DE2418486A1 - Combustible gases detection circuit - has several channels each with a pickup sensitive to combustible gas-air mixture - Google Patents

Abstract

The detector includes pickups which change their resistance when exposed to a combustible mixture, and are supplied with constant current, with bridge circuits between pickups and their current sources. Signal processing elements connected with the bridge output for its output signals adjustment. A channel selection unit is connected to the channel outputs and selects the channel with highest signal output. A display unit displays the detected gas concentration, with means controlling an external signal. Failure detecting units connected to the above current sources deliver an output signal when a current source fails. This unit output is connected to the channel selection unit, so that it delivers an output signal to channel selection means so long as any of the channel delivers a signal.

Description

MULTIPLE CHANNEL DETECTOR FOR COMBUSTIBLE GASES.

Extract of the invention.

The invention relates to; rely on a system for determining presence of flammable gases using remote sensors that separate Generate output signals, which indicate the gaseous environment of each sensor, whereby the signals are first processed and then fed into a channel selection network which causes an output from only one channel, its signal the largest one, the output of which is connected to display devices, the indicate high and low levels and trigger appropriate alarms The system is able to switch off a channel in the event of an error in it, in order to reduce a false alarm and a continued function of the system in the operating channel.

Background of the invention.

6 Gas detection devices of the general type of the present invention Invention have one of their principal uses as a means of early warning to be provided in a flammable gas condition, and are often used to the presence of explosive mixtures of flammable gases or to determine liquid vapors and L @ ft in connection with many operating modes in industry, manufacturing and / or mining. There are feelers in such facilities Installed in a place where the penetration of a flammable gas with great Probability will occur first, this location usually being away from the whereabouts of a machine worker or the associated electronic Unity is. Industrial and mining machinery plants are often considerable and shock conditions, and the typical sensors that are used to detect Gas used are very sensitive to such harsh conditions, so the inoperability of gas detectors due to a failure of the sensor common problem is. Currently known gas detectors use either one single channel or two channels. Where minfacllk-a-: laldetectors are used, causes the frequent failure of sensors or, for the same reason, of any one intermediate area of the system is a frequent interruption of operations.

Dual channel systems have heretofore been available and they work some degree of redundancy. Such binaries sum the outputs of two Channels, which has the advantage that it continues to provide meaningful minimum information is taken care of, even if an error has occurred in one of the channels. The difficulty of course the fact is that an output of such a summation system is pointless for the Specification of the current degree of concentration. In other words, the Gas concentration readings are usually given as a percentage of the lower explosive limit (UßG), and if the outcome of such a system z. B. shows loo% it is not known whether one of the sensors loo R has detected the LEL or both of them have found 50% LEL.

The result is that a specific percentage of the LEL fails with found such a system with any reasonable degree of reliability can be. In addition, errors due to electrical noise and temperature fluctuations there multiplier, where the outputs of two channels are summed.

Summary of the Invention, The present invention provides one Multi-channel gas detector before, in which they are two or more spaced apart Provides sensors for the required redundancy; the invention also provides a means that only scans a channel indicating the worst condition, so that a realistic measurement of the maximum concentration of the gas is made can be. The output of each channel is fed into a selection network, which samples both signals and selects the one that has the greatest amount, where an analog display is given and, using a near-level threshold detector, Outputs are generated at the set minimum and maximum levels of gas concentration to display. The system also includes means for indicating whether any of the channels has become inoperable or not, but in case of failure in less than in all channels, the system continues its function in the one that is still in operation Channel or channels. The system also indicates the status if there is an error occurred in all channels, and looks for such a case control organs for the automatic shutdown of the affected system.

E8 also describes two special versions that are are generally similar, but each with slightly different uses suitable is. In the first embodiment, the sensor signals are passed through a comparator compared with each other, whose Ausxangtgenalter controls that with the reinforced Outputs of each channel are connected to exclude the unwanted signal. In the second version, the channel selection is unidirectional and uniform Vers-tarkerspannua, trackers that have an ideal diode characteristic, which by back-influencing only the coarser signal with the output connection couples.

