JPWO2019159512A1 - Load sensor and load detector - Google Patents

Abstract

The load sensor according to the embodiment includes a strain generating body provided with a load receiving portion, an insulating layer provided on the strain generating body, and a first resistance portion provided on the insulating layer and connected in series. A second resistance portion and a first output terminal for outputting a voltage between the first resistance portion and the second resistance portion are provided, and the first resistance portion is connected in series and is circular or elliptical. It is provided with a plurality of first strain gauges arranged on the circumference of the first circle, and the second resistance portions are connected in series and arranged on the circumference of the second circle which is a circle or an ellipse. A plurality of second strain gauges are provided, and the first circle and the second circle are concentric circles or concentric ellipses centered on the load receiving portion.

Description

The present invention relates to a load sensor and a load detection device.

Conventionally, a load sensor using a strain gauge has been used. As such a load sensor, a bridge circuit is formed by four strain gauges arranged on a strain generating body, and a load is detected by the output voltage of the bridge circuit.

Japanese Patent No. 60784478

However, in the above-mentioned conventional load sensor, when the direction in which the load is applied is not perpendicular to the strain-causing body, there is a problem that the strain of the strain-causing body is biased and the load detection accuracy is lowered.

The present invention has been made in view of the above problems, and an object of the present invention is to improve the detection accuracy of a load sensor provided with a strain gauge.

The load sensor according to the embodiment includes a strain generating body provided with a load receiving portion, an insulating layer provided on the strain generating body, and a first resistance portion provided on the insulating layer and connected in series. A second resistance portion and a first output terminal for outputting a voltage between the first resistance portion and the second resistance portion are provided, and the first resistance portion is connected in series and is circular or elliptical. It is provided with a plurality of first strain gauges arranged on the circumference of the first circle, and the second resistance portions are connected in series and arranged on the circumference of the second circle which is a circle or an ellipse. A plurality of second strain gauges are provided, and the first circle and the second circle are concentric circles or concentric ellipses centered on the load receiving portion.

According to each embodiment of the present invention, the detection accuracy of the load sensor provided with the strain gauge can be improved.

The plan view which shows an example of the load sensor 100. The side view which shows an example of the load sensor 100. The figure which shows an example of the circuit structure of the load sensor 100. The figure which shows an example of a bed 200. A partially enlarged view showing an example of the leg portion 5 of FIG. FIG. 5 is a cross-sectional view of the leg portion 5 of FIG.

Hereinafter, each embodiment of the present invention will be described with reference to the accompanying drawings. Regarding the description of the specification and the drawings according to each embodiment, the components having substantially the same functional configuration are designated by the same reference numerals, and the superimposed description will be omitted.

<First Embodiment>
The load sensor 100 according to the first embodiment will be described with reference to FIGS. 1 to 3. The load sensor 100 according to the present embodiment is a sensor that detects an applied load and includes a strain gauge. A strain gauge is an element whose resistance value changes according to the strain. FIG. 1 is a plan view showing an example of the load sensor 100. FIG. 2 is a side view showing an example of the load sensor 100. Hereinafter, for convenience, the top, bottom, left, and right in the figure will be described as the top, bottom, left, and right of the load sensor 100.

As shown in FIGS. 1 and 2, the load sensor 100 includes a strain generating body 1, an insulating layer 2, a first resistance portion R1, a second resistance portion R2, a third resistance portion R3, and a fourth resistor. A unit R4, a first output terminal T1, a first output terminal T2, and a conversion circuit 3 are provided.

The strain generating body 1 is a plate-shaped member to which a load is applied, and is formed of a metal plate. The load sensor 100 detects the load applied to the strain generating body 1 by detecting the strain of the strain generating body 1 using a strain gauge. As shown in FIG. 1, the strain generating body 1 has a first portion 11 and a second portion 12.

