JPH0243126B2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to a load cell scale.

Generally, some load cell scales are equipped with a stopper. In conventional load cell type scales, a stopper is installed at the bottom of the plate support rod to prevent damage to the load cell due to overload, and in scales where part of the plate support rod and part of the load cell are integrated, had a stopper installed at the bottom of the load cell. However, the amount of displacement of the load cell is usually 0.1 to 0.3 relative to the rated load.
Since the displacement is about 1/2 mm, it is extremely difficult to control the load limit of the load cell so that the stopper operates within a large variation range of, for example, 1/2 to 1/10 of the displacement. Furthermore, load cell scales that have double plates via an elastic body such as a spring and a stopper between them have defects in strength because the four corner loads on the plates are applied to the springs, etc. There was a drawback that the load limit of the load cell changed depending on the load position on the plate.

Embodiments of the present invention will be described below based on the drawings.

FIG. 1 is a configuration diagram showing the above embodiment. The load cell 1 has a double beam shape, and a plate 2 on which a sample is placed is fixed to the upper end of a plate holder 9. plate 2
The gap between the upper part of the load cell 1 and the upper part of the load cell 1 is small. The support part 12 of the load cell 1 is fixed inside the scale, and when a load is applied on the pan 2, the load cell 1
is deformed, and the load displacement point of the plate support portion 9 is displaced. A protrusion 11 is formed integrally with the load cell 1 at a load displacement point of the plate holder 9. The protrusion 11 has a horizontally formed abutment surface, and the force point 1 of the lever 3 is connected to that surface.
0 are almost in point contact. The lever 3 rotates about a bearing 4 as a fulcrum. The stoppers 6 and 7 suppress the swing of the free end 5 of the lever 3 within a predetermined range. The load limit of the load cell 1 is set by adjusting the width between the stoppers 6 and 7 with a screw according to the allowable load of the load cell 1.

Note that a weight 8 of a predetermined weight is attached to a predetermined position of the lever 3 on the free end 5 side. By adding this weight 8, the dead weight of the scale is eliminated. Further, this dead weight can also be eliminated by applying a force to the lever 3 in the opposite direction to the load using a spring or the like.

Next, the operation of the above embodiment will be explained. When unloaded, the free end 5 of the lever 3 is moved by the stops 6 and 7.
Do not come into contact with. Therefore, when a sample is placed on the pan 2 and a load is applied, the vertical displacement of the protrusion 11 of the pan holder 9 is magnified by the lever 3. Furthermore, when a load greater than the set value is applied, the free end 5 hits the stopper 6, and no load greater than the set value is applied to the load cell 1.

Note that since the contact surface of the protrusion 11 is formed horizontally, the force point 10 is
slides on the contact surface, and its horizontal displacement is not transmitted to the lever 3.

Next, a modified embodiment of the invention will be described with reference to FIG.

A protrusion 23 integrally formed with the load cell 1 is provided at a load displacement point of the plate holder 9. Protrusion 2
3 is connected to the force point 21 of the lever 3 via an elastic body 22. The elastic body 22 and the fulcrum 20 of the lever 3 are each made of a leaf spring. The elastic body 22 and the fulcrum 20 have their leaf spring surfaces aligned with the lever 3.
It is formed almost perpendicular to the axial direction of the
In this way, the horizontal displacement of the plate holder 9 is not affected by the deflection of the lever 3 at all, and only the vertical displacement of the load cell 1 can be transmitted to the lever 3. Further, the force point 21 of the lever (3) and the protrusion 23 of the tray holder 9 are integrally connected, so that mutual wear does not occur and the lever can withstand permanent use.

As described above, the present invention has the following effects.

It is possible to provide a stopper having a small variation of about 1/10 to 1/100 of the displacement of the load cell due to the rated load.

Since the displacement of the load cell is magnified and suppressed by the lever, the load limit of the load cell can be set with high precision.

The allowable load of a load cell is usually the rated load.
150%, but it is possible to manufacture a scale that can withstand a higher load.

Since the free end of the lever is a stopper that swings in the vertical direction, by adding weight to the lever and applying it to a load cell that can measure up to the negative load range, the measurement range can be doubled.

Compared to a scale in which two plates are connected by a spring and a stopper is provided between them, in the scale of the present invention, only the load cell has superior strength against the four corner loads on the plate. Furthermore, regardless of the position of the load on the plate, the load limit at which the stopper operates is constant.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention. FIG. 2 is a block diagram showing a modified embodiment of the invention. 1...Load cell, 2...Plate, 3...Lever,
4... Bearing, 5... Free end, 6, 7... Stopper, 10... Force point, 11... Projection.

Claims (1)

[Claims] 1. In a scale that measures load using a load cell, there is a lever that rotates around a fulcrum provided inside the scale to magnify the displacement of the load cell due to the load, and a lever that suppresses the swing of the free end of the lever within a predetermined range. 1. A load cell type scale comprising: a stopper that is connected to the load cell; and a protrusion that is formed integrally with the load cell and that is engaged by the force point of the lever.