DE2239270B2 - Gas detector - Google Patents

Description

The invention relates to a gas detection device with at least one semiconductor gas detection element and one AC voltage source through which an AC voltage is applied to the electrodes of the semiconductor gas pump ments is laid. Such a gas detector is for example by the US-PS Jb 31 436 or US-PS 36 44 795 became known.

It has become known through DT-AS 12 01 094. Provide gas detector diodes in a bridge circuit, the output of which is independent of the gas concentration is, while it has become known from US-PS 34 82 233, an amplifier in gas analyzers to be provided for detecting the change in resistance of a gas detection element. After all, it's through that US-PS 35 93 126 become known, brückenschaltun conditions with a downstream amplifier in general To use determination of resistance changes.

The increasing demand for town gas and liquefied natural gas and the corresponding increase in consumption led to a corresponding increase in the number of gas explosions and other gas accidents. Such accidents are mainly due to the fact that a high percentage of liquefied natural gas is added to the town gas in the gas supply to remove the peculiar smell of town gas and to brighten the gas flame, so that the gas consumers can leak gas. so a leak, neither smell nor see. _S5 difficult problems arise from this, especially in cold regions, in which sufficient thermal insulation of the house from the environment is required.

In less densely populated areas, propane gas is widely used in place of town gas widespread, since no large gas pipeline system is required for this. Since propane gas is also not that strong smells like town gas, explosions and accidents occur here too. Also, propane gas is turned on very often Ships and boats used for heating purposes. In these cases gas explosions and accidents can still occur have more serious consequences.

The known gas detection devices described at the beginning show how to avoid these dangers Semiconductor gas detection element which can absorb and desorb the above-mentioned gases. D.ese However, gas detectors did not work satisfactorily, among other things due to self-heating, a phenomenon peculiar to gas detectors.

In the known gas detection devices, the heating and the detection or detection electrode of the semiconductor gas detection element are permanently e ^; ne voltage, and the change in the electrical resistance or the line resistance between the heater and the plate or anode as a result of gas absorption serves to detect gas leakage. This gas detection device works with the highest possible voltage, as this increases the gas detection capability of the device. However, the increase in voltage leads to greater self-heating and thus to malfunctions. The reduction in voltage in turn has the disadvantage that the detector does not detect a gas leak with sufficient certainty or tends to respond incorrectly as a result of the noise in the subsequent circuit.

The invention is based on the object of providing a gas detection device while avoiding such malfunctions to create at which the gas concentration-line resistance curve essentially straight in a range of gas concentration from 0.2 to 0.6%

Your task is achieved according to the invention by that the alternating voltage applied to the electrodes of the gas detection element is sufficiently small. around a To avoid self-heating of the gas detection element, and that the gas detection element in a branch of a a bridge circuit existing voltage difference comparator is connected, at the output of a Differential amplifier for detecting the change in resistance of the gas detection element proportional to the gas concentration connected. The overall combination of these features is essential to the invention.

The voltage applied to the electrodes of the gas detection element is expediently about 24 volts.

With the gas detection device according to the invention, it is possible to use a large number of gas detection elements Detection of leaking gas at a large number of locations with just a single gas detector use. For example, a single gas detection device with several gas detection elements is sufficient for monitoring a multitude of rooms in a house.

Furthermore, the gas detection device according to the invention, the costs for the detection of escaping gas is reduced and greater safety is created against accidents caused by gas.

Reference is made to the drawing for a detailed explanation of the invention. It shows:

F i g. 1 shows a circuit diagram for the operation of a known semiconductor gas detection element for gas absorption and desorption,

F i g. 2 the working method of the Gasspürelerrentes F i g. 1 at different, applied voltages,

3 shows a block diagram of a gas detection device according to the invention,

4 shows a circuit diagram of a preferred embodiment of the device according to Fig. 3,

5 shows a schematic representation of the voltage difference generator in the circuit according to F i g.4 and

F i g. 6 the circuit diagram of a converter, preferably for use of the device according to the invention on a ship or the like.

According to FIG. 1 is a semiconductor gas detection element for

Gas absorption and desorption applied to an AC voltage source via a resistor Xi. This gas detection element works like this. that when gas is absorbed or desorbed on the surface of the Gasspürele-Bientes the number of electrons on the surface of the element increases or decreases, which leads to a corresponding change in the electrical resistance (line resistance) between the filament // and the plates Pdes If a constant voltage is applied to the filament H and plate P of the element via the resistance R \ , the change in the line resistance can be determined from the change in the voltage drop across the filament and the plate.

If you want the greatest possible change in the voltage drop across the filament and plate of the If you want to achieve the element, you can apply a high voltage. You have already got very high Tensions worked At high voltage, however, the semiconductor element tends to generate heat. There the semiconductor element has a negative resistance, the heat generation leads to the decrease the resistance and to increase the current The increase in current in turn increases the heat generation, so that there is a vicious circle, the phenomenon of self-heating. This is the main urge the malfunction of gas detectors.

Fig. 2 shows the relationship between the gas concentration and the line resistance r. if the value of the resistor Ri is about 3 kiloohms, and if you work with four different AC voltages, 100, 50, 24 and b volts. The graph shows that the curve for 100 full is not straight. In addition, self-heating in the case of Hi.'ser voltage cannot be avoided. The curve for 50 volts is still not straight. In contrast, the curve for 24 volts in the explosive concentration range between 0.2 and 0.6% is approximately straight. The curve for b volts is over the entire concentration range in FIG. 2 practically straight, but delivers only a very small output signal, so that even if an additional amplifier stage is used, the device may malfunction due to noise, fluctuations in the power supply and the like.

The invention eliminates such malfunctions; t. Furthermore, the voltage is set to a value reduced, in which the gas concentration-power resistance curve in the most practical most the range of interest of 0.2-0.6% is approximately straight.

According to FIG. 3, several semiconductor gas detection elements ELEM for gas absorption and desorption are connected to an electrical monitoring circuit 2, which in turn is connected to a power supply 5. If gas is absorbed by one of the Gasspürele.nente ELEM , as a result of a gas leak, the resistance value of the gas detection element 1 changes depending on the gas concentration, as in FIG. 2 shown. As a result of the change in the electrical resistance, the electrical monitoring circuit 2 switches on a signaling device 6, for example an alarm bell or a buzzer, and at the same time a gas cut-off device 3 located in the gas line 4 is actuated.

In Fig. 4 the device according to the invention is more detailed shown. The primary winding of a transformer T ″ is connected to an AC voltage supply £ The transmission ratio of primary and secondary

winding of the transformer T is chosen so that with an alternating voltage of 100 volts between a and b of the primary winding an alternating voltage of 1.2 volts for the filament of a gas detection element El £ M between points c and d of the secondary winding and an alternating voltage of 24 volts occurs between points d and e of the secondary winding which lies between the filament and the plate of the element. The gas detection element ELEM is chosen so that its critical resistance changes depending on the absorption or desorption of gas. The electrical resistance should decrease with increasing concentration of the absorbed gas. The reduction in resistance is detected by a voltage difference comparator, consisting of the resistors Äi, R2 and Ri and the gas detection element ELEM. The voltage difference comparator has the advantage that a malfunction due to fluctuations in the supply voltage is extremely unlikely.In addition, a simple electrical connection to a differential amplifier in the next stage can be achieved by simply changing the resistance of the trimming resistor Ri or Ri , which is also the case with several gas detection elements ELEM is possible.

In Fig. 5, the operation of the voltage difference, .komparators, consisting of the resistors Ri, Ri and /? 3 and the gas detection element ELEM is explained in more detail. The adjustable resistance Ri is set in such a way that the voltage difference between points / and g is equal to zero when no gas is absorbed at the gas detection element ELEM , ie when no gas escapes. If gas is absorbed by the detection element ELEM as a result of a gas leak, the resistance of the gas detection element ELEM is reduced as a result. The voltage at the gas detection element ELEM decreases as a result, the voltage at the resistor /? I and thus at point f increases. In contrast, the voltage at the connection point g between the resistors R2 and Ri remains unchanged, so that a voltage difference occurs between the points f and g . This voltage difference is amplified by a voltage amplifier or differential amplifier, consisting of two transistors Tn. Tn and the resistors A4, Rs and Ri . The transistors Tn and Tn have the same characteristics, so that fluctuations in the power supply and the drift as a result of temperature changes remain very small, so that the malfunctions customary in the known devices are practically eliminated. The reduction in the sensitivity of the gas detection element caused by the use of a low voltage source can thus be sufficiently compensated for by the special characteristics of the differential amplifier in the next stage and the gas detection device has only an extremely low tendency to malfunction.

Since the potential at point f is higher than at point g, the base current of transistor Tn is greater, whereby its collector current also increases. The larger collector current causes a large voltage drop across resistor /? 4, which reduces the voltage at point Λ. This reduces the base voltage of the transistor Tn and this switches on a relay RY. When the relay RY is switched on, a switching contact goes from the fixed contact / to the other fixed contact / As a result, a signaling device Lk, for example a signaling lamp or a buzzer, which is connected to contact j , is switched on and generates an alarm signal, while at the same time a

Gas cut-off device Li, such as a cut-off valve, connected to contact j , is switched off. The disconnection device Li works in such a way that it does not automatically re-enable the gas flow when the current is switched on again. Inadvertent gas leakage from heating systems and other gas consumers is definitely avoided. A damping capacitor C is located parallel to the relay winding .

The mode of operation of the gas detection device according to the invention remains unchanged if, instead of a single gas detection element ELEM, several gas detection elements ELEM \, ELEM1 ... are connected in parallel. as indicated in Figure 4. To adjust the resistance elements, the resistance Ri of the voltage difference comparator must be set accordingly in this case.

When using the gas detector according to the invention on a ship or in places where none If AC power is available, the converter shown in Fig. 6 can be used. Of the Converter is built into the gas detector and converts direct current into alternating current. Of the Converter includes a voltage stabilizer, an oscillator and a circuit for increasing the voltage. The voltage stabilizer is connected to the DC voltage supply and consists of transistors Tn ' to Tn', Zener diodes Di and Di to stabilize the base and collector voltage of the transistors 7h 'and Tn', resistors R ' and Ri' to stabilize the functioning of the diodes D and Di, a resistor Ri ' for controlling the base and emitter current of the associated transistors 7h' and

ίο 7h ', feedback resistors Rs' to Ri', rectifier diodes / λ to Ds and smoothing capacitors Ci and Ci. The oscillator comprises transistors Tn, Tn. Windings L \ to La, diodes Di and Ds, resistors Rs, Ä9 and a capacitor Ca. The diodes Di, Ds, the resistor Ä9 and the capacitor Ca are intended to suppress the surge voltage in the windings Zj and La , while the resistor Rs controls the base current of the transistors Tn and Tn and determines the oscillation frequency. The circuit for voltage

Voltage increase comprises a winding Ls magnetically coupled to the windings Li and La for the desired alternating voltage.

For this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Gas detection device with at least one semiconductor gas detection element and an alternating voltage source through which an alternating voltage is applied to the electrodes of the semiconductor gas detection element, characterized in that the alternating voltage applied to the electrodes of the gas detection element (ELEM) is sufficiently small to be ι ο to avoid self-heating of the gas detection element (ELEM) , and that the gas detection element is connected to a branch of a bridge circuit consisting of the voltage difference comparator (Ri, R2, Ri, ELEM) , at the output of which a differential amplifier (Tn, Tn, /? ■ * , Rs, Rr) is connected to detect the change in resistance of the gas detection element proportional to the gas concentration 2. Apparatus according to claim I, characterized in that the on the electrodes of the gas detection element (£ Z. £ A ^ lying voltage is about 24 volts.