The first portion 11 is a circular portion that is distorted in response to a load. The first portion 11 has a plurality of openings 13 on the outer peripheral portion, and the outer peripheral portion is fixed to the load detection target by inserting a bolt through each opening 13. Further, as shown in FIG. 2, a load receiving portion 14 for receiving a load from the detection target is provided at the center of the first portion 11. In this way, by fixing the outer peripheral portion of the circular first portion 11 and applying a load to the center, the strain of the first portion 11 according to the load can be made uniform.

In the example of FIG. 2, the load receiving portion 14 is a nut having a hemispherical head, and is provided on the lower surface of the strain generating body 1 through which a screw 15 provided on the upper surface of the strain generating body 1 is inserted. Although it is fixed to the first portion 11, the position and fixing method of the load receiving portion 14 are not limited to this. The load receiving portion 14 may be provided on the upper surface of the strain generating body 1 or may be fixed by a nut. In the latter case, a bolt having a hemispherical head may be used as the load receiving portion 14.

The second portion 12 is a substantially rectangular portion extending from the first portion 11. The shape of the second portion 12 can be arbitrarily designed.

The insulating layer 2 is an insulating layer provided on the strain generating body 1. The insulating layer 2 may be an oxide film, a nitride film, or an insulating film made of resin formed on the strain generating body 1, or is an insulating printed circuit board fixed on the strain generating body 1. May be good. The printed circuit board may be a flexible substrate or a rigid substrate. In either case, the entire surface of the insulating layer 2 is fixed to the strain generating body 1 so as to be distorted according to the strain of the strain generating body 1. The insulating layer 2 has a first portion 21 and a second portion 22.

The first portion 21 is a circular portion that is distorted in response to a load. The first portion 21 is fixed to the first portion 11 of the strain generating body 1 so that the center coincides with the first portion 11. The first portion 11 is provided with a first resistance portion R1, a second resistance portion R2, a third resistance portion R3, and a fourth resistance portion R4. Further, an opening for inserting the screw 15 is provided in the central portion of the first portion 21.

The second portion 22 is a substantially rectangular portion extending from the first portion 21. The shape of the second portion 22 can be arbitrarily designed. The second portion 22 is provided from the first portion 11 to the second portion 12 of the strain generating body 1. A conversion circuit 3 is provided in the second portion 22 on the second portion 12 of the strain generating body 1.

Here, the circuit configuration formed on the insulating layer 2 will be described with reference to FIG. FIG. 3 is a diagram showing an example of the circuit configuration of the load sensor 100. As shown in FIG. 3, on the insulating layer 2, the first resistance portion R1, the second resistance portion R2, the third resistance portion R3, the fourth resistance portion R4, the first output terminal T1, and the first A two-output terminal T2 and a conversion circuit 3 are provided.

One end of the first resistor portion R1 is connected to the power supply, and the other end is connected to the first output terminal T1. One end of the second resistance portion R1 is connected to the first output terminal T1, and the other end is connected to the ground. That is, the first resistance section R1 and the second resistance section R2 are connected in series to form a half-bridge circuit. The voltage between the first resistance section R1 and the second resistance section R2 (the voltage obtained by dividing the power supply voltage Vdd by the first resistance section R1 and the second resistance section R2) is set as the output voltage V1 from the first output terminal T1. It is output. The first output terminal T1 is connected to the conversion circuit 3, and the output voltage V1 is input to the conversion circuit 3.

One end of the third resistor R3 is connected to the power supply, and the other end is connected to the second output terminal T2. One end of the fourth resistor R4 is connected to the second output terminal T2, and the other end is connected to the ground. That is, the third resistance portion R3 and the fourth resistance portion R4 are connected in series to form a half-bridge circuit. The voltage between the third resistance section R3 and the fourth resistance section R4 (the voltage obtained by dividing the power supply voltage Vdd by the third resistance section R3 and the fourth resistance section R4) is set as the output voltage V2 from the second output terminal T2. It is output. The second output terminal T2 is connected to the conversion circuit 3, and the output voltage V2 is input to the conversion circuit 3.

