DE202011108281U1 - Valve for liquid disposal in a vacuum system - Google Patents

Abstract

Valve for liquid disposal in a vacuum system, in particular for water disposal in a permanent vacuum system comprising a valve chamber having a water inlet, a connectable to a vacuum source water outlet and a valve body which is formed and arranged to close the water outlet in a closed position and in a Open position to release the water outlet, characterized by an activator chamber which is coupled to the valve chamber such that an increase in pressure in the valve chamber leads to a pressure drop in the activator chamber, wherein the activator chamber is coupled to the valve body such that the valve body at a pressure drop in the Activator chamber occupies the open position.

Description

The invention relates to a valve for the liquid disposal in a vacuum system, in particular for water disposal in a permanent vacuum system comprising a valve chamber having a water inlet, a connectable to a vacuum source water outlet and a valve body which is formed and arranged in a closed position to the water outlet close and release the water outlet in an open position.

Vacuum systems for liquid disposal are also sometimes referred to as vacuum systems and serve, for example, from sanitary facilities to dispose of liquids, such as on the valve subsequent lines and possibly a tank. Valves of the type mentioned are used for example in mobile application areas, such as in trains or aircraft, or to save water, for example in areas with water scarcity used. Sanitary facilities or facilities in the present application are, for example hand basins, toilets or showers. For liquids to be disposed of, for example, water, gray water or wastewater. For simplicity, water or wastewater will be referred to as the liquid to be disposed of; However, the statements apply equally to other discharged or to be disposed of liquids.

Under a permanent vacuum system such a system is understood, in which the valve connected to the waste water pipes and possibly a waste water tank are constantly subjected to a negative pressure.

In valves of the type mentioned, the water to be discharged passes through the water inlet into the valve chamber. The outflow of water from the valve chamber through the water outlet is prevented by the valve body in the closed position. In the open position of the valve body releases the water outlet, so that the water can escape through the water outlet from the valve chamber. In a vacuum system, the water outlet is directly or indirectly connected to a vacuum source, for example via a sewer pipe and a waste water tank, wherein tank and pipe are preferably under a permanent negative pressure. In this way, the water to be discharged is sucked in the open position of the valve body from the valve chamber through the water outlet.

In existing valves, the valve body is designed, for example, as a floating body. However, this may result in the float being sucked by the vacuum at the water outlet to the water outlet and will no longer float, so that the valve closes before the drainage water has left the valve chamber completely through the water outlet. In addition, the buoyancy of the float is adjusted to the voltage applied to the water outlet vacuum level and the diameter of the water outlet, so that a sufficient, a negative pressure caused by the suction force counteracting buoyancy of the float is ensured.

There are also valves with a reservoir with level sensor, in which at a certain level of the reservoir, the level sensor releases a valve below the reservoir to start the suction. Here, however, an electrical or electronic control is required and thus given a dependence on a corresponding power supply and the reliability of the electrical or electronic control.

It is therefore an object of the present invention to provide a valve of the type mentioned, which reduces or avoids one or more of the disadvantages mentioned. It is a further object of the present invention to provide a valve of the initially mentioned type which functions reliably, and preferably independently of the vacuum level of the vacuum system.

The invention is achieved by a valve of the type mentioned, which is characterized by an activator chamber which is coupled to the valve chamber such that an increase in pressure in the valve chamber leads to a pressure drop in the activator chamber, wherein the activator chamber is so coupled to the valve body in that the valve body assumes the open position in the event of a pressure drop in the activator chamber.

The invention is based on the recognition that when the valve is closed, d. H. with the valve body in the closed position, through the water inlet into the valve chamber entering water leads to an increase in pressure in the valve chamber. This resulting in the valve chamber pressure increase by entering, dissipated water is used according to the invention to bring about a pressure drop in an activator chamber, which in turn causes the valve body is in the open position.

When applied to the water outlet vacuum, the valve is closed because the valve body is sucked in its closed position by the negative pressure to the water outlet.

