UA61611A - System for controlling inflammable gas content in mine atmosphere - Google Patents

Abstract

Control system for inflammable gas content in mine atmosphere includes signaling apparatus, measuring parameter transformer, power supply unit, measuring circuit for low concentrations of inflammable gas, switchboards, scale amplifiers, active rectifiers, measuring circuit for methane high concentrations, linearizer, limiting devices, indication unit, time relay, telemetric amplifier, unit for formation of tele-signaling signals, appliance for light signaling.

Description

Description of the invention

The invention relates to mining automation, and more specifically to systems for automatic control of the content 2 of combustible gas (for example, methane) in the mine atmosphere and can be used for automatic gas protection and autonomous or centralized control of the content of combustible gas in mining operations of coal mines and other industrial objects.

A well-known methane content control system is available, see, for example, Karpov E. F., Birenberg N. Z., Basovsky B. I.

Automatic gas protection and control of mine atmospheres. - M.: Nedra, 1984. - P. 117 - 129), which 70 consists of an AS-5 signaling device and a DMT-4 thermocatalytic methane sensor. At the same time, the alarm device has the first input through which the power supply voltage is supplied to the alarm device from the network, the second input through which the telemetry (TV) signal (0-5mMA) is received from the output of the DMT-4 sensor and through the first output of the AC-5 device is transmitted on devices located on the surface of the mine. Through the first output of the signaling device, a frequency signal of tele-alarming (TcS) (continuous and discrete) is also output in relation to the achievement of 12 methane content in the atmosphere of given limit values, through the second output of the signaling device, for example, with the help of a contact, the equipment of the protected station is turned off. A sound alarm device is connected to the third output of the alarm device, which is turned on when the content of the controlled gas in the atmosphere reaches the specified limit values. The AS-5 alarm device also has an input - an output to which the DMT-4 methane sensor is connected. This input - output is connected to the input - output of the DMT-4 sensor and through it the power supply of the DMT-4 sensor is carried out and the reception of telesignaling (TS) signals from the input - output of the DMT-4 sensor about the methane content exceeding the specified limit values. The AS-5 alarm device has an indicator of the current value of the content of combustible gas in the atmosphere, as well as two light indicators that light up in cases of connecting the device to the network and receiving a signal from the DMT-4 sensor that the content of combustible gas has reached the specified limit value.

The alarm devices produced are designed for one (see the description above) or three control points, in this case the alarm device has a larger number of control outputs, inputs - outputs and light indicators. The DMT-4 sensor has one input - output, which is connected to the second input of the alarm device and is designed to output a TV signal proportional to the current value of the methane content in the monitored atmosphere. --

Disadvantages of the specified methane content control system are the relatively large power consumption of the sensitive -/- de elements of the DMT-4 sensor, which does not allow constructive implementation of the sensitive element in an intrinsically safe design, the methane sensor is not unambiguous and has relatively large dimensions and mass (see, for example , Introduction to ke, theories of combustion and the method of contact combustion. Material! of the symposium of firms! "Riken Keiki". - Tokyo, 1983; "--

GOST 24032-80 "Mining gas analytical equipment. General technical requirements, method! tested"|.

This reduces the reliability of automatic gas protection and limits the field of application of the methane content control system.

The mentioned shortcomings are partially eliminated in the well-known equipment for controlling methane in mining operations | see, for example, Stationary apparatus for controlling methane in mining operations // E. F. Karpov, B. I. Basovsky, E. «

Sh. Landa and others - Labor safety in industry. - M.: Nedra, Mo2, 1991.-60.2 - 8). - 50 The control equipment also consists of an AC signaling device for one or three control points with inputs and outputs similar to those described above, a converter of the parameters of the measuring PPV and a remote sensor