As can be seen from FIG. 3, the third resistance portion R3 and the fourth resistance portion R4 are connected in parallel with the first resistance portion R1 and the second resistance portion R2, and are bridged together with the first resistance portion R1 and the second resistance portion R2. Configure the circuit. The first resistance portion R1, the second resistance portion R2, the third resistance portion R3, and the fourth resistance portion R4 all have a plurality of strain gauges as described later, and the resistance value changes according to the load. Therefore, the output voltage V1 becomes a voltage corresponding to the resistance values of the first resistance portion R1 and the second resistance portion R2 that have changed according to the load. Similarly, the output voltage V2 becomes a voltage corresponding to the resistance values of the third resistance portion R3 and the fourth resistance portion R4 that have changed according to the load. That is, the output voltages V1 and V2 are both voltages corresponding to the load.

The conversion circuit 3 is a circuit that detects a load based on the output voltages V1 and V2. Specifically, the conversion circuit 3 converts the difference between the output voltages V1 and V2 into a load with reference to a table prepared in advance. In the example of FIG. 3, it is assumed that the conversion circuit 3 is one IC (Integrated Circuit), but the conversion circuit 3 may be composed of a plurality of discrete components.

Next, the configurations of the first resistance portion R1, the second resistance portion R2, the third resistance portion R3, and the fourth resistance portion R4 will be described with reference to FIG.

The first resistance portion R1 includes four first strain gauges r1 connected in series by printed wiring (not shown). The first strain gauge r1 may be formed by printing a metal material or a resistance material in which carbon is mixed with a binder resin on the insulating layer 2, or by attaching a metal foil to the insulating layer 2. May be good. Further, the first strain gauge r1 may be an independent element mounted on the insulating layer 2. In either case, the entire surface of the first strain gauge r1 is fixed to the strain generating body 1 so as to be distorted according to the strain of the insulating layer 2. With such a configuration, when a load is applied to the strain generating body 1, the strain generating body 1 is distorted according to the load, the insulating layer 2 is distorted together with the strain generating body 1, and the first strain gauge r1 is distorted together with the insulating layer 2. The resistance value of each first strain gauge r1 changes according to the strain, and the resistance value of the first resistance portion R1 changes according to the change of the resistance value of each first strain gauge r1. As a result, the output voltage V1 changes according to the load.

The first strain gauges r1 are arranged at equal intervals (every 90 °) on the circumference of the first circle centered on the center of the strain generating body 1 (load receiving portion 14). By arranging each of the first strain gauges r1 in this way, it is possible to suppress an error in the resistance value of the first resistance portion R1 that occurs when the direction of the load is inclined (not perpendicular) to the strain generating body 1. This is because the strain of the first strain gauge r1 arranged on the inclination direction side of the load becomes large, and at the same time, the strain of the first strain gauge r1 arranged on the side opposite to the inclination direction becomes small. By suppressing the error of the first resistance portion R1, the error of the output voltage V1 can be suppressed.

The first resistance portion R1 may be provided with a plurality of first strain gauges r1, and the number thereof is not limited to four. In either case, the first strain gauges r1 are preferably arranged at equal intervals on the circumference of the first circle. However, it is also possible not to arrange the first strain gauges r1 at equal intervals.

The second resistance portion R2 includes four second strain gauges r2 connected in series by printed wiring (not shown). The second strain gauge r2 may be formed by printing a metal material on the insulating layer 2, or may be formed by attaching a metal foil to the insulating layer 2. Further, the second strain gauge r2 may be an independent element mounted on the insulating layer 2. In either case, the entire surface of the second strain gauge r2 is fixed to the strain generating body 1 so as to be distorted according to the strain of the insulating layer 2. With such a configuration, when a load is applied to the strain generating body 1, the strain generating body 1 is distorted according to the load, the insulating layer 2 is distorted together with the strain generating body 1, and the second strain gauge r2 is distorted together with the insulating layer 2. The resistance value of each second strain gauge r2 changes according to the strain, and the resistance value of the second resistance portion R2 changes according to the change of the resistance value of each second strain gauge r2. As a result, the output voltage V1 changes according to the load.

