RU2396732C1 - Ultrasonic piezoelectric converter - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: ultrasonic piezoelectric converter includes branch pipe (1), acoustic line from electrically conducting material (2), insulator (4) providing non-supply of voltage to piezoelectric element (5) from fault currents and voltages from operating electric equipment in pipeline with controlled medium, piezoelectric element (5), supply conductors (10), damping device from electric insulating material (6), spring (7), hollow cylindrical housing (3) and cover (8) with hole (9), which provides rigid fixation of parts.

EFFECT: providing protection against false electric signals.

1 dwg

Description

The proposed technical solution relates to the field of instrumentation, and can be used to measure the parameters of the controlled environment in the pipeline with higher accuracy and less impact of external noise.

Similar technical solutions are known, see, for example, US patent No. 4297607, which contains the following set of essential features:

- pipe;

- a steel tread fixed in the region of the lower end of the pipe;

- a hollow cylindrical body located inside the pipe and installed with its lower base on the upper surface of the steel tread;

- a sound pipe made of an electrically conductive material located inside a hollow cylindrical body and installed with its lower surface on the upper surface of the steel tread;

- a piezoelectric element located inside the hollow cylindrical body, mounted with its lower surface on the upper surface of the sound duct;

- a composite damper located inside the hollow cylindrical body, mounted with its lower surface on the upper surface of the piezoelectric element;

- an insulator located inside the hollow cylindrical body and mounted on the upper surface of the composite damper;

- a cover mounted on the upper end of the pipe and located on its upper surface on the upper surface of the insulator and on the upper base of the hollow cylindrical body.

Common features of the proposed technical solution and the above described analogue are:

- pipe;

- a hollow cylindrical body located inside the pipe;

- a sound pipe made of an electrically conductive material and located inside a hollow cylindrical body, in the region of its lower base;

- a piezoelectric element located inside the hollow cylindrical body, mounted with its lower surface on the upper surface of the sound duct;

- a damper located inside the hollow cylindrical body and mounted with its lower surface on the upper surface of the piezoelectric element;

- an insulator located inside a hollow cylindrical body;

- a cap mounted on the upper end of the pipe and located on its upper surface on the upper base of the hollow cylindrical body;

A similar technical solution is also known (see US patent No. 3925692), which is selected as a prototype and which contains the following set of essential features:

- pipe;

- a sound pipe made of an electrically conductive material and installed inside the lower end of the pipe;

- a hollow cylindrical body located inside the nozzle and installed with its lower base on the upper surface of the sound duct;

- a piezoelectric element located inside the hollow cylindrical body and installed with its lower surface on the upper surface of the sound duct;

- a damper located inside the hollow cylindrical body and mounted with its lower surface on the upper surface of the piezoelectric element;

- a spring located inside the hollow cylindrical body and installed with its lower end on the upper surface of the damper;

- an insulator located inside the hollow cylindrical body and mounted on the upper end of the spring;

- a cover mounted on the upper end of the pipe and located on its upper surface on the upper surface of the insulator and on the upper base of the hollow cylindrical body.

Common features of the proposed technical solution and prototype are:

- pipe;

- a sound pipe made of an electrically conductive material and installed inside the lower end of the pipe;

- a hollow cylindrical body located inside the nozzle and installed with its lower base on the upper surface of the sound duct;

- a piezoelectric element located inside a hollow cylindrical body;

- a damper located inside the hollow cylindrical body and mounted with its lower surface on the upper surface of the piezoelectric element;

- a spring located inside the hollow cylindrical body and installed with its lower end on the upper surface of the damper;

- an insulator located inside a hollow cylindrical body;

- a cap mounted on the upper end of the pipe and located on its upper surface on the upper base of the hollow cylindrical body.

The technical result, which cannot be achieved by any of the similar technical solutions, consists in eliminating the stresses appearing on the piezoelectric element that appear in the pipeline with a controlled medium due to stray currents, and voltages from working electrical equipment (pumps, etc.) that fall into the pipeline with controlled environment.

The reason for the impossibility of achieving the above technical result is that the established practice of creating ultrasonic piezoelectric transducers is an issue related to the protection of piezoelectric elements from false electrical signals arising from voltages appearing in the pipeline with a controlled environment due to stray currents and voltages from working electrical equipment (for example, pumps, etc.), does not pay due attention.

Given the characteristics and analysis of known similar technical solutions, we can conclude that the task of creating ultrasonic piezoelectric transducers that have the necessary protection against false electrical signals arising from voltages that appear in the pipeline with a controlled environment due to the presence of stray currents, and voltages from the working electrical equipment and, as a result, having a higher noise immunity of ultrasonic piezoelectric transducers, is relevant for today one day.

The technical result indicated above is achieved by the fact that in an ultrasonic piezoelectric transducer containing a pipe, a sound pipe installed inside the lower end of the pipe, a hollow cylindrical body located inside the pipe and installed with its lower base on the upper surface of the sound pipe, a piezoelectric element located inside the hollow cylindrical body , a damper located inside the hollow cylindrical body and mounted with its lower surface on the upper surface a piezoelectric element, a spring located inside the hollow cylindrical body and installed with its lower end on the upper surface of the damper, an insulator located inside the hollow cylindrical body, and a cover mounted on the upper end of the pipe and located on its upper surface on the upper base of the hollow cylindrical body, the damper is made of electrical insulation material, the insulator is installed with its lower surface on the upper surface of the sound duct and its upper surface on the bottom surface of the piezoelectric element, and the upper end of the spring is located on the inner surface of the cover.

The implementation of the damper from an insulating material, the location of the insulator and the upper end of the spring, as described above, allows you to create the design of the proposed ultrasonic piezoelectric transducer, in which when applying voltage to the piezoelectric terminals from the output of the ultrasonic frequency electrical signal source, convert this voltage to ultrasonic signals and provide radiation of a part of them through an insulator and sound duct into a controlled environment of the pipeline and to ensure absorption of their other hour ty damper. And when there are voltages from stray currents and voltages from working electrical equipment (for example, pumps, etc.) falling into a pipeline with a controlled environment, prevent them from entering the piezoelectric element both from the side of the sound pipe and from the side of the damper spring, spring-loaded relative to the inner surface and thus provide the necessary protection against false electrical signals. In this, the achievement of the technical result indicated above is manifested.

The proposed ultrasonic piezoelectric transducer is illustrated by the following description and drawing, which shows the ultrasonic piezoelectric transducer.

The proposed ultrasonic piezoelectric transducer contains:

branch pipe - 1;

sound pipe - 2, made, for example, of stainless steel and installed inside the lower end of the pipe - 1;

- hollow cylindrical metal casing - 3, located inside the nozzle - 1, installed with its lower base on the surface of the upper base of the sound duct - 2;

- insulator - 4, made, for example, of polycor and installed at its bottom

surface on the upper surface of the sound duct - 2;

- a piezoelectric element - 5, located inside a hollow cylindrical metal case - 3, mounted with its lower surface on the upper surface of the insulator - 4 and connected by conductors - 10 to the terminals of the ultrasonic frequency electrical signal source (the position of the ultrasonic frequency electrical signal source is not shown in the drawing);

- damper - 6, located inside the hollow cylindrical metal casing - 3 and installed with its lower surface on the upper surface of the piezoelectric element - 5, while the damper - 6 is made of electrical insulating material, such as fiberglass;

- spring - 7, located inside the hollow cylindrical metal casing - 3 and installed with its lower end on the upper surface of the damper - 6,

- cover - 8 with a hole - 9, mounted on the upper end of the pipe - 1 and located on its upper surface on the upper surface of the base of the hollow cylindrical metal casing - 3 and on the upper end of the spring - 7.

The proposed ultrasonic piezoelectric transducer operates as follows.

By means of a threaded connection or by welding, the body of the nozzle - 1 of the ultrasonic piezoelectric transducer is fixed in the hole made in the pipe wall in order to load the piezoelectric transducer on a controlled medium. In this case, electrical contact inevitably arises between the pipeline with the controlled medium, on the one hand, and the elements of the proposed ultrasonic piezoelectric transducer, on the other hand, as a result of which voltages from stray currents and voltages from working electrical equipment (for example, pumps, etc.), pipelines with a controlled environment can get on the piezoelectric element - 5 of the ultrasonic piezoelectric transducer and cause the appearance of false signals.

When applying piezoelectric element-5 through the conductors -10 voltage from the output of the source of electrical signals of ultrasonic frequency, the piezoelectric element-5 converts this voltage into ultrasonic signals and emits them. In this case, part of the energy of ultrasonic signals is radiated into the damper - 6 and absorbed by it, and part of the energy of ultrasonic signals is radiated to the insulator -4 and through it to the sound duct - 2, the length of which is equal to the length of the near zone of the piezoelectric pattern - 5 in the sound duct material, which ensures focusing of the ultrasonic beam at the end of the sound pipe (outer, lower surface) and the emission of ultrasonic signals into the controlled medium of the pipeline. When exposed to a piezoelectric element, 5 voltages from stray currents and voltages from working electrical equipment (for example, pumps, etc.) falling into a pipeline with a controlled environment, which can reach quite large values, false signals are excited in it. To eliminate this phenomenon in the proposed ultrasonic piezoelectric transducer between the upper surface of the sound pipe - 2 and the lower surface of the piezoelectric element - 5 install an insulator - 4, which prevents the influx of stresses appearing in the pipeline with a controlled environment from stray currents, and voltages from operating equipment falling into the pipeline with a controlled environment, on the piezoelectric element - 5, and thus provides the necessary protection for the piezoelectric element - 5 from false electrical signals.

Thus, the proposed ultrasonic piezoelectric transducer, due to the isolation of the piezoelectric element from the sound duct and the casing, prevents the influx of voltages from stray currents and voltages from working electrical equipment appearing in the pipeline with a controlled medium to the piezoelectric element and ensures its protection from false electrical signals. Which, in turn, when using the proposed ultrasonic piezoelectric transducer in various systems of ultrasonic control of the parameters of the controlled medium in the pipeline provides higher measurement accuracy. Therefore, the proposed ultrasonic piezoelectric transducer will take its rightful place among the known objects of a similar purpose.

Claims (1)

An ultrasonic piezoelectric transducer comprising a pipe, a sound pipe installed inside the lower end of the pipe, a hollow cylindrical body located inside the pipe and installed with its lower base on the upper surface of the sound pipe, a piezoelectric element located inside the hollow cylindrical body, a damper located inside the hollow cylindrical body and installed by lower surface on the upper surface of the piezoelectric element, a spring located inside the hollow a cylindrical body and installed at its lower end on the upper surface of the damper, an insulator located inside the hollow cylindrical body, and a cover mounted on the upper end of the pipe and located on its upper surface on the upper base of the cylindrical hollow body, characterized in that the damper is made of electrical insulation material, and the insulator is installed with its lower surface on the upper surface of the sound duct and its upper surface on the lower surface with a piezoelectric coagulant, and the upper end of the spring is located on the inner surface of the cover.