DE19516974A1 - Photo-acoustic gas sensor for monitoring air-conditioned room - Google Patents

Abstract

A photoacoustic gas sensor for detecting the presence of e.g. CO2, CO, NO, etc. in a room has a measurement chamber (1) having an air filter (2) giving access to the atmosphere of the room (V). A controller (9) generates LF pulses (i1) for energising a piezo-electric loudspeaker (7) with response registered by a suitable low-cost microphone (5) whose output signal (S) is selectively amplified (6) and stored as a system response reference by the microprocessor (13) and memory (14). The controller (9) also pulses (i2) a light-source (4) which irradiates the chamber (1) via an optical bandpass filter (3) to promote excitation of e.g. CO2 molecules and give rise to a photo-acoustic response corrected against the stored reference for ageing and/or temperature and signalled (K) at the terminal (15).

Description

The invention relates to a photoacoustic gas sensor according to the preamble of Claim 1.

Such gas sensors are suitable, for example, for the detection of a specific gas or also for Determination of the concentration of a specific gas in a room.

Gas sensors of this type are advantageous in air conditioning technology in buildings for measuring the Concentration of carbon dioxide CO₂ used in a room.

A photoacoustic gas sensor of the type mentioned in the preamble of claim 1 is made EP 0 590 813 A1 and also generally known from photoacoustic spectrometry. Of the Photoacoustic effect, in which radiation energy is converted into sound energy, occurs in the gas sensor when, when irradiating intensity-modulated light of a certain wavelength into a gas, from Gas absorbed energy is converted into heat. The oscillations of pressure resulting in the gas or volume can be measured using a measuring microphone.

The known gas sensor only delivers a for a certain gas concentration over a longer period of time the temperature-independent output signal when the measuring microphone used in the gas sensor in is essentially independent of age and temperature and is therefore expensive. The manufacturing cost of the Known photoacoustic gas sensors are expensive due to the necessarily to be installed Measurement microphone significantly increased. The sensitivity of inexpensive microphones - for example Condenser microphones - is, however, in contrast to the sensitivity of measurement microphones, strongly depending on the temperature. Furthermore, the sensitivity of the inexpensive microphones is also still strongly age-dependent.

The invention has for its object a working on the photoacoustic principle To improve gas sensor so that even a microphone, the sensitivity of which strongly depends on the temperature and is dependent on aging, can be used in the gas sensor.

According to the invention, the stated object is achieved by the features of claim 1. Beneficial Refinements result from the dependent claims.

Exemplary embodiments of the invention are described in more detail below with reference to the single drawing figure explained.

The only drawing figure shows the photoacoustic gas sensor in a schematic representation.

In the single drawing figure, 1 denotes a measuring chamber of a gas sensor operating according to the photoacoustic effect. An air filter 2 is arranged on the measuring chamber 1 , through which a gas V to be detected by the gas sensor can be fed into the measuring chamber 1 . The measuring chamber 1 has an optical bandpass filter 3 , through which light of a certain wavelength λ can be radiated into the measuring chamber 1 . The gas sensor has a switchable light source 4 , by means of which a pulsating light beam impinging on the optical bandpass filter 3 can be generated. The spectrum of the light source 4 has at least the wavelength λ. A microphone 5 is also arranged on the measuring chamber 1 . The microphone 5 is advantageously followed by a selective amplifier 6 for amplifying an output signal S of the microphone 5 and for suppressing interference.

A controllable sound generator 7 is advantageously arranged on the measuring chamber 1 . In an advantageous embodiment of the gas sensor, the measuring chamber 1 has an opening 8 in the area of the sound generator 7 , which opening is covered by the sound generator 7 . By means of the sound generator 7 , a reference tone or a reference noise J for the calibration of the output signal S of the microphone 5 can advantageously be generated by a control device 9 . Forming the opening 8 has the advantage that with the sound generator 7, the reference noise J can be generated with the same power on the part of the control unit 9 with a larger sound level inside the measuring chamber 1 .

The sound generator 7 is a commercially available, inexpensive loudspeaker. A loudspeaker that works according to the reciprocal piezoelectric effect can advantageously be used. Speakers operating according to the reciprocal piezoelectric effect, with which loudspeakers can be used to convert an electrical voltage change into sound energy caused by crystal movement, are also referred to as piezo buzzers.

The control unit 9 advantageously has a first output 10 connected to the sound generator 5 for a first signal i 1 for generating the reference noise J. Furthermore, the control unit 9 advantageously has a second output 11 connected to the light source 4 for a second signal i 2 for modulation the intensity of the light source 4 . The second signal i₂ preferably has a frequency in the order of 20 Hz, whereby the light source 4 can be operated with a periodic pulse. The pulsating light source 4 may excite existing molecules in the measuring chamber 1 , which absorb light of the wavelength λ in a known manner, whereby noises generated by the photoacoustic effect are converted by the microphone 4 into the signal S. The amplifier 6 is advantageously connected on the output side to an input 12 of the control unit 9 .

