SU1610302A1 - Apparatus for determining mass of liquid in filter materials - Google Patents

Abstract

The invention relates to devices for accurately weighing the amount of fluid carried by a filter element, preferably used in a curtain filter. The aim of the invention is to improve the accuracy of measuring the amount of fluid entrained in a measured sample of filter material. A sample of material 4 is placed in the frame 22, suspended on the thread 3 to the force-compensation meter 2, then the same sample is inserted into the cassette 17 of the simulator 10. Both samples are reliably connected using stops 18 and staples 20 with the levers 19. Simulator 10 by means of threads 11 and the contacts 16 are attached to the included electromagnets 12 mounted on the movable shelf 5. The system thus connected is lowered into the tank 1 by means of the movement mechanism 7. After the test sample leaves the tank 1 liquid, the movable stop 14 through the switch 15 opens the circuit of electromagnets 12 and the simulator is reset. At this point, the weight of the fluid entrained by the filter element is recorded. 2 Il.

Description

The invention relates to devices for accurately weighing the amount of fluid entrained in a filter element, preferably used in curtain filters.

The purpose of the invention is to improve the accuracy of measuring the amount of fluid entrained in a measured sample of filter material by creating conditions close to actual conditions of the filter.

Fig, 1 shows the proposed device during the lifting of the test sample of filter material from the liquid tank together with the simulator, a general view; in fig. 2 t is the same at the time of weighing the mass of fluid carried by the material when the simulator was separated from the test sample.

The device contains a liquid tank 1, a force-compensating meter 2 with thread 3 for hanging the measured sample 4. The force-compensating meter 2 is an autonomous tracking system that automatically measures the input force by the zero method by achieving an equilibrium between two oppositely directed torques. A prototype 4 of the material is suspended on one of the arms of the sensor of the compensating meter on the thread, and a counterweight is suspended on the second shoulder that compensates for the dry weight of the sample of material. The scale of the recorder (not shown) records the net weight of the fluid in the prototype material. The sample under study is lowered and raised using a movable shelf 5 moving in guides b using a movement mechanism 7 consisting of an electric motor, a drum 8 and cables 9. A simulator 10 is mounted on Suspensions on a moving shelf 5 to approximate the test conditions to real ones 11. In addition, electromagnets 12 and brackets 13 with a movable stop 14 are mounted on the movable shelf 5 and a switch 15 is mounted on the rail. On the suspensions 11 contacts 16 are installed at a distance from the movable shelf 5 longer than the electromagnet Fig. 12. The simulator 10 is made of a cassette 17 with constraints 18 and latches, which in turn consist of levers 19 and brackets 20 interconnected. In order to evenly and reliably lift the test sample 4 to the drum 8, two cables are attached .9, and along the edges there are inclined ribs 21, which give the initial direction of winding the cables 9, test sample 4 is installed in

a frame 22 connected to a force-compensation meter 2 by a thread 3.

The device works as follows.

In order to determine the amount of water

entrained by the filtering material during the movement of the curtains through the filter tank with water during the regeneration of this material from solid dust particles, it was necessary to conduct studies, during which it would be possible to weigh the mass of moisture trapped by the material. Weighing of water entrained by the filtering material is carried out in the device, the description of which is given above. A sample of the filtering material from which the blinds will be made is installed in the frame 22, (FIG. 1), suspended on the thread 3 to one of the arms of the compression compensator measure 2, then the same sample is inserted into the cartridge 17 to imitate the operation of the curtain filter, in which all the curtains are in contact with each other. During the exit of the curtain from the water tank, most

5 moisture flows into the lower curtain. In the proposed device, the separation of the upper material from the lower one is excluded, since the frame 22 with the test material is installed between the limiters 18 of the simulator cassette 17 and clamped with brackets 20, which are connected to the levers 19 and pivotally connected to the cassette 17 and threads 11 The contacts 16 are located on the thread x 11 in such a position that when the electro magnets 12 are turned on and the contacts 1-6 are connected to them, the brackets 20 are reliably pressed against the material under study (sample 4). The system thus connected from the test material (sample 4) and simulator 10

0 is lowered into the water tank 1 by turning on the mechanism 7 for moving and rotating the drum 8. The movable shelf 5, together with the filtering materials (sample 4 and simulator 10) and the slope compensation meter 2, are moved down by their own weight. When the movement mechanism 7 is activated in the lifting mode, the drum 8 rotates in the other direction and through the cables 9 lifts the entire

0 system. After the sample 4 and simulator 10 exit above the water surface, the movable stop 14 reaches the switch 15 and opens the electromagnet circuit, as a result of which the contacts 16 are opened and connected to the set 17 with the simulator 10 from the sample 4 (Fig. 2) At this moment The force compensation meter records, on the recorder, the mass of liquid remaining in the sample under test. Height

the rise of the sample under study can be adjusted by mixing the movable stop 14 relative to the bracket 13. The lifting speed of the movable bar 5 together with the materials is regulated by changing the speed of the electromotor mb-Khanizm 7 of the ground motion. In order to eliminate the winding of the cables 9 onto the drum 8 in several rows, due to which acceleration occurs when the test specimen with the simulator rises, along the edges of the drum 8 there are inclined rims 21 giving the cables 9 a winding direction in one layer, excluding overlaps and uneven winding.

The connection of the filament 3 of the force-compensation meter 2c frame 22 allows (without modifying the connection itself) to examine various samples of filter material by placing it between these frameworks,

The indicated ha in the drawing near the right lever 19 (not indicated by the position number) is necessary so that the sample to be tested moves strictly vertically. This ta ha is not indicated, since structurally in the proposed device it is possible to mount the suspensions 11 on the movable bar 5 parallel to each other and at the same distance from the thread 3, to which the frame 22 with the test material (sample 4) is attached, in this case m ha is not required.

Claims (1)

Invention Formula A device for determining the mass of a liquid in filter materials of a curtain filter containing a force-measuring sensor mounted on a movable shelf placed above the liquid tank, suspended from the drum cable associated with its rotation drive, characterized in that A cassette for the sample to be measured is inserted into it, two electromagnets with a limit switch, a second cable through which the movable shelf is suspended to the drum, a simulator made in the form of another filter cassette a material pivotally connected from two opposite sides through a corresponding arm with a flexible suspension equipped with a contact for an electromagnet and a bracket under a cassette for the sample to be measured, with the electromagnets attached to the movable shelf from below, the limit switch fixedly mounted , to which flexible suspensions are attached, and the distance from the movable shelf to the contacts is greater than the length of the electromagnet, in this case the drum is made with inclined flanges. FIG. 2