From" methane DMV, in which working and comparative sensitive elements with intrinsically safe values of consumed power are placed, which allows to simplify the design of sensitive elements, reduce the dimensions and weight of the measuring PPV converter, which has an input - output for connecting the supply voltage and issuing TC signals to the device signaling when the limit values of the controlled parameter are exceeded, an output for outputting the TV signal and an input for connecting the DMV methane sensor. However, the readings of methane control equipment - in mining operations are also not clear-cut. This shortcoming is partially eliminated in the well-known detector of combustible gas, mainly methane | see application Мо2475733 Франции МКИ 0 1 М27/16 Inventions in the USSR and abroad b Mo1, 1982, which has the first bridge circuit, which includes catalytic and compensating elements, which - 20 are in contact with the controlled gas. The compensation element of the first bridge is part of the second bridge circuit in which it performs the functions of a sensitive element. The second bridge circuit also contains an element protected from and controlled gas, which in this bridge is compensatory. The detector also contains means for switching the supply voltage of both bridge circuits depending on the concentration of the monitored gas.

In the specified combustible gas detector, when the content of combustible gas rises above a certain level, the first 25 bridge, which contains a thermocatalytic sensitive element, is turned off and the second bridge, which works on conductometric principle. At the same time, the compensating element of the second bridge circuit, disconnected and cold in the initial state, begins to heat up, and measurement by the second bridge is possible only after the end of the transient process associated with the heating of the compensating element. At this time, methane content is not measured, which reduces the reliability of gas protection. In addition, the detector of the presence of combustible 60 gas does not perform a number of functions performed by methane control equipment in mining operations: disconnection of the equipment of the protected site, formation of TV, TC signals, time delay for disconnection of the equipment of the site in the event of a short-term exceedance of the first set limit value of methane, and others functions.

The task of the proposed invention is to eliminate the above-mentioned shortcomings of the combustible gas detector while preserving and expanding the functionality of methane control equipment in mining operations.

The task is achieved by the fact that in the control system of the content of combustible gas in the mine atmosphere, which contains an alarm device, the input - output of which is connected to the input - output of the converter of the measuring parameters, to the input - output of which a power supply unit is connected, the first output of which is united with the first

INPUT of the measuring circuit of low concentrations of combustible gas, the second input of which is connected to the output of the first switch, the output of the measuring circuit of low concentrations of combustible gas is connected in series with the first scale amplifier, the first active rectifier, which is characterized by the fact that in order to increase the reliability of control of safe working conditions according to the gas factor, expansion of functional capabilities, a measuring circuit of high methane concentrations was introduced, connected in series with the second large-scale 7/0 amplifier, the second active rectifier, linearizer, the third limiting device, the output of which is connected to the first inputs of the second, third, of the fourth switches, the input of the third limiting device is connected to the second inputs of the second and third switches, the first output of the third switch is connected to the input of the indicating device, the third input of the third switch is connected to the second output of the first active rectifier and the third input of the second switch, the first the output of which is connected and with the inputs of the first and second /5 limit devices, the second output of the second switch is connected to the second input of the fourth switch, the fourth input of the third switch is connected to the third input of the fourth switch, the fourth input of the second switch and the output of the fourth limit device, the input of which is connected to the first output of the first active rectifier and the fifth input of the second switch, the first output of the time relay is connected to the fourth input of the fourth switch, the output of which is connected to the input of the telemetry amplifier, and the fifth

The input of the fourth switch is connected to the "minus" of the power supply unit, the "plus" of the power supply unit is connected to the sixth input of the second switch, the first and second outputs of the second limit device are connected to the second input of the time relay and the first input of the telesignaling signal generator, respectively , the output of the time relay is connected to the second input of the telesignaling device, the first output of which is connected to the light signaling device, and the second output to the input - the output of the measuring parameter converter.

The introduction of additional functional units into the well-known (described above) combustible gas control system provides, in addition to the performed functions, the unambiguity of readings in the range from 0 to 10095 rpm. fractions of combustible gas in accordance with GOST 240032-80.

