SU662050A1 - Device for measuring volume of porous fibrous materials - Google Patents

Description

(54) DEVICE FOR MEASURING THE VOLUME OF POROUS FIBROUS MATERIALS

The invention relates to agriculture, namely, sericulture, and can be used in determining the silk mass of cocoons.

A device for measuring the volume of living cocoons is known, which contains auxiliary and working capacity and a pressure gauge for comparing pressures 1.

It is also known a device for measuring the volume of porous fibrous materials containing a working, auxiliary and two storage containers placed in a thermostat 2.

These devices have the following disadvantages: to create an overpressure in the comparative and loading tanks, the method of bypassing compressed air from auxiliary tanks is used, the pressure in which is controlled with the help of pressure gauges having: low ACCURACY class. Therefore, in the known devices, there is a fault due to the difference in the magnitude of the excess pressure in the working tanks when they are the same load. In addition, the V-shaped liquid manometer used in such a device does not allow automating the process of determining the silk-bearing condition. as it uses liquid level as a pointer. And to increase the sensitivity of the required, significantly increase the overpressure in the measuring capacitances, which is not always possible 1, 2.

The purpose of the invention is to increase the accuracy and quickly measure the volume of living cocoons.

The goal is achieved by the fact that the tanks are equipped with pneumatic dozers, which are made in the form of a spherical chamber with a flat, soft diaphragm, which divides the chamber into hemispheres, with loading

5, the tank is connected to the air flow meter by means of a drain valve with an electrocontact diaphragm sensor, and the caps to the tanks are made in the form of a disk with an annular seal and a clamping lever.

FIG. 1 is a schematic diagram of the device; in fig. 2 - pneumatic doser; in fig. 3 - comparative and bootable

EMC © (GTI with a common cover; Fig. 4 - Electro-contact membrane sensor of zero differential pressure.

The device contains a compressor 1, a receiver 2, solenoid valves 3-7, pneumatic dozers 8 and 9, consisting of hemispherical limiting cases - the upper 10 and lower 11 and a soft flat diaphragm 12 fixed along the flange, fittings 13 and 14. Using a vacuum gauge 15 and the electrocontact gauge 16 control the operation of the pneumatic feeders.

Comparative container 17 and loading container 18 are made paired and equipped with a sealing device that allows to seal the containers without changing their initial volume and consisting of a latch 19 fixing the first, primary container volume, seal 20, cover 21, pressure lever 22, lower cam 23, the upper cam 24 and the handle 25. The electrocontact diaphragm sensor 26 of zero differential pressure consists of a membrane 27 dividing the sensor housing into two parts 28, each of which has fittings 29 for connecting to the system. A fungus 30 is fixed on the membrane, in the center of which there is a contact 31 located opposite to the fixed contact on the screw 32. The drain valve 33 through the air flow meter 34 communicates the loading capacity to the atmosphere. The comparative and foreign containers, as well as the pneumatic doser, are placed in a thermostat to eliminate the effect of changes in the ambient temperature.

The device works as follows.

In the initial position, valves 4, 6 and 7 are open, and valves 3, 5 and 33 are closed. A reference sample of cocoons with known silkness is laid in a comparative capacity of 17, and cocoons, whose silk cone need to be determined, are placed in loading capacity 18. Then, the sealing device is closed by turning the handle 25. At the same time, the upper cam 24 rotates and informs a vertical downward movement to the lower cam 23, the presser lever 22, the lid 21 and the retainer 19, which fixes the chamber volume, and the lid 21 seals the joint between the cylinder and retainer. The force is transmitted to the seal 20 only around the perimeter of the cover 21, therefore, at any values of the force transmitted with the lever 22, there is no change in the initial volume of the comparative and load capacities.

After closing the sealing device, compressor 1 is turned on. When valve 4 is open and valves 3 and 5 are closed, the compressor operates in vacuum pump mode. At the same time, a vacuum is created in the pneumatic doser, under a soft flat diagram 12, and it is attracted tightly against the lower body - the stopper 11 with the choke 14. Since valves 6 and 7 are open in the upper cavity of the pneumatic feeders, as well as in the comparative 17 and 18 load tanks, atmospheric pressure is established. Upon reaching a certain amount of vacuum controlled

vacuum gauge 15, valves 4, 6, 7 are closed, and valves 3 and 5 are opened. From this moment on, compressor 1 starts to operate in compressor mode. The air injected in advance and injected by the compressor into the receiver 2 enters the lower

the cavity of the pneumatic dozers 8 and 9, the mode of operation of which is controlled by an electric contact pressure gauge 16. Aperture 12, the passage is in the initial position, adjacent to the upper body - the stopper 10 with the choke 14 ,. displaced the entire amount of air in the spherical cavity of the pneumatic feeder, respectively, into a comparative 17 and a loading 18 tank. As a consequence, strictly defined overpressure is created in the containers. If the value is pressure

neither in containers 17 and 19 are the same (which takes place with the equal silkness of the loaded sample of cocoons with the reference one), then the pressure difference between these tanks is zero. What the sensor 26 signals.

In the case of unequal silkworm of the loaded sample of cocoons and the reference one, the drain valve 33 opens automatically, and the excess air from the loading tank is discharged to the atmosphere through the flow meter 34. Upon reaching zero pressure drop between the comparative and loading tanks, the sensor 26 closes the drain valve 33. The countdown

removed from the air flow meter 34, will be proportional to the alkalinity of the loaded cocoon sample. According to a pre-compiled nomogram, the sample silk cocoons are determined. Then all the valves are opened, except for the bleed 33, the compressed air is released from the system, and then the valves 3 are closed, and 5. This completes the cycle.

To establish the zero position on the electrocontact membrane sensor, it repeats the whole cycle with loading the reference samples — cocoons with equal silk content — into the comparative and loading capacities. Next, using the adjusting screw 32, the stationary contact is shifted until it interacts with the contact mounted on the membrane of the zero differential pressure sensor.