DE1650448C3 - Start-up relief valve device for positive displacement machines - Google Patents

Description

45

The invention relates to a start-up relief valve device for positive displacement machines, in particular Piston compressor with a valve housing in which a check valve and a vent valve coaxial with it is provided, wherein a coil spring arranged around a portion of the check valve is and one end to a collar of the valve body and the other end to one Stop of the valve housing, the check valve in its closed position and the vent valve in its open position presses and the pressure that builds up pushes the check valve against the force of the helical spring opens.

Compressors, pumps and the like for flow media can be connected with their outlet channels directly to a fluid load when they are started up. The compressor or the pump must therefore be constructed in such a way that the external starting load can be overcome in addition to the internal starting load. The starting load can be reduced by providing a relief valve which reduces the load on the compressor outlet. Where such a valve is provided, a check valve can also be provided downstream of the relief valve in order to prevent a flow of the medium through the relief valve to the compressor or to the pump. This check valve can flutter or cause rapid vibrations caused by pressure surges. These vibrations cause excessive wear on the check valve and reduce its service life considerably. When compressing gases (e.g. from air) some moisture in the gas is condensed during the compression. This moisture must be drained periodically in order to prevent contamination of the associated equipment.

In US-PS 27 72 690 is a start-up relief valve device of the type outlined at the beginning. Although there is a piston swinging o « Prevents valve, this known arrangement is so affected that this piston in its open position of a combination of compressive forces acting on its inner end and a suction force acting on its inner end its outer end acts. The vent valve is not actuated by the check valve, but a separate closing spring is provided for this. This known arrangement is also technically complex and not resistant to the effects of vibrations.

From DT-PS 7 34 464 a device for venting the pressure line of reciprocating compressors is for the purpose of facilitating the restart has become known, in which the closing of the vent valve takes place under the influence of the back pressure between the compressor and the shutdown of the Compressor closing check valve forms. A device for damping the back and forth Movement of this known valve is not provided, however.

The object on which the invention is based is to provide a start-up relief valve device of the above type so that the vent valve, which is functionally separated from the non-return valve, time-delayed only by the non-return valve is operated.

According to the invention, this object is achieved by dai3 the vent valve consists of a sleeve, which together with the non-return valve via a Coupling ring is supported on the helical spring that the check valve has a piston collar that extends through a cylindrical surface of the check valve is separated as a backlash from the coupling ring and that the Piston collar arranged in a damping chamber

The valve sleeve is expediently L-shaped in cross section, with the leg of the valve sleeve being one Forms stop for the coupling ring.

Here, the L-leg is an advantage of the valve sleeve au ^r the backlash slidably, wherein the valve sleeve may abut in the closed position against a stop of the valve housing.

The valve body of the check valve expediently has a shoulder for the coupling ring.

With the valve construction according to the invention, the flutter caused by entering the valve Pressure surges is caused, significantly reduced, which reduces friction and wear overall will. Vibrations that occur as a result of pressure surges entering the valve are dampened, and the opening of the relief valve and the fitting of the non-return valve will be shortened Amount of time after switching off a pump or a

Compressor that feeds the medium to the valve, delayed.

Pie invention is based on exemplary embodiments explain in more detail using the drawing. In the drawing shows

F i g. 1 shows a longitudinal section along the line I-1 in FIG. 4th by a start-up relief valve device, with the check valve closed and the vent valve is open,

F i g. 2 one of the F i g. 1 similar view, with the vent valve closed and the check valve is open,

Figure 3 is an exploded perspective View on a reduced scale of the valve according to FIGS. 1 and 2,

F i g. 4 is an end view from the right end of FIG. 1 after the line 4-4 and

Fig. 5 is a partial view of a modified embodiment.

The start-up relief valve device according to the invention has a valve body 1 with a bore 3 which has an inlet end 5 and an outlet end 7. In the body 1, a check valve seat is located in the vicinity of the outlet end 7 of the bore 3 9. The valve body 1 is provided with a vent channel 11 i $, extending from the bore 3 through the body to the outside of the body. A valve sleeve 13 moves back and forth in the bore 3 to open and close the connection of the channel 11 with the bore. In the bore 3 a hollow check valve 15 slides, which can rest against a seat 9 (according to FIG. 1) in order to close the bore 3 for the passage of the medium. The check valve 15 moves out of its position in FIG. 1 in its position shown in Figure 2 to open the valve device for the passage of the fluid. The check valve 15 slides inside the sleeve 13 and is provided with a piston collar 17 which has a lost motion connection with the sleeve 13 for moving the sleeve and for closing the vent channel 11 when the check valve 15 is moved to open the bore 3. This check valve 15 is open at its left end and has bores 19 in the vicinity of its right end. When the valve is in its in F i g. 2, there is a passage for the medium from the inlet 5 to the outlet 7 through the interior of the check valve 15 and the bores 19.