The introduction of the measurement scheme of high concentrations ensures the measurement of the concentration of combustible gas from

O to 10095 rpm. particles by the conductometric method. "- z Introduction of the second large-scale amplifier and the second active rectifier allows to amplify and rectify the signal from the measuring circuit of high concentrations. The linearizer allows you to obtain a linear characteristic - measurements in the range from OO to 10095 rpm. particles of combustible gas. The third and fourth limit devices allow to receive control signals when the concentration of combustible gas of the third and fourth limit values is reached and with the help of these signals to influence the second, third and fourth switches. --

The first switch allows you to manually influence the first measuring circuit of low CO concentrations, performing an artificial imbalance of the bridge circuit, which leads to the activation of the third limiting device and, accordingly, to the influence on the second, third and fourth switches. This allows you to manually check the operation of the circuit and check whether the second high concentration measuring circuit should be balanced. "

The second switch allows, under the influence of control signals from the third and fourth limit devices with c, when the concentration of combustible gas of the third or fourth limit values is reached, to block with a positive potential iO, which exceeds the trigger settings of the first and second limit devices, as well as ;" switch the signal from the measuring circuit of low concentrations to the signal from the measuring circuit of high concentrations at the input of the fourth switch, which, under the influence of control signals from the third and fourth boundary devices, will allow the signal from the measuring circuit of low concentrations to be passed to the input of the telemetry amplifier as a constant, and the signal from the measuring circuit high concentrations - intermittently, with an interval set by the time relay, for example, the signal from the measuring circuit of high concentrations is passed for 8 seconds, and the zero-level signal connected to the second input of the fourth b switch from the power supply unit is passed for 8 seconds. This will make it possible to control the content of high concentrations of combustible 5p gas from the surface of the mine using the same teleinformation transmission channels and the same measuring devices - which control low concentrations of combustible gas. as the third switch allows at the input of the display device to switch the signal from the measuring circuit of low concentrations to the signal from the measuring circuit of high concentrations under the influence of control signals from the third and fourth limit devices. This allows you to visually observe the content of combustible gas in the atmosphere

HIGH concentrations.

The parallel inclusion and non-stop operation of both circuits in the measurement mode allows to reduce the time to a minimum

P" of the transition process during commutations during switching from one mode to another and thus will ensure the reliability of unambiguous measurement of the content of combustible gas in the atmosphere in the range from О to 10095 volume fraction of combustible gas. Thus, all introduced functional devices and connections between them are implemented to achieve the set task - to achieve unequivocal readings in the range from 0 to 10095 volume fraction of combustible gases, to preserve and expand the functional capabilities of methane content control equipment in mining operations.

The essence of the invention is explained by the drawing, where the figure shows the structural diagram of the claimed device. The scheme of the claimed device consists of an alarm device 1, a converter of measuring parameters 65 2, consisting of a power supply unit C, a measuring circuit 4 of low concentrations, a measuring circuit 5 of high concentrations, the first scale amplifier b, the first active rectifier 7, the first limiting device 8, telesignaling signal generating device 9, light signaling device 10, first switch 11, second limit device 12, telemetry amplifier 13, fourth limit device 14, time relay 15, second switch 16, third switch 17,

The fourth switch 18, the second scale amplifier 19, the second active rectifier 20, the linearizer 21, the third limiting device 22, the display device 23.

