SU798536A1 - Plant for testing specimens in corrosion-active media at high pressure and temperature - Google Patents

Description

5 and nuts 6. The flange 4 is equipped with a heater 7,

Inside the camera 1 is set to capture

8 for attaching the test specimen

9 and a device for pressure compensation, made in the form of two edges attached to the chamber 1 and in parallel with the installed membranes 10

and 11, forming a sealed cavity A, and the membrane 10 is rigidly connected to the stem 12 connected to the gripper 8, and the membrane 11 is rigidly connected to the sleeve 13 freely attached to the rod 12. Sensors 14 are mounted on the membranes forming the sealed cavity A perceiving force applied to the sample, and collected in a bridge circuit.

The sample loading unit consists of an electric motor 15, which transmits forces through the system of gearboxes 16 to the power rod 17, which passes through the gland (not shown) and abuts against the sample under test.

The installation is equipped with a pump 18 serving to supply the medium to chamber 1 and create a high pressure in it with a gas volume compensator consisting of a pressure vessel 19 and a cylinder 20 with compressed nitrogen, a pipe 21 connecting the chamber 1 with a volume compensator, and installed on the pipeline valve 22 for draining the medium.

The installation works as follows.

The test sample 9 is fixed in the gripper 8 and the flange 3 is closed with studs 5 and nuts 6. When the electric motor 15 is switched on, the sample 9 is loaded with a power rod 17. The loading force sensed by the sample 9 is transferred to the membrane 10, which bends by a certain amount, causing the signal of the sensors 14 is proportional to the loading force transmitted by the power rod 17. The pump 18 creates in the chamber 1 a high pressure of the medium, which, acting on the sample 9 and the grip 8, causes an additional deflection of the membrane 10, and the investigator but, and further increase the signal sensor 14 mounted thereon. At the same time, the sleeve 13 is observed to move along the stem 12 and the deflection of the membrane 11 with sensors W, which passes only due to the pressure of the medium. Balancing the bridge circuit, eliminating the pressure effect on

readings of sensors mounted on the membrane 10.

The subsequent change in the pressure of the medium in the chamber according to any law leads to a proportional change in the deflection f of both membranes 10 and 11, which eliminates the effect of pressure on the test results. The medium is heated by the heater 7, and the increase in the volume of the medium is compensated

due to absorption by its vessel 19, laziness through pipe 21. After the sample is destroyed, the heater 7 is turned off and, opening the valve 22, the pressure is released.

The proposed design of an installation with a pressure compensation device used in it allows testing both at variable temperatures and pressures, and at constant

0 approaching test conditions to operational. The installation allows an increase in the accuracy of testing samples that are destroyed with large plastic deformation, since it does not contain

J bellows with a small axial stroke, as well as due to the use of a device to compensate for the effect of medium pressure.

Claims (2)

1. USSR author's certificate number 243936, cl. G 01 N 3/36, 1968. 2. USSR author's certificate  120945, class G 01 N 3/18, 1958 (prototype).