RU175814U1 - GAS ANALYZER - Google Patents

Abstract

The utility model relates to portable gas analyzers designed to automatically measure the concentrations of toxic, poisonous and explosive gases present in the surrounding atmosphere. The claimed gas analyzer contains a sensor module that provides an output signal proportional to the concentrations of the components of the analyzed gas environment, a microcontroller connected to the sensor module, containing an information processing unit configured to generate an information output signal the current values of the analyzed component concentrations of the gaseous medium and an emergency output signal indicative of the threshold values are exceeded the analyzed gaseous medium component concentrations. A display for displaying information, an alarm tool and a keyboard are connected to the microcontroller. The microcontroller is equipped with a clock generating unit, a polling unit for the sensor module, the input of which is connected to the output of the sensor module, and the output is connected to the input of the information processing unit, the power mode control unit, and also the display brightness control unit, the input of which is connected to the output of the information processing unit, and the output is connected to the display input. The polling unit of the sensor module is configured to periodically transmit the output signal of the sensor module to the input of the information processing unit for a time corresponding to the duration of the clock pulses. The power mode control unit is configured to periodically disable the polling unit of the sensor module and the information processing unit from the power supply for a time corresponding to a pause between clock pulses. The display brightness control unit is designed to increase the brightness of the LEDs for the backlight of the display when a control signal generated by the information processing unit arrives at its input.The technical result is to minimize energy consumption, which reduces energy consumption during operation of the gas analyzer and increases its battery life. 1 n and 1 z.p. f-ly, 1 ill.

Description

The invention relates to portable gas analyzers designed to automatically measure the concentrations of toxic, poisonous and explosive gases present in the surrounding atmosphere, in particular carbon dioxide, oxygen, carbon monoxide, hydrogen sulfide and others.

Currently, portable gas analyzers are being actively developed, which allow for the rapid analysis of ambient air or a gas medium in off-laboratory conditions.

So known portable gas analyzer [RU 2408007], containing a sensor module made on the basis of one or more piezosensors, as well as a microcontroller (MK), designed to process the signal of the sensor module. The signal from the MK output corresponding to the content of the components of the gas mixture in the analyzed sample is transmitted to a digital display. All gas analyzer units are mounted in a single compact housing.

However, the gas analyzer in question does not contain an alarm system that is triggered when the current values of the concentrations of the components of the analyzed gas environment exceed their threshold values, which reduces the information content of the device.

Known portable gas analyzer [RU 127928], which is selected as the closest analogue.

This gas analyzer contains a sensor module that provides an output signal proportional to the content of the components of the analyzed gas medium, as well as a microcontroller connected to the sensor module. The microcontroller includes an information processing unit that generates an information output signal about the current values of the concentration of the components of the analyzed gas environment and an emergency output signal that carries information on exceeding the threshold values of the concentration of the components of the analyzed gas environment. The gas analyzer under consideration also contains a display connected to the microcontroller for displaying information, an alarm means and a keyboard with which the user controls the operation of the device.

Signals proportional to the measured content of the components of the analyzed gas medium from the output of the sensor module are continuously fed to the microcontroller. The microcontroller processes the information received from the sensor module and calculates the current concentration values of these components, which are displayed on the display. In addition, the microcontroller compares the current concentration values with threshold values and, if they are exceeded, an alarm is generated that is sent to the alarm facility, which uses LEDs and an acoustic emitter.

The presence of an alarm means increases the information content of the device.

However, in the gas analyzer under consideration, all units operate continuously, actively consuming electricity, which leads to relatively high energy costs and reduced battery life.

The problem to which the claimed utility model is directed is to reduce power consumption and increase battery life.

The essence of the utility model is that in a gas analyzer containing a sensor module providing an output signal proportional to the concentrations of the components of the analyzed gas medium, a microcontroller connected to the sensor module containing an information processing unit configured to generate an information output signal about current concentrations components of the analyzed gas environment and the emergency output signal that carries information on exceeding the threshold values of the centerings of the components of the analyzed gas environment, as well as a display for displaying information, an alarm device and a keyboard connected to the microcontroller, according to the utility model, the microcontroller is equipped with a clock pulse generating unit, a sensor module polling unit, the input of which is connected to the output of the sensor module, and the output is connected to the input the information processing unit, the power mode control unit, and the display brightness control unit, the input of which is connected to the output of the information processing unit, and the output d is connected to the input of the display, while the polling unit of the sensor module is configured to periodically pass the output signal of the sensor module to the input of the information processing unit for a time corresponding to the duration of the clock pulses, the power mode control unit is configured to periodically disable the polling unit of the sensor module and unit processing information from the power source for a time corresponding to a pause between clock pulses, and the display brightness control unit olnen secured increase the brightness of the backlight LED of the display when entering at its input a control signal generated by the information processing unit.

In the particular case of the utility model, the duration of clock pulses is from 10 to 40 ms, and their period is from 1.3 to 1.6.

A significant difference of the claimed device is the presence in the microcontroller of a clock pulse generating unit, a sensor module polling unit, as well as a power mode control unit.

Thanks to these blocks, the operation of the main components of the microcontroller, accompanied by active consumption of electricity, is controlled by clock pulses and is carried out periodically for a time corresponding to their duration.

In addition, the presence of a display brightness control unit in the microcontroller is of fundamental importance, due to which the brightness of the LEDs of its backlight is regulated, which is maintained at a low level in normal operating mode, which leads to a decrease in power consumption in the specified mode, and increases only by a control signal, generated by the information processing unit.

Thus, the technical result achieved by using the inventive utility model is to minimize energy consumption, which leads to lower energy consumption during operation of the gas analyzer and increase the battery life.

It is advisable that the duration of the clock pulses was from 10 to 40 ms, and their period was from 1.3 to 1.6 s. The specified parameters are selected experimentally and provide stable operation of the device while achieving significant energy saving and increasing battery life.

The figure shows a block diagram of the inventive device.

The gas analyzer contains a sensor module 1 connected to the microcontroller 2, as well as a display 3 connected to the microcontroller 2, an alarm means 4 and a keyboard 5.

The sensor module 1 is based on one or more sensors (in particular, from 1 to 5), which respond to the components of the analyzed gas medium, and is designed to generate an output signal proportional to the measured content of these components in the analyzed gas. In particular, the sensor module 1 comprises optical sensors for measuring the content of combustible gases and CO2 and electrochemical sensors for measuring the content of oxygen and toxic gases in the analyzed medium.

The microcontroller 2 includes an information processing unit 6, configured to calculate the current values of the concentrations of the components of the analyzed gas medium based on the signal from the output of the sensor module 1, and generate an information output signal 7 about the indicated current values of the concentrations transmitted to the display 3. Microcontroller 2 also configured to compare the current values of the indicated concentrations with threshold values and generate an alarm output signal 8 transmitted to the means 4 of alarm.

The alarm means 4, in particular, includes a light-emitting diode indicator, a sound emitter and a vibration alarm means, which is used as a vibration motor (not shown in the drawing).

The microcontroller 2, in particular, contains an analog-to-digital Converter 9, used in the case when the sensor module 1 contains sensors that generate output signals in analog form, and provides the conversion of these analog signals into digital form.

The gas analyzer is equipped with a non-volatile memory 10, designed to record the current values of the concentrations of the components of the analyzed gas medium, calculated in block 6.

The microcontroller 2 also comprises a polling unit 11 for a sensor module, a power mode control unit 12, and a clock pulse generating unit 13 connected to the blocks 11 and 12 and controlling their operation.

Block 11 provides a periodic passage of the signal from the output of the sensor module 1 to the input of block 6 at the moments when the block 13 generates clock pulses and is made, in particular, in the form of a logical coincidence circuit.

In this case, if the sensors that produce the output signals in analog form are used as part of the sensor module 1, block 11 ensures the passage of signals from these sensors to the input of block 6 after converting them into a digital form in converter 9.

Block 12 provides for periodic disconnection of blocks 11 and 6 (as well as block 9 when it is present in the microcontroller) from a power source (not shown in the drawing) during pauses between clock pulses generated by block 13. As a block 12, in particular, PWM generator configured to adjust the duty cycle of the pulse.

In addition, the microcontroller 2 includes a display brightness control unit 14, configured to increase the brightness of the radiation of the backlight LEDs of the display by a control signal 15 generated by the information processing unit 6.

The specified control signal 15 can be generated by block 6, in particular, in case of exceeding the current values of the concentrations of the components of the analyzed gas environment of their threshold values, as well as in the case of input to the input of block 6 from the output of the keyboard 5 when the user is working with it. As the block 14, in particular, a PWM generator can be used, which is configured to adjust the duty cycle of the pulse.

All of the above blocks and structural elements of the gas analyzer are connected in a single miniature housing.

The device operates as follows.

When the gas analyzer is turned on, the sensors included in the sensor module 1 react to the components of the analyzed gas medium, and the sensor module 1 generates an output signal proportional to the measured content of these components in the analyzed gas.

In the case of using as part of the sensor module 1 sensors that generate output signals in analog form, these output signals are converted in converter 9 into digital form.

Block 13 generates clock pulses that control the operation of block 11 in such a way that said block 11 provides a signal transmitted by the sensor module 1 to the input of block 6 at the moments when the block 13 generates clock pulses.

In block 6, the current values of the concentrations of the components of the analyzed gas medium are calculated and the corresponding information output signal 7 is generated, which is transmitted to display 3.

Information about the current values of the concentrations of the components of the analyzed gas medium from block 6 also enters the non-volatile memory 10.

The information on the display 3 is updated when the current values of the concentrations of the components of the analyzed gas medium change.

In order to reduce power consumption, block 12 disconnects block 11 and block 6, as well as block 9 from the power supply for a time corresponding to the pause between clock pulses generated by block 13. In addition, in the normal operating mode of the gas analyzer (in the absence of alarm 8) the brightness of the LEDs of the background illumination of the display 3 is minimal.

In case of exceeding the current values of the concentrations of the components of the gas environment of their threshold values, the unit 6 generates an alarm signal 8, transmitted to the means 4 of the alarm system.

In emergency operation of the gas analyzer, the indicator light, sound emitter and vibration alarm are triggered. In addition, in emergency operation, unit 6 generates a signal 15, according to which there is an increase in the brightness of the LEDs of the backlight of the display 3.

An increase in the brightness of the backlight of the display 3 also occurs in the case of a user using the keyboard 5.

Thus, the presence of blocks 11, 12, 13, 14 ensures the achievement of the main mode of operation of the gas analyzer, in which the blocks of the microcontroller 2 consume a minimum of electricity, and the brightness of the backlight of the display 3 is minimal.

Claims (2)

1. A gas analyzer containing a sensor module that provides an output signal proportional to the concentrations of the components of the analyzed gas environment, a microcontroller connected to the sensor module, containing an information processing unit, configured to generate an information output signal about the current values of the concentrations of the components of the analyzed gas environment and emergency output signal carrying information on exceeding threshold concentrations of components of the analyzed gas cf dy, as well as a display for information display connected to the microcontroller, an alarm means and a keyboard, characterized in that the microcontroller is equipped with a clock pulse generating unit, a sensor module polling unit, the input of which is connected to the output of the sensor module, and the output is connected to the input of the information processing unit power supply control unit, as well as a display brightness control unit, the input of which is connected to the output of the information processing unit, and the output is connected to the display input, while the sensor polling unit The module is designed to periodically pass the output signal of the sensor module to the input of the information processing unit for a time corresponding to the duration of the clock pulses, the power mode control unit is designed to periodically disconnect the polling unit of the sensor module and the information processing unit from the power source for a time corresponding to a pause between clock pulses, and the display brightness control unit is designed to increase the brightness of the LED The backlight of the display when entering at its input a control signal generated by the information processing unit. 2. The gas analyzer according to claim 1, characterized in that the duration of the clock pulses is from 10 to 40 ms, and their period is from 1.3 to 1.6 s.

Images