Only by a pressure increase occurring in the valve chamber and the resulting pressure drop in the activator chamber, the valve body is moved into the open position, against the suction force acting on the valve body at the water outlet. In this way, the valve is in operation by default in the closed position and opens only when water to be discharged is located in the valve chamber.

A vacuum level in the vacuum system is preferably from -0.2 to -0.8 bar, in particular from -0.4 to -0.6 bar.

It is particularly preferred that the valve opens when the vacuum level is 15 to 50% of the normal pressure in the activator chamber.

An advantage of the valve according to the invention is that the operation of the valve is independent of the level of vacuum applied to the water outlet. Another advantage is that the valve according to the invention requires no electrical or electronic control components and thus the functioning is independent of a supply of electrical energy. Another advantage is that an emptying of the valve is also independent of the connection of the valve to a vacuum source.

The valve also has the advantage that, when there is no vacuum at the water outlet, the valve body is not held in the closed position, so that water between the valve body and the water outlet can escape from the valve chamber. This is especially useful for defrosting the frost (deflation) of the valve: For example, if trains are not in operation and are shut down, it is necessary to avoid freezing damage at cold temperatures, so that the valves and adjacent lines are free of water so that freezing water will not damage to the valves or lines may occur.

Another advantage of the present invention is that the valve according to the invention closes tightly only when a negative pressure at the water outlet; if there is no negative pressure at the water outlet, the water can leave the valve chamber between valve body and water outlet; There is thus no liquid to be discharged in the valve, in particular in the valve chamber, when the vacuum system is not in operation. This emptying of the valve is done automatically, d. H. in this context, that the emptying takes place automatically and does not have to be initiated and is furthermore independent of a power supply or of a vacuum connection. Thus, for example, if the vacuum system is switched off in one go, the valve according to the invention runs empty without such emptying has to be initiated or the valve requires a supply of energy or negative pressure.

It is particularly preferred that the pressure in the activator chamber falls with a rise in pressure in the valve chamber to a pressure level which corresponds to the voltage applied to the water outlet vacuum level. This can be achieved in an advantageous manner that the suction effect acting on the valve body by the voltage applied to the water outlet by a corresponding effect by the existing in the activator chamber vacuum is completely or at least partially balanced and thus premature suction of the valve body to the water outlet even before the discharged water has left the valve chamber is prevented. It is particularly preferred that for this purpose the activator chamber can be connected to the same vacuum source as the water outlet.

Preferably, the valve body is arranged in the installation situation at the lowest point of the valve chamber.

Preferably, a seal, for example an O-ring, is arranged between the water outlet and the valve body.

A preferred embodiment of the valve is characterized in that the activator chamber is formed adjacent to the valve chamber.

This embodiment has the advantage that the coupling according to the invention between the valve chamber and the activator chamber for realizing the pressure conditions according to the invention can be realized in a particularly simple design. Furthermore, this embodiment has the advantage that the valve requires only a small space.

In a further preferred embodiment, the valve is characterized in that the activator chamber can be coupled to a vacuum line in such a way that, when the pressure in the valve chamber rises, the activator chamber can be connected to the vacuum line to produce a pressure drop in the activator chamber.

The pressure drop in the activator chamber is preferably generated by connecting the activator chamber to a vacuum line. The vacuum line is preferably then released when the pressure drop in the activator chamber is to be generated, ie when a pressure increase occurs in the valve chamber. It is particularly preferred that the vacuum line is connectable to the same vacuum source with which also the Water outlet is connectable. This is a particularly advantageous construction in which the operation of the valve is independent of the vacuum level created by the vacuum source since the same or a substantially equal vacuum level is applied both to the water outlet and to the activator chamber. Since the pressure drop in the activator chamber triggers the movement of the valve body into the open position, by connecting the activator chamber and water outlet to the same vacuum source, the forces acting on the valve body can be compensated or chosen such that a desired opening and closing behavior of the valve body is independent of the valve body adjacent vacuum level is achieved.

