RU81349U1 - DEVICE FOR STABILIZING LIQUID PRESSURE AT THE INPUT OF THE DISPENSER - Google Patents

Abstract

The utility model relates to process control, and can be used as a pressure vessel, providing stable pressure at the inlet of the liquid reagent dispenser, both pulsed and continuous dispensers. It is used for dosing flotation reagents at concentration plants in metallurgy. Structurally, it is made in the form of a cylindrical vessel, inside of which there is a vertically movable float connected to a pusher acting on a shut-off device that moves against the input liquid reagent flowing into the end of the cylindrical vessel. When the input fluid stream is larger than the output stream, the float floats and blocks the flow of fluid into the vessel. Moreover, the level in the pressure vessel changes within small limits. The proposed device allows to reduce the weight and overall characteristics of pressure tanks by 5-10 times.

1 n.a.s.f-ly, 1 ill.

Description

The proposed utility model relates to automation, in particular, to devices for dispensing liquid reagents during flotation of non-ferrous and other metals ores to stabilize a given flow rate of a liquid reagent.

A device [1] is known for stabilizing the pressure at the inlet of a liquid reagent dispenser — a supply tank representing a pressure vessel, a float, a lever system, a locking device, a separator — a separation grid, input and output pipes. The device [1] has a narrow input pressure range, is imperfect, complex, has large dimensions and low reliability due to the presence of a lever system mechanically associated with the float and the locking device.

A device [2] is known - a flushing cistern containing a volumetric cistern, inside of the casing of which control valves are mounted, consisting of a liquid inlet valve, a liquid discharge valve containing floats, pushers of the saddle, rod and lever, overflow hole. The device [2] is complicated, has low reliability and low throughput of the inlet fluid.

The prototype of the proposed device is a device [1].

The scheme of the proposed device is presented in Fig. 1, which shows:

1 - consumption capacity,

2 - dosed reagent,

3 - inlet pipe

4 - manual control valve,

5 - detachable connection, for example, "American" [3].

6 - fitting saddle,

7 - locking device

8 - pusher (stock),

9 - pressure tank

10 - supporting bracket,

11 - locking spring

12 - centering element

13 - float,

14 - guides

15 - output pipeline

16 - dispenser of liquid reagents,

17 - fitting

18 - the direction of movement of the locking device 7,

ΔН is the change in the level of the reagent in the supply tank 1,

H - level above the locking device 7,

Δh is the change in the level of the reagent in the pressure vessel 1,

D _BX - diameter of the nozzle-saddle 6,

Dп - diameter of the float.

A float 13 is located inside the pressure vessel 9. The vertical movement of the float 13 inside the pressure vessel 9 is provided by a centering element 12 mounted on the support bracket 10, a pusher 8 and guides 14 fixed on the lower part of the float 13. The support bracket 10 is fixed in the upper part of the pressure vessel 9 The pusher 8 is fixed in the float 13.

With the manual control valve 4 open, the ratio is:

Fp-Pp + Fpr≥Fp (1),

where Fp is the buoyant force of the liquid reagent acting on the float 13, Pp is the weight of the float with the pusher 8 and the locking device 7, Fpp is the force of the compressed spring 11 acting on the locking device 1, Fp is the force acting on the locking device 7, due to pressure of the reagent from the supply tank side 1. A change in the level Δh for the cylindrical pressure tank 9 and the cylindrical float 13 is characterized by a stabilization coefficient

ΔH / Δh = (Dп / D _BX ) ² , (2),

Therefore, with the corresponding diameters 3 of the inlet fitting-saddle 6 and the float 13, a preset stabilization coefficient of the level of the liquid reagent in the pressure vessel 9 is provided.

The proposed device operates as follows.

When you open the dispenser 16 of liquid reagents, the level of reagent h in the pressure tank decreases and the buoyancy force Fp acting on the float 12 connected to the shut-off device 7 decreases due to a decrease in the level of the reagent in the pressure tank 9. Therefore, under the action of the pressure force of the reagent on the shut-off device 7, the level h in the pressure vessel 9 is restored due to the shut-off device moving down in the direction indicated by the bidirectional arrow 18. The condition for stabilizing the reagent level in the pressure vessel 9 is raising the reagent inlet stream 2 through the nozzle-saddle 6 above the outlet stream from the liquid reagent dispenser 16 installed on the outlet pipe 15. The inlet 17 serves to ensure equality of external and internal pressure in the pressure vessel 9 and to control the excess of the permissible level of reagent in the pressure vessel 9.

The locking spring 11 allows you to increase the permissible input pressure of the reagent from the supply tank 1, which allows to increase the throughput of the device without increasing the volume of the float 13. This is a useful distinguishing feature of the proposed device in comparison with the prototype and allows to reduce the overall dimensions of the device.

The device is set to a predetermined input pressure of the liquid reagent when releasing the connector 5 of the connector 6 by releasing it by moving it in the direction of movement of the input stream of the liquid reagent.

The proposed device due to the elimination of the lever system in it made it possible to reduce the weight and overall dimensions compared to the functionally identical device [1] by 5-10 times, to provide improved environmental and ergonomic characteristics and therefore is a useful device used in various fields of production when dispensing liquid reagents.

The novelty of the utility model is provided by the presence of new structural elements, the presence of new relationships between them, the new design of the elements and their relative position. Namely: the presence of a direct pusher connected to a locking device that blocks the flow of reagent, locking spring, support bracket and interacting with each other through the nozzle-saddle, the presence of a detachable connection between the inlet pipe and the nozzle-saddle, their relative position in the direction of the buoyant force of the reagent, acting on the float. The proposed device for stabilizing the pressure of a liquid (reagent) has high reliability,

due to the proposed design, and has a small size due to the fact that the pressure tank is a casing for the float, and the dimensions of the float are small due to the locking spring inserted into the device.

The proposed device is widely applicable for dosing by pulsed and continuous batchers of flotation reagents in technological processes of enrichment in metallurgy and other industries.

Literature:

1. Product documentation - “Installation for placement of pulse reagent feeders URIP-6A”, OJSC “Soyuztsvetmetavtomatika”, - Moscow, 2004

2. Product documentation - “Drain tank fittings”, AB 68.00.000 / 03, Pskov, CJSC Uklad, 2007

3. The catalog “American Coupling”, 2008, Standard LLC, www.standart-trade.ru

Claims (1)

A device for stabilizing a liquid pressure at the inlet of a liquid reagent dispenser, comprising a consumable container, a manual inlet valve, inlet and outlet pipelines, a container with a float located therein and connected to a locking device, characterized in that the float floating in the liquid (reagent), connected directly to the pusher (rod) inserted into the device, one end of which is rigidly connected to the float, and the second end of the pusher is connected to the locking device; a support bracket with a pusher centering element is introduced, a spring connected to the pressure vessel, one end of which completely covers the centering element, pushing away from the support bracket, and the second spring end acts on the locking device moved in the container; in the lower part, the float is equipped with guides that provide a movable connection between the float and the pressure vessel by sliding the guides on the inner surface of the pressure vessel, and the diameter of the pressure vessel float exceeds the diameter of the nozzle-saddle; through a detachable sleeve, the pressure tank is connected by a pipeline to the supply tank.