The second strain gauges r2 are arranged at equal intervals (every 90 °) on the circumference of the second circle centered on the center of the strain generating body 1. The second circle is a concentric circle of the first circle that is smaller than the first circle. By arranging each of the second strain gauges r2 in this way, it is possible to suppress an error in the resistance value of the second resistance portion R2 that occurs when the direction of the load is tilted with respect to the strain generating body 1. This is because the strain of the second strain gauge r2 arranged on the inclination direction side of the load becomes large, and at the same time, the strain of the second strain gauge r2 arranged on the side opposite to the inclination direction becomes small. By suppressing the error of the second resistance portion R2, the error of the output voltage V2 can be suppressed.

Further, since the outer peripheral portion of the first portion 11 is fixed, when a load is applied to the strain generating body 1, the central portion side and the outer peripheral portion side of the first portion 11 are distorted in opposite directions. As a result, when a load is applied to the strain generating body 1, the resistance value of the first strain gauge r1 arranged on the outer peripheral side of the first portion 11 and the second strain arranged on the central portion side of the first portion 11 The resistance value of the gauge r2 changes in the opposite direction. That is, when a load is applied to the strain generating body 1, the resistance value of the first resistance portion R1 and the resistance value of the second resistance portion R2 change in opposite directions. A half-bridge circuit is formed by such a first resistance portion R1 and a second resistance portion R2, and the voltage between the first resistance portion R1 and the second resistance portion R2 is output as an output voltage V1 to obtain a load. The corresponding change in output voltage V1 can be amplified.

The second resistance portion R2 may be provided with a plurality of second strain gauges r2, and the number thereof is not limited to four. In either case, the second strain gauges r2 are preferably arranged at equal intervals on the circumference of the second circle. However, it is also possible not to arrange the second strain gauges r2 at equal intervals.

Further, as in the example of FIG. 1, each second strain gauge r2 is preferably arranged between the center of the first circle and the second circle and each first strain gauge r1. That is, each second strain gauge r2 is preferably arranged on a line segment connecting the center of the first circle and the second circle and each first strain gauge r1. By arranging the first strain gauge r1 and the second strain gauge r2 in this way, the influence of the inclination in the direction of the load can be made uniform between the first resistance portion R1 and the second resistance portion R2.

The third resistance portion R3 includes four third strain gauges r3 connected in series by printed wiring (not shown). The third strain gauge r3 may be formed by printing a metal material on the insulating layer 2, or may be formed by attaching a metal foil to the insulating layer 2. Further, the third strain gauge r3 may be an independent element mounted on the insulating layer 2. In either case, the entire surface of the third strain gauge r3 is fixed to the strain generating body 1 so as to be distorted according to the strain of the insulating layer 2. With such a configuration, when a load is applied to the strain generating body 1, the strain generating body 1 is distorted according to the load, the insulating layer 2 is distorted together with the strain generating body 1, and the third strain gauge r3 is distorted together with the insulating layer 2. The resistance value of each third strain gauge r3 changes according to the strain, and the resistance value of the third resistance portion R3 changes according to the change of the resistance value of each third strain gauge r3. As a result, the output voltage V2 changes according to the load.

Each third strain gauge r3 is arranged at equal intervals (every 90 °) on the circumference of a third circle centered on the center of the strain generating body 1 (load receiving portion 14). By arranging each third strain gauge r3 in this way, it is possible to suppress an error in the resistance value of the third resistance portion R3 that occurs when the direction of the load is inclined (not perpendicular) to the strain generating body 1. This is because the strain of the third strain gauge r3 arranged on the inclination direction side of the load becomes large, and at the same time, the strain of the third strain gauge r3 arranged on the side opposite to the inclination direction becomes small. By suppressing the error of the third resistance portion R3, the error of the output voltage V2 can be suppressed.

The third resistance portion R3 may be provided with a plurality of third strain gauges r3, and the number thereof is not limited to four. In either case, the third strain gauges r3 are preferably arranged at equal intervals on the circumference of the third circle. However, it is also possible not to arrange the third strain gauges r3 at equal intervals.

