JPH0519904U - Strain sensor - Google Patents

Abstract

(57) [Abstract] [Purpose] It is possible to paste accurately and efficiently at a predetermined measurement position and measurement direction on the surface of a measured object having a complicated shape. A sensor main body is arranged at an opening position in a housing having at least one surface opened, and the sensor main body is supported by a gel-like filler filled in the housing and formed toward the outside of the opening of the housing. The flange portion is provided with a fixing hole for fixing the housing to a locking portion provided in advance on the surface of the object to be measured, and further, a screw hole is provided on a surface facing the opening of the housing. . And
With the housing fixed to the surface of the object to be measured, a screw for pressurizing is screwed into the screw hole so that the tip of the screw presses the sensor main body to the surface of the object to be measured through the gel filler. Further, a lead wire for leading the strain signal of the sensor body to the outside of the housing is provided.

Description

[Detailed description of the device]

[0001]

[Industrial application]

 The present invention relates to a strain sensor for measuring strain generated on the surface of an object to be measured, and more particularly to a strain sensor in which a sensor body is housed in a housing in advance.

[0002]

[Prior Art]

 For example, in various types of machinery, we regularly monitor that the machine is operating normally, and inspect and repair the part that has an abnormality before it becomes a major accident if an abnormality occurs. Has been done.

As the simplest device for detecting the occurrence of an abnormality in such a mechanical system, for example, an acceleration sensor is attached to the outer surface of a bearing of a rotary shaft, and the acceleration vibration of the bearing is monitored by an accelerometer. A vibration monitoring device is used that outputs an alarm when the acceleration vibration exceeds a predetermined threshold.

However, in general, the acceleration greatly changes depending on the rotation speed of the shaft, and therefore the method of detecting abnormal vibration by the acceleration sensor greatly reduces the reliability in the low speed rotation state.

In order to eliminate such an inconvenience, a strain sensor is directly attached to a bearing or the like, the amount of strain generated due to abnormal vibration is directly measured, and the load applied to the bearing is calculated from the amount of strain. Then, a monitoring device has been proposed that outputs an alarm when this load exceeds a certain threshold.

[0006]

[Problems to be solved by the device]

 However, even in the method of directly attaching the strain gauge to the surface of the measured object such as the bearing as described above, there are still the following problems to be solved.

That is, in an object to be measured having a complicated shape such as a bearing, when a load (stress) is applied from the outside, the stress distribution becomes complicated. Therefore, the strain distribution also has a complicated shape. As a result, the measured strain amount changes greatly depending on the position and direction of the strain gauge applied. In mechanical equipment, there are many bearings of the same standard. When monitoring the loads applied to each of these bearings at the same time, it is naturally necessary to attach strain gauges to each bearing under the same conditions.

However, it is very difficult to attach the strain gauges to the same position and the same direction of each bearing. Especially when the object to be measured such as a bearing is small, much labor and time are required for its positioning work.

Further, the strain gauge is generally adhered to the surface of the object to be measured with an adhesive such as an epoxy resin, but in general, the epoxy resin adhesive requires a certain period of time to cure, and during that period. It is necessary to press the strain gauge on the surface of the object to be measured. If this jig for pressure contact is not specially prepared, put a heavy object or use a spring clip. However, there is a concern that the strain sensor position that was accurately positioned would be displaced during this pressure contact process.

The present invention has been made in view of such circumstances, and by housing the sensor main body in the housing and fixing the entire housing to a locking portion provided in advance on the measured object, An object of the present invention is to provide a strain sensor capable of accurately fixing the sensor body at a predetermined position and direction, greatly improving the work efficiency of mounting on the surface of the object to be measured, and capable of always detecting a correct strain amount. To do.