In a preferred embodiment, the valve is characterized in that between the valve chamber and the activator chamber, a pressure-elastic element, preferably a membrane, is arranged and designed such that increases in an increase in pressure in the valve chamber, the volume of the valve chamber and the volume of the activator chamber is reduced , In this embodiment, the desired coupling of the valve chamber and the activator chamber is achieved in that between the valve and the activator chamber, a pressure-elastic element, preferably a membrane, is arranged. The compressive elastic element deforms as the pressure in the valve chamber increases to increase the volume trapped in the valve chamber and reduce the volume trapped in the activator chamber. In the formation of the pressure elastic element as a membrane, this can be done for example by a curvature of the membrane in the direction of the activator chamber. By means of such a pressure-elastic element, a direct coupling of the valve chamber with the activator chamber can thus take place. To generate the desired pressure conditions, d. H. the pressure drop in the activator chamber at a pressure rise of the valve chamber, the movement of the pressure elastic element resulting from the pressure increase of the valve chamber is to be converted into a pressure drop mechanism of the activator chamber. Such a pressure reduction mechanism can be, for example, that the activator chamber is connected to a vacuum line by the deflection of the pressure-elastic element.

In a further preferred embodiment, the valve is characterized in that the valve body is connected to the pressure elastic element such that at least one movement of the pressure elastic element in a first direction leads to a movement of the valve body. It is particularly preferred that the valve body is connected to the pressure-elastic element such that the at least one movement of the pressure-elastic element in a first direction leads to a movement of the valve body in the same direction and / or by the same path.

In these embodiments, the valve body is preferably connected directly or via a connecting means with the pressure-elastic element, so that a deflection of the pressure-elastic element at least in a first direction also leads to a movement of the valve body, preferably to a movement of the valve body from the closed position to the open position , A particularly simple and therefore advantageous construction results when the pressure elastic element, preferably a membrane, is coupled to the valve body in such a way that a movement of the pressure elastic element in a first direction by a certain way to a rectified movement of the valve body by the same path leads. However, other embodiments and other couplings of the pressure-elastic element with the valve body are also possible.

It is particularly preferred that the valve body is connected to the pressure-elastic element via a rod-shaped element. In this embodiment, it is a particularly simple and therefore preferred constructive connection between the valve body and pressure-elastic element, in particular the membrane.

A further embodiment of the valve is characterized by an activator valve which is arranged and designed to connect the activator chamber to a vacuum line in an active position and to separate the activator chamber from the vacuum line in a passive position.

For the preferred connection of the activator chamber with the vacuum line, in particular for connecting the activator chamber with a vacuum source, and in particular with the vacuum source to which the water outlet is connectable, an activator valve is provided in this embodiment that either release the connection of the activator chamber to the vacuum line or can lock. In this way, the pressure in the activator chamber can be controlled by the activator valve.

In a further preferred embodiment, the valve is characterized in that the activator valve is arranged and configured such that the activator valve assumes the active position when the pressure in the valve chamber rises.

In order to realize the inventive coupling between the valve chamber and activator chamber, it is preferred that the activator valve assumes the active position at a pressure increase in the valve chamber, so that the activator chamber with the vacuum line is connected and in the activator chamber, a negative pressure is built up, which leads to the present invention desired pressure drop in the activator chamber with pressure increase in the valve chamber.

A further preferred embodiment is characterized in that the pressure-elastic element is coupled to the activator valve such that the activator valve assumes the active position at least in one direction during a movement of the pressure-elastic element.

As already described above with reference to the valve body, it is also or alternatively preferred that the activator valve is controlled by a movement of the pressure-elastic element. In particular, the activation of the activator valve, d. H. the opening of the activator valve in the active position, in which the activator chamber is connected to the vacuum line, is preferably triggered by a movement of the pressure-elastic element in at least one direction.