At the same time, all electronic devices of the circuit, the connections of which with power supply unit 3 are not shown due to their insignificance, and the measuring circuits of low 4 and high 5 concentrations of combustible gas connected to power supply unit C in parallel are powered from power supply unit C. 70 The system for monitoring the content of combustible gas in the mine atmosphere includes an alarm device 1, the input - output of which is connected to the input - output of the converter of the measuring parameters 2, to the input - output of which the power supply unit 3 is connected, the first output of which is connected to the first input of the measuring circuits 4 of low combustible gas concentrations and the input of the measuring circuit 5 of high combustible gas concentrations, the second input of the measuring circuit 4 is connected to the output of the first switch 11, the output of the measuring circuit 4 of low 7/5 concentrations of combustible gas is connected in series to the first scale amplifier 6 , the first active rectifier 7, the first and second outputs of the telesignaling device 9 are connected to the light signaling device 10 and the input - output of the measuring parameter converter 2, respectively, the first and second inputs of the telesignaling device 9 are connected to the output of the first boundary device 8, the first output of the second boundary device 12 resp i.e., the second output of the second limiting device 12 is connected to the input of the time relay 15, the first output of which is connected to the third input of the telesignaling device 9, the measuring circuit 5 of high methane concentrations is connected in series with the second scale amplifier 19, the second active rectifier 20, the linearizer 21, the third limit device 22, the output of which is connected to the first inputs of the second 16, third 17, fourth 18 switches, the input of the third limit device 22 is connected to the second inputs of the second 16 and third 17 switches, the first output of the third switch 17 is connected to the input of the display device 23, the third input of the third switch 17 is connected to the second output of the first active rectifier 7 and the third input of the second switch 16, the first and second outputs of which are connected to the first 8 and the second 12 limit devices and the second input of the fourth switch 18, respectively, the fourth input of the third switch 17 is connected to the third input of the fourth switch ator 18, the fourth input of the second switch 16 and the output of the fourth boundary device with de

From 14, the input of which is connected to the first output of the first active rectifier 7 and the fifth input of the second switch 16, the second output of the time relay 15 is connected to the fourth input of the fourth switch 18, the output of which is connected to the input of the telemetry amplifier 13 , the output of which forms the first output of the parameter converter 2, Ge connected to the input of the signaling device 1, moreover, the fifth input of the fourth switch 18 is connected to the "minus" of the power supply unit 3, and the "plus" of the power supply unit C is connected with the sixth input of the second switch 16. --

The following characteristic regimes corresponding to a certain content of combustible gas in the atmosphere can be identified for the operation of the scheme: absence of combustible gas in the atmosphere; the content of combustible gas in the atmosphere is below the first limit value (for example, below 195 parts by volume); the content of combustible gas in the atmosphere is above the first limiting value, but below the second limiting value (for example, above 195 parts by volume, but below 295 parts by volume); Шщ с the content of combustible gas is above the second limit value, but below the third set limit value (for example, above 295 parts by volume, but below 595 parts by volume); ;" combustible gas content above the third set limit value, but below the fourth set limit value (for example, above 595 parts by volume, but below 1095 parts by volume); the content of combustible gas is above the fourth specified limit value (for example, above 1095 parts by volume and up to

Ge" 10095 vol. parts);

The first mode: system operation in the absence of combustible gas in the atmosphere. In this mode, the output signal of measuring circuits of low 4 and high 5 methane concentrations is zero. The same value of signals will be on

At the outputs of the first b and second 19 scale amplifiers, the first 7 and second 20 active rectifiers and the linearizer 21. At the outputs of the limit devices 14 and 22 operating in the comparator mode, a signal level corresponding to a logical unit is established. Accordingly, the level of a logical unit will also be set on the third and fourth control inputs of the second as 16, third 17 and fourth 18 switches. With such a combination of signals at the control inputs of the switches, the following occurs: in the second switch 16, a signal passes from its fifth input and, accordingly, from the second output of the active rectifier 7 to its first output and the inputs of the first 8 and second 12 boundary devices, and the signal, is zero, the second output of the second switch 16 and the first input of the fourth switch 18 pass the signal from the second input of the switch 16 and, accordingly, from the first output

P of the active rectifier 7, which is equal to zero. Due to the fact that a signal equal to zero arrived at the inputs of limit devices 8 and 12, a signal of a logical unit was established at its outputs, which passes to the first and second inputs of the device for generating telesignal signals 9 and the input of the time relay 15, on the third input of the device for the formation of telesignaling signals A logical unit signal is received. With such signals at the inputs of the telesignaling signal generation device 9, the signals for turning on the light signaling 10 and the signal for turning off the power to the signaling device 1 do not arrive. In the third switch 17, the signal from the second input passes to its output and, accordingly, to the input of the indicating device 23, that is, the second output of the first active rectifier 7, and the readings on the digital display will be zero at low concentrations. In 65, the fourth switch 18 receives a signal from the second output of the second switch 16 at its output and, accordingly, at the input of the telemetry amplifier 13. This will be the signal from the first active rectifier 7, and it will be zero.

