RU78558U1 - OVER PRESSURE VALVE - Google Patents

Abstract

The technical result of this technical solution is to increase the reliability of valve operation in a wide range of changes in air pressure in ventilated rooms. The technical result is achieved by an overpressure valve characterized by the presence of a cylindrical body and a rotary plate pivotally connected to the body located in the body, wherein the plate is connected to the body by a plate rotation lever, the upper end of the rotation lever is rigidly connected to the plate, the lower end of the lever is made with a movable fixed counterweight , the front part of the lever is pivotally connected to the body, the valve is made with an eccentric plate clamp to the body, which is mounted on the body and its eccentric located with the possibility of interaction with the rotation lever and fixation in the working position with the plate closed. Cycle lever - figuratively with the front and bottom parts extending towards the plate, the rigid connection of the upper end of the lever with the plate is made by means of a detachable connection, the stud of which is screwed into a threaded hole made on the back of the plate, the hinged connection of the front of the lever with the body is made using brackets that are made on the housing, the front of the lever is located between the brackets and connected with screws with the possibility of rotation relative to the brackets around the screws. The eccentric clip includes an eccentric, -shaped eccentric rotation lever with an eccentric fixed to it and a latch for this lever, the eccentric rotation lever located in the holes of the brackets, the eccentric located between the brackets, the bent end of the eccentric rotation lever is a rotation handle, the other end of the lever

the rotation is made with a screw thread and a lever lock is screwed onto it, interacting with the surface of one of the brackets. The threaded hole on the back of the plate is made in the protruding elongated part of the plate, which is made on the back of the plate. A movable lockable counterweight is installed in the groove of the lower part of the lever, extending towards the plate. A movable lockable counterweight is pivotally mounted at the end of the lever with the possibility of its rotation relative to the lever in a vertical plane. 10 ill., 1 n.p.f., 6 p.f.

Description

This technical solution relates to devices of ventilation systems that ensure equalization of air pressure in ventilated rooms or in interconnected ducts having expansion cavities, or in ducts in general, in particular, to safety valves for balancing air pressure. The valve is designed to automatically maintain constant air pressure in adjacent rooms, including shelter rooms, by flowing air from one room to another in one direction. The valve is intended for its use in the field of construction, including in the field of construction of safety shelters.

Overpressure safety valves are known, each of which is characterized by the presence of a body and a rotary plate pivotally connected to the body located in the body, the plate being connected to the body by a plate turning lever, the upper end of the plate turning lever is rigidly connected to the plate, the lower end of the lever is movable in the longitudinal direction of the valve by a fixed counterweight (SU 1649217, 05/15/1991; SU985627, 12/30/1982; SU1439363, 11/23/1987; RU2162585, 11/27/2001; RU2166143, 04/27/2001; RU2293239, 02/10/2007; RU2059935, 05/10/1996; RU2067263, 09/27/1996; RU2080521, 05/27/1997; RU2133923, 07/27/1999; JP5 2-26061, 1973; GB109382. 1938).

The technical result of the technical solution presented in this description is to increase the tightness and reliability of the valve in a wide range of changes in air pressure in ventilated rooms. Another result of the technical solution is the creation of a simple valve design.

The technical result is achieved by an overpressure valve, characterized by the presence of a cylindrical body and a rotary plate pivotally connected to the body located in the body, wherein the plate is connected to the body by a plate turning lever, the upper end of the lever is rigidly connected to the plate, the lower end of the lever is made with a movable fixed counterweight, the middle part of the lever is pivotally connected to the body, the valve is made with an eccentric plate clamp to the body, which is mounted on the body and its eccentric position n with the possibility of interaction with the lever and fixation in the working position with the plate closed.

Cycle lever -shaped with the front and bottom parts extending toward the plate, the rigid connection of the upper end of the lever with the plate is made by means of a detachable connection, the stud of which is screwed into a threaded hole made on the back of the plate, the hinged connection of the front of the lever with the body is made using brackets that are made on the housing, while the front of the lever is located between the brackets and connected with screws with the possibility of rotation relative to the brackets around the screws.

The eccentric clip includes an eccentric, -shaped eccentric rotation lever with an eccentric fixed to it and a latch for this lever, the eccentric rotation lever located in the holes of the brackets, the eccentric located between the brackets, the bent end of the eccentric rotation lever represents the rotation handle, the other end of the rotation lever is screwed and screwed onto it lever lock interacting with the surface of one of the brackets.

The threaded hole on the back of the plate is made in the protruding elongated part of the plate, which is made on the back of the plate.

A movable lockable counterweight is installed in the groove of the lower part of the lever, extending towards the plate.

A movable lockable counterweight is pivotally mounted at the end of the lever with the possibility of its rotation relative to the lever in a vertical plane.

The drawings show one embodiment of the valve in its various designs.

