breaker 143 .

If the measured resistance is less than 1 megohm, one of the current-limiting resistors located in the special cable 20 has been bridged. This can e.g. B. happen by touching the conductive work surface when soldering. In this case only LED 151 is activated, LED 153 lights up and OK is reported to the computer. The acoustic signal does not sound. The circuit breaker 143 remains closed and the power supply to the working medium is not interrupted.

If the measured resistance value is between 1 and 10 megohms, only LED 153 lights up. The acoustic signal does not sound, OK is reported to the computer, the power supply to the work equipment is not interrupted.

The message to the computer 1 can be made in parallel or in series, depending on the number of devices 10 to 13 and thus the workplaces and distance to the computer 1 . With parallel wiring, a three-wire line per device is pulled to the computer 1. In general, the number of devices 10 to 13 connected to a computer 1 should be between 20 and 50.

With serial wiring, a ring arrangement is created in such a way that a shift clock is supplied by the computer 1 , which is looped through from device to device, and that the corresponding output of a device is connected to the corresponding input of the following device. The output of the last device 13 is connected to the computer 1 . Likewise, the masses of the devices 10 to 13 and the computer 1 are connected to one another. The arrangement and function described in detail for the device 13 basically also applies to the devices 10 to 12 or other devices of the same type.

The invention is not tied to the illustrated embodiment. The switch 201 can be replaced by a switchable jack socket. The adaptation 5 can essentially consist of a floppy disk or another information carrier with corresponding stored information. All features shown in the description, the following claims and the drawings can be essential to the invention both individually and in any combination with one another.

Claims (7)

1. A device for detecting the conditions of the electrostatic protection at workplaces, which has means for electronic signal detection, for logical linking and for optical and / or acoustic display, characterized by connection means ( 155 ) for connecting the optical and / or acoustic display ( 136 ) with a computer ( 1 ) with a visual display ( 4 ) and a power supply unit ( 131 ) for the power supply of all means ( 134 , 135 , 136 , 155 ). 2. Device according to claim 1, characterized by a circuit breaker ( 143 ) via which the display means ( 136 ) are connected to a working medium. 3. Arrangement according to at least one of the preceding claims, characterized in that it comprises a plurality of devices ( 10 to 13 ) which are connected with a single computer ( 1 ) in parallel or in series. 4. Arrangement according to claim 3, characterized in that the most distant device ( 13 ) from the computer ( 1 ) is provided with a terminating plug ( 28 ). 5. Arrangement according to claim 4, characterized in that there is a return line ( 166 ) between the connection means ( 155 ) of the individual devices ( 10 to 13 ) and the computer ( 1 ). 6. Arrangement according to at least one of claims 3 to 5, characterized in that the computer ( 1 ) is provided with an adaptation ( 5 ). 7. Arrangement according to claim 6, characterized in that the adaptation ( 5 ) is designed as an information carrier.