CS260655B1 - Device for pyroelectric materials' properties measuring and testing - Google Patents

Abstract

The solution relates to the construction of the test Equipment for pyroelectric materials a solves the problem of shielding parasitic radiation as well as unwanted electrical fields as well as achievement, geometric constancy of the device behind the purpose of obtaining stable and reproducible measurement results. The nature of the device is that the pyroelectric sensor is removably mounted in an electrical shielded connector open in the direction of the breaker infrared radiation that is attached to the electrically shielded impedance receptacle converter. Between the infrared breaker radiation and the electrical sensor is thermally stabilized reference infrared radiation source. This the reference source is shielded to pyroelectric sensor and its emission surface is reversed to the infrared interrupter movable screen radiation.

Description

BACKGROUND OF THE INVENTION The present invention relates to a device for measuring and testing properties of pyroelectric materials, in particular for work on optimizing pyroelectric sensor parameters.

It is already known to measure and test the properties of pyroelectric materials using a device comprising a controllable infrared radiation source, a light breaker and a pyroelectric detector, the input of which is a pyroelectric sensor.

Such devices are generally composed of various components available in laboratory practice and their durability, reliability and reproducibility of the results depend on the quality and arrangement of the elements used. As a rule, the question of the elimination of parasitic radiation, the shielding of unwanted electric fields, and the geometrical stability of the assembly, which is usually disassembled into individual elements after completion of a series of works, are then strictly not followed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a device for measuring and testing the properties of pyroelectric materials in which standard known elements such as a controllable infrared radiation source, an interruption device and a pyroelectric detector, the input of which is a pyroelectric sensor, are complemented by other measures. equipment providing time-stable measurement results free from parasitic influences.

260 655

SUMMARY OF THE INVENTION The pyroelectric sensor is interchangeably housed in an electrically shielded connector open in the direction of the infrared interrupter, which connector is attached to an electrically shielded impedance converter housing connected to the pyroelectric sensor output. The device is provided with a reference source of infrared radiation in an autostabilized version. This reference infrared radiation source is arranged between the infrared interrupter and the pyroelectric sensor. It is expediently shielded from the pyroelectric sensor and, with its emission surface, faces the movable orifice plate of the infrared interrupter. Alternatively, an autostabilized infrared radiation source may be provided on the movable orifice of the infrared interrupter on the side facing the pyroelectric sensor.

The output of the impedance converter is connected to a synchronous detector coupled to the infrared interrupter and to the output of the synchronous detector connected to the evaluation device. In a simpler version, a selective amplifier adjusted to the frequency of the infrared interrupter may be connected to the output of the impedance converter.

The electrically shielded connector for the pyroelectric sensor comprises a metal tube which is divided by an axial plane into a fixed part and a movable part, which are connected together by a hinge and a lock, and in both parts there is a teflon electrically insulating filler with straight contacts for pyroelectric sensor terminals.

The effect of the present solution is that the device provides long-term stable and reliable reproducible measurement results with easy interchangeability of tested pyroelectric sensors.

260 655

The electrically shielded connector allows the exchanged pyroelectric sensors to be always placed in exactly the same position in the infrared beam path. The responses of these sensors are not affected by the parasitic electric fields and by placing the impedance transducer as close to the pyroelectric sensor as possible, the high impedance signal is transformed into a low impedance, interference-free signal.

The thermally autostabilized design of the reference source simplifies the operation of the entire device by eliminating the need for further stabilization of the reference source temperature.

1 shows a schematic diagram of the individual mechanical and electronic parts of the apparatus, FIG. 2 shows a basic assembly of the basic parts of the apparatus with respect to their mutual geometrical arrangement, and FIG. 3 shows a two-part electrically shielded connector for receiving the pyroelectric sensor.

According to FIG. 1, the device consists of an infrared radiation source 1 having a temperature regulator 2, downstream of which there is an aperture diaphragm 2 and an interrupter 4 with a respective power supply 6 of the interrupter 4.

Furthermore, a pyroelectric sensor 6 is provided with an impedance converter 2 and a source 8 of converter 2. The converter 6 is connected to a synchronous detector 2, which again has its own source 10. Behind it is provided either an analog pointer 11 _} or a digital pointer 12.

The infrared radiation source 1 emits a radiant flux which, upon impact on the absorption electrode of the pyroelectric sensor 6, converts into heat, causing an overall temperature rise of the pyroelectric sensor 6. This results in a change in the spontaneous polarization of the pyroelectric sensor 6 material as a result of the polarization balance

- 4,260,055 effect. This current is proportional to the temperature change over time. Therefore, the pyroelectric sensor 6 is insensitive to continuous radiation and the signal response occurs only when the radiation is interrupted. For this purpose, it is necessary to include an interrupter 2 with an appropriate source 2 in the infrared path. The aperture diaphragm 2 calibrates the cross-section of the infrared beam, i.e., shields the radiant heat at the unusable emission surface of the infrared source 1. This source 1 may advantageously be a temperature standard usually referred to as an absolutely black body. It is a cylinder in which an emission cone is formed to form a cavity, the reflectance of which is negligibly small, so that it absorbs all radiation incident on it. If the black body is maintained at a certain temperature by a temperature regulator 2 supplying the electrical resistance winding within the cylinder, a precisely defined radiant flux emerges from the cavity. Measurements are generally carried out at a temperature of Τ = 5θθ ° K.

