DE3001100A1 - Multiple sensor gas or fire detector system - employing microprocessor which tests condition of each sensor in turn - Google Patents

Abstract

All the sensors or detectors (15/I...15/XV) are connected in parallel across one common cable (20,29,37). Each sensor has a window detector, digital comparator, or other method for identifying an incoming command addressed to it. Commands for other sensors are ignored. The control unit comprises an interface unit (14) which connects the sensors with the microprocessor (12) and with an output unit (13). A power supply (11) serves the control unit and also provides power, via a transformer (38), to the sensors. When a sensor receives a command from the processor its measuring circuits are switched on. The results of the measurement are then transmitted to the processor. Output (13) controlled by the processor is typically to an alarm unit (19), hard copy printer (18), VDU (17) and memory (16). The connecting cable may use some fibre optic cores.

Description

Method for controlling and monitoring several

Detectors for gas, smoke, etc. The invention relates to a method for controlling and monitoring several detectors as gas, smoke or similar used measuring sensor as well as storage of the measured values obtained by means of a remote control center of control and monitoring devices, with all Measuring sensors as substations of the control center are connected to the control center via a line You have already tried (0. 26 55 zip 271) to give each measuring sensor an oscillating circle @ assign where the frequency-determining resistance of the resistance of the sensor With such a method, a larger Monitor the number of sensors one after the other. However, it has the disadvantage that the frequency of the oscillating circuit already depends on the normal temperature changes is influenced In order to switch this off, one had to adjust the bandwidth for the measurement of a single probe too wide, so that the number of probes with one device probe to be measured is quite limited0 On the other hand, it has already been proposed (GM 76 31 379), iiur a measuring sensor directly to the monitoring devices connect and using a specially designed switch (llrekt never to be monitored Taking air from the measuring points with hoses is also a considerable effort here necessary, if only one sensor is available, the expense of electrical ones Sciialt averaging can therefore be kept relatively small0 Instead, Branch; (i per relocation the tubing associated with difficulties.

The present invention is therefore based on the object ctie Avoid disadvantages of the known method and at the same time the possibility to create, on the one hand, the data received from the individually queried sensors to monitor for inadmissibly high concentrations of harmful gases, to save this data and with; to compare other data, for example from neighboring rooms, and on the other hand correcting the sensor itself if there are unacceptably high changes in its Properties will suffer during the service life.

The solution to the problem is that all sensors are parallel are connected to a line and each sensor is directly connected to a detection element, iwe is connected to a window discriminator, digital comparator etc. and a control center, which are made up of known assemblies such as input, digital-to-analog converter, Processor, memory, interface (interface), output point (output) and / or There is a power supply that connects the sensors to the control center Line can connect individually and the supply voltage via a transformer is taken from the network that is present or brought up at the location of the sensor.

The central unit advantageously controls each sensor to be monitored @ by means of a possibly shaped current or voltage that it emits, which the recognition element can pass.

The sensor that can be used for the invention has in the sensor head @ a semiconductor sensor, an electronic circuit, IC or similar unc a transformer, whereby the circuit sends the measurement signals to the control center and the transformer supplies the heating voltage and the supply voltage for the circuit and the sensor.

The advantage of the invention is obvious. The new probe is provided with the essential elements which on the one hand the operation of the sensor enable and which on the other hand, the detection of this sensor and the forwarding whose values allow, these elements being essential thanks to micro-technology wedges Use up space so that the normal expansion of the sensor is not significant over the previously known cup of one consisting only of semiconductors and heating coils The probe. Furthermore, only three-pole gluing on the all measuring sensors are connected in parallel, each individual measuring sensor with the central unit be burned in connection, after which all functions are then over this line be transported between the control center and the measuring probe. With the additional The transformer arranged in the measuring sensor can be used to operate each sensor necessary current can be taken from the network available at the location of the sensor. Gives you can add three more lines or wires to the line, so can also from the control center the normal mains power can be supplied, which makes a normal Mains voltage The leading ring line can be connected to the cem sensor at the desired location and therefore a network is available at every location for the sensor to which it is connected 0 Referring to the drawings, there is an exemplary embodiment of the invention shown, namely Figure i shows a block diagram of the control center Figure 2 a Block diagram of the interface according to FIG. 1 and FIG. 3 a perspective view a partially cut-away measuring sensor, according to FIG. 1, the control center consists of a network supply unit (11, a processor (CPU) 12, an output point 13 and an interface (Iinterface) 14, these individual devices unt @@ each other @are connected to each other via the specified lines and the arrows indicate the direction of data flow Show.

The interface 14 is thus connected to the measuring sensors 15 / I to 15 / XV and the output point 13 can with a memory 16, a screen 17, a Printer 18 and / or connected to and provided with a display and alarm unit 19 In Figure 2 is the block diagram of an interface 14 according to the invention the structure of which is most easily explained using a functional description can be, at the same time the interaction of the individual devices according to figure 1 can be seen 0 When the power supply unit 11 is switched on, the control center put into operation, so the program is from the processor 12 at a certain Address e.g. the measuring probe 15/1, started by using the line 20 from the interface 14 to the measuring sensor 15 / I a voltage, e.g. of 1.5 V, which value the measuring sensor 15 / I is assigned, is sent. At the same time, the processor 13 switches over line 21 and selector switch 22, changeover switch 23 to position K and via the decoder ali the calibration potentiometer assigned to the measuring sensor 15 / I 25 for the amplifier 26, The voltage in line 20 has # existing voltage: im Sensor 15 / S pass the window discriminator of the electrical circuit 27 know and at the same time switched on the semiconductor switch that is also present there, so that now the data of the sensor 28 (Figure 3) over the line 29 can flow back to the control center. As the window discriminators de: others Sensor 15 / II to 15 / XV for the above-mentioned voltage in line 2 blocked only the data of the sensor 10 / I are transferred. the line 29 reported back. The data stream flowing in Leiti 29 consists of an alternating voltage component and a DC voltage component.

