RU2060533C1 - Device for adjusting liquid discharge - Google Patents

Abstract

FIELD: electric engineering; instrument engineering. SUBSTANCE: device has turned over airtight cup, vessel-governor, bell, bowl, air tube and branch, Mariotte vessel, head tank, more tube, discharge vessel, drainage cock, service liquid, and hole. EFFECT: improved design. 2 cl, 3 dwg

Description

 The invention relates to devices for controlling continuous fluid flows, for example, in technological processes of coating products of extended shape, and can be used in electrical, instrument-making, and other industries.

 Known pressure regulator and fluid flow rate, containing a Marriott vessel, equipped with shut-off, air and drain valves, and connected to a pressure tank, which maintains a constant liquid level, with a flow tank for draining an adjustable fluid equipped with a drain valve. The flow rate of the merging liquid is determined by the height of its column in the supply tank, which depends on the level of the liquid in the Marriott vessel, which is installed using shutoff, drain and air taps.

 The disadvantage of this device is the disruption of the fluid flow at the time of leveling in the Marriott vessel by manipulating the shutoff, air and drain valves.

 The aim of the invention is to improve the accuracy of controlling the parameters of the fluid flow by influencing the process without interrupting the fluid flow and simplifying the design.

 This is achieved by the fact that the Marriott vessel, connected to a pressure tank and a supply liquid equipped with a drain valve, is additionally equipped with a regulator with an upside-down sealed glass, a bowl with a bell with the possibility of vertical movement, an air tube and a pipe. In this case, the cavity of the inverted sealed cup, the lower edge of which is located below the level of the working fluid located in the regulator vessel, which has the ability to move vertically, is connected by an air tube to the cavity of the Marriott vessel, and the specified pipe is inserted into the fluid located at the bottom of the cavity of the sealed chamber glass, and the other end brought into the cavity of the bell, the lower edge of which is located above the surface of the working fluid in the bowl. The capacity regulator and bell are equipped with drives for their vertical movement.

 In order to simplify the design, the bell can be made in the form of a float with an internal cavity, in the wall of which a hole is made above its waterline connecting the internal cavity with the atmosphere.

 In FIG. 1 schematically shows the proposed device for controlling fluid flow; figure 2 droplet; figure 3 is a variant of the bell, made in the form of a float.

 The device comprises an inverted sealed cup 1 placed in a regulator vessel 2, which can be vertically moved, a bell 3, placed in a cup 4 and capable of vertical movement, an air tube and a nozzle 5. The upper part of the cavity of the glass 1 is connected by an air tube 6 to a Mariotte vessel 7 with a flow tank 10 connected to it by a tube 9, equipped with a drain valve 11, and a pressure tank 8. The lower part of the cavity of the sealed canister 1 is connected by a pipe 5 to the bell cavity 3. The regulator capacity 2 is equipped with a drive 12 for its vertical movement with respect to the glass 1; the bell 3 is equipped with a drive 13 for its vertical movement with respect to the bowl 4.

 In the tank-regulator 2 is a working fluid 14, the level of which is located above the lower edge of the sealed glass 1.

 In the bowl 4 is a working fluid 15, the level of which is located below the lower edge of the bell 3 or the through hole 16 in the wall of the float 3 when using the float as a bell (see figure 3).

The device operates as follows:
After closing the drain valve 11 into the Marriott vessel 7 through a hydraulic shutter 17 or a drop former (see Fig. 2), liquid is drained from the pressure tank 8 until a pressure of "H" equal to the height of the liquid column between the level is established in the cavity of the Marriott vessel And in the pressure tank 8 and level B, the level of discharge of liquid into the Marriott vessel 7. At the same time, in the supply tank 10, the column of liquid rises to level B, which exceeds the level of liquid G in the Mariotte vessel by N.

 When the fluid flows from the supply tank 10 through an open drain valve 11, the pressure drop from the decrease in the liquid level in the supply tank 10 is transferred through the tube 9 to the Marriott vessel, which leads to the outflow from the pressure tank 8 into the Marriott vessel 7 of such a quantity of liquid that drains through the drain crane 11.

 Vertical movement with the drive 12 of the tank-regulator 2 upwards leads to an increase in the level of the working fluid 14 in relation to the sealed glass 1 and, according to the principle of communicating vessels, to an increase in pressure in the cavity of the glass 1, which is transmitted through the air tube to the cavity of the Marriott vessel, reducing fluid level G in a Mariotte vessel and thereby reducing fluid flow. Vertical movement by means of a drive 12 of the tank-regulator 2 downwards leads to a decrease in the level of the working fluid 14 relative to the sealed cup 1 and, by the principle of communicating vessels, to a decrease in pressure in the cavity of the cup 1, which is transmitted through the air tube to the cavity of the Marriott vessel, increasing the liquid level G in a Mariotte vessel and thereby increasing fluid flow.

 Vertical movement by means of the actuator 13 of the bell 3 down and immersion of its lower edge under the level of the working fluid 15 located in the cup 4, leads to an increase in the level of the working fluid in the cup relative to the bell, which, by the principle of communicating vessels, leads to an increase in pressure in the cavity of the bell 3. With this increase in pressure, part of the air from the cavity of the bell 3 is displaced through the pipe 5 into the cavity of the glass 1 in the form of an air bubble under increased pressure. The connection of the bubble with the air in the cavity of the glass leads to an increase in pressure in this cavity, which propagates through the air tube into the Marriott vessel 7, lowering the height of the liquid column G in the Marriott vessel and thereby reducing the liquid flow rate.

 The return of the bell 3 up to its original position leads to the opening of its lower edge with the surface of the working fluid 15, the entry of atmospheric air into the cavity of the bell 3 and thereby prepares the bell 4 for subsequent immersion in the working fluid to reduce the flow rate of the merging fluid.

 The use of a device for regulating the flow of liquid will allow an effect to control or regulate the flow of liquid without interrupting it in various technological processes, in particular, for example, when applying liquid to the surface of products of extended shape: wire, tapes, strips, threads.

Claims (2)

 1. A device for controlling the flow of liquid, containing a Marriott vessel with a pressure tank attached to it and a supply tank, characterized in that it is equipped with a regulator with an upside-down sealed cup, a bowl with a bell mounted for vertical movement, an air tube and a pipe, the cavity of the inverted sealed glass, the lower edge of which is located below the level of the working fluid located in the capacity of the regulator, installed with the possibility of vertical movement Nia, an air tube connected with the cavity of the vessel Mariotte, and one end of said tube inserted into the liquid at the bottom of the cavity sealing glass and at the other end of the bell cavity displayed in the lower edge of which is located above the working surface of the liquid in the bowl.  2. The device according to claim 1, characterized in that the bell is made in the form of a float, in the wall of which a hole is made above its waterline connecting the cavity of the float with the atmosphere.

Images