1 shows an overpressure valve (first embodiment),

Figure 2 is a cross section of the valve of figure 1,

Figure 3 - diagram of the valve,

4 shows an overpressure valve (second embodiment),

Figure 5 is a cross section of the valve of figure 4,

Figure 6 shows the overpressure valve (third version),

Fig.7 is a cross section of the valve of Fig.6,

On Fig shows the overpressure valve (fourth version),

Fig.9 is a cross section of the valve of Fig.8,

Figure 10 presents the second execution of the lever mechanism of rotation of the plate. In this embodiment, the lower end of the lever is made rectilinear and a counterweight is connected pivotally with the possibility of fixation. In this version of the lever, it does not have a lower part. The front of the lever is not shown in FIG. 10.

The indicated versions of the valves are designed for different differential pressures in the rooms and these versions differ from each other in the diameters of the passage openings of the air ducts, as well as the layout solutions associated with the specified passage openings.

The overpressure valve is characterized by the presence of a cylindrical body 1 (Fig. 1) and a rotary disk 2 pivotally connected to the body located in the body. The plate is connected with the housing through the lever 3 of rotation of the plate (figure 2). The upper end of the lever 3 of the rotation of the plate is rigidly connected with the plate, the lower end of the lever is made with a movable counterweight 4 movable in the longitudinal direction of the valve. The lever 3 is pivotally connected to

body 1. The valve is made with an eccentric clamp 5 plates to the body. The plate clip is mounted on the housing 1 and its eccentric 6 is located with the possibility of interaction with the lever 3 of rotation of the plate and the possibility of fixing in the working position with the plate closed. The counterweight is made of two parts, with the ability to rotate relative to the lower part of the lever 3, or from one part. The counterweight 4 is mounted on the lower part of the lever 3 movably relative to this part and with the possibility of its fixation in a predetermined working position. In this case, the counterweight can be mounted pivotally on the lower part of the lever 3 and in shape it can be rectangular, round, elongated with an offset center of gravity relative to the axis of rotation, or have any other shape.

The lever 3 rotation plates made -shaped with the front and bottom parts 7 and 8, respectively, extending towards the plate. A rigid connection of the upper end of the lever 3 with the plate 2 is made by means of a detachable connection, the pin 9 of which is screwed into a threaded hole made on the back of the plate. The hinge connection of the lever 3 with the housing 1 is made by means of brackets 10 and 11 (Fig. 1), which are made on the housing, and by means of a lever 3 located between the brackets of the front part 7. The lever front part 7 is connected to the brackets by adjusting screws 12 with the possibility of turning the front part 7 of the lever relative to the brackets 10 and 11 around the screws 12. The counterweight 4 (FIG. 2) is movably fixedly mounted in the groove 13, which is made in the lower part 8 of the lever 3. The eccentric clip 5 includes an eccentric 6, -shaped lever 14 for turning the eccentric, the latter is rigidly fixed to the lever 14. The clamp also includes a latch 15 of the lever 14 and the eccentric 6 in their working positions. The eccentric rotation lever 14 is located in the holes of the brackets 10 and 11, the eccentric 6 is located between the brackets, the bent vertical end of the eccentric rotation lever 14 serves as a handle for turning the eccentric, and the other end of the lever 14 is made with screw thread and

the latch 15 of the lever is screwed on it. The latch interacts with the surface 16 of the bracket 11.

A threaded hole on the back of the plate 17 is made in the protruding elongated portion 18 of the plate.

The movable counterweight 4 is fixed in the groove 13 of the lower part 8 of the lever 3 by means of a screw 19 located in the holes of the counterweight and in the groove 13 of the lower protrusion 8 of the lever 3. The counterweight 4 in another design (Fig. 10) is connected by a screw 19 to the end of the lever 3 s the possibility of its rotation around the screw and the possibility of fixing it with a screw in a predetermined working position.

A casing 20 is fixed to the valve body 1, to which the cover 21 is pivotally attached with a plurality of holes 22. The body is bolted 23 to the duct flange 24 (not shown), while the flange is mounted, for example, in a wall between rooms (not shown).

The upper end of the lever 3 of the rotation of the plate is made with an eye 25, in the hole of which there is a stud 9, on the end of which are screwed nuts 26 for fastening the lever 3 to the plate 2. Positions 27 and 28 show the gaskets. A handle 29 is fixed on the latch 16 for screwing the latch 16 onto the threaded end of the latch 14 of the latch 16. The eccentric 6 interacts with the lever 3.

Figure 4-9 shows other versions of the valves that are identical to the first embodiment of the design of the overpressure valve, while the lever 3 in the first version of the valve is made curved (figure 2), the levers 3 in other versions of the valve (figure 3, 5, 7, 9) are made rectilinear. Valve designs also differ from each other through passage sections of valve bodies, plate diameters, masses of counterweights and layouts designed for different working conditions with specified ventilation systems

The overpressure valve operates as follows.

Move the counterweight (figure 2) in the slots 13 of the lower part 8 of the lever 3 and fix it on the lever with a screw 19 in a predetermined design position, which

it is designed to operate the valve at a certain excess air pressure to the right of the plate 2. The design position is selected using a calibrated ruler (not shown), which is located on the lower part 8 of the lever 3 from the screw 19. For finer adjustment of the design position of the counterweight, one part or each the part made with the center of gravity displaced relative to the screw 19 is rotated around the screw 19 and more precisely control the moment of resistance of rotation of the plate 2 from the action of air on it. Fine adjustment is achieved by shifting the center of mass of each part of the counterweight relative to the lower part 8 of the lever. The angle of rotation of the parts of the counterweight is also selected on a calibrated scale (not shown) plotted on the lower part 8 of the lever 3.

If the counterweight 4 has a shifted center of gravity and is mounted on the lower end of the lever 3 with the possibility of its fixation and rotation relative to the lever (Fig. 10), then the moment of resistance of the rotation of the plate 2 from exposure to air is adjusted by turning the counterweight 4 relative to the lever 3 .

Next, the adjusting screws 12 adjust the ease of rotation of the lever 3 and the plate 2 in the housing 1 and after carrying out the adjustment work, the cover 21 is closed and the valve is sealed. When the air pressure increases to the right of the plate 2 (Fig. 2), air passes through the openings 22 of the cover 21 and puts pressure on the plate 2 from its rear side 17. At the same time, the plate rotates around the screws 12 and occupies the position shown in Fig. 3. The air flows from right to left through the formed window between the plate 2 and the housing 1 and after some time the air pressure in the room in front of the valve (right) and in the room after the valve (left) is equalized. The counterweight 4 creates a torque and rotates the lever 3 and with it the plate 2 around the screws 12 clockwise and the opening of the housing 1 is closed by the plate 2, while the plate takes the position shown in figure 2.

Then the described cycle of balancing the excess air pressure is repeated. Moreover, in the event of excessive pressure in the room

to the left of plate 2 (Fig. 2), air does not pass through the valve into the room located to the right of the plate.

In conditions of security, when complete sealing of adjacent rooms is necessary, manually plate 2 is pressed against the seat of the housing 1 by turning the eccentric 6, for which the lever 14 is turned counterclockwise. Then the lever and the eccentric are fixed by the latch 15 from their displacements, for which the handle 29 is turned and the latch 15 is screwed onto the threaded horizontal part of the lever 14. At the same time, the latch 15 is pressed against its surface 16 of the bracket 11. In the locked position, the eccentric 6 is hermetically closed and air movements through it are excluded.

The valve designs shown in FIGS. 4–9 work similarly. The horizontal movement of the plate at the end of its stroke provides uniform compression of the gasket 27, which significantly increases the tightness of the valve and the reliability of its operation, providing a given level of tightness during prolonged operation of the valve. Moreover, the improvement of these parameters was obtained through the use of a relatively simple mechanism for moving and rotating the plate and the layout solution of the valve, expressed by a combination of essential features.

Claims (6)

1. Overpressure valve, characterized by the presence of a cylindrical body and a swivel plate pivotally connected to the body located in the body, wherein the plate is connected to the body by a plate turning lever, the upper end of the lever is rigidly connected to the plate, the lower end of the lever is made with a movable fixed counterweight, middle part of the lever is pivotally connected to the body, the valve is made with an eccentric plate clamp to the body, which is mounted on the body, and its eccentric is located with the possibility of interaction with p lever and fixation in working position with the plate closed. 2. The overpressure valve according to claim 1, characterized in that the lever for turning the plate is made

-shaped with the front and bottom parts extending toward the plate, the rigid connection of the upper end of the lever with the plate is made by means of a detachable connection, the stud of which is screwed into a threaded hole made on the back of the plate, the hinged connection of the front of the lever with the body is made using brackets that are made on the housing, while the front of the lever is located between the brackets and connected with screws with the possibility of rotation relative to the brackets around the screws. 3. An overpressure valve according to any one of claims 1 and 2, characterized in that the eccentric clip includes an eccentric,

-shaped eccentric rotation lever with an eccentric fixed to it and a latch for this lever, the eccentric rotation lever located in the bracket holes, the eccentric located between the brackets, the bent end of the eccentric rotation lever represents the rotation handle, the other end of the rotation lever is screwed and screwed onto it lever lock interacting with the surface of one of the brackets. 4. The overpressure valve according to claim 2, characterized in that the threaded hole on the back of the plate is made in the protruding elongated part of the plate, which is made on the back of the plate. 5. The overpressure valve according to claim 1, characterized in that the movable lockable counterweight is installed in the groove of the lower part of the lever, extending towards the plate. 6. The overpressure valve according to claim 1, characterized in that the movable fixed counterweight is pivotally mounted at the end of the lever with the possibility of its rotation relative to the lever in a vertical plane.