It is therefore a fundamental task of the present invention, a improved gas detector for use in various industrial systems that has sufficient redundancy to shut down the system in the event of a fault in one of the sensor channels.

It is also an object of the present invention to provide a multi-channel gas detection system that is able to eliminate the presence of preselected gas concentration levels determine, while at the same time an analog display of the most dangerous gas concentration of the two sensors.

These and other objects of the present invention are achieved by the following detailed description in conjunction with the accompanying drawings immediately understandable.

Description of the drawings.

Big. 1 is a functional block diagram of the invention, which shows the basic operational functions of the system.

Fig. 2 is a schematic diagram of the ore embodiment of the Gas detector that uses a comparator for channel selection.

Figure 3 is a partial schematic picture of the ideal diode channel repeller after the second run.

Figures 4a and 4b is a complete schematic diagram of FIG the second run.

Description of the invention.

According to Fig. 1, the invention consists essentially of a two-channel system, although multiple channels are possible. A power supply io is with a voltage regulator 11 connected, which fixed reference voltages to two separate generators for supplies constant current, one denoted by 12 for channel A and the other is designated 14 for channel B. The controller 11 also supplies the display circuits through the conductor 15 with a fixed reference voltage.

The constant current generators 12 and 14 are accordingly with the remote sensors 16 and 18 connected. Every feeler is in his own Conventional execution in being of the type using a bridge circuit, which has an active resistance element which is catalyzed in this way that a flammable gas-air mixture will oxidize it and thereby an increase in the temperature and thereby a greater change in the resistance value. The outputs of each sensor become separate signal conditioning systems 220 and 222 fed in accordingly, which gains and means for balancing of the bridge circles to zero.

The signals from channels A and B are generated by the processing systems 220 and 222 are fed into a channel selection network; zwerk 224, which both signals samples and the signal, which has the greatest amount, causes at the output 225 to appear. The output at 225 is then used with the display and control circuits 226 which readings of high and / or low levels of gas concentrations and provide control signals by which various alarm and shutdown relays are actuated can be used to expose workers to a potentially dangerous gas condition and to draw attention to the automatic shutdown of the system in the area is working. Failure detectors 228 are associated with constant current generators 12 and 14 and provide outputs to channel selectors 224 and display and control circuits 226. In the event of an error in any of the channels, the selector 224 cause the signal of the operational channel to appear at Sugang 225, and the exit detector will generate an output indicating which one Channel has failed. The occurrence of errors in both channels will make the indications and cause control circuits to emit an alarm signal and means for Switch off the system, as detailed in the following Explanations of the preferred embodiments will be described.

Description of the first embodiment.

In Fig. 2, also in Fig. 1, the electrical energy is from a Power supply 1o through the voltage regulator 11 to two separate sources for constant current is supplied, one for channel A, labeled 12, and the second for channel B, labeled 14. The bowler 11 ensures a regulated, fixed, temperature-compensated Reference voltage to maintain a constant current from sources 12 and 14 and vm to establish fixed reference values for the threshold value detector through the conductor 15. Constant current is supplied independently through sources 12 uiid 14 to the remote ones Sensors 16 and 18 supplied. Any of the sensors used herein are conventional in its design and the circuits connected to it as well, and the following panel Description will only deal with the sensor 16 for channel A and its associated circuit, the same description also for the sensor of channel B should apply. The sensor 16 contains an active resistance element 20 and a reference resistance element 22. The reference element 22 does not respond Changes in gas composition, but it resembles changes in ambient temperature off, as well as changes in humidity and the like. The other resistors 24 and 26 are connected via the sensor 16 and thus form a Wheatstone bridge. With the node 21 between the sensors elements 20 and 22 is a variable Resistance 28 connected, the other side of which is connected to the node 33 between the Resistors 24 and 26 is connected. Likewise associated with dcn 'Resisted 24 and 26 is a variable resistor 30.

he wiper arm 32 of the resistor 30 is with the node 33 between the resistors 24 and 26 connected. The wiper arm 34 of the resistor 28 is connected by line 36 to the input of a differential amplifier 38, the other input of which is connected to the node 33 by the line 40. This 3-back circle for each channel thus ensures a reference output in on line 4o and a variable output on line 36 for the differential amplifier. Similarly, probe 18 of channel B sees one through its bridge circle Reference output on line 42 and a variable output on line 44 as inputs for the differential amplifier 46 of channel B. The purpose and the function of the variable resistors 30 and 28 are explained below will.

