JPH0577251B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a weight sensor device that electrically extracts a load in a thrust direction as a change in output.

[Conventional technology]

This type of weight sensor is incorporated into various electronic devices. For example, in order to prevent uneven heating, microwave ovens place food on a turntable inside the cooking chamber and heat the food while rotating the turntable at a constant speed during microwave irradiation. go.

Among these, automatic cooking microwave ovens are equipped with a weight sensor that detects the weight of the food on the turntable, selects an appropriate cooking program based on this weight and the type of food, and then It will be executed automatically.

Usually, the weight of food or the like is transmitted to a rotating shaft via a turntable. Therefore, this rotating shaft is rotatable around the axis with respect to the bearing part in order to rotate the turntable, and at the same time is movable in the thrust direction in order to detect the load in the thrust direction. Must be supported in the state. For this reason, the conventional bearing portion is a complex rotary sliding bearing, which is relatively complex and difficult to integrate into a small, predetermined spatial location of the microwave oven.

Also, when detecting weight by mechanical and electrical means, if temperature characteristics are not taken into account,
Measurement accuracy does not improve.

[Purpose of the invention]

SUMMARY OF THE INVENTION Therefore, it is an object of the present invention to improve the support part of the rotating shaft, to make the device thinner, and to eliminate temperature errors.

[Means for solving the invention]

Therefore, the present invention provides a fixed frame,
One end of the two springs is fixed, and the other end rotatably supports the motor and rotating shaft by the motor case.

In this way, the motor and rotating shaft are
The two springs allow for axial cantilevering. As a result, the rotating shaft only needs to be structured so that it rotates relative to its bearing portion, and does not need to be able to be displaced in the thrust direction.

Further, since the motor case is supported between two springs, the supporting portion can be made thinner, and the entire device can be installed in a small space.
Furthermore, when a load is applied to the rotating shaft in the thrust direction, the two springs act as if they were parallel links, and the rotating shaft is always parallel to the direction of the load, allowing accurate weight detection. It will be done.

Further, in the present invention, the temperature characteristics are set in opposite directions between the mechanical part and the electrical part, thereby suppressing the temperature error.

〔Example〕

1 to 3 show the mechanical configuration of a basic embodiment of a weight sensor device 1 of the present invention.

This weight sensor device 1 has a driving motor 2.
A rotary shaft 3 is rotatably driven by the motor 2 and is displaceable in the thrust direction in response to a load from the weight of the object to be measured. The motor 2 and rotating shaft 3 are incorporated into the case 4. That is, the motor 2 is fixed inside the case 4 with the motor shaft 5 protruding.
The rotational force is transmitted to the rotating shaft 3 inside the case 4 via a gear train 6 for reduction.

The rotating shaft 3 is rotatably supported around the axis by upper and lower bearings 7 on the case 4 side, protrudes from the case 4 at its upper end, supports the turntable 8, and has a chamfered portion at its lower end. It is in contact with the upper surface of the lower spring receiver 9.

This spring receiver 9 is connected to the upper spring receiver 10.
At the same time, it is fixed to one end of the case 4 with a plurality of setscrews 11 in a state where the case 4 is sandwiched therebetween. These spring receivers 9, 10 are fixed to the free ends of the pair of springs 12, 13 by fixing means such as caulking. These springs 12,1
3 is, for example, a plate with a rectangular outline,
The base end portion is fixed to the U-shaped support plate 14 by fixing means such as caulking, and is fixed to the rising portion of the L-shaped frame 16 via this support plate 14 and a plurality of mounting screws 15. There is.

In this way, the spring receivers 9, 10, the spring 1
2, 13 and the support plate 14, the rotation shaft 3 can be displaced in the thrust direction, and the support plate 14 on the one end side
A parallel spring mechanism is constructed in a cantilevered state with the fixed side being the fixed side. Usually, these springs 12, 13 are
When there is no load on the rotating shaft 3 side, the frame 16
Although it is in a plane parallel to the bottom side of the cylinder, it elastically displaces in the thrust direction when a load is applied in the thrust direction. Note that this maximum displacement is regulated by the perforation 17 of the frame 16.

