RU143487U1 - PIEZO-ELECTRIC MOVING ACCELEROMETER SENSOR - Google Patents

Abstract

1. A piezoelectric shear sensor of the accelerometer, comprising a housing, a cylindrical housing base with two symmetrically arranged struts, the cross section of which is in the form of circle segments mounted on each of the flat opposite sides of the struts of the piezoelectric elements, an inertial body in the form of a parallelepiped, the opposite planes of which are paired with piezoelectric elements, a clamping ring mating with the cylindrical sections of the racks, and a sensor current output mounted on the housing with sockets the method, characterized in that the piezoelectric elements are equipped with electrodes and are electrically isolated from the racks, the unipolar sides of the piezoelectric elements with the electrodes are located symmetrically with respect to the inertial body, and all unipolar electrodes are electrically connected to each other and simultaneously with their current output, while the sensor housing is made in the form of a conjugated to the base of a pipe section with a cover and sockets of a connector of the current leads of the electrodes of the piezoelectric elements mounted on the cover, which are the current leads of the sensor. 2. The piezoelectric sensor according to claim 1, characterized in that the piezoelectric elements are made in the form of packages of piezoelectric plates with electrodes, adjacent unipolar sides of the piezoelectric plates are connected through a common electrode and are located symmetrically relative to the inertial body.

Description

The utility model relates to the field of instrumentation and can be used to measure the parameters of mechanical vibrations of objects.

Accelerometers in which piezoelectric shear deformations are used to determine object motion parameters compared to other types of accelerometers using other types of deformations, for example, compression or bending, are known (M. Serridge, Torben R. Licht. Piezoelectric accelerometers and preamplifiers. Reference for theory and exploitation. "Larsen and the son." Gloustrup, Denmark, 1987 - 187 c).

Piezoelectric shear sensors of accelerometers have a low pyroelectric effect, consisting in the reaction of the sensor element to the effect of temperature changes, including spasmodic, due to the symmetric change in the size of the sensor constituent elements, mainly along its sensitivity axis, and in the perpendicular directions. The sensors have low deformation sensitivity and can be made small-sized with small masses, which allows them to be used for diagnostics on small moving objects, such as cars, engines, individual elements of aircraft, etc.

The well-known "Piezoelectric sensor" RU 2289821, G01P 15/09, 12/20/2006, the sensitive element of which experiences shear deformation under mechanical loads.

The known sensor contains a base in the form of a glass with a lid and coaxially mounted annular piezoelectric element and inertial body fixed in the glass on its walls. The base and inertial body are equipped with electrical leads connected to the registration unit of the accelerometer.

A known piezoelectric sensor operates as follows.

Under the influence of vibrational acceleration along the axis of sensitivity of the sensor, the sensor piezoelectric element in contact with the inertial body and the walls of the base glass experiences shear deformation, and an electric charge is formed on the cylindrical surfaces of the piezoelectric element, the magnitude of which is proportional to the magnitude of the acting acceleration. Registration of the generated charge is carried out through current outputs connected to the base and inertial body.

For reasons that impede the achievement of the following technical result when using the known device, is the influence on the output signal of the sensor of an additional interference signal induced by external fields at the base of the sensor.

Also known is the piezoelectric shear sensor of the accelerometer ("Shear type accelerometer" WO 9409373, G01P 15/09, 1994-04-28), which, by the combination of essential features, is the closest analogue of the claimed device.

Known piezoelectric shear sensor of the accelerometer, contains a housing and a cylindrical base with two symmetrically arranged racks, the cross section of which has the form of circle segments. Piezoelectric elements are installed on each of the flat opposite sides of the racks, between which an inertial body in the form of a parallelepiped is placed, the opposite planes of which are paired with the piezoelectric elements. Racks along their cylindrical sections are covered by a clamping ring. The base and inertial body are equipped with current leads connected to an electrical connector on the side wall of the housing.

A known piezoelectric sensor operates as follows.

Under the influence of vibrational acceleration along the axis of sensitivity of the sensor and the resulting reaction of the inertial body to acceleration, the piezoelectric elements undergo shear deformation, and an electric charge is formed on their surfaces, the magnitude of which is proportional to the magnitude of the acting acceleration. Registration of the generated charge is carried out through an electrical connector connected via current leads to the base and inertial mass.

For reasons that impede the achievement of the following technical result when using the known device, is the influence on the output signal of the sensor of an additional interference signal induced by external electromagnetic fields and / or external electric potentials in the base of the sensor housing. The interference signal, in particular, can be caused both from the electromagnetic field of the measurement object and from electrical contact with it and electrical contact with the available, as a rule, screen of the sensor’s communication line with the accelerometer registration unit.