The outputs of amplifiers 38 and 46 from channels A and B, respectively connected by lines 48 and 50 to the input of comparator 52. Of the Output from amplifier 38 is also through line 62 across the series resistor 64 to the node 66 and then through the series resistor 68 to the node 70. Likewise, the output from amplifier 46 is passed through line 72 across the series resistor 74 to node 76 and then through series resistor 78 to node 70. Switch 58 is connected to node 66 and switch 6o is connected to node 76. The function of the comparator 52 is to to check the output values of each amplifier for channels A and B and the signal with the largest amount. After comparing the outputs, the delivers Comparator 52 control signals on lines 54 and 56, which are connected to switches 58 and 60 are connected. When the exit. from amplifier 38 e.g.

is larger, the comparator will generate control signals to the switch 60 to bet3en and the switch 53 in the off position. to maintain. when the switch 60 is actuated, the output from the amplifier 46 becomes essentially connected to earth at point 61. Obviously occurs the the opposite condition occurs when the output from amplifier 46 is greater. the Channel identification indicators 8o and 82 are with switches 58 and 60, respectively tied together. Under the aforementioned exemplary conditions, the indicator 82, when switch B is operated, an output is obtained from switch 60 which is the indicator 32 lit which is suitably connected to indicate that channel A provides the output for summing node 70. The summation node 70 is connected to the input of an amplifier 84, which has a feedback resistor 86 is provided between the output and the input of the amplifier. A measuring device 88 is connected to the output of amplifier 84 to provide an analog display of the To deliver the output signal of the sensor channel selected by the comparator 52 became.

Amplifier 84, resistors 64, 68, 74, 78 and the feedback resistor 86 are interconnected in such a way that they form an effective amplifier circuit. The J-resistors 64 and 68 in series comprise the input resistance for the output signal from amplifier 38 and, similarly, series resistors 74 and 78 for the Amplifier 46. In this arrangement the outputs from the channel amplifiers are in a summing arrangement connected to one another at node 70; but the switches 58 and 60 controlled by comparator 52 prevent summing the outputs from both amplifiers by effectively grounding one of them so that under normal operating conditions (there is a failure of one of the two channels not available) the switches are so effective that they only have a channel output allow it to appear at the input to amplifier 84. In case of failure, like As described in more detail below, the switches can be equally effective by grounding both amplifier inputs.

The meter 88 is calibrated so that its scale divisions represent the percentage indicate the lower explosive limit (LEL) of a given gas, so that the entire scale range of the measuring device would show loo ß LEL. The output from the amplifier 84 is passed through line 9o to a two signal stage detector 92. Of the Stage detector 92 provides two outputs on lines 94 and 96, respectively. A reference voltage that is branched off from the voltage regulator 11 through the conductor 15 is, is supplied to the variable 5.liderstande 93 and loo, then by the Lines 102 and 104 to the step detector 92. By setting the changed Resistors 98 and loo can set the threshold values of the detector 92 in accordance with FIG pre-selected minimum and maximum permissible level values of the LEL are set will.

The output from detector 92 on line 94 becomes an alarm trigger 106 in response to the case for which the input signal for the detector 92 reaches the preselected minimum level value determined by the potentiometer 98 is set. The output of the alarm trigger 106 becomes the small alarm relay 108 forwarded, the closure of which a suitable indicator 11o will light up leaves, preferably to create a visual glow and also external Contacts 112 are actuated which are connected to external terminals 114 to which any Type of alarm device or remotely mounted indicator desired may be connected.

When the input signal for the detector 92 is through the potentiometer loo set level value is reached, which is preferably at a fixed The maximum allowable value of the LEL is set, the signal is similar passed through the line 96 to an alarm trigger 116, the output of which with a Large alarm relay 118 is connected, its closure in a similar bar a visual Indicator 120 actuated. External relay contacts 122 are used in the same way for connection with external connections 124 provided to a Alarm device or connect a remotely located indicator.

