PL225525B1 - Photoacoustic chamber - Google Patents

Abstract

The subject of the invention is a photoacoustic chamber having main cavities which are connected by a main channel (2), thus creating a Helmholtz resonator. To both main cavities (1) are connected through channels (3). To the opposite ends of the through channels (3) are connected buffer cavities (4), and to them external channels (5), connecting the interior of the chamber with the environment. The volume of the buffer cavities (4) is much larger than the volume of the main cavities (1). In each of the main cavities is placed a microphone (6), and above each of the main cavities is placed a light source (7). The light beams (8) emitted by the light sources (7) and modulated in counterphase pass through windows (9) and induce a photoacoustic signal in the chamber, which is converted into an electrical signal by means of microphones (6) and subjected to differential detection. The length of the through channels (3) and external channels (5) corresponds to 1/4 of the acoustic wave length excited in the substance filling the chamber for the frequency at which the light beams (8) used to excite the photoacoustic effect are modulated. The chamber is symmetrical, and the plane of symmetry (10) is located halfway along the main channel (2) and is perpendicular to it.

Description

The subject of the invention is a photoacoustic chamber, which is an element of photoacoustic devices intended, in particular, to determine the physical and chemical properties of gases or liquids.

Many types of photoacoustic measuring chambers are known. One of the frequently used solutions of the photoacoustic measuring chamber is the Helmholtz resonator, which consists of two cavities connected by a channel. An important feature of such a chamber is that the resonance used in it does not arise based on the standing wave phenomenon, but is related to the cyclic pumping of gas or liquid through the channel connecting the cavities.

There are known, e.g. from the patent specification PL 210 128 B1, open photoacoustic chambers with a Helmholtz resonator. Open chambers allow for free exchange of the tested substance, i.e. liquid or gas, with the environment, which is their advantage over closed chambers. A significant disadvantage of an open photoacoustic chamber, however, is that acoustic disturbances occurring outside the chamber relatively easily penetrate its interior, disturbing the photoacoustic signal produced and measured therein, and consequently limiting the measurement sensitivity of such an open photoacoustic chamber.

Patent description PL 214 327 B1 describes the construction of an open photoacoustic Helmholtz chamber, in which the Helmholtz resonator is connected to acoustic filters consisting of passage channels, buffer cavities with volumes much larger than the volume of the cavity with the tested substance, and external channels connecting the buffer cavities with the tested substance. surroundings. With an appropriately selected length of the external channels, the acoustic impedance of these channels, seen from outside the chamber, is very high. Thus, the penetration of external acoustic disturbances into the chamber is reduced.

The essence of the invention is that to both main cavities of the chamber, forming the Helmholtz resonator, passageways are attached to which acoustic filters are attached, consisting of buffer cavities connected to the passageways, with volumes much larger than the volume of the main cavities of the chamber, to which are the buffer cavities. external channels are included connecting the buffer cavities to the environment.

With the construction of the chamber as in the invention, external acoustic disturbances penetrate in a similar way to both main cavities of the chamber. This means that the components of the same disturbing signal appearing in both main cavities have similar amplitude and phase. One of the important properties of the Helmholtz resonator is that in the case of operation at the resonant frequency, the transition of the acoustic signal from one cavity to another through the main channel is accompanied by a phase change by 180 °, which means that two components appearing in a given main cavity from this of the disturbance signal itself, one component of which is the result of the passage of the interference through the path composed of one external channel, the buffer cavity and the traverse channel, and the other component is the result of the passage of the interference through the path composed of the second external channel, the buffer cavity, the through channel, the second main cavity and the main channel will be out of phase and therefore cancel out partially. Consequently, in the solution according to the invention, the suppression of the penetration of external acoustic disturbances into the chamber interior is much stronger than in known solutions of open photoacoustic chambers with a Helmholtz resonator.

Preferably, the lengths of the passageways are selected so that, at the frequency on which the beam of light used to induce the photoacoustic effect is modulated, they correspond to 1/4 of the acoustic wave length generated in the substance to be tested, especially gas or liquid filling the chamber. With the length of the through-going channels selected in this way, their acoustic impedance, seen from the side of the main cavities of the chamber, is very high. As a result, the resonance of the chamber is very little dampened by the presence of through-channels and acoustic filters.

Preferably, the lengths of the external channels are selected such that, at the frequency on which the light beam used to induce the oral photoacchion is modulated, they correspond to 1/4 of the acoustic wavelength generated in the substance to be tested, in particular gas or liquid, filling the chamber. With the length of the external channels selected in this way, the acoustic impedance of the external channels, seen from the outside of the chamber, is very high. Thus, the penetration of external acoustic disturbances into the chamber interior is significantly reduced.

Preferably, the outer channels are parallel to each other with their outer ends on the same side of the chamber. In this case, the external acoustic disturbances at the ends of both external channels have very similar amplitudes and phases, and this leads to a strong cancellation of components from these disturbances in the main cavities of the chamber according to the invention.