The alternating voltage component becomes an amplifier via the capacitor 30 31, from there the frequency-to-voltage converter 32 and the switch 23 to the analog-to-digital converter 33 out and over the line 34 to the functioning as an evaluation device Part of the processor 12 passed. When this measurement is finished, the processor switches 12 of the toggle switch 23 to position M and fetches it there via the amplifier 35 pending DC voltage component of the data stream from line 29 to the analog-digital converter 33 and from there also via line 34 to processor 12. Line 36 is used only for controlling the A-D converter 33.

The processor 12 now corrects the measured value on the basis of the value from the amplifier 31 coming correction value and indicates the corrected measured value obtained in this way the issuing point 13, from where the distribution to the stations 16, 17, or 18 he follows. Simultaneously, either in the processor 12 or in the output point 13 the incoming corrected measured value with a specified target value or also with several setpoints corresponding to the alarm threshold, compared and if necessary Alarm triggered, which can also be seen e.g. through a display panel which sensor the alarm is pending. There can also be others in this context important values etc. are displayed.

Immediately thereafter, the processor 12 performs for the measuring sensor 15 / II through the same cycle, then for the measuring probe 15/111 and so on continue to the last measuring probe 15 / XV, after which the return jump to the measuring probe 151I takes place. The amount of time to complete all cycles for all probes can on the one hand be determined and varied by processor 12 but depends on the other hand, it also depends on the capacitance of lines 20, 29 and 37, although the latter Line only functions as a ground line, You can also use the power supply ii a supply voltage of 220 V directly to the measuring sensors 15 / I to 15 / XV the lines 38 lead, but this depends on the local conditions and regulations which in some cases do not allow the power line 38 mXt den Data lines 20,29,37 are guided in a cable. This is particularly evident good advantage of the invention because the transformer housed in the sensor 39 can also be connected to the network available at the location of the sensor can, even if this n # r carries a voltage of 110 V, for which the transformer 39 can be interpreted from the outset in such a way that ca arni @ ht only a tension of 220 V but also 110 V for the jviesssensor after switching over In FIG. 3 i @ t the measuring sensor according to the invention is shown, which consists of a a screw-on flange 40 provided housing 41, in which the circuit 27, consisting of a window discriminator and semiconductor holder, as well as the transformer 39 is arranged, preferably cast in plastic, between the housing 41 and a cover 42, which is held in place with the screws 43, is a piece of pipe 44 made of sintered metal, which is gas-permeable, arranged in the semiconductor sensor 28 is attached and electrically connected to the circuit 27, at any In place of the housing 41, the gas cable 45 is led out through that of the measuring pen is connected to the control center.

The line 20,29,37, which in the example shown is a copper cable natArRich can also consist of one or more glass fibers for light transmission. In this case, instead of the window discriminator in the measuring sensor, a similarly acting one must be used Digital comparator be arranged and the interface must be the optical fiber o If necessary, you can even use the interface to create one Optical fibers lead to each individual measuring sensor while adapting the interface to the changed circumstances0 L e r s e i t e

Claims (5)

Method for controlling and monitoring several Measuring sensors used as gas, smoke or similar detectors and storage the measured values obtained by means of a remote control center from control and monitoring devices, with all sensors being used as substations of the control center one line itit the control center are connected, characterized in that all Sensors (15 / I to 15 / xv) are connected in parallel to a line (20,29,37) and each sensor (15 / I to 15 / xv) directly connected to a detection element such as eienem window discriminator, digital comparator, etc. is connected and a control center which are made up of known assemblies such as input, digital-analog Wadler (33), Processor (12), memory (16), interface (14), output point (1)) and / or power supply part (11), via which the measuring sensor with the Central connecting line (20,29,37) can connect individually and the Supply voltage via a transformer (39) that is available at the location of the measuring sensor or removed from the network. 2.) The method according to claim 1, characterized in that the aie /.entrale each sensor to be monitored (15 / I to 15 / xv) by means of a sensor sent by it, possibly impressed current or voltage which pass through the detection element can be driving. 3.) The method according to claim 2, characterized in that the of the control center emitted current after passing the detection element, such as window discriminator or digital comparator, the selected measuring sensor a switch, preferably Iial conductor switch, actuated, whereby the values of the central sensor are reported back will. 4.) Measuring sensor for performing the method according to the claims 1-3, characterized in that in addition to a semiconductor sensor (28) an electronic Circuit (27), IC or similar a transformer (39) is arranged in the probe head is, the circuit (27) sends the measurement signals to the control center and the transformer (39) the heating voltage and the supply voltage for the circuit (27) and the sensor (28) returns. 5.) Process according to claims 1-4, characterized in that the line (2o, 29,37) consists of glass fibers as a light line and in the measuring sensor (15 / I to 15 / XV) a digital comparator is arranged.