Further, it is preferable that the first strain gauge r1 and the third strain gauge r3 are alternately arranged at equal intervals (every 45 °). As a result, it is possible to suppress an error in the difference between the output voltages V1 and V2 that occurs when the direction of the load is tilted with respect to the strain generating body 1.

Further, it is preferable that the first circle and the third circle are the same. That is, it is preferable that the first strain gauge r1 and the third strain gauge r3 are arranged on the same circumference. As a result, the change in the resistance value of the first resistance portion R1 and the change in the resistance value of the third resistance portion R3 according to the load can be made uniform.

The fourth resistance portion R4 includes four fourth strain gauges r4 connected in series by printed wiring (not shown). The fourth strain gauge r4 may be formed by printing a metal material on the insulating layer 2, or may be formed by attaching a metal foil to the insulating layer 2. Further, the fourth strain gauge r4 may be an independent element mounted on the insulating layer 2. In either case, the entire surface of the fourth strain gauge r4 is fixed to the strain generating body 1 so as to be distorted according to the strain of the insulating layer 2. With such a configuration, when a load is applied to the strain generating body 1, the strain generating body 1 is distorted according to the load, the insulating layer 2 is distorted together with the strain generating body 1, and the fourth strain gauge r4 is distorted together with the insulating layer 2. The resistance value of each of the fourth strain gauges r4 changes according to the strain, and the resistance value of the fourth resistance portion R4 changes according to the change of the resistance value of each of the fourth strain gauges r4. As a result, the output voltage V2 changes according to the load.

The fourth strain gauges r4 are arranged at equal intervals (every 90 °) on the circumference of the fourth circle centered on the center of the strain generating body 1. The fourth circle is a concentric circle of the third circle, which is smaller than the third circle. By arranging each of the fourth strain gauges r4 in this way, it is possible to suppress an error in the resistance value of the fourth resistance portion R4 that occurs when the direction of the load is tilted with respect to the strain generating body 1. This is because the strain of the fourth strain gauge r4 arranged on the inclination direction side of the load becomes large, and at the same time, the distortion of the fourth strain gauge r4 arranged on the side opposite to the inclination direction becomes small. By suppressing the error of the fourth resistance portion R4, the error of the output voltage V2 can be suppressed.

Further, since the outer peripheral portion of the first portion 11 is fixed, when a load is applied to the strain generating body 1, the central portion side and the outer peripheral portion side of the first portion 11 are distorted in opposite directions. As a result, when a load is applied to the strain generating body 1, the resistance value of the third strain gauge r3 arranged on the outer peripheral side of the first portion 11 and the fourth strain arranged on the central portion side of the first portion 11 The resistance value of the gauge r4 changes in the opposite direction. That is, when a load is applied to the strain generating body 1, the resistance value of the third resistance portion R3 and the resistance value of the fourth resistance portion R4 change in opposite directions. A half-bridge circuit is formed by such a third resistance portion R3 and a fourth resistance portion R4, and the voltage between the third resistance portion R3 and the fourth resistance portion R4 is output as an output voltage V2 to obtain a load. The corresponding change in output voltage V2 can be amplified.

The fourth resistance portion R4 may include a plurality of fourth strain gauges r4, and the number thereof is not limited to four. In either case, the fourth strain gauges r4 are preferably arranged at equal intervals on the circumference of the second circle. However, it is also possible not to arrange the fourth strain gauges r4 at equal intervals.

Further, as in the example of FIG. 1, each fourth strain gauge r4 is preferably arranged between the center of the third circle and the fourth circle and each third strain gauge r3. That is, it is preferable that each of the fourth strain gauges r4 is arranged on a line segment connecting the centers of the third and fourth circles and each of the third strain gauges r3. By arranging the third strain gauge r3 and the fourth strain gauge r4 in this way, the influence of the inclination in the direction of the load can be made uniform between the third resistance portion R3 and the fourth resistance portion R4.

Further, it is preferable that the second strain gauge r2 and the fourth strain gauge r4 are alternately arranged at equal intervals (every 45 °). This makes it possible to suppress an error in the difference between the output voltages V1 and V2 that occurs when the direction of the load is tilted with respect to the strain generating body 1.