Preferably, the internal structure of the chamber, i.e. the dimensions and position of the recesses and channels, has a plane of symmetry perpendicular to the main channel connecting the main cavities and lying halfway along the length of the main channel. In the case of such a symmetrical structure of the chamber, the acoustic properties of both tracks consisting of the external channel, the buffer cavity, the through channel and the main cavity are the same, and as a consequence, external acoustic disturbances passing through these chamber elements result in the formation of identical components in the main cavities of these disturbances. and it leads to a very effective cancellation of these components.

It is advantageous to place microphones in both main cavities, and then stimulate the test substance with a beam modulated with the resonance frequency of the chamber and detect the photoacoustic signal using a differential technique, i.e. by subtracting signals from the outputs of both microphones. Since for the resonance frequency the photoacoustic signal in both main cavities is in counter-phase and the external acoustic disturbances penetrating inside the chamber have the same phase, due to the subtraction of signals from both microphones, the amplitude of the photo-acoustic signal at the output of the subtractor will be doubled, and the components from external disturbances will be doubled. will be greatly reduced.

It is preferable to stimulate both main cavities of the chamber with light beams of the same wavelength and optical power, which light beams are counter-phase modulated at a frequency corresponding to the chamber resonance. Since for the resonant frequency the photoacoustic signal from a given light source in both main cavities is out of phase and each beam will produce the same photoacoustic signal component, the resultant photoacoustic signal amplitude will be doubled.

The advantages of the photoacoustic chamber and photoacoustic detection system according to the invention over the known photoacoustic chambers with a Helmholtz resonator are the much stronger suppression of the penetration of external acoustic disturbances into the chamber and the generation of a much weaker output signal from these disturbances, resulting in a significant improvement in the sensitivity of photoacoustic measurements.

The subject of the invention is presented in an exemplary embodiment in the drawing which shows a photo-acoustic chamber.

In the embodiment shown in the figure, the two main cavities (1) are connected by a main channel (2), thus forming a Helmholtz resonator for amplifying the photoacoustic signal. Through-ducts (3) are attached to both main cavities (1). The buffer cavities (4) are attached to the opposite ends of the through-flow channels (3), and the external channels (5) connect the chamber interior with the environment, thanks to which the test substance in the form of gas or liquid can freely flow into the main cavities (1). ) from outside the chamber. The volume of the buffer cavities (4) is much larger than the volume of the main cavities (1). A microphone (6) is placed in each of the main cavities, and a light source (7) is placed above each of the main cavities. The light beams (8) emitted by the light sources (7) and modulated in the counter-phase pass through the windows (9) and excite a photoacoustic signal in the chamber, which by means of microphones (6) is converted into an electrical signal and subjected to differential detection. The length of the through (3) and external (5) channels corresponds to 1/4 of the acoustic wave length excited in the substance filling the chamber for the frequency with which the light beams (8) are modulated and used to induce the photoacoustic effect. The chamber is symmetrical and the plane of symmetry (10) is in the middle of the main channel (2) and perpendicular to it.

Claims (7)

1. Photoacoustic chamber in the form of a Helmholtz resonator, for amplifying the photoacoustic signal, containing main cavities (1) connected with a channel and filled with the substance to be tested, characterized in that both main cavities (1) are connected to through-channels (3) to which filters are attached acoustics consisting of buffer cavities (4) connected to through channels (3) with volumes much larger than the cavities (1) and external channels (5) connecting the buffer cavities (4) with the surroundings. PL 225 525 B1 2. The photoacoustic chamber according to claim 1, The length of the passage according to claim 1, characterized in that the through-flow channels (3) preferably have a length such that at the frequency on which the light beam used to induce the photoacoustic effect is modulated, it corresponds to 1/4 of the acoustic wavelength generated in the tested substance, especially gas or the liquid filling the chamber. 3. The photoacoustic chamber according to claim 1 A method as claimed in claim 1, characterized in that the external channels (5) preferably have a length such that at the frequency on which the light beam used to induce the photoacoustic effect is modulated, it corresponds to 1/4 of the acoustic wave length generated in the substance, especially gas. or the liquid filling the chamber. 4. The photoacoustic chamber according to claim 1 A device according to claim 1, characterized in that the outer channels (5) are preferably parallel to each other and their outer ends are on the same side of the chamber. 5. The photoacoustic chamber according to claim 1 A device as claimed in claim 1, characterized in that it preferably has a plane of symmetry (10) perpendicular to the main channel (2) connecting the main cavities (1) and lying halfway along the length of the main channel (2). 6. The photoacoustic chamber according to claim 1 The method of claim 1, characterized in that microphones (6) for differential detection of the photoacoustic signal are provided in both main cavities (1). 7. The photoacoustic chamber according to claim 1 3. A method according to claim 1, characterized in that it is equipped with light sources generating counter-phase modulated light beams (8) transmitted through the cavities