A time delay circuit 126 is connected to the power supply lo and generates an output on line 123 which leads to alarm triggers 1o6 and 116 is directed. When the system is first energized, it becomes the time delay 126 switch off the alarm triggers 106 and 116 temporarily, for a period of time, sufficient to give the rest of the system an opportunity to stabilize.

Especially for cases where the external contacts 114 and 124 are not connected solely to alarm systems, but also to systems that are in the LaÕe are to switch off machine systems with which the present device It may be related to some false alarm or an unnecessary one To prevent decommissioning. By switching off the alarm trigger up to The time delay effectively prevents any restabilization of the Icircle Alarm that could occur in response to false signals during stabilization occur in the system.

Current measuring elements 130 and 132 are 12 with the constant Stromquel len and 14 connected respectively to produce an output when the current is through the remote probe or its associated cable for any reason is interrupted. The output of the current sensor 13o is through the line 131 directed to the AND circuit 134. The output of the current sensor 132 passed through line 135 to AND circuit 134. The output of the AND circle 134 is connected to the circuit 136 for the failure trigger, the output of which in turn is connected to the failure rule 138, which is a visual indicator - such as e.g. a lamp 14o -actuated and also with external contacts 142 as well as with external Connections 144 is connected, which with suitable alarm and display devices can be connected. In this way, the failure relay 133 is normally closed and does not provide a display as long as channels A and B are in operation and as long as signals flow on lines 141 and 133 to the U? TD rice. enn any fault in either or both of the remote sensors occurs, the W.ID circuit 134 does not provide a signal to trigger the trigger 136 and thereby opening relay 138 and providing an indication. Additionally is the conductor 133 is connected to the switch 60 by the line 148. Hence becomes a Signal through line 146 when a failure occurs in channel A, switch 58 actuate to zero the output of amplifier 38 .. This will make the Comparator 52 react in such a way that it opens the switch 6o to the signal-from Route channel B to summing node 70.

The calibration of the bridge circles of each sensor is easy with the help of variable resistors 30 and 28 to be achieved. In order to make this possible, it is first necessary to ensure that the output signal for the meter 88 is either channel A or channel B signal. This is done with the help of the manual channel selection switch reaches 15o, that of the automatic selection function of the comparator 52 is superimposed when the switch 150 is out of its neutral Position is brought into contact with either junction 152 or 154.

Assume that the movement of switch 15o to the connection point 152 causes comparator 52 to select the channel A signal, the display device becomes 88 show the signal generated by sensor 16. Is the feeler 16 in clean air, the setting of the zero potentiometer 30 can then be carried out when the meter 88 has been zeroed. Then the flende Element exposed to a gas with standardized calibration that has a known percentage Composition, and the slide potentiometer 28 is adjusted so that a it gives an indication on meter 88 representing the known percentage of LEL for the appropriate gas. -While the implementation With this setting it is not necessary to use the manual payment switch 150 as long in its closed position, like the probe for the other channel is not exposed to a high concentration of gas. Repeat the same procedure then choose the sensor from channel B.

For setting the values at which large or small alarms are triggered is to be, the zero potentiometer 30 is shifted from each channel until the Meter 88 shows the desired percentage of the LEL T. at which the minor alarm should be triggered, usually at about 35%. Da3 potentiometer 98 is then set until the small alarm relay 108 is triggered. Then the potentiometer 30 again until the meter shows its maximum @ value, and then the potentiometer loo is adjusted until the large alarm relay 118 is triggered. The zero potentiometer 30 is then reset to have a zero reading on the device to deliver.

After power has been applied to the system and the time that has passed the time delay 126 is determined to have expired, the failure relay 138 operated when the current to one of the sensors has been interrupted. When the failure relay is operated and both channel identifiers So and 82 light up, is displayed, that both switches 58 and 6o have been closed, causing failure in both Channels is displayed.

Description of the second exemplary embodiment.