The combination of control signals on the fourth switch 18 is such that this signal will be transmitted to the input of the telemetry amplifier 13 in a constant mode and at its output there will be a current signal corresponding to the zero content of combustible gas in the controlled atmosphere.

If there is no combustible gas in the atmosphere, the first 11 switch is used to check the functioning of the main nodes of the control system. When the switch 11 is manually switched (which may consist of a button), a jump-like imbalance of the low concentration measuring circuit 4 occurs, and a signal appears at its output, the magnitude of which, after being amplified by the scale amplifier 6 and rectified by the active rectifier 7, exceeds the trigger setting of the first 8, the second 12 and the fourth 14 marginal 7/0 devices, as a result of which logical zero signals appear at their outputs. A change in the signals at the first and second inputs of the telesignaling device 9 and at the input of the time relay 15 leads to the output of signals for the activation of the light signaling of the first and second levels in the signaling device 10 and the output of a signal to turn off the electricity of the station in the signaling device 1. Change of the output signals of the fourth 14 boundary device and, accordingly, on the third control inputs of the second 16, third 17 and 7/5 of the fourth 18 switches leads to a change in the state of the switches.

The signal from the fifth input of the second switch 16, that is, from the second output of the power supply unit 3 corresponding to the logical unit, will pass to the first output of the second switch 16 and, accordingly, to the inputs of the first 8 and second 12 boundary devices. The signal from the first input and, accordingly, from the output of the linearizer 21 will pass to the second output of the second switch 16 and, accordingly, to the input of the fourth switch 18, the same signal will pass to the output of the Third switch 17 and, accordingly, to the input of the display device 23, where the digital display will show zero readings for high concentrations, because the measuring circuit of high concentrations 5 is in the measurement mode, and there is no combustible gas. From the output of the fourth switch 18 to the input of the telemetry amplifier 13, a zero signal from the high concentration measurement path will also arrive. In this position, the scheme allows, in addition to checking the path of power outage and light signaling, to check and, if necessary, adjust the balance of the measuring circuit of high concentrations 5 according to the indications of the digital panel of the indication device 23. When releasing the button, that is, moving the switch "11 to the initial position, the scheme jumps to the initial position.

The second mode: the content of combustible gas in the atmosphere is below the first limit value (for example, above 095 parts by volume, but below 195 parts by volume). In this mode, at the outputs of the measuring circuits of low 4 and high 5 -" where the concentrations appear, signals are amplified by the first b and second 19 scale amplifiers and rectified by the first 7 and second 20 active rectifiers. The state of the switches 16, 17 and 18 - - is determined by the control signals coming from the outputs of the fourth 14 and the third 22 boundary devices.

Since the content of combustible gas in the atmosphere in this mode is below the trigger settings of limit devices 14 and 22, the state of the switches will not change, the connections in the electrical circuit of the system will remain unchanged, and the state --

The scheme will be similar to the first regime. In the display device 23, the corresponding level of the content of combustible gas will be displayed on the digital panel, and at the output of the telemetry amplifier 13 there will be a current signal corresponding to the content of combustible gas.