The valve body 1 is made up of two housing parts IA and Iß manufactured, with the housing part Iß in the Housing part IA is screwed in. The outer surface of the body is hexagonal around it To facilitate assembly. A sealing ring 21 seals the connection between the valve housing parts away. The inlet 5 of the bore 3 is located in the housing part IA, while the outlet 7 of the bore in the Housing part Iß is provided. The inlet 5 is threaded for connection to a line from the delivery side of the compressor, the pump od. The like. (not shown), or it can directly whose delivery side are connected. The housing part Iß also has a thread, so that a Line or a coupling can be made with the valve body and with a consumer device that is to be supplied with the print medium.

The valve body 1 has a shoulder 23 in the housing part 1A facing the housing part Iß, and shoulders or stops 25 and 27 which face the shoulder 23 in the housing part \ B. These stops 23, 25 and 27 form a stepped bore. A cylindrical surface 29 is provided between the stops 23 and 25. The vent channel 11 opens into the bore 3 through this surface 29. The sleeve 13 rests with a tight fit against the surface 29 and moves back and forth along the right-hand end of this surface (as seen in the drawing), moving out of its in F i g. 1, in which the ventilation duct «ti is connected to the bore 3, in its position shown in FIG. 2 moves in which it rests against the stop 25. It thus covers the ventilation duct 11 and prevents a connection between it and the bore 3. The stroke of the check valve 15 is limited by the piston collar 17, which is between a position in contact with the stop 23 at the left end of the surface 29 (Fig . 1) and moved to a position in which it rests against the sleeve 13, which in turn rests against the stop 25 (FIG. 2). Adjacent to the stop 23, a cylindrical surface 31 is provided in the housing part IA which forms a guide through which a tight-fitting, tubular part 33 of the check valve 15 slides.

When the piston collar 17 moves away from the stop 23, between the piston collar 17, the Surface 29, the stop 23 and the tubular part 33 of the check valve a closed and relatively airtight expandable damping chamber 35 is formed. Some air or medium can get in the damping chamber 35 between the valve part 33 and the guide 31 in the bore and around the sleeve 13 and penetrate between the piston collar 17 and the surface 29 (or out of the damping canister 35 exit). When the valve is in its right position (Fig.2) and a movement to the left to Closing of the valve device begins, delaying the air or the medium in the Damping chamber 35 is included, the movement of the check valve 15 so that its movement to the left until the piston collar 17 rests on the stop 23 (position according to FIG. 1) relatively is slow. When the check valve 15 moves to the right, there is a slight negative pressure in the Damping chamber 35 until the medium leaks into this chamber. This negative pressure also decelerates the movement of the valve 15. The damping chamber 35 thus increases the inclination of the check valve 15 rapid vibrations within the bore 3 down. Such vibrations occur when the valve device z. B. is used with compressors or reciprocating pumps, the Flow medium is fed to the inlet 5 intermittently.

A radially inwardly extending leg 37 at the left end of the valve sleeve 13 slides on the cylindrical surface 39 on check valve 15 adjacent to piston collar 17. From a comparison the F i g. 1 and 2 shows that the surface 39 slides back and forth below the leg 37. It exists thus a lost motion connection between the check valve 15 and the valve sleeve 13, by means of which the vent channel 11 is closed after a limited movement of this valve 15 to the right. As a result of this lost motion connection, any oscillation of the check valve 15, which is caused by the Damping chamber 35 is not damped, not transferred to the sleeve 13. Hence the opens The ventilation duct also does not open with every pressure surge

the compressor.

Adjacent to the surface 39 on the check valve 15 is a cylindrical surface 41, the Diameter is smaller than that of the surface 39. Between the surfaces 39 and 41 there is a shoulder 43. The Surface 41 is surrounded by a coupling ring 45 which rests against shoulder 43. To the cylindrical A helical spring 47 is arranged on surface 41, which is against the stop 27 and against the coupling ring 45 is supported so that the latter and dam ^ the check valve 15 are loaded to the left in the position shown in FIG. The coupling ring 45 has a smaller one Diameter than the right and the middle part of the valve sleeve 13, but a larger diameter than the leg 37. When the check valve 15 from the in F i g. 2 into the position shown in FIG. 1 position shown is moved, the coupling ring 45 first comes under the right and the middle part of the valve sleeve 13 and then applies to the right side of the leg 37 to the valve sleeve 13 together with the Move check valve 15 to the left. This movement turns vent channel 11 into bore 3 Approved. As a result of the lost motion connection between the coupling ring 45 and the leg 37 of the Valve sleeve 13, the Rickschlag valve 15 can execute a limited sliding movement in the bore 3, without this movement being transmitted directly to the valve sleeve 13 via the coupling ring 45.

The check valve 15 is hollow and open at the left or inlet end. The right end 15 is through a cap part 49 completed. The bores 19 extend radially adjacent through the valve wall to cap 49 and may be offset longitudinally as shown. The holes 19 form together with the cavity of the valve and its open left end a passage through which Medium from the inlet 5 to the outlet 7 can flow when the check valve is in its in Fig.2 Offenlagc shown is located.

In the Vcniilobcrfläche 41 a groove 53 (Fig. 3) is provided on the cap part 49, in which a sealing ring 55 is seated. The sealing ring 55 protrudes somewhat beyond the surface 41 and rests against the valve seat 9 in the valve body 1 in order to seal the connection between the valve and its seat.

The valve can be assembled in that the knob 33 of the check valve 15 is inserted into the valve housing 1 / i, the sleeve 13 is moved over the closed end 49 of the valve onto the surface 39 and against the piston collar 17 and then the coupling ring 45 and the coil spring 47 can be placed around the cover 41 of the valve. Then, the sealing ring is inserted into the groove 53 and 55 of the seal ring 21 disposed about the Ocwindc at the left end of the VcntilgchUusclcils \ B. Then the valve body IB is screwed into the valve body part A.

The start-up relief valve device can then be placed between a pressure medium source and a switch or the like, / u which the fluid are guided should be arranged. For example, the inlet end 5 can be directly connected to the outlet port of a Air compressor or to a line from the compressor, and the outlet end can directly or indirectly with a receptacle for the compressed air to be connected.

The operation of the start-up relief valves is as follows

If the valve device is between an air compressor and a container assigned to it is arranged and the compressor is not loaded, the valve parts are in the Fig. 1 shown Position so that fluid from the container does not enter the outlet end 7 and through the valve device can reach the inlet end 5. The ventilation channel 11 forms a connection between the bore 3 and the outside air so that the valve device is under atmospheric pressure. There is a Passage from the vent channel 11 via the bores 19 in the check valve 15, the cavity of the valve and through inlet 5 to the compressor outlet so that the latter is also under atmospheric pressure.

When the compressor starts, air enters and passes through the valve device through the inlet end 5 the hollow check valve 15 and the bores 19 so that they are initially through the vent channel 11 reaches the outside air. If the speed or the speed of the compressor increases, this increases Volume of the air supplied to the valve device also increases. If this volume of air has the capacity of the vent channel U for the exit of the compressed air exceeds, the check valve 15 is through the The pressure difference upstream and downstream of the cap part 49 is moved to the right. This Movement is delayed by the coil spring 47, which is compressed when the check valve is open 15 moved to the right, as well as through the damping chamber 35, which thereby expanded is that the piston collar 17 moves away from the stop 23, so that a slight negative pressure in the Damping chamber 35 arises, which controls the movement of the check valve 15 into its position shown in FIG delayed. By moving the check valve 15 to the right, the holes 19 with the Brought outlet 7 of the valve body in communication. the Compressed air can then flow freely through the passage through the cavity of the check valve 15, the

Bores 19 and the valve body is formed and in reach the line leading to the container.

When the check valve 15 moves to the right to open, the valve sheet 39 slides freely below of the leg 37 on the sleeve 13 of the Entlüfuingsvenii-

les until the piston collar 17 on the left side of the sleeve is applied. A further movement of the check valve 15 to the right causes the sleeve 13 to close the connection between borehole 3 and the Kunal 1t moves, which closes the vent valve

will. If the channel 11 is relatively narrow, the loss of outside air before it is closed by the sleeve 1.1 is low. When the vent valve is closed and the check valve is open, compressed air can flow through the valve device

are fed. The parts of the valve device

remain in the position shown in Fig.2 as long as dci

Compressor enough air to overcome the force

the coil spring 47 delivers.

When the start-up relief valve device ftli

a compressor with reciprocating piston is used, it is constantly exposed to pressure surges in front of the compressor. When this bumps under pressure If not attenuated, they would be affected by vibrations and considerable deterioration of the parts of the valve device cause wodurcl the efficiency of the valve is reduced and desser service life is shortened. In the case of the erfindungsgc Maßcr Valve device are the vibrations of the dei

Damping chamber 35 damped, which fills with the fluid and any rapid movement of the Check valve 15 counteracts effectively. The sleeve 13 of the vent valve is of limited vibration without reciprocation of the valve 15 due to the sliding connection between the check valve 15 and the sleeve 13 isolated.

When the compressor is shut down, the fluid pressures are equal downstream of the outlet end 7 and upstream of the inlet end 5 rapidly, and the check valve 15 is through the Helical spring 47, which is supported between the stop 27 and the coupling ring 45, to the left in his Closed position loaded. The movement of the check valve 15 to the left is caused by the fluid in the damping chamber 35 slowed down or decelerated. This fluid slowly leaks around the check valve 15 around and enables its gradual return to the closed position shown in FIG. During the initial movement of the check valve 15 to the left, the valve surface 39 slides underneath of the valve sleeve leg 37, and the sleeve 13 remains essentially at a standstill. When the coupling ring 45 moved to the left, it passes underneath the left and middle parts of the sleeve and finally rests on the Leg 37 to move the sleeve 13 together with the check valve 15 to the left. If the Sleeve 13 their in F i g. 1 reaches the position shown, the compressed air is through the holes 19 and the Entlüfiungskanal 11 diverted to the outside air, whereby the compressor is relieved. The compressed air downstream the valve device is prevented from passing through the valve device by the seal 55, which lies against the valve seat 9.

When the start-up relief valve device Compressed air or other gases are supplied, some condensation can occur at the outlet of the compressor and take place in the valve device. It is desirable to remove this condensate with it it is not conveyed to a container or to any facility which will contain the compressed gas records. In the valve device according to the invention, this moisture passes through the ventilation duct 11 off when the compressor is started. the The escape of moisture is achieved through the relatively large volume of gas which is transported through the Channel 11 due to the slight delay in opening the check valve and closing the Enllufiungskunals exits, This delay happens as a result of the backlash 39 between the sleeve 13 and the check valve 15 and as a result of the effect the damping chamber 35. When the check valve 15 moves to the right, it expands the damping chamber 35. This creates a slight negative pressure in the damping chamber, which delays rapid movement of the valve so that a large Volume of air can escape through the ventilation duct 11, which takes the existing moisture with it. the Movement of the check valve to the right is further delayed by the coil spring 47, the must be squeezed when the valve is moved to the right.

In Figure 5 is a modified embodiment of the Start-up relief valve device shown. In the embodiment of Figure 5 extends a Bore 59 through the end of the cap member 49 for the passage of fluid to and from the upstream end of the valve. When the check valve 15 is withdrawn, as shown in FIG. 1 and 5 is shown, fluid from outlet 7 in the bore 59 and through the bores 19 for the purpose Exit through the vent channel 11. Otherwise, the valve according to FIG. 5 to the one shown in FIG. 1 to 4 shown valve similar. The compressor is unloaded in the manner described.

During the initial operation of a compressor, air (or other fluid) enters the The cavity of the check valve 15 of the arrangement shown in FIG. 5 enters through the vent channel 11 from, and part of the air flows through the bore 59. As the bore 59 and the ventilation duct 11 are relatively narrow, a pressure difference soon arises across the valve cap part 59. As a result the check valve 15 moves to the right until the bores 19 with the outlet 7 in connection are, as shown in FIG. 2 is shown. The check valve 15 is then moved in the manner described to close the vent channel 11. If the Compressor comes to a standstill, coil spring 47 pushes check valve 15 into its IMg. 5 location shown and opens the F.nilüfuingskanal 11, see above that a discharge both obcrstroinseilig nls me downstream of the start-up relief valve device can take place.

Although the crfindungsgemalk arrangement / ur Use with a compressed air system has been described, it is suitable for liquid wedge systems.

1 sheet of drawings

Claims (5)

Patent claims: 1. Start-up relief valve device for displacement machines, in particular reciprocating compressors with a valve housing in which a check valve and a coaxial vent valve is provided, a helical spring which is arranged around a portion of the check valve and with its one end on a collar of the valve body and with its the other end is supported on a stop of the valve housing, pushes the check valve into its closed position and the vent valve into its open position and the pressure building up opens the check valve against the force of the helical spring, characterized in that the vent valve consists of a sleeve (13), which is supported together with the check valve (15) via a coupling ring (45) on the helical spring (47) that the check valve (15) has a piston collar (17), which by a cylindrical surface (39) of the check valve as a backlash from the coupling ring ( 45) separately is and that the piston collar (17) is arranged in a damping spring (35). 2. Valve device according to claim 1, characterized in that the valve sleeve (13) in cross section Is L-shaped and the leg (37) of the valve sleeve has a stop for the coupling ring (45) forms. 3. Valve device according to one of claims 1 or 2, characterized in that the L-leg (37) of the valve sleeve (13) can be slid on the lost motion (39). 4. Valve device according to claim 1, characterized in that the valve sleeve (13) in the In the closed position against a stop (25) of the valve housing (Iß). 5. Valve device according to claim 1, characterized in that the valve body of the check valve (15) has a shoulder (43) for the coupling ring (45).