Referring to Figures 3 and 4, the second or alternative is used Embodiment of the present invention uses a somewhat different type of channel selection, albeit the function is retained that only the signal that is greatest, is selected. The first implementation, however, is by the capabilities of the comparator limited and also by how many sensor channels can be accommodated, whereas the second version has the ability to accommodate two or more channels, while always delivering an output becomes the most dangerous (represents x'as concentration state. This creates a gas detector, the sensor can have a variety of measuring points and represents more than just a reinforcement or a redundant system Although the first version is a sensor can not burn at separate measuring points, is a reinforced one for most purposes Redundancy is an essential aspect.

The second version uses unidirectional, Amplifier voltage followers combined to form a unit, one electronically have generated ideal diode characteristics. The outputs from each channel are connected to a common node so that the output signal with the largest The amount of backinfluencing on the diode or the diodes of the other channels, in that there is a single voltage output signal in the form of the largest signal value which is fed into the display and control circuits.

In Fig. 3, the differential amplifier 3o2 receives plus and minus inputs from the remote probe of channel A. The mode of operation of the amplifier 3o4 is similar in that it takes its inputs from the probe of channel B. the Combination of resistors 306, 308 and 310 and feedback resistor 312 form part of the signal processing like the networks 220 and 222 from Fig. 1 so that the zero point and the full scale range can be set. the Combination of resistors 306 and 312 together with amplifier 302 and the Diode 314 include the voltage follower, which is an ideal diode characteristic having. The function of the field effect transistors (FET) 316 and 318 is described below to be discribed; It should suffice at this point that, if the amplifier 3o2 and 304 deliver outputs and no failures have occurred, the FET's ineffective are. As a result, if VA is greater than VB, the voltage at node will be 320 VA equalize, because the diode 322 is influenced back by VA and therefore not conductive is. the complete operation of this variant and its advantages will be easily understood from FIG.

In Fig. 4a, as before, regulated constant current sources 324 and 326 connected to an energy source at the connections 325 and 327 accordingly, to provide outputs at terminals 328 and 329. The circles for the channels A and B are identical, and an explanation of one will suffice.

The output of source 324 at location 328 is removed with the arranged sensor A, which has an active resistance 33o and a passive one Resistor 332 includes. These two resistors together with resistors 334 and 336 connected in series with the variable resistor -333 the balance weight of a Wheatstone bridge circle.

The variable efistor 338 provides the zero setting similarly the resistor 30 in Fig. 2. The variable I.tisterstand 340 is between the resistors 330 and 332 and connected to the wiper arm 339 of the resistor 338. The wiper arm 341 of the resistor 34o is connected in series with the resistor 306 and the capture of the differential amplifier 3c2.

The wiper arm 339 of the resistor 338 is connected to the resistor -3c8 and the other input of amplifier 302 connected in series. Resistance 310 is between the positive input terminal of 302 and ground potential and with one side of resistor 332 connected. The output terminal 342 of the amplifier 3o2 is connected to diode 314, which has the polarity shown, whereby the feedback resistor 312 is connected to the negative input of the amplifier 302 will. A shunt resistor g44 is connected in parallel with the diode 314 to to form a path for the leakage straw so that the output voltage is in the utmost Fall.at node 320 will occur, for the purpose of calibration less than zero can be. A capacitance 346 is parabolic to the inputs of amplifier 302 switched and acts as a low-pass filter by removing the high frequencies as a result of external Cuts out disturbances. Similarly, the capacitance is sl46 with the line 350 connected to the output of the amplifier through the diode 314 is connected, and the other side of capacitance 348 is connected to line 352 connected, and this capacity in turn serves the purpose of eliminating high-frequency interference, wherein the response time is determined by the value of the resistor 354, which is to is connected in parallel. The output line 350 is connected to one of the connections of the FEi? 316, the other terminal of which is connected to node 320. The node 320, with which likewise the other connection of the FET 318 of the circle from channel 8 is connected in a similar manner by a series resistor 356 connected to a meter 353, the other side of which is connected to ground potential is. A diode 36a is connected between line 350 and ground potential. This diode is used to protect the FET 316 ..