The third mode: the content of combustible gas in the atmosphere is above the first limit value, but below the second limit value (for example, above 195 vol. part, but below 295 vol. part). The state of switches 16, 17 and 18 "remains unchanged, because the level of combustible gas content does not exceed the level of settings of limit devices 7) with 14 and 22. This means that the signals from the measuring circuits of low 4 and high 5 concentrations after amplification and . rectification will fall on the inputs of limit devices 8, 12, 14 and 22. Since the level of signals exceeds the activation set point of only the second limit device 12, only at its output the signal changes from the level of logical one to the level of logical zero, at the output of limit devices 8, 14 and 22 signals will remain unchanged, that is, there will be a logic one. The signal from the first output of the boundary device 12 enters the

Ge" device for the formation of telesignaling signals U, where the signal for triggering the light signaling at the first limit level is formed and enters the input of the light signaling device 10. From the second output - limit device 12, a signal is sent to the time relay 15, from where the signal is sent to the third input of the signal generation device

The telesignaling system 9 receives a signal that forms a command to turn off technological objects according to the first 5p limit level with a time delay, and which from the second output of the telesignaling signal generation device 9 - enters the first input - the output of the PPV converter 2 and the signaling device 1. In the display device 23, the corresponding level of the content of combustible gas will be displayed on a digital display (above 195 parts by volume, but below 290 parts by volume) and at the output of the telemetry amplifier 13 there will be a continuous current signal corresponding to the content of combustible gas. 5B Fourth regime: the content of combustible gas in the atmosphere is above the second limit value, but below the third specified limit value (for example, above 295 vol. part, but below 595 vol. part). State of switches 16,

P 17 and 18 remains unchanged, because the level of combustible gas content did not exceed the level of settings of limit devices 14 and 22. The level of signals exceeds the settings of activation of limit devices 8 and 12, and at their outputs the level changes from the level of logical one to the level of logical zero, and at the outputs of limit devices 14 and 22, the signals remain unchanged, that is, there will be a logical unit. Signals from the outputs of limit devices 8 and 12 enter the device for generating telesignal signals 9, where a signal for triggering the light alarm at the first and second limit levels is formed and enters the input of the light signaling device 10. From the second output of the telesignaling signal generating device 9 to the first input - output of the PIPV converter 2 and the signaling device 7, a signal to disconnect 65 technological objects according to the second level of activation is received. In the display device 23, the level of the content of combustible gas will be displayed on the digital panel, and at the output of the telemetry amplifier 13 there will be a current continuous signal corresponding to the content of combustible gas (above 2905 parts by volume, but below 595 parts by volume).

Fifth mode: the content of combustible gas in the atmosphere is above the third specified limit value, but below the fourth limit value (for example, above 595 parts by volume, but below 1095 parts by volume). In this mode, signals

From the measuring circuits, low 4 and high concentrations, after amplification and rectification, will enter the inputs of limit devices 8, 12, 14 and 22. The signal levels are such that they exceed the trigger settings of limit devices 8, 12 and 14. Limit device 22 will remain in the initial position. Exceeding the setpoints of the limit devices 8 and 12 will lead to a state similar to their state in the fourth mode, and exceeding the setpoint of the limit device 14 will lead to a change in the control signals on the switches 16, 17 and 18 and lead them to another 7/0 state, which will also lead to an electrical the system circuit is also in a different state, that is, the connections between the system devices are changed. A change in the signals at the output of the fourth boundary device 14 and, accordingly, at the third control inputs of the second 16, third 17 and fourth 18 switches will lead to a change in the state of the switches. The signal from the fifth input of the second switch 16 will pass to the first output of the second switch 16 and, accordingly, to the inputs of the first 8 and second 12 limit devices, the signal from the first input 7/5 of the Switch 16 will pass to the input of the fourth switch 18 and, accordingly, from output of the linearizer 21, the same signal will pass to the output of the third switch 17 and, accordingly, to the input of the display device 23, where the readings on the scale of high concentrations corresponding to the content of combustible gas in the atmosphere will be displayed on the digital panel. From the output of the fourth switch 18 to the input of the telemetry amplifier 13, a signal from the path of the measuring circuit 5 of high concentrations will be received. This signal will be intermittent. The frequency of interruptions will be determined by the frequency received at the fifth control input of the switch 18 from the first output of the time relay 15. A current intermittent signal will be output from the output of the telemetry amplifier 13, which will correspond to the content of combustible gas on the scale of high concentrations.

The sixth mode: the content of combustible gas in the atmosphere is above the fourth set limit value (for example, above 1095 parts by volume and up to 10095 parts by volume). In this mode, the signals from the measuring circuits of low 4 and high 5 concentrations, after amplification and rectification, will arrive at the inputs of limit devices 8, 12, 14 and 22. The signal levels are such that they will exceed the trigger settings of all limit devices. At the same time, the state of the electrical circuit will not change, because the signal from the output of the limit device 22, which will arrive at the fourth control inputs of the second 16, third 17 and fourth 18 switches, will not change their state. At the same time, if in this measurement range a signal is received from the measuring circuit of low 4 concentrations, the level of which will be below the trigger settings of limit devices 8, 12 or 14, i.e., the unambiguity of the readings of the measuring circuit of low 4 concentrations will be violated, the signal from the output of the boundary device 22 everything will be equal "7 to keep the switches 16, 17 and 18 in the same state. Bringing the switches 16, 17 and 18 to a state similar to their state in the fourth mode is possible only if from the outputs of the boundary devices 14 and 22, the control inputs of switches 16, 17 and 18 will receive signals of the logical unit level. --

Thus, in comparison with known technical solutions, the proposed system for controlling the content of combustible gas in the mine atmosphere provides unambiguous control and measurement of the content of combustible gases in the range from 0 to 10095 parts by volume, provides the possibility of using existing communication channels and information presentation devices on the surface of the mine. The elements of the system are implemented on samples and elements that are serially produced, for example, blocks 1, 3, 4...20 can be implemented according to schemes similar to the blocks of methane analyzers AT1.1, ATZ.1 | see, for example, Stationary monitoring equipment Methane in furnaces with laboratory works // E. F. Karpov, B. I. Basovsky, E. Sh. Landa et al. - Labor safety in industry. - M.:

Nedra, Mo2, 1991. - P. 2 - 8). Switches 16, 17, 18 can be implemented on microcircuits K561KP2.

Claims (1)

;" The formula of the invention The system for monitoring the content of combustible gas in the mine atmosphere, containing an alarm device, the input-output of which is connected to the input-output of the converter of the measuring parameters, to the input-output of which the power supply unit is connected, the first output of which is connected to the first input of the measuring the circuit of low concentrations of combustible gas, the second input of which is connected to the output of the first switch, the output of the measuring circuit - the circuit of low concentrations of combustible gas is connected in series with the first large-scale amplifier, the first kch active rectifier, which differs in that in order to increase the reliability of control of safe working conditions according to the gas factor, expansion of functional capabilities, a measuring circuit of high methane concentrations was introduced, connected in series with the second scale amplifier, the second active rectifier, linearizer, the third limiting device, the output of which is connected to the first inputs of the second, third, fourth switches, the input of the third boundary device is connected to the second by the inputs of the second and third switches, the first output of the third switch is connected to the input of the indicating device, the third input of the third switch is connected to the second output of the first active rectifier and the third input of the second switch, the first output of which is connected to the inputs of the first and second limit devices, the second output of the second switch is connected to the second input of the fourth switch, the fourth input of the third switch is connected to the third input of the fourth switch, the fourth input of the second switch and the output of the fourth limit device, the input of which is connected to the first output of the first active rectifier and the fifth input of the second switch, the first output of the time relay is connected to the fourth input of the fourth switch, the output of which is connected to the input of the telemetry amplifier, and the fifth input of the fourth switch is connected to the "minus" of the power supply unit 65, "plus" of the power supply unit is connected to the sixth input of the second switch, the first and second outputs of the second limit switch devices are connected to the second input of the time relay and the first input of the telesignaling device, respectively, the output of the time relay is connected to the second input of the telesignaling device, the first output of which is connected to the light signaling device, and the second output to the input-output of the converter measuring parameters. « «- «- (Se) «- (Se) - with . and? (o) - (o) - 70 - 60 b5