[0011]

[Means for Solving the Problems]

 In order to solve the above-mentioned problems, the strain sensor of the present invention has a housing having an opening on at least one surface, a sensor main body arranged at an opening position in the housing, and a housing filled with the sensor and supporting the sensor main body. Gel filling material, a flange portion that is formed toward the outside of the opening of the housing, and a fixing hole that is drilled in this flange portion and that fixes the housing to a locking portion that is provided in advance on the surface of the measured object. Holes, screw holes formed on the surface facing the opening of the housing, and with the housing fixed to the surface of the object to be measured, by screwing into the screw holes, the tip of the screw inserts a gel filler. It is equipped with a pressure screw for pressing the sensor body against the surface of the object to be measured, and a lead wire connected to the sensor body and leading a strain signal out of the housing.

[0012]

[Action]

 According to the strain sensor thus configured, the engagement portion is provided on the surface of the measured object at a position facing the fixing hole of the flange portion of the housing. Therefore, if the flange portion is fixed to the locking portion using, for example, a fixing screw, the mounting position on the surface of the measured object of the housing is uniquely determined.

A sensor main body is arranged at an opening position facing the surface of the object to be measured in the housing, and the sensor main body is fixed at the opening position by a gel filler filled in the housing. Therefore, when the housing is fixed to the surface of the object to be measured, the sticking position of the sensor body on the surface of the object to be measured is uniquely determined.

After that, if the pressurizing screw is screwed into the screw hole formed at the position opposite to the opening in the housing, the gel filler filled inside is biased toward the opening. The sensor body is pressed against a predetermined position on the surface of the object to be measured.

[0015]

【Example】

 An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is an external view showing a strain sensor of an embodiment, and FIG. 2 is a sectional view. In the figure, reference numeral 1 denotes a housing formed by bending a strip-shaped metal plate into a substantially U-shaped cross section. A screw hole 2 is formed at a central position of the roof portion 1a of the housing 1. Then, the space formed by the roof portion 1a, the side surface portions 1b, 1b, and the lower opening 1c is filled with a gel filler 3 such as silicon. Therefore, the position of the lower surface of the gel filler 3 coincides with the position of the opening 1d at the lower end of the housing 1.

On the lower surface of the gel-like filler 3, a thin film-like main body 4 is attached to the center of the opening 1d of the housing 1. For example, five lead wires 5 are led out from the main body 4 through the inside of the gel filler 3 from the side surface of the gel filler 3 to the outside of the housing 1. Then, the five lead wires 5 are assembled into a flexible flat cable.

Flange portions 1e and 1f are formed by bending outward on both sides of the opening 1d at the lower end of the housing 1. Then, fixing holes 6a and 6b are formed in the central portions of the flange portions 1e and 1f.

Further, a pressurizing screw 7 is prepared in which a screw groove to be screwed into a screw hole 2 formed in the roof portion 1a of the housing 1 is engraved. A straight groove is formed on the upper end of the pressure screw 7 for screwing the pressure screw 7 into the screw hole 2 with a screwdriver.

In the gauge body 4, for example, as shown in FIG. 4, six thin film resistors R1 to R6 are deposited on the insulating thin film substrate by using the plasma CVD method to form the thin film resistors R1 to R6. Similarly, a metal thin film formed by a photoetching method on an insulating thin film substrate is connected in a double bridge method. The thin film resistors R1 to R4 form a first Wheatstone bridge circuit 4a, and the thin film resistors R3 to R6 form a second Wheatstone bridge circuit 4b.

Of the six thin film resistors R1 to R6, two thin film resistors R1 and R3 have a gauge factor G and a temperature coefficient K is the other four thin film resistors R2, R4, R5 and R6. And the temperature coefficient K are set to orders of magnitude larger than the temperature coefficient K. Further, only one thin film resistor R1 among the six thin film resistors R1 to R6 has its strain detection direction aligned with the direction parallel to both side surface portions 1b and 1c of the housing 1. The strain detection directions of the other five thin film resistors R2 to R6 are set to be in a direction orthogonal to the strain detection direction of the thin film resistor R1.