If the calibration potentiometer 340 or 338 or a fault occurs in the sensing circuit, amplifier 302 could be a large negative Provide output signal, so that the combination of the diode 36o and the resistor 354 result in a combination that records the negative tlert of which m node 320 will appear as a slightly negative value, sufficient to protect the FET, but sufficiently negative that the gauge 358 is smaller for the purpose of calibration than can be zero. A test switch 355, one terminal of which with a positive Potential source is connected through the diode 357 and the series resistor 359 connected to the wiper arm 339 of the bridge circle. If switch 355 is closed, so it creates a positive tension on one side of each bridge circuit and thus disturbs the equilibrium, so that each amplifier has an output signal above of the level value for major alarm is generated, simulating a condition that triggers suitable alarm devices.

Referring now to Figure 4b, node 320 is with node 32ca connected from which the oignal-on two lines connected to this node are connected, is branched, whereby the line 362 extends to the input of the differential amplifier 366 and the line 364 to the input of the differential amplifier 368 extends. The other Input to amplifier 366 is through the series resistor 370 connected to the variable 5th resistor 372 and then 6t through another Series resistor 374 with a positive DC potential. A feedback resistor 376 is connected between the output of amplifier 366 and reference input 367. In this way, amplifier 366 acts as a threshold detector having an output delivers when the signal in line 362 exceeds the signal at input 367, and this threshold is through the setting of the variable potentiometer 372 certainly. In this order, the 3G6 amplifier is used in such a way that it has a Causes a small alarm or a threshold display. Line 378 to amplifier 366 only provides a positive direct current potential and through the resistance 379 and the zener diode 380 also for a source of a regulated positive Potential for any purpose in the circuit. The output of the amplifier 366 is connected to the base of transistor 384 through series resistor 382, whose emitter is connected to earth and whose collector is in series with a Indicator light 386 is connected to the source of a negative uncontrolled Voltage through lines 390 and 436 is connected. A diode 392 is between connected to the base of transistor 384 and to ground potential. Usually when the alarm thresholds have not been reached and no failures have occurred at the output of amplifier 355 a high voltage, and thus the transistor 384 has a strong base compared to the emitter potential, which is a reverse Can cause this transistor to pass through.

Diode 392 blocks the output of amplifier 366 up to one relatively small positive voltage so as to protect transistor 384. if an alarm threshold has been exceeded, as regulated by the negative Voltage reversal is determined at 394, the potential acts parallel to the diode 392 back to the diode, and this makes the base of transistor 384 negative and causes the transistor to pass through series lamp 386 guides and thereby illuminates them, thereby producing a visual indication becomes that the preselected low alarm threshold has been exceeded. The amplifier 368 is in a similar fashion connected by his variable input through line 364 and its reference input through potentiometer 394 to input 395. This amplifier is also with a Feedback resistor 396 and a series output resistor 398 with a diode 400 which is connected between the output and the earth. The diode 4oo works similarly to diode 392 to protect transistor 402, its base is connected to the output of amplifier 368, the emitter of which is connected to ground and its collector by a lamp 404 connected in series with the source of a negative unregulated voltage through line 406 is connected.

The transistors 408 and 410 are connected in parallel with their Emitter and collectors are each connected to one another and the emitters to the Ground potential are connected and the collectors have an output signal in the line arc12 deliver. The bases of the transistors 408 and 410 are through the resistors 41 and 416 connected to line 390, respectively. The output line 412 of the Paired transistors is through resistor 418 to the base of the Transistor 420 connected, the emitter of which is connected to a negative voltage source and its collector: through the F, eihenwi.derstande 422, 424 and 426 with a positive Voltage source are connected, the series resistors for a suitable bias for the collector and also for a quiescent current for the base of transistor 428 to the node 425 between the series resistors 424 and 426 connected is. The diode 430 connected between the base of transistor 428 and the Connected to ground potential, transistor 428 protects it by keeping the positive voltage limited at the base so that reverse strike-through is not caused. Of the Output of transistor 428 from its collector provides an output signal in the line 432 to the contact release 433, the one or more relays or the like includes what is used to control the machinery with which this gas detector can be connected so that in the event that the Alarm thresholds or, in the event of failures in all channels, a signal for shutdown can be given to the system. The diode 434 is between the collector of the transistor 402 is connected to node 423 between resistors 422 and 424.

During normal operation, both transistors 408 and 41o be conductive and an output on line 412 for the base of the transistor 420 generate so that the transistor 420 is also conductive, as is the transistor 42o is. When the transistor 428 is conductive, the voltage across the diode 430 is negligible negative. If the value for the large alarm set by potentlometer 394 is not has been exceeded, the transistor 402 is not conductive and therefore acts a counter voltage to the diode 434.

The collector of transistor 42o has essentially a voltage level which is equal to the negative unregulated voltage source, so that at the node 423 the voltage roughly between the slightly negative ert on diode 430 and the negative voltage source, whereby the diode 434 has a reverse voltage When the input from line 364 to amplifier 368 receives the input 395, so that the threshold for major alarm is exceeded, the Transistor 402 is turned on and the voltage at its collector becomes substantially conducted from a negative potential to earth, and this increases the voltage on the collector exceed the voltage at node 423, causing diode 434 to generate a voltage receives, which tries to increase the voltage at node 423 and thereby the Voltage at node 425, as if transistor 428 were turned off, ind.em the output on line 432 is interrupted to trigger the contact switch off.

Referring now again to Figure 4a, there is the failure detector area of the circuit from the transistor 44o, whose base via the .iiderstand 442 is connected to the constant current source 324. The collector of transistor 44o is about the Series resistor 444 to the base of the transistor 446 and resistor 448 is connected between the base and emitter and on the other hand connected to the source of negative potential. The collector of transistor 446. is through a series-connected diode 450 and through a Series-connected lamp 452 connected to the earth potential. The collector of the Transistor 446 is connected by line 447, diode 454 and line 352 connected to the gate electrode of FET 316. This approaches in the event of a failure in sensor A, when transistor 446 turns on, the collector has a voltage value, which is close to the Nino voltage source, which turns the FET 316 off. When this occurs, the voltage output from amplifier 302 becomes the node 320 interrupted so that each output on channel A is effectively separated from the circuit but the gas detector can be completely on channel B or any additional Keep working channels that can be used. He can continue to work to provide high and low alarm signals as previously described.

The indicator light 452 becomes a visual indicator of this failure and will also indicate in which channel the error occurred. In similarly, when transistor 44o becomes conductive in response to a failure was made, the output signal at junction F to the base of the transistor 4o8 turn off transistor 408 so that this transistor continues to have no current for transistor 420 provides. However, transistor 410 continues to be conductive remain so that transistor 420 will similarly remain on. In the event that failures occur in both channels, both transistors 408 and 41o are turned off, leaving no output in the composite Failure line 412 is supplied, with transistors 420 and 428 turned off ground so that the contact release will disconnect all circuits with which it is connected connected is. In such a case, the failure lamps become the cause of the failure but in the event that the alarm threshold lamps 386 and 404 are not illuminated they will indicate that the reason for the shutdown is rather a failure than has been a high gas concentration.

While the actual invention and two specific embodiments shown and described by it, it will be apparent to one of ordinary skill in the art Other embodiments or changes or modifications may be included herein without departing from this invention in its broader aspects, and it is intended herein to include all such modifications and equivalents as used to the true extent of this invention.

Claims (12)