Further, it is preferable that the second circle and the fourth circle are the same. That is, it is preferable that the second strain gauge r2 and the fourth strain gauge r4 are arranged on the same circumference. As a result, the change in the resistance value of the second resistance portion R2 and the change in the resistance value of the fourth resistance portion R4 according to the load can be made uniform.

As described above, according to the present embodiment, the plurality of first gauge elements r1 are arranged at equal intervals on the circumference of the first circle. With such a configuration, even when the direction of the load is tilted with respect to the strain generating body 1, the influence of the tilt of the load is canceled among the plurality of first gauge elements r1. This also applies to the second resistance portion R2, the third resistance portion R3, and the fourth resistance portion R4. Therefore, the load sensor 100 can accurately detect the load based on the output voltages V1 and V2 even when the direction of the load is tilted with respect to the strain generating body 1.

Further, according to the present embodiment, even if the positions of the plurality of first gauge elements r1 are displaced due to manufacturing errors, the influence of the displacement of the first gauge elements r1 is affected by the displacement of the plurality of first gauge elements r1. Is offset between. This also applies to the second resistance portion R2, the third resistance portion R3, and the fourth resistance portion R4. Therefore, the load sensor 100 has output voltages V1 and even when the first gauge element r1, the second gauge element r2, the third gauge element r3, and the fourth gauge element r4 are displaced due to manufacturing errors. The load can be detected accurately based on V2.

In addition, in this embodiment, the configuration which does not include the third resistance part R3 and the fourth resistance part R4 is also possible. Even in such a case, the load sensor 100 can accurately detect the load based on the output voltage V1.

Further, the first portion 11 of the strain generating body 1 may have an elliptical shape. In this case, the first circle, the second circle, the third circle, and the fourth circle are concentric ellipses centered on the center of the first portion 11 (load receiving portion 14), which is similar to the first portion 11. Is preferable.

<Second Embodiment>
The load detecting device according to the second embodiment will be described with reference to FIGS. 4 to 6. The load detection device according to the present embodiment can be any device provided with the load sensor 100. The load detector is, for example, a chair, bed, table, or stretcher, but is not limited to this. Hereinafter, a case where the load detecting device is a bed will be described as an example.

FIG. 4 is a diagram showing an example of the bed 200 according to the present embodiment. The bed 200 of FIG. 4 includes a top plate 4 and four legs 5. The top plate 4 is a portion for a person to lie down, and is composed of a frame and a floor plate. When the bed 200 is used, a mattress or the like is laid on the upper portion of the top plate 4. The legs 5 horizontally support the top plate 4.

FIG. 5 is a partially enlarged view showing an example of the leg portion 5 of FIG. FIG. 6 is a cross-sectional view of the leg portion 5 of FIG. The leg portion 5 is arranged between the first support portion 51 that supports the top plate 4, the second support portion 52 that supports the first support portion 51, and the first support portion 51 and the second support portion 52. The load sensor 100 is provided. The first support portion 51 has a recess 511 at the lower end for accommodating the screw 15 of the load sensor 100. The second support portion 52 includes a housing 53, a caster 54, and a pressing portion 55.

The housing 53 is a tubular member that connects the first support portion 51 and the caster 54, and has a hollow portion 531. The upper end of the housing 53 is fixed to the lower ends of the load sensor 100 and the first support portion 51, and the lower end of the housing 53 is fixed to the upper ends of the casters 54. The load receiving portion 14 of the load sensor 100 is housed in the hollow portion 531 of the housing 53.

The caster 54 includes wheels that can rotate around a horizontal axis and universal metal fittings that rotatably support the wheels around a vertical axis. The caster 54 allows the bed 200 to be easily moved.

The pressing portion 55 is a rod-shaped member extending upward from the upper end of the caster 54, and is housed in the hollow portion 531 of the housing 53. The pressing portion 55 is designed so that the upper end thereof can press the load receiving portion 14 when a load is applied to the bed 200.