Therefore, in the state where the DC amount reference voltage is applied between both terminals G 1 and E 2 of the first and second Wheatstone bridge circuits 4a and 4b, the voltage difference between the respective middle points of the first Wheatstone bridge circuit 4a ( It is possible to extract Vb-Va) as a distortion detection signal and the voltage difference (Vc-Vb) at each midpoint of the second Wheatstone bridge circuit 4b as a temperature detection signal.

The size of the gauge body 4 is, for example, about [4.4 mm (horizontal) × 3.4 mm (vertical)]. Therefore, the size of the housing 1 is about [8 mm (horizontal) × 6 mm (vertical; strain detection direction) × 3 mm (height)] at the most.

FIG. 3 is a schematic sectional view showing a state where the strain sensor is actually attached to the surface 8 of the object to be measured. The strain measurement position on the surface 8 of the object to be measured and the direction of strain measurement at the position are predetermined according to the shape of the object to be measured. Then, fixing screw holes 8a and 8b as two locking portions for attaching the housing 1 are engraved on a line orthogonal to the strain measuring direction centering on the measuring position.

Then, with the adhesive applied to the surface of the gauge body 4, the fixing screws 9a and 9b are attached to the fixing screw holes 8a and 8b through the fixing holes 6a and 6b of the blange portions 1e and 1f. The housing 1 is screwed and fixed to the surface 8 of the object to be measured. Therefore, the lower surface of the gauge body 4 accurately faces the strain measurement position. Further, the strain detecting direction of the entire gauge body 4 indicated by the strain detecting direction of the thin film resistor R1 also coincides with the strain detecting direction to be accurately measured.

Then, in this state, the pressing screw 7 is screwed into the screw hole 2 of the roof portion 1a by using a screwdriver or the like. When the pressurizing screw 7 is screwed in, the tip of the pressurizing screw 7 urges the gel filler 3 toward the surface 8 of the object to be measured, so that the gauge main body 4 moves to the surface 8 of the object to be measured. Is pressed against. By using the gel filler 3, the rotational movement of the lower end surface of the pressurizing screw 7 is not transmitted to the sensor body 4, and only the pressure contact pressure with respect to the measured object surface 8 is applied to the sensor body 4. .

Then, this state is maintained until the adhesive is cured. When the adhesive has hardened, the pressure screw 7 is removed.

In the case of the strain sensor configured as described above, at the measurement point on the surface 8 of the object to be measured where the strain is to be measured in advance, at a predetermined interval in the direction orthogonal to the strain measuring direction, the fixing screw is attached. The holes 8a and 8b are engraved. Then, only by fixing the housing 1 in which the sensor body 4 is attached to the lower surface using the fixing screws 9a and 9b, the sensor body 4 faces the strain measurement position and the strain measurement direction which are set in advance accurately. . Then, the sensor main body 4 is adhered to the specified position on the surface 8 of the object to be measured in the specified direction only by screwing in the pressing screw 7.

The engraving work of the fixing screw holes 8a and 8b on the surface 8 of the object to be measured described above can be engraved with high accuracy by using a general machine tool. Even if a large number of fixing screw holes 8a and 8b are formed on the surface 8 of the object to be measured, the positions of the screw holes 8a and 8b for fixing are not greatly deviated between the surfaces 8 to be measured. Therefore, even if many strain sensors of the embodiment are mounted on the surface 8 of the object to be measured, the mounting positions and the mounting directions of the surface 8 of the object to be measured do not greatly change.

Therefore, the same signal processing can be performed on the strain signal obtained from each strain sensor attached to each surface 8 of the object to be measured.

Further, since the work of aligning the strain sensor with respect to the surface 8 of the body to be measured becomes almost unnecessary, the work efficiency of mounting the strain sensor is significantly improved. Furthermore, even an operator unfamiliar with the strain sensor installation work can easily and accurately install the strain sensor.

FIG. 5 is a diagram showing a case where the strain sensor of the embodiment is incorporated in an abnormality monitoring device for monitoring an abnormal load applied to the bearing. A pair of fixing screw holes 8a and 8b are preliminarily formed on the surface of the side surface 10a of the bearing 10 of the bearing in a direction orthogonal to the load direction indicated by an arrow in the figure. Then, the housing 1 is fixed in the fixing screw holes 8a and 8b. After that, the gauge main body 4 is attached in a predetermined position and in a predetermined direction by screwing in the pressure screw 7.

FIG. 6 is an actual measurement diagram showing the relationship between the load applied to the bearing 10 of the bearing described above and the output voltage of the strain detection signal extracted from the first Wheatstone bridge circuit 4 a of the sensor body 4. It was demonstrated that the load and the output signal have a good linear relationship.

As described above, the fixing screw holes 8a and 8b are provided in advance at the measurement positions on the surface 8 of the object to be measured, and the housing 1 in which the sensor main body 4 is incorporated is attached and fixed to the fixing screw holes 8a and 8b. , The mounting position and mounting direction of the sensor body 4 are automatically determined uniquely. Therefore, even if a large number of measured objects exist, each strain sensor can be mounted accurately, the measurement accuracy of each strain can be improved, and the variation in measured values between the measured objects can be minimized. .

The present invention is not limited to the above embodiment. In the sensor of the embodiment, as shown in FIGS. 1 and 2, from the manufacturing viewpoint, the front side and the rear side of the housing 1 are open, but the front side and the rear side are made of metal plates. It may be covered.

[0036]

[Effect of the device]

 As described above, according to the strain sensor of the present invention, the sensor main body is housed in the housing, and the entire housing is provided with a locking portion such as a fixing screw hole or the like, which is provided at the measurement position on the surface of the measured object in advance. It is fixed to. Therefore, the sensor body can be accurately attached and fixed at a predetermined measurement position and measurement direction. As a result, the mounting work efficiency on the surface of the object to be measured can be greatly improved, and the correct amount of strain can always be detected.

[Brief description of drawings]

FIG. 1 is a perspective view showing a schematic configuration of a strain sensor according to an embodiment of the present invention,

FIG. 2 is a sectional view showing the sensor of the embodiment.

FIG. 3 is a schematic cross-sectional view showing a state in which the sensor of the example is attached to a measured object,

FIG. 4 is a circuit diagram of a sensor body in the sensor of the embodiment,

FIG. 5 is a perspective view showing a bearing to which the sensor of the embodiment is attached,

FIG. 6 is a load / output characteristic diagram of the sensor of the embodiment.

[Explanation of symbols]

1 ... Housing, 1a ... Roof part, 1b, 1c ... Side part,
1d ... Opening, 1e, 1f ... Flange part, 2 ... Screw hole, 3
… Gel-like filler, 4… Geshi main body, 5… Lead wire, 6
a, 6b ... Fixing hole, 7 ... Pressurizing screw, 8 ... Object surface, 8a, 8b ... Fixing screw hole, 9a, 9b ... Fixing screw. 10 ... Bearing.

Claims (1)

[Scope of utility model registration request] 1. A housing having at least one open surface
(1), a sensor body (4) arranged at an opening position in the housing, a gel filler (3) for filling the housing and supporting the sensor body, and an opening of the housing A flange portion (1e, 1f) formed toward the outside of (1d), and a locking portion (8a,
8b) fixing holes (6a, 6b) and screw holes formed in the surface (1a) of the housing facing the opening.
(2) and, with the housing fixed to the surface of the object to be measured, screwed into the screw hole to press the sensor main body against the surface of the object to be measured through the gel filler at the tip thereof. A strain sensor having a pressurizing screw (7) for operating and a lead wire (5) connected to the sensor body and leading a strain signal to the outside of the housing.