On the other hand, this weight sensor device 1 includes an oscillation circuit 18 and a buffer circuit 19 as electrical parts.
It is equipped with A detection coil as part of the oscillation circuit 18 is incorporated into the spring receiver 9 and the frame 16 together with the core 21 . That is, one coil 20 is wound in an annular manner around a coil bobbin 22 made of plastic, for example, and on the upper surface of the attachment part 23 of the spring receiver 9.
It is fixed to the hole 24 etc. by fitting or the like. The coil bobbin 22 is open only below the center position of the coil 20, and the upper surface is formed of the same material so as to be integrally closed.

The core 21 is configured as a magnetic male screw for position adjustment, and the frame 16
is inserted upward into the female thread 25 of the coil 2.
It faces the center of 0. The coil 20 and core 21 are an element of the weight detection means, are electromagnetically coupled, and change their electric characteristics, that is, self-inductance, proportionally by changing their relative positions.

Next, FIG. 4 illustrates the configuration of the electrical part. The oscillation circuit 18 is configured by combining a frequency adjustment volume 27, capacitors 29 and 30, and an inverting amplifier 28 between both ends of the coil 20 and the ground 26 for L-C anticoupling oscillation. . Further, the buffer circuit 19 is constructed by combining resistors 31 and 32 and inverting amplifiers 33 and 34 between the output side of the oscillation circuit 18 and the output terminal 35.

Note that these rotating elements are incorporated into a rotating substrate 36, attached to the side surface of the frame 16, for example, and connected to the coil 20 by a lead wire 37.

When an object to be measured 40 such as food is placed on the turntable 8, its weight becomes a load in the thrust direction on the rotating shaft 3 and acts on the lower spring receiver 9, so the springs 12 and 13 are It bends due to the load, exerts elasticity in the direction that opposes the load, and is displaced to a balanced position. At this time, the rotating shaft 3 and the coil 20 are displaced in the direction in which the load is applied while maintaining a substantially parallel state.

At this time, since the relative positional relationship between the coil 20 and the core 21 changes in proportion to the load in the thrust direction, that is, the weight of the object 40, the coil 20
The self-inductance of changes. As a result, the oscillation circuit 18 changes its oscillation frequency according to the change in self-inductance.

The oscillation frequency f at this time is determined by the self-inductance L and the capacitance of capacitors 29 and 30, respectively.
If C ₁ and C ₂ are used, it is given by the following formula.

f=1/2π√(1 ₁ +1 ₂ ) The coil 20 approaches the fixed core 21,
As the coupling between the two becomes deeper, the oscillation frequency f of the oscillation circuit 18 gradually decreases. Therefore, by identifying this oscillation frequency f, the weight of the object to be weighed 40 can be measured indirectly.

Next, FIG. 5 shows the temperature-frequency characteristics. The coil 20 changes in the direction of decreasing the oscillation frequency f as the temperature rises. Also, spring 1
2 and 13 change more greatly as the temperature increases due to temperature changes in the elastic modulus and thermal expansion of the spring material, so the oscillation frequency f also changes in the smaller direction. On the other hand, the oscillation circuit 18 itself changes the oscillation frequency f in a higher direction as the temperature rises in order to offset these characteristics.

Therefore, as a whole, the output of the oscillation circuit 18,
That is, the oscillation frequency f is set so that it has a flat characteristic as shown by the dotted line with respect to temperature changes. As a result, as the weight or load changes, the oscillation frequency f changes along a smooth upward-sloping curve as shown in FIG.

[Other Examples]

Next, in FIG. 7, the coil 20 is provided upward,
On the other hand, this is an example in which the core 21 is fixed to a female thread 39 of a fixed core receiver 38. The core receiver 38 is directly fixed to the upper surface of the frame 16, and also functions as a cover for preventing foreign matter from entering the center hole of the coil 20.

According to the above embodiment, the attachment relationship between the coil 20 and the core 21 is opposite to that of the above embodiment, and the degree of coupling between the two becomes shallow due to the load.
As shown in FIG. 8, the temperature-frequency characteristics of the springs 12 and 13 change with a slope opposite to that of the previous embodiment. The greater the deflection of the springs 12 and 13, the higher the oscillation frequency f becomes.
Even if no extreme correction is made on the 8 side, the overall characteristics will be in a flat state. Further, the load-frequency characteristic at this time changes with a slope opposite to that of the above embodiment, as shown in FIG. Such characteristics are set in consideration of changes in the temperature of the usage environment and adjustment with correction side software.