The electrical spare circuit of the pyroelectric sensor 2 represents a current source with a parallel capacitor connected. This combination gives the pyroelectric sensor 6 a high impedance character and therefore an impedance converter 2 has been connected to the pyroelectric sensor 2 output providing low impedance transformation. The pyroelectric sensor 6 in conjunction with the impedance converter 2 represents a pyroelectric detector.

From the infrared interrupter 2, it is possible to derive pulses controlling the synchronous detector 2 provided with the power supply 10.

At the output of the synchronous detector 2 ^{, a} rectified voltage ^is drawn for the evaluation device, which is an analog indicator 11 or a digital indicator 12. As mentioned above, a selective amplifier that operates at the frequency of the infrared interrupter 6 can be used instead of the synchronous detector 2.

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The last member of the evaluation circuit is either an analog pointer 11 _; or digital indicator 12 «If there is a need to adjust the signal level for either of these indicators 11 or 12, either a synchronous detector j ^ or a suitable amplifier may be inserted either

Fig. 2 shows a grouping of the main members of the device along the optical axis, as well as the electrical coupling between them.

The infrared radiation emits from the source 1, schematically in the section shown as an absolutely black body with a conical emission cavity, the radiation passes through the aperture iris diaphragm and is intermittently transmitted to the pyroelectric sensor f, followed by an impedance converter 4.

The interrupter 8 is actuated by an oscillating movement by the source f0, and a signal introduced as a control signal to the synchronous detector f0 is derived from this movement, followed by the aforementioned indicators 11 or 12.

An infrared reference source 13 in a thermally autostabilized embodiment is included in the assembly. The body of this reference source 13 is of the order of millimeter dimensions and is positioned such that its radiation is shielded from the pyroelectric sensor 6 while impinging on the reflective surface of the interrupter 8 at an angle such that the reflected radiation flow completely covers the absorption electrode of the pyroelectric sensor fa.

The body of the infrared reference source 13 is formed of a ferroelectric substance; the plate with two opposing electrodes forms a ferroelectric capacitor, which is heated by its own dielectric losses by alternating voltage of a suitable frequency and amplitude.

The equilibrium state of thermal autostabilization is established under the conditions of equilibrium between the electrical heating input from the source and the power radiated from the condenser to the surroundings.

FIG. 3 shows, in the open state, a two-part electrically shielded connector for the pyroelectric sensor 6. This connector is formed by a metal tube which divides the axial plane into a fixed part 14 and a movable part 15. The two parts 14 and 15 are connected together by means of a hinge 16 and a lock 17. In both parts 14, 15 a Teflon electrically insulating filler 18, 18 'is provided with straight contacts 19, 19' for the pyroelectric sensor terminals.

A fixed portion of the connector is attached to an electrically shielded housing 20 in which the impedance converter 2 of the pyroelectric sensor 6 is arranged.

The device according to the invention can also be used as an infrared radiometer with all its positive effects.

In this case, the pyroelectric sensor 2 will be a permanent part of the evaluation circuit, and instead of the infrared radiation source 1 with the temperature controller 2, the measured object or the measured object is placed in front of the aperture iris 2. the device comes to such an object. However, the output indicators 11 and 12 will be calibrated according to the intended use.

Claims (8)

SUBJECT OF THE INVENTION 260 655 Apparatus for measuring and testing pyroelectric materials, comprising a controllable infrared radiation source, an interrupter, and a pyroelectric detector, the input of which is a pyroelectric sensor, characterized in that the pyroelectric sensor (6) is interchangeably housed in an electrically shielded connector open in to an infrared interrupter (4), the connector being attached to an electrically shielded housing (20) for an impedance converter (7) connected to the output of the pyroelectric sensor (6). Device according to claim 1, characterized in that it is provided with a reference source (13) of infrared radiation in a thermally autostabilized version. Device according to Claims 1 and 2, characterized in that the thermally stabilized infrared reference source (13) is arranged between the infrared interrupter (4) and the pyroelectric sensor (6). Device according to Claims 1, 2 and 3, characterized in that the thermally autostabilized reference source (13) of the infrared radiation is shielded from the pyroelectric sensor (6) and with its emission surface faces the movable screen of the infrared radiation interrupter (4). Device according to Claims 1 and 2, characterized in that the thermally stabilized infrared reference source (13) is provided on the movable orifice plate of the interrupter (4) on the side facing the pyroelectric sensor (6). Device according to claim 1, characterized in that a synchronous detector (9) coupled to an infrared interrupter (4) is connected to the output of the impedance converter (7) and an evaluation device is connected to the output of the synchronous detector (9). Device according to claim 1, characterized in that a selective amplifier adjusted to the frequency of the infrared interrupter (4) is connected to the output of the impedance converter (7). Device according to claim 1, characterized in that the electrically shielded connector for the pyroelectric sensor (6) is formed by a metal tube which is divided by an axial plane into a fixed part (14) and a movable part (15) which are connected to each other. a rotatable hinge (16) and a lock (17), and in both parts (14, 15) there is provided a teflon electrically insulating filler (18, 18 *) with straight contacts (19, 19 *) for the pyroelectric sensor terminals (6). 3 drawings