PATENT CLAIMS Electrical circuit arrangement for the detection of flammable gases, characterized by the combination of the following features: electrical circuits, which form a large number of different channels (A, B), with each channel (A, B) sensors (16,18) are assigned which change their electrical resistance indicate when exposed to a flammable mixture of gas and air, which also have energy sources (12, 14) each with one of the sensors (16, 18) are connected to the supply of constant current, and furthermore bridge circuits have, which are arranged between the energy sources (12, 14) and the sensors (16, -18) are and each have an output; Elements (220, 222) for signal processing, each with the output of a bridge circuit for setting their Output signals are connected; Elements (224) for channel selection, their inputs are each connected to the channels (A, B), means being provided for channel selection which are responsive to the size of the respective input signals and an output signal according to the input signal with the highest amount; Display organs (226), which are connected to the output (225) of the elements (224) for channel selection in order to display the level of the detected gas concentration, further means (226) for Control, which are connected to the display elements (226), depending on the selected output signal to provide an external control signal, and elements (228) to determine a failure, each connected to the energy sources (12, 14) and for an error in the current flow between the energy sources (12, 14) and the associated sensors (16, 18) connected to them respond to an output signal to deliver, with the output of the elements (228) for detection failure is connected to the elements (24) for channel selection and the elements (228). For the detection of a failure become effective by the fact that they the elements Cause (224) to select the channel, an output signal to the means (226) for control as long as any of the various channels (A, 3) provide an output signal supplies. 2. Arrangement according to claim 1, characterized in that the display organs (226) an analog display device (88) for providing a quantitative display of the relative size of the selected channel signal. 3. Arrangement according to claim 2, characterized in that the display organs (226) furthermore have means (12) for determining the level, which in turn have gowns for the optional setting of one or more threshold values include and output signals depending on the selected channel signal with the largest amount. 4. Arrangement according to claim 1, characterized in that the means to determine a failure (228) also display means for displaying the occurrence and the origin of the failure output signal. 5. Arrangement according to claim 1, characterized in that the elements (224) for channel selection include amplifiers (38, 46) which are connected to each output (36, 40, 42, 44) of the bridge circuits are connected, each amplifier (38, 46) has an output (62, 72) which is connected to a common node (70) is that a comparator (52) is provided which is connected to each of the amplifiers (38, 46) is connected to the amounts of the outputs (L! 8, 50) of the amplifiers (38, 46) to compare and optionally with the node (70) only one of the amplifiers (38, 45) whose output signal is the largest. 6. Arrangement according to claim 1, characterized in that the elements (224) for channel selection include amplifiers (38, 46) which are connected to each output (36, 40, 42, 44) of the bridge circuits are connected that the outputs (62, 72) each Amplifier (38, 46) connected to a common node (70) that the Inputs (48, 50) of the comparator (52) with the outputs of the amplifiers (38, 46) are connected that switch (58, 6o) with the outputs (62, 72) of the amplifier (38, 46) and the comparator (52) are connected so that the comparators act in such a way that that they respond to the largest amplifier signal and the switches (58, 6o) so operate so that only the largest amplifier signal is connected to node (70) will. 7. Arrangement according to claim 6, characterized in that further Time delay means (126) are provided, the input of which is connected to the power source (lo) and the output of which are connected to the display elements (226) that the time delay means (126) then respond to the power source (io) and the display elements (226) for a turn off a predetermined length of time when the power is turned on. 8. Arrangement according to claim 1 or 2, characterized in that furthermore visual display devices (80, 32) are provided which are connected to the elements (224) for channel selection are connected to indicate which channel signal is connected to the Node (70) is connected. 9. Arrangement according to claim 3, characterized in that visual Display devices (silo, 120) connected to the means (92) for determining the level to indicate the state when one or more threshold values have been exceeded have been. lo. Arrangement according to claim 3, characterized in that the means (92) for determining the level comprise: first and second outputs (94, 96), first and second alarm triggers (106, 116) connected to the outputs (94, 96) are, display devices (mio, 120), each with the blarm triggers (106, 116) are connected, first and second adjustment members (98, 100) with the means (92) are connected to determine the level, the first setting element (99) for setting the first output (94) to a preselected level for Eleinalarm and the second setting element (lot) for setting the second output (96) a preselected level for large alarms are provided and wherein each of the display devices - (llo, 7 120) controls for connecting its output to a remote one Place au £ wclst. 11. The arrangement according to claim 1, characterized in that the elements for channel selection have differential amplifiers connected to each output of the bridge circuits connected, furthermore, a diode which is rich with the output of the amplifier is connected, and have a feedback resistor connected to an input of the amplifier and through the diode connected in series with the amplifier output is connected, whereby an ideal diode characteristic is achieved, and that the Amplifier outputs from a point between the diode and the feedback resistor are connected to each other at a common node. 12. The arrangement according to claim 11, characterized in that switch are provided in series between each amplifier output and the common Node are connected, the switch being effective with the detection elements of failure. Blank page