A particularly preferred embodiment of the valve is characterized in that the activator valve is connected via an activator lever with the pressure-elastic element.

In this preferred embodiment, the valve includes an activator lever that is configured and arranged to couple the activator valve to the pressure elastic member to move the activator valve from the passive position to the active position and back.

In a further preferred embodiment, the valve is characterized in that the activator valve has a valve seat and a plunger, wherein the plunger is arranged and designed to close the valve seat in the passive position and to release it in the active position.

The activator valve is preferably closed and opened via a plunger, which can be pressed onto and lifted off the valve seat. It is particularly preferred that the plunger is moved by the activator lever. In addition to these preferred embodiments, however, other embodiments of the activator valve and its activation are possible.

In an advantageous embodiment, the valve is characterized in that the valve body is designed as a floating body.

In the formation of the valve body as a float, the freezing of the valve is supported in a particularly preferred manner in that the valve body floats through the water located in the valve chamber, whereby the water can drain from the water outlet. Since the frost discharge preferably takes place in a state in which there is no negative pressure at the water outlet, the valve body can float freely and drain the water through the water outlet completely.

In a further preferred embodiment of the invention, the valve is characterized in that the activator chamber has a throttle valve which is designed and arranged to supply the activator chamber with a fluid such that a pressure drop in the activator chamber can be compensated.

After the discharged water has flowed out of the valve chamber through the water outlet, it is advantageous if the valve body returns to the closed position. To achieve this, the pressure drop in the activator chamber, which has brought the valve body in the open position, to compensate again, so that the valve body returns to the closed position. For this purpose, the pressure in the activator chamber of the negative pressure generated by the pressure drop back to the output pressure level, or to bring to ambient pressure.

The preferred embodiment provides for a throttle valve, through which a fluid, preferably air, can get into the activator chamber in order to be able to compensate for the negative pressure in the activator chamber. The throttle valve is preferably dimensioned such that, as long as there is an increased pressure in the valve chamber (i.e., water is present in the valve chamber), the fluid flowing through the throttle valve can not completely compensate the negative pressure in the activator chamber. Only when the increase in pressure in the valve chamber subsides, and preferably the membrane has returned from its bulged position back to the starting position and thus preferably the connection of the activator chamber with the vacuum line again locks, which flows through the throttle valve in the activator chamber fluid in the activator chamber compensate for the prevailing negative pressure.

It is particularly preferred that the throttle valve is designed as a diaphragm with a flow length L = 0.

In a particularly preferred embodiment, the valve is characterized in that the throttle valve is designed and arranged to supply the activator chamber with air from an environment of the valve.

In this way, no pressure line is required to the negative pressure in the activator chamber but by the connection of the activator chamber with the environment of the valve via the throttle valve can be achieved in a particularly simple manner, the required pressure increase in the activator chamber for closing the valve.

Finally, it is provided in a further preferred embodiment that the valve body and a valve seat such kind each other, in particular formed that abuts a vacuum applied in the suction line of the valve body sealingly on the valve seat for closing the water outlet and without a vacuum in the suction line Water outlet at least partially releases for discharging water from the valve chamber. With this configuration it is achieved that water can always flow out of the valve chamber when the device is not in use and consequently does not prevail in the suction line, because the valve body exerts no sealing effect on the water outlet. This allows a self-contained and permanent freezing of the freezer, making the entire device reliable in relation to changing outside temperatures and freezing conditions. In this case, the permeability between the valve body and outlet provided for this purpose can be achieved by the valve body has a prestressed or elastically deformable sealing seat which rests without force on the valve seat such that one or more small opening gaps are present under the influence of a vacuum in the suction line be closed by elastic deformation of a sealing element.

A preferred embodiment of the invention will be described by way of example with reference to the accompanying figure.

1 shows a cross section through an exemplary embodiment of a valve according to the invention.

This in 1 illustrated valve 100 for the liquid disposal in a vacuum system, in particular for the removal of water in a permanent vacuum system, comprises a housing 1 in which a valve chamber 12 is formed in the over a supply line 22 and a water inlet 5 discharged water (not shown) in the valve chamber 12 can occur. The water can be the valve chamber 12 through the water outlet 21 and the suction line 8th , which leads to a waste water tank (not shown), left again. The suction line 8th is connected to a waste water tank (not shown) and is connected to a vacuum source (not shown) and thereby subjected to a negative pressure, so that this negative pressure also at the water outlet 21 is applied.

At the water outlet 21 is a seal 3 arranged. The water outlet 21 is located in the operating state of the valve at the lowest point of the valve chamber 12 , so in the valve chamber 12 water (not shown) under the influence of gravity from the water outlet 21 can expire.

In the in 1 pictured situation is the valve 100 in the closed position, wherein the valve body 2 , which is designed here as a floating body, sealing on the seal 3 the water outlet 21 is applied. The valve body 2 is in this position by the water outlet 21 applied negative pressure.

In the upper area of the valve 100 is an activator chamber 13 formed by the valve chamber 12 through as a membrane 6 trained pressure elastic element is separated. The membrane 6 is over a flange 17 on the housing 1 of the valve 100 attached. The activator chamber 13 is via a vacuum connection 4 connectable to a vacuum source. Preferably, the water outlet 21 and the vacuum connection 4 connectable to the same vacuum source. The activator chamber 13 also has an orifice, ie a throttle valve with a flow length of L = 0, on the air from the environment of the valve 100 into the activator chamber 13 can flow in.

The housing cover of the valve 100 has a bulge in the middle 15 on, in the one end of a rod-shaped element 14 that works with both the membrane 6 , as well as with the valve body 2 is firmly connected, can enter and exit.

In the activator chamber 13 is an activator valve 20 arranged, which is a pestle 10 which is in the 1 indicated position on the valve seat 18 sealingly seated and so the activator chamber 13 from one to the vacuum port 4 connected vacuum source separates. The pestle 10 is via an activator lever 9 with the membrane 6 coupled. When the diaphragm moves in the direction of arrow A, this causes both the activator lever 9 as well as the rod-shaped element 14 also move the same way in the direction of arrow A. By attaching the valve body 2 on the rod-shaped element 14 also performs the valve body 2 a movement in the direction of arrow A by the same path, as well as with the activator lever 9 coupled pestles 10 , By opening the plunger 10 enters the interior of the activator chamber 13 over the valve opening 19 and the vacuum port 4 with a vacuum source in communication, causing a pressure drop in the activator chamber 13 leads and to a further movement of the membrane 6 in the direction of the arrow A or to hold the membrane 6 in the to the activator chamber 13 arched position.

In the 1 illustrated position of the valve 100 in the closed position, the valve is in its default position, ie when the suction line is connected to the water outlet 21 is the valve 100 normally closed. When water passes through the water inlet 5 in the valve chamber 12 enters, gives the valve body 2 the water outlet 21 free, as by the pressure increase through the into the valve chamber 12 entering water the membrane 6 moved up, and thereby the activator lever 9 is taken, in turn, the plunger 10 from the valve seat 18 takes off and thus the activator chamber 13 with the vacuum line 4 combines. This will create a negative pressure in the activator chamber 13 generated and the membrane 6 moved further in the direction of arrow A or held in such a position. Because the rod-shaped element 14 at the point 16 firmly with the membrane 6 is connected, also moves the valve body 2 according to the membrane 6 upwards, the end of the rod-shaped element 14 in the bulge 15 the housing cover can slide upwards. This is supported by the buoyancy force of the valve body designed as a floating body 2 at the water outlet 21 opposing negative pressure counteracts. When all the water from the valve chamber 12 through the water outlet 21 has expired, the pressure in the valve chamber also decreases 12 again and also a buoyancy force of the valve body