JPS6133542Y2 - - Google Patents

Description

[Detailed Description of the Invention] This invention relates to a load cell used in a weight detection section of a scale.

The strain gauge 2 used for the load cell is the first
As shown in Figure a, four sheets are pasted on the inside of the cell body 1, and used by connecting them to a bridge as shown in Figure b.

In this case, it is ideal that the creep characteristic, that is, the characteristic in which the bridge output changes over time after loading, be zero, as shown in FIG. 2c.
Also, for example, when coating after applying strain gauge 2, the coating changes the creep characteristics, so if the creep characteristics change to +1 μV, for example, the creep characteristics must be set to -1 μV before coating. No. Therefore, it is desirable that the creep property can be set to a desired value other than zero.

However, when conventional commercially available strain gauges are used, they often exhibit positive or negative creep characteristics as shown in FIGS. 2a and 2e.

In view of the above-mentioned conventional circumstances, this invention aims to obtain a load cell whose creep characteristic is zero or has a desired value.

The main feature of this invention is to reduce the creep characteristics of the load cell to zero or to a desired value by combining a strain gauge with positive creep characteristics and a strain gauge with negative creep characteristics. This will be explained in more detail below.

As shown in the second column of the figure, the creep characteristics are measured after a certain period of time ( _t1 : for example, 30 minutes) has elapsed since the power was turned on.
When the bridge output of the load cell is stable, a certain load (W: for example 4 kg) is applied for a certain period of time ( _t2 :
It shows the change in the bridge output of the load cell at the beginning and end of time t ₂ (for example, 10 minutes). Furthermore, as mentioned above, the value that changed at time _t2 does not return to its original state immediately even after the load is removed, but gradually returns to its original state.

Now, when a load cell bridge is constructed by combining two strain gauges of A and B types under the same conditions, four of the same type each, it will exhibit creep characteristics with the same value in the positive and negative directions. For example, when only four strain gauges A are used, a creep characteristic of +2 μV is shown as shown in Figure 2a, and when only strain gauge B is used, as shown in Figure 2e.
Assume that it exhibits a creep characteristic of -2 μV as shown in .

In this case, as shown in Figure 2b or Figure 2d, if one strain gauge A or B on the applied voltage side is replaced with strain gauge B or A to form a bridge, the positive and negative creep properties are reduced by half. In other words, a bridge with a creep characteristic of +1 μV or -1 μV can be obtained. Furthermore, as shown in Figure 2c, the two strain gauges on one pole on the output side are mutually switched from A to B (or from B to A).
In other words, there are strain gauges A on both poles on the input side.
By connecting B and B, it is possible to obtain a bridge whose creep characteristics are almost zero by replacing them.

Figure 2c shows A and B2 at both poles on the positive and negative applied voltage sides.
A bridge is constructed by connecting strain gauges of different types and connecting strain gauges of the same type, A or B, to each pole on the output side, but conversely, an embodiment as shown in Fig. 3 is also considered. It will be done. That is,
A bridge is constructed by connecting strain gauges of the same type, A or B, to each pole on the applied voltage side, and connecting strain gauges of different types, A and B, to both poles on the output side. However, this is not a very desirable combination.

This is because, in many cases, the fact that the creep characteristics of the A and B types are different means that there is also a slight difference in the temperature characteristics due to the difference in the strain gauge manufacturing rod.

In this proposal, since we only want to utilize the difference in creep characteristics between the two types, A and B, we want to avoid this difference in temperature characteristics from appearing as the load cell output. To do this, it is necessary that the two strain gauges of type A and B attached to the load cell be in the same thermal state under the same temperature conditions.
As a result of experiments, when the temperature and thermal conditions were the same, the combination shown in Figure 2c and the combination shown in Figure 3 showed the same characteristics, but when the temperature and thermal conditions changed, the combination shown in Figure 2c showed the same characteristics. A better result was obtained with c, that is, a value closer to zero in the creep property was obtained. Generally, load cells are used in situations where the temperature and thermal conditions change, so if it is desired to reduce the creep characteristics to zero, a circuit like the one shown in FIG. 3 is less preferable than the one shown in FIG. 2c.

As explained above, with this invention, the creep characteristic can be set to zero or a desired value simply by combining two types of strain gauges, and therefore accurate measurement can be performed.

[Brief explanation of drawings]

Figure 1 a and b are load cells and their connection diagrams, Figure 2
Figures a, b, c, d, and e show an example (row) of this invention that combines two types of strain gauges and its creep characteristics (row), and Figure 3 shows another example of this invention. . In the figure, A... strain gauge having positive creep characteristics, B... strain gauge having negative creep characteristics.

Claims (1)

[Utility Model Claims] (1) A load cell having four strain gauges connected to a bridge, characterized in that at least one of the pairs of strain gauges at both poles of the applied voltage side or both poles of the output side of the bridge is given a positive creep characteristic and the other strain gauge is given a negative creep characteristic, thereby giving zero or desired creep characteristics overall. (2) A load cell as described in Utility Model Claim 1 in which two strain gauges with different creep characteristics are connected to both poles of the applied voltage side of the bridge and two strain gauges with the same creep characteristics are connected to both poles of the output side. (3) A load cell as described in Utility Model Claim 1 in which two strain gauges with different creep characteristics are connected to one pole of the applied voltage side of the bridge and two strain gauges with the same creep characteristics are connected to the other pole. (4) A load cell as described in claim 1 of the utility model registration, in which two strain gauges with different creep characteristics are connected to both poles on the output side of the bridge, and two strain gauges with the same creep characteristics are connected to both poles on the applied voltage side.