Because the gas sensor has the sound generator 7 , an advantageous method for calibrating the gas sensor can be carried out. The procedure basically comprises the following steps:

• - A first step in which the reference signal J is generated by the first signal i 1 in the sound generator 7 , the light source 4 being advantageously switched off.
• A second step in which the signal S generated by the reference noise J in the microphone 5 is preferably selectively amplified and detected as a reference value R and
• a third step in which the reference value R is stored.

The output signal S of the microphone 5 generated by the photoacoustic effect and amplified by the amplifier 6 during a measurement of the concentration of the gas V in the gas sensor can be corrected by the control unit 9 by means of the reference value R.

The gas sensor can be calibrated using the method described above, preferably periodically, if necessary, with which the measurement errors caused by the temperature dependence of the microphone 5 or by its aging can be eliminated.

The control unit 9 advantageously has a microprocessor 13 and a memory 14 which can be used to store the reference value R. The reference value R is advantageously determined by the microprocessor 13 . Furthermore, the two signals i₂ and i₁ are advantageously generated and controlled using the microprocessor 13 . An output value K, which is advantageously determined by control unit 9, is available at a third output 15 . Depending on the requirements of the gas sensor, the measured value K is, for example, a measure of the concentration of the gas V. In a variant of the gas sensor, the measured value K is a binary value which indicates whether the concentration of the gas V exceeds a certain threshold value or not.

If the amplifier 6 is designed for the selective amplification of signals with the frequency of the signal i₂ or i₁, a disturbing noise of the signal S in the amplifier 6 is effectively suppressed.

Advantageously, the two signals i₁ and i₂ have the same frequency, so that electronic assemblies of the gas sensor, in particular the selective amplifier 6 , can be carried out inexpensively.

The optical bandpass filter 3 is advantageously designed in a known manner as an interference filter, the filter characteristic being designed for the gas V to be detected or measured. If the gas to be measured V is, for example, CO₂, then the optical bandpass filter 3 is transparent to infrared light of the wavelength of 4.25 μm, which means that the controlled light source 4 and the bandpass filter 3 periodically monochromatic light control of the wavelength of 4.25 μm in the Measuring chamber 1 is accessible.

The calibratable gas sensor with the sound generator 7 can in principle be designed in a known manner for measuring or detecting a specific gas, in particular the optical bandpass filter 3 being designed for the wavelength λ associated with the gas and the frequency of the two signals i 1 and i 2 being adapted if necessary. The calibratable gas sensor can be designed, for example, for measuring or detecting an oxygen or nitrogen compound such as CO, CO₂ or NO.

Claims (3)

1. Photoacoustic gas sensor with
a measuring chamber ( 1 ),
an air filter ( 2 ) arranged on the measuring chamber ( 1 ), through which a gas (V) to be detected by the gas sensor can be admitted into the measuring chamber ( 1 ),
an optical bandpass filter ( 3 ) arranged on the measuring chamber ( 1 ), through which light of a certain wavelength (λ) can be fed into the measuring chamber ( 1 ),
a switchable light source ( 4 ), by means of which a light pulse impinging on the optical bandpass filter ( 3 ) can be generated,
a microphone ( 5 ) arranged on the measuring chamber ( 1 ) and
with a selective amplifier ( 6 ) connected downstream of the microphone ( 5 ) for amplifying an electrical output signal (S) of the microphone ( 5 ),
characterized in that a controllable sound generator ( 7 ) is arranged on the measuring chamber ( 1 ), with which a reference noise (J) for calibrating the output signal (S) of the microphone ( 5 ) can be generated. 2. Photoacoustic gas sensor according to claim 1, characterized in
that the amplifier ( 6 ) is connected on the output side to an input ( 12 ) of a control unit ( 9 ),
that the control device ( 9 ) has an output ( 10 ) connected to the sound generator ( 7 ),
that from the reference signal (J) generated by the microphone ( 5 ) and amplified by the amplifier output signal (S) of the microphone ( 5 ) by the control unit ( 9 ) a reference value (R) can be calculated and stored in the control unit ( 9 ) and
that the output signal (S) of the microphone ( 5 ) generated by the photoacoustic effect and amplified by the amplifier ( 6 ) can be corrected by the control device ( 9 ) by means of the reference value (R). 3. Photoacoustic gas sensor according to one of claims 1 or 2, characterized in that the sound generator ( 7 ) is a speaker working according to the reciprocal piezoelectric effect.