FR2709546A1 - Methods and devices for producing calibration masses - Google Patents

Abstract

The invention relates to a method for producing calibration masses used for metrological tests. They are easy to manipulate by virtue of two gripping systems (journals and hole pierced in the axis of the mass). The operations of comparison with reference masses and adjustment are carried out without horizontal displacements.

Description

The development of the organization of Quality increases the needs for metrological controls, in particular for weighing operations, essential operations in many industrial processes. Mandatory periodic controls of instruments are carried out using standards.

When the value of the standards reaches or exceeds one hundred kilograms, it is agreed to call them "calibration masses". These masses must themselves be periodically compared to reference masses. The development of the organization of Quality in the industry considerably increased the number of control operations, and the value of the masses used.

It is therefore advantageous to optimize the conditions for production, adjustment and comparison, these are the objectives of the present invention.

According to the current state of the art, the calibration weights generally consist of a vertical metal cylinder whose diameter and height are approximately equal. The mass is adjusted by polishing. The operation is made delicate by the risk of exceeding the object, causing the scrap of the part. In addition, the ratio of dimensions indicated above makes it difficult to stack the masses, an operation often necessary during inspections.

According to the present invention, the mass diameter is approximately four times the height, thus allowing easy and stable mass stacking.

According to the present invention, the mass is provided with four pins located in orthogonal axial planes. Each pin is located in the upper third of the generator of the cylinder, which allows the mass to be supported in a stable manner by only two pins. According to the invention, to prevent compression of the air in the cavity during assembly of the pin, a groove is formed along a generatrix of the internal cylindrical part of the pins. The length of this groove is such that it does not open to the outside after assembly to eliminate the risk of particle deposits. In the context of the invention, three of the pins are mounted tight in their housing by the cryogenic process. According to the invention, the internal cylindrical part of the fourth pin is terminated by a thread making this pin removable during adjustment. The front of the threaded part can be touched up during adjustment.

For applications requiring a one-piece mass, the pin can be secured by known means. During the comparison operations between a calibration mass and a reference mass, the process requires successive and alternating applications of the two masses to the comparison instrument. In the current state of the art, these manipulations are carried out by lifting and lateral transfer by known handling means. The duration of these operations is relatively penalizing.

Figures 1, 2, 3 explain the construction of the devices. FIG. 1 represents a calibration mass according to the invention: 1 is the cylindrical body, 2, 3, 4 are three journals mounted tight, 5 is a dismountable journal. 2 shows a pin mounted tight.: L is the cylindrical body, 2 is the air exhaust groove. Figure 3 shows a removable pin.: Is the cylindrical body 2 is the threaded part, 3 is the surface allowing the adjustment, 4 is a flat allowing the tightening.

The use of these various devices facilitates the production and adjustment according to an objective of the invention.

According to the invention, the comparison instrument is a weighing gantry of a known model and devices falling within the scope of the invention are implemented so that the operations can be carried out without horizontal displacement.

Figure 4 facilitates the understanding of the process and the devices.

In figure 4, 1 is the reference mass, 2 the calibration mass being checked, 3 is a lifting beam, 4 the comparator sensor, 5 lifting winches, 6 a transport pallet, 7 the weighing gantry, 8 an axial hole made according to the invention in the reference mass, 9 a seat arranged in this hole according to the invention, 10 a suspension rod, 11 a cone arranged on this rod.

The operation is as follows: At the start of operation, the winches 5 keep the mass 1 raised by straps. The mass 2 is brought onto a pallet and the straps of the lifter 3 are placed on the pins. The pallet 6 is lowered and the mass 2 is applied to the sensor 4. After reading and entering, the mass 2 is raised and the winches 5 lower the mass 1.

The seat 9 comes to rest on the cone 1 1 applying the mass 1 to the sensor 4.

After reading and entering, mass 1 is read, a cycle can start again, the relative value of handling times is reduced.

Claims (6)

1) Calibration mass intended for metrological controls, in particular for weighing operations, characterized in that it is produced in the form of a cylinder whose diameter is approximately four times its height 2) Calibration mass according to claim 1 characterized in that it is provided with four journals located in orthogonal axial planes 3) Calibration mass according to claim 2 characterized in that the journals are provided with a groove (fig. 2/4: 2) along a generatrix of the cylindrical part of the trunnion located inside the mass after assembly, this groove not opening out after assembly. 4) Calibration mass according to claim 2 characterized in that at least one of the pins is provided with a threaded part (fig. 3/4: 2) allowing its disassembly for adjustment, at least until the end trimming. 5) Calibration mass according to claim 2 characterized in that at least one of the pins at its internal end (fig. 3/4: 3) to the mass prepared for machining allowing adjustment. 6) Method for producing a calibration mass according to claim 5 characterized in that the comparison and adjustment operations are carried out without horizontal displacements (fig. 4/4). 7) Calibration mass according to claims 1 and 4 characterized in that a hole (fig. 4/4: 8) is drilled in the axis of the mass and provides a conical seat (fig. 4/4: 9 ). 8) Calibration mass according to claims 1 and 5 characterized in that the conical seat (fig. 4/4: 9) is located in the upper part of the axiaL hole (fig. 4/4: 8)