The task to which the claimed utility model is directed is to increase the accuracy of measuring the parameters of mechanical vibrations of objects.

The technical result obtained by the implementation of the claimed utility model consists in eliminating the influence on the output signal of the sensor of an additional interference signal induced by external electromagnetic fields and / or external electric potentials in the base or body of the sensor by eliminating the electrical contact of the piezoelectric elements with the base and body of the sensor.

The specified technical result in the implementation of the utility model is achieved by the fact that in the inventive piezoelectric shear sensor of the accelerometer, comprising a housing, a housing base with two symmetrically arranged racks, the cross-section of which has the form of circle segments mounted on each of the flat opposite sides of the piezoelectric racks placed between them an inertial body in the form of a parallelepiped, the opposite planes of which are paired with piezoelectric elements, a clamping ring mating with the cylinder unlike the known sensor, the piezoelectric elements are provided with electrodes and are electrically isolated from the racks, the unipolar sides of the piezoelectric elements with electrodes are located symmetrically with respect to the inertial body, and all unipolar electrodes are electrically connected to each other and simultaneously with their current output, In this case, the sensor housing is made in the form of a pipe segment with a cap coupled to the base and piezoele electrode sockets for connecting the current leads of electrodes mounted on the cap ENTOV which are current leading sensor.

The specified technical result in the implementation of the utility model is also achieved by the fact that in the inventive piezoelectric sensor, the piezoelectric elements are made in the form of packages of piezoelectric plates with electrodes, the unipolar sides of the piezoelectric plates are connected through a common electrode and are located symmetrically relative to the inertial body.

In FIG. 1 shows the inventive piezoelectric shear sensor with two piezoelectric elements, containing one piezoelectric plate with electrodes; in FIG. 2 is a view of its cross section; in FIG. 3 shows the inventive piezoelectric shear sensor with piezoelectric elements from two packages containing two piezoelectric plates with electrodes; in FIG. 4 is a view of its cross section.

The piezoelectric shear sensor of the accelerometer contains (Fig. 1 and Fig. 2) a cylindrical base 1 with two symmetrically arranged racks 2 and 3, the cross-section of which has the shape of circle segments. On each of the flat opposite sides of the racks 2 and 3, piezoelectric elements (piezoelectric plates) 6 and 7 with electrodes on each of their polarized sides (±) 6 and (±) 7 are installed on the insulating gaskets 4 and 5, respectively, on the piezoelectric element 6 - electrodes 8 (+6) and 9 (-6), and on the piezoelectric element 7 - electrodes 10 (+7) and 11 (-7).

An inertial body 12 is placed between the piezoelectric elements 6 and 7 with the electrodes 12. In this case, the unipolar sides of the (±) 6 and (±) 7 piezoelectric elements with the electrodes, for example, 8 (+6) and 10 (+7), are oriented symmetrically with respect to the inertial body 12.

A clamping ring 13 is mounted on the cylindrical sections of the struts 2 and 3 of the base 1.

All unipolar electrodes 8 (+6) and 10 (+7), as well as 9 (-6) and 11 (-7) are electrically connected to each other and simultaneously with their current output, respectively, electrodes 8 (+6) and 10 (+ 7) - with current output 14 (+), and electrodes 9 (-6) and 11 (-7) - with current output 15 (-).

To increase the sensor output signal, it is advisable to perform the piezoelectric elements 6 and 7 in the form of two packets, for example, of two piezoelectric plates with their own electrodes in each packet. It has been practically established that up to eight piezoelectric plates can be used in each package depending on their thickness, however, a possible increase in the number of piezoelectric plates in the package leads to a decrease in the thickness of the inertial body 12, a decrease in its mass, and, as a result, the effect of increasing the number piezoelectric plates will be compensated, and the design of the accelerometer sensor and assembly technology are significantly complicated.

In this case, each of the piezoelectric elements 6 and 7 of the sensor is made in the form of packages of two piezoelectric plates with its own electrodes (±): the piezoelectric element 6 is made in the form of a package of piezoelectric plates 16 and 17, and the piezoelectric element 7 is in the form of a package of piezoelectric plates 18 and 19 (Fig. 3 and Fig. 4).

For a sensor with such piezoelectric elements, adjacent unipolar, for example, with a negative potential, sides of the package of piezoelectric plates (-) 16 and (-) 17 and sides of the package of piezoelectric plates (-) 18 and (-) 19, not adjacent to the inertial body 20 located between them, are connected through common electrodes, respectively, 21 (-) and 22 (-), are located symmetrically with respect to the inertial body 20, are electrically connected to each other and simultaneously with their current output 23 (-). Accordingly, the electrodes 24 (+) and 25 (+) of the sides of the piezoelectric plates (+) 16 and (+) 17 with positive potential, as well as the electrodes 26 (+) and 27 (+) of the sides of the piezoelectric plates (+) 18 and (+) 19 with the same positive potential, they are electrically connected to each other and simultaneously with their current output 28 (+).

The sensor housing, which forms a closed shielded inner space around the sensing element, is made in the form of a pipe segment 29 and a cover 30 connected to the base 1 with a socket of a connector 31 (+) mounted on it and connected to a current output 14 (+) or 28 (+), and the socket of the connector 32 (-) connected to the current output 15 (-) or 23 (-). Both connectors 31 (+) and 32 (-) are the sensor current outputs.

The piezoelectric shift sensor of the accelerometer works as follows.

When operating under the influence of vibrational acceleration along the axis of sensitivity of the sensor communicated to him by the measurement object, and the resulting reaction of the inertial body to acceleration, the piezoelectric elements 6 and 7 experience shear deformation, and on their surfaces (±) 6 and (±) 7 isolated from the base 1 corresponding electric charges are generated, the magnitude of which is proportional to the magnitude of the acting acceleration.

Electric charges are removed from the surfaces of the piezoelectric elements (±) 6 and (±) 7 using electrically connected electrodes 8 (+6) - 10 (+7) and 9 (-6) - 11 (-7) and through the current outputs connected to them , respectively, 14 (+) and 15 (-), charges are supplied to the connectors 31 (+6) and 32 (-), connected via a usually shielded communication line to the registration unit (not shown in the drawing).

During operation of the sensor, both external electromagnetic fields and the electromagnetic field of the measurement object together with its electric potential create their electric potential in the base 1, in the sensor housing and in the possibly available conductive extended screen of the sensor communication line with the registration unit (not shown in the drawings). Electrical isolation from the base 1 of the sensor of the piezoelectric elements 6 and 7 and their placement in a shielded enclosed space eliminates the influence of external factors that create interference signals on the accuracy of measuring the vibration parameters of the object.

The manufacture in an enclosed shielded space of electrically isolated piezoelectric elements 6 and 7 (Fig. 1 and Fig. 2), made in the form of packages of piezoelectric plates (Fig. 3 and Fig. 4), for example, from two parallel (±) pairs of piezoelectric plates connected by polarized sides: 16-17 and 18-19 with their electrodes 24 (+) - 21 (-) - 25 (+) and 26 (+) - 22 (-) - 27 (+) and the corresponding current outputs 23 (-) and 28 (+ ) connected to the connectors 31 (+) and 32 (-), can significantly increase the output signal of the sensor, because Packs of piezoelectric plates undergo shear deformations, each of which generates its own charge. At the same time, the capacitance of the sensor and its conversion coefficient are increased with the exception of the effect on the sensor output signal of an additional interference signal induced by external electromagnetic fields and / or external electric potentials in the base or body of the sensor.

Thus, it can be seen that the above information confirms the possibility of implementing a utility model, achieving the specified technical result and solving the problem.

Claims (2)

1. A piezoelectric shear sensor of the accelerometer, comprising a housing, a cylindrical housing base with two symmetrically arranged struts, the cross section of which is in the form of circle segments mounted on each of the flat opposite sides of the struts of the piezoelectric elements, an inertial body in the form of a parallelepiped, the opposite planes of which are paired with piezoelectric elements, a clamping ring mating with the cylindrical sections of the racks, and a sensor current output mounted on the housing with sockets the method, characterized in that the piezoelectric elements are equipped with electrodes and are electrically isolated from the racks, the unipolar sides of the piezoelectric elements with the electrodes are located symmetrically with respect to the inertial body, and all unipolar electrodes are electrically connected to each other and simultaneously with their current output, while the sensor housing is made in the form of a conjugated to the base of a pipe section with a cover and sockets of the connector of the current leads of the electrodes of the piezoelectric elements mounted on the cover, which are the current leads of the sensor. 2. The piezoelectric sensor according to claim 1, characterized in that the piezoelectric elements are made in the form of packages of piezoelectric plates with electrodes, adjacent unipolar sides of the piezoelectric plates are connected through a common electrode and are located symmetrically relative to the inertial body.