KR19990055093A - High Power Shear Acceleration Sensor - Google Patents

Abstract

The present invention relates to a high output shear type acceleration sensor with excellent assembly workability and improved output characteristics.

A feature of the present invention is that four piezoelectric elements, one each on both sides of two inertial masses, are disposed, and these piezoelectric elements are simply bolted to be pressed and supported by a pair of sensor bases provided with bolt-nut grooves and bolt through holes. To assemble and manufacture shear type acceleration sensors.

The sensor structure of the present invention is excellent in output characteristics by omitting a special additional process such as low temperature treatment for assembling using the restoring force of the shape memory alloy and fastening the piezoelectric element, the center support, and the inertial mass with a constant torque using a direct bolt. The advantage is that the manufacturing assembly process is simple.

Description

High Power Shear Acceleration Sensor

The present invention relates to a structure of a high output acceleration sensor, and more particularly, by placing an inertial mass between a piezoelectric element and a coupling jig in the manufacture of a shear type acceleration sensor, thereby fastening a larger number of piezoelectric elements in a conventional delta shear type. The present invention relates to a high output shear type accelerometer which improves the output and improves assembly workability.

In the case of rotary machines used in industrial sites, since the rotation speed is mostly 1800 RPM or less, the frequency of the vibration is less than 30 Hz, so the magnitude of vibration is quite small.

An acceleration sensor for detecting vibration acceleration of such a rotating body is usually manufactured by increasing the size of the piezoelectric element or increasing the inertial mass for high power. In this case, the size of the entire acceleration sensor becomes large, which makes it difficult to mount it inside the machine.

In order to solve this problem, the sensor output can be increased by increasing the number of piezoelectric elements irrespective of the size of the sensor, and an amplification circuit is installed in the impedance converter unit that converts the charge generated in proportion to external vibration to a high output. Can be obtained.

1 is a configuration diagram of a conventional delta shear type acceleration sensor, and the piezoelectric element 23, the inertial mass 21, and the center support 24 are joined using a fixing ring 22 made of a shape memory alloy. In addition to preventing bending, three piezoelectric elements can be used to obtain high output.

FIG. 2 is a cross-sectional view of the AA ′ cross-section of FIG. 1, in which an insulating epoxy and an insulating ceramic are applied at an appropriate ratio between a base 25 of the accelerometer and a base support base plate 32 at a thickness of about 1 mm, and then 150 ° C. Heat-cure at about 30 minutes to form an insulating layer that insulates the outside from the acceleration sensor.

The center support 24 is installed on the components subjected to the above process, the inertial mass 21 and the piezoelectric element 23 are surrounded by a fixed ring 22 which has been subjected to low temperature, and then the temperature is applied so that they are completely combined, and then the piezoelectric element The electrode of (23) is connected to the impedance transducer (5) and bonded using a high temperature adhesive on the fastened inertial mass (21).

Thereafter, the internal signal line 27 is connected to the connector 30 having the external signal line 29 and the waterproof sensor is bonded to cover the acceleration sensor housing 31.

However, in the conventional sensor manufactured in such a form, three piezoelectric elements 23 are fastened between the inertial mass 21 and the center support 24 by using a fixing ring 22, such as a shape memory alloy. Special materials should be used, and the inertial mass 21 is in the form of an arc corresponding to one-third of the circle, which makes it difficult to manufacture using tungsten.

An object of the present invention, in the shear type acceleration sensor, two inertial masses of the cube is placed between the jig for coupling with the central support and four piezoelectric elements can be installed on both sides of the inertial mass to enable high-power acceleration sensing It is to provide a shear type acceleration sensor.

1 is a plan view of a conventional Delta Shear type acceleration sensor.

FIG. 2 is a cross-sectional structural view taken along the line AA ′ of FIG. 1.

3 is a planar structural diagram of a shear type acceleration sensor according to the present invention.

4 is a cross-sectional view taken along the line AA ′ of FIG. 3.

* Explanation of symbols on the main parts of the drawing *

1 sensor base 2 insulation layer

3: intermediate support 4: joining jig

5: impedance converter 6: inertial mass

7: piezoelectric element 8: internal signal line

9: coaxial cable 10: external signal line

11 connector 12 sensor housing

13: base plate 14: nut

15: Fixing bolt

Referring to the accompanying drawings, the shear acceleration sensor of the present invention will be described.

As shown in FIG. 3, the sensor structure of the present invention aligns two coupling jig 4, two inertia mass 6 in the form of a cube, and four piezoelectric elements 7 in the form of a square, and then fixes the bolt 15. The fixing nut 14 has a structure of fastening with a constant torque of 4kgf-cm.

4 is a cross-sectional view taken along line AA ′ of FIG. 3, wherein an insulating epoxy and an insulating ceramic are mixed between the base 1 of the accelerometer and the base support base plate 13 at an appropriate ratio and coated to a thickness of about 1 mm. It has been shown to insulate the outside and the interior of the acceleration sensor by forming an insulating layer 2 by heating and curing at 150 ° C. for about 30 minutes.

Subsequently, a central support 3 for transmitting external vibrations transmitted to the base to the piezoelectric element is installed on the parts subjected to the above process, and the inertial mass 6 and the piezoelectric element 7 are aligned using the coupling jig 4. Then, the fixing bolt 15 is used to fasten the piezoelectric element 7, the inertial mass 6, and the coupling jig 4 with a constant torque.

The jig 4 functions to couple the central support, the piezoelectric element, and the inertial mass.

After connecting the electrode to the impedance converter (5) consisting of a circuit that converts the charge generated in proportion to the external vibration in the form of voltage, and then bonded using a high temperature adhesive on the coupling jig (4).

The internal signal line 8 is connected to the connector 11, the acceleration sensor housing 12 is waterproofed and bonded, and finally, the external signal line 10 of the coaxial cable 9 is connected to the external system.

The shear type acceleration sensor of the present invention has a high output compared to the conventional method by using four piezoelectric elements, unlike the existing delta shear type, and does not require a separate atmosphere condition for the assembly work. Workability is excellent.

The relation between the output value of the acceleration sensor and the number of piezoelectric elements is as follows.

Q = nd ₁₅ m _s a

Where Q is the output charge value (pC / g), n is the number of piezoelectric elements, d15 is the piezoelectric charge constant (pC / g), and a is the acceleration value.

As given in the above formula, as the number of piezoelectric elements n increases, the acceleration sensing output value increases proportionally.

In addition, in the present invention, since the inertial mass has the shape of a cube, there is no problem when machining tungsten, and a fixed jig is manufactured by using a stainless steel, and a jig is manufactured by using a bolt to combine the cold jig at a low temperature during manufacturing and assembly. Process can be reduced, making a significant contribution to cost reduction.

As described above, the present invention can omit a special additional step such as low temperature treatment during assembly by using the restoring force of the shape memory alloy when fabricating and assembling the shear type acceleration sensor, thereby increasing the assembly productivity and directly using the piezoelectric element using a bolt. The output characteristics are excellent by fastening the center support and the inertial mass with a constant torque, and high output is obtained by using a plurality of piezoelectric elements.

Claims (2)

Piezoelectric elements 7 are arranged on both sides of the inertia mass 6 of the pair of cubes, and two jigsaw masses having piezoelectric elements on both sides of the intermediate support 3 are interposed therebetween. The high output shear type acceleration sensor which arrange | positions (4) and is bolted by fixed torque at both sides of the said jig | tool is comprised. 2. The high power shear type according to claim 1, wherein an insulating layer is formed by mixing and curing ceramic and epoxy to maximize the insulation and vibration transfer between the base of the piezoelectric element and the bottom plate of the center support when casing the acceleration sensor. Acceleration sensor.