Next, in the embodiment shown in FIGS. 10 and 11, the coil 20 is attached to the attachment part 23 of the upper spring receiver 10, and a part of the lower spring receiver 9 is made into a depression by drawing, and the upper surface of the coil 20 is The rotation axis 3
This is an example in which a burnt hole 41 is formed in a portion of the frame 16 that contacts the lower end portion of the frame 16 and corresponds to the drawn portion, thereby reducing the thickness of the entire device. Further, the support body 14 is in contact with the lower surface side of the frame 16 as well as the side surface thereof, and is fixed at that portion by a mounting screw 15. As a result, the base end portions of the springs 12, 13 are supported with higher rigidity than in the previous embodiment.

[Other embodiments]

In any of the above embodiments, the coil 20 is fixed to the movable part, and the corresponding core 21
is fixed to the fixed side part. However, the mounting positions of both may be reversed.

In addition, the rotating shaft 3 has a spring receiver 9 directly at its lower end.
However, the portion receiving this load may be brought into indirect contact with a plate-shaped portion having a low coefficient of friction interposed therebetween.

Of course, since the coil 20 and the core 21 are an example of weight detection means, this weight detection means is not limited thereto, and may also be configured with other pressure-to-electricity conversion elements such as a load cell.

〔Effect of the invention〕

The present invention provides the following unique effects.

First, since the motor case is supported between two springs, the entire device can be made thinner.

In addition, the two springs are supported in a cantilevered manner at the base end, and are fixed to each other by the motor case at the other end, so when a load is applied, they behave as if they were parallel links. , since there is parallel movement at the rotation axis, when measuring the thrust load,
The thrust load does not generate force components other than the thrust load, so the measurement of the load is accurate.

Furthermore, since the rotating shaft is movable in the thrust direction by the deflection of the two springs, the rotating shaft and its bearing do not have to be movable relative to each other in the thrust direction. Therefore, the bearing part only needs to allow rotational movement, and relative displacement in the thrust direction is unnecessary, so the function of the bearing part can be simplified, and its structure can also be simplified.

In particular, an oscillation circuit that converts the load into an oscillation frequency is provided, and the weight detection means, the spring, and the oscillation circuit are set in a direction that cancels out changes in the oscillation frequency characteristics due to temperature changes, so even if the temperature changes,
The oscillation frequency can be held constant, improving measurement accuracy.

[Brief explanation of drawings]

FIG. 1 is a plan view of the weight sensor device of the present invention;
Figure 2 is a vertical sectional view of the same, Figure 3 is a vertical sectional view seen from different directions, Figure 4 is a circuit diagram of the electrical part, Figure 5 is a graph of temperature-frequency characteristics, and Figure 6 is a load - Graph of frequency characteristics, Fig. 7 is a broken side view of the main part of another embodiment, Fig. 8 is a graph of temperature-frequency characteristics of another embodiment, Fig. 9 is load of another embodiment. - A graph of frequency characteristics, FIG. 10 is a plan view of yet another embodiment, and FIG. 11 is a partially cutaway side view. 1... Weight sensor device, 2... Motor, 3...
...Rotating shaft, 4...Case, 9, 10...Spring receiver, 12, 13...Spring, 14...Support plate, 16
... Frame, 18 ... Oscillation circuit, 19 ... Buffer circuit, 20 ... Coil, 21 ... Core, 40
...Weighing items such as food.

Claims (1)

[Claims] 1 A frame, two springs whose proximal ends are fixed to the frame, a motor attached to the free end of the spring, and a motor that is rotatably held in a case of the motor and protrudes from the case to thrust. a rotating shaft that receives a load in a direction; a weight detecting means installed between the spring and the frame and converting a relative positional change between the spring and the frame into a change in electrical quantity; and a part of the weight detecting means. and an oscillation circuit that generates an output at an oscillation frequency according to a change in the quantity of electricity, and the characteristics of the oscillation frequency due to temperature changes of the spring, the weight detection means, and the oscillation circuit are set in a direction to cancel each other out. A weight sensor device characterized by: