JPH04274720A - Strain gauge-type load cell - Google Patents

Abstract

PURPOSE:To obtain a highly accurate strain gauge-type load cell with superior resistances to moisture, rust and chemicals and having durability. CONSTITUTION:In this strain gauge-type load cell, a strain gauge 1 is attached to a strain generating part 3 of a strain generating body 2 made of aluminum or aluminum alloy. A butyl rubber plate 4 is arranged at the upper and lower surfaces of the strain generating body 2 to which the strain gauge including the strain gauge 1 is attached. The butyl rubber plate 4 is totally covered with a coating material 5 of butyl rubber or chloroprene rubber.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a strain gauge type load cell, and more particularly to a strain gauge type load cell suitable for use in an environment where the metal constituting the strain body is likely to corrode.

0002

2. Description of the Related Art Conventionally, this type of strain gauge type load cell has been disclosed in Japanese Patent Laid-Open No. 64-49924. This strain gauge type load cell has a strain gauge attached to the strain-generating part (flexible part) of a strain-generating body made of a high-strength aluminum material, etc., and the surface of the strain-generating body containing the strain gauge is made of a styrene-butadiene conjugate. Alternatively, it is covered with a coating material whose main component is a styrene-isoprene copolymer material.

[0003] In order to cover the surface of the strain-generating body with a coating material, a polymeric material such as a styrene-butadiene compound or a styrene-isoprene compound is liquefied with a solvent, and then applied to the entire surface of the load cell. This is done by drying it. In strain gauge type load cells covered with such a coating material, there is almost no increase in creep in high weighing load cells of 100 kg or more, and hysteresis, linearity,
Good results with good reproducibility were obtained.

0004

However, when the above-mentioned coating material is used in a load cell with a low weighing capacity of 30 kg or less, there is a problem in that the creep value increases, which affects the accuracy of the scale. In particular, the temperature dependence of the elastic modulus of polymer materials such as styrene-butadiene co-compounds or styrene-isoprene co-compounds is large, and when used in low-temperature environments (below 10°C), the accuracy of the load cell will be affected. influenced. In addition, the coating material deteriorates over a long period of time, and not only does the elastic modulus of the rubber increase and become harder and the creep value increases, but the coating also peels off and no longer fulfills its original purpose of moisture and rust prevention. The durability was significantly reduced.

The present invention has been made in view of the above-mentioned points, and an object of the present invention is to provide a highly accurate strain gauge type load cell that is excellent in moisture resistance, rust prevention, and chemical resistance, and is durable.

[0006]

[Means for Solving the Problems] In order to solve the above problems, the present invention provides a strain gauge type load cell having a structure in which a strain gauge is attached to a strain generating part of a strain body, the strain gauge including at least the strain gauge. It is characterized in that the strain-generating part to which the gauge is attached is covered with a butyl-based rubber coating material or a chloroprene-based rubber coating material.

The strain generating body is made of high-strength aluminum subjected to alumite treatment, and at least the portion where the alumite of the strain generating portion is shaved off or the portion where the alumite is scraped off and the strain generating portion including the strain gauge are made of butyl. It is characterized by being covered with a chloroprene-based rubber coating material or a chloroprene-based rubber coating material.

[0008] Also, the strain gauge attached to the vicinity of the strain-generating portion of the strain-generating body subjected to alumite treatment is characterized by having a more negative creep characteristic than the strain gauge attached to the strain-generating body not subjected to alumite treatment. shall be.

[0009]

[Function] By covering with the coating material as described above, the butyl rubber coating material or chloroprene rubber coating material has a lower elastic modulus than that of the styrene-butadiene co-compound system or the styrene-isoprene co-composite system.
In addition, since the temperature dependence of the elastic modulus is small, the coating material used in a low-basis load cell does not affect the accuracy of the load cell, resulting in a moisture-proof and rust-proof load cell with good temperature characteristics and high accuracy.

[0010] Butyl rubber coating material or chloroprene rubber coating material has excellent moisture resistance, rust prevention, chemical resistance, and weather resistance, and the coating material does not change much over time.
Because there is no change in elastic modulus or peeling due to long-term deterioration,
The accuracy of the load cell is maintained and the usage environment is not restricted, and durability is improved semi-permanently.

[0011] The butyl rubber coating material or the chloroprene rubber coating material itself has a rust prevention effect, and due to the synergistic effect with the alumite of the load cell strain body,
Furthermore, it exhibits excellent rust prevention effects, improving durability. In addition, the alumite is peeled off when adjusting the four corners of the load cell, and by covering this area as a local surface treatment, the rust prevention effect is maintained, the durability is excellent, and the accuracy of the load cell does not deteriorate.

[0012] Furthermore, by making the strain gauge attached to the alumite-treated strain body have a more negative creep characteristic than the strain gauge attached to the non-anodized strain body, the alumite treatment can be applied. The increased creep caused by this is offset by a strain gauge with negative creep characteristics.

[0013]

Embodiments Hereinafter, embodiments of the present invention will be explained based on the drawings. 1 and 2 are diagrams showing the structure of a strain gauge type load cell according to the present invention. FIG. 1 is an external perspective view, and FIG. 2 is a sectional view taken along line XX in FIG. 1. This load cell is a known so-called double beam type load cell having upper and lower beams.

The strain-generating body 2 is made of aluminum or an aluminum alloy material, and thin-walled flexible parts (strain-generating parts) 3 are formed at predetermined positions of the upper and lower beams, and a strain gauge is provided near the flexible parts 3. (Strain gauge) 1 is attached. Butyl rubber plates 4 are disposed as waterproof materials on the upper and lower surfaces of the strain body 2 including the strain gauge 1. Furthermore, its upper surface is covered with a butyl rubber or chloroprene rubber coating material 5. Further, its upper surface is covered with a silicone coating 6.

The butyl-based rubber coating material 5 is formed by applying a rust preventive material containing butyl rubber as a main component dissolved in a quick-drying solvent (toluene, n-hexane, etc.). This allows the solvent to evaporate after application, resulting in a thin cover coat of butyl-based rubber.

The chloroprene-based rubber coating material 5 is formed by applying a rust preventive material containing chloroprene as a main component dissolved in a quick-drying solvent (toluene, n-hexane, etc.). This allows the solvent to evaporate after application,
A thin cover coat of chloroprene rubber.

As for the coating method, if the flexure element 2 is dipped in a liquid butyl-based or chloroprene-based rubber coating material and the entire surface of the flexure element 2 is covered, the application work can be simplified and the man-hours can be reduced. can be reduced.

The butyl-based or chloroprene-based rubber coating material 5 has the property of being extremely sticky and sensitive to organic solvents. Therefore, as described above, by applying silicone coating 6 using silicone resin over coating material 5, handling becomes easier and at the same time protection from organic substances can be achieved.

Furthermore, the butyl-based or chloroprene-based rubber coating material 5 has excellent moisture resistance, rust prevention, chemical resistance, and weather resistance, so that changes in elastic modulus and peeling due to long-term deterioration of the coating material 5 do not occur. The accuracy of the load cell is maintained and the usage environment is not restricted, and durability is improved semi-permanently.

As described above, by covering the surface of the strain body 2 including the strain gauge 1 with the butyl-based or chloroprene-based rubber coating material 5, the rubber coating material 5 can be coated with a styrene-butadiene copolymer or chloroprene-based rubber coating material. Styrene
The elastic modulus is lower than that of isoprene co-compound systems, and the temperature dependence of the elastic modulus is small, so the rubber coating material 5 does not affect the accuracy of the load cell even when used in a low-basis load cell, so the temperature characteristics can be improved. We can also provide high-precision moisture-proof and rust-proof load cells.

FIG. 3 is a diagram showing creep (%) for each coating material versus temperature. As shown in the figure, the solution-form butyl-based or chloroprene-based rubber coating material of the present invention is applied to a conventional coating material made of a styrene-butadiene-based compound or a styrene-isoprene-based compound. It can be seen that creep is significantly reduced in the case of coatings formed using

FIG. 4 is a diagram showing the structure of another strain gauge type load cell according to the present invention (corresponding to the XX sectional view in FIG. 1).
It is. As shown in the figure, the surface of the strain-generating body 2 is subjected to an alumite treatment in order to enhance the rust prevention effect, and an alumite layer 7 is formed. The upper surface of the alumite layer 7 is covered with a butyl-based or chloroprene-based rubber coating material 5, and the upper surface is further covered with a silicone coating 6. In addition,
The parts that overlap with the explanation of FIG. 2 will be deleted.

The butyl-based or chloroprene-based rubber coating material 5 has a rust-preventing effect in itself, and has a synergistic effect with the alumite layer 7 of the strain body 2 of the load cell.
Furthermore, it exhibits excellent rust prevention effects, improving durability.

Furthermore, for adjustment of the four corners of the load cell or other adjustments, a portion of the strain-generating portion may be cut off to form a cut portion 3a, as shown in FIG. As a surface treatment for the area where the alumite layer 7 has been peeled off due to this cutting, by covering this area with a butyl-based or chloroprene-based rubber coating material, even if areas other than the strain-generating area corrode, the rust prevention effect is maintained and durability is maintained. The accuracy of the load cell can be maintained. Therefore, it is very effective as an emergency treatment after adjusting the load cell at the site.