With the above configuration, when a person rides on the bed 200, the load sensor 100 is pushed down by the first support portion 51, and the load receiving portion 14 is pressed from below by the pressing portion 55. As a result, a load corresponding to the weight of the person is applied to the load receiving portion 14, so that the load sensor 100 can detect the weight (load) of the person.

The present invention is not limited to the configurations shown here, such as combinations with other elements in the configurations and the like described in the above embodiments. These points can be changed without departing from the spirit of the present invention, and can be appropriately determined according to the application form thereof.

In addition, this international application claims priority based on Japanese Patent Application No. 2018-024953 filed on February 15, 2018, and the entire contents of the application are incorporated into this international application.

1: Distortion body 2: Insulation layer 3: Conversion circuit 4: Top plate 5: Leg 11: First part 12: Second part 13: Opening 14: Load receiving part 15: Screw 21: First part 22: Second part 51: First support part 52: Second support part 53: Housing 54: Caster 55: Pressing part 100: Load sensor 200: Bed

Claims (16)

A strain-causing body with a load receiving part and
The insulating layer provided on the strain-causing body and
A first resistance portion and a second resistance portion provided on the insulating layer and connected in series,
A first output terminal that outputs a voltage between the first resistance portion and the second resistance portion,
With
The first resistance portion includes a plurality of first strain gauges connected in series and arranged on the circumference of a first circle which is a circle or an ellipse.
The second resistor includes a plurality of second strain gauges connected in series and arranged on the circumference of a circular or elliptical second circle.
The first circle and the second circle are load sensors that are concentric circles or concentric ellipses centered on the load receiving portion. The load sensor according to claim 1, wherein the first strain gauge is arranged at equal intervals on the circumference of the first circle. The load sensor according to claim 1 or 2, wherein the second strain gauge is arranged at equal intervals on the circumference of the second circle. The load sensor according to any one of claims 1 to 3, wherein the second strain gauge is arranged between the first strain gauge and the center of the first circle. The load sensor according to any one of claims 1 to 4, wherein the first resistance portion includes two or four first strain gauges. The load sensor according to any one of claims 1 to 5, wherein the second resistance portion includes two or four second strain gauges. A third resistance portion and a fourth resistance portion provided on the insulating layer and connected in series,
A second output terminal that outputs a voltage between the third resistance portion and the fourth resistance portion,
With
The third resistance portion and the fourth resistance portion are connected in parallel with the first resistance portion and the second resistance portion.
The third resistor includes a plurality of third strain gauges connected in series and arranged on the circumference of a circular or elliptical third circle.
The fourth resistor includes a plurality of fourth strain gauges connected in series and arranged on the circumference of a circular or elliptical fourth circle.
The load sensor according to any one of claims 1 to 6, wherein the third circle and the fourth circle are concentric circles or concentric ellipses centered on the load receiving portion. The load sensor according to claim 7, wherein the third strain gauge is arranged at equal intervals on the circumference of the third circle. The load sensor according to claim 7 or 8, wherein the fourth strain gauge is arranged at equal intervals on the circumference of the fourth circle. The load sensor according to any one of claims 7 to 9, wherein the fourth strain gauge is arranged between the third strain gauge and the center of the third circle. The load sensor according to any one of claims 7 to 10, wherein the third resistance portion includes two or four third strain gauges. The load sensor according to any one of claims 7 to 11, wherein the fourth resistance portion includes two or four fourth strain gauges. The first circle and the third circle are the same,
The load sensor according to any one of claims 7 to 12, wherein the second circle and the fourth circle are the same. The first strain gauge and the third strain gauge are alternately arranged at equal intervals.
The load sensor according to any one of claims 7 to 13, wherein the second strain gauge and the fourth strain gauge are alternately arranged at equal intervals. The load sensor according to any one of claims 1 to 14, wherein the strain-causing body has an outer peripheral portion fixed. Top plate and
The first support portion that supports the top plate and
A second support portion that supports the first support portion and
The one according to any one of claims 1 to 15, which is arranged between the first support portion and the second support portion and is loaded from the first support portion or the second support portion. With the load sensor
A load detector equipped with.

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