As described above, when alumite treatment is applied to the strain-generating body 2 made of aluminum or an aluminum alloy in order to impart a rust-preventing effect, the alumite treatment increases creep. Therefore, it is possible to reduce the creep of the load cell by using a strain gauge that has negative creep characteristics rather than a strain gauge that is bonded to a non-anodized strain body.

In the low weighing load cell, butyl rubber plates 4 are provided on the upper and lower surfaces of the flexure element 2 as waterproof materials. Since the top of the butyl rubber plate 4 is covered with a butyl-based or chloroprene-based rubber coating material 5, the pinholes in the butyl rubber plate 4 are also closed by applying the solution rubber coating 5 to the top surface of the butyl rubber plate 4. Improve moisture resistance.

In addition, in the case of a high-basis load cell, when a moisture-proof film 8 of a laminate film or aluminum foil is arranged on the top surface of the butyl rubber plate 4, as shown in FIG. By covering with 5, these moisture-proof films 8 can also have a rust-preventing effect.

[0028]

[Effects of the Invention] As explained above, according to the present invention, the following excellent effects can be obtained. (1) Butyl-based rubber coating materials or chloroprene-based rubber coating materials have a lower elastic modulus than styrene-butadiene co-compounds or styrene-isoprene co-compounds, and the temperature dependence of the elastic modulus is less. The coating material used for weighing load cells does not affect the accuracy of the load cell, so it has good temperature characteristics, high precision moisture proofing,
It becomes a rust-proof type load cell.

(2) The butyl-based rubber coating material or chloroprene-based rubber coating material is moisture-proof, rust-proof, chemical-resistant,
It has excellent weather resistance and does not cause changes in elastic modulus or peeling due to long-term deterioration of the coating material, so the accuracy of the load cell can be maintained and the environment in which it can be used is not restricted, improving durability semi-permanently.

(3) The butyl-based rubber coating material or the chloroprene-based rubber coating material has a rust-preventing effect by itself, and the synergistic effect with the alumite of the load cell strain body provides an even better rust-preventing effect. Improve durability. In addition, by covering the alumite that is peeled off during load cell adjustment, etc. as a local surface treatment, the rust prevention effect is maintained and the durability and accuracy of the load cell do not deteriorate.

[0031] Furthermore, by using a strain gauge that is attached to an alumite-treated strain body as a strain gauge that has a more negative creep characteristic than a strain gauge that is attached to a non-anodized strain body, it is possible to make the alumite treatment easier. Since the creep that increases due to application is offset by the negative strain gauge with negative creep characteristics, there is no decrease in accuracy, and the synergistic effect of the butyl rubber coating material or chloroprene rubber coating material and alumite provides excellent rust prevention effects. is obtained.

[Brief explanation of the drawing]

FIG. 1 is an external perspective view showing the structure of a strain gauge type load cell according to the present invention.

FIG. 2 is a sectional view taken along line XX in FIG. 1;

[Figure 3] Creep [%] of each coating material versus temperature
] is a figure showing.

FIG. 4 is a sectional view showing the structure of another strain gauge type load cell according to the present invention.

FIG. 5 is an external view showing the structure of another strain gauge type load cell according to the present invention.

FIG. 6 is a sectional view showing the structure of another strain gauge type load cell according to the present invention.

[Explanation of symbols]

1 Strain gauge 2 Strain body 3 Flexible portion 4 Butyl rubber plate 5
Rubber coating material 6
silicone coating 7
Alumite 8 Moisture-proof membrane

Claims (3)

[Claims] 1. A strain gauge type load cell having a structure in which a strain gauge is attached to a strain generating part of a strain generating body, wherein the strain generating part including at least the strain gauge and to which the strain gauge is attached is coated with butyl rubber. A strain gauge type load cell characterized by being covered with a material or a chloroprene rubber coating material. 2. A strain gauge type load cell having a structure in which a strain gauge is attached to a strain-generating portion of a strain-generating body, wherein the strain-generating body is made of aluminum or an aluminum alloy subjected to alumite treatment, and at least the strain-generating portion is A strain gauge type load cell characterized in that a portion where the alumite is shaved off or a strain generating portion including a portion where the alumite is scraped off and a strain gauge are covered with a butyl rubber coating material or a chloroprene rubber coating material. 3. A strain gauge type load cell having a structure in which a strain gauge is attached to a strain-generating portion of a strain-generating body, wherein the strain-generating body is made of alumite-treated aluminum or an aluminum alloy; The strain gauge attached to the strain gauge has a more negative creep characteristic than the strain gauge attached to the strain body that is not subjected to alumite treatment, and the strain gauge to which the strain gauge is attached, including at least the strain gauge, is made of butyl rubber A strain gauge type load cell characterized by being covered with a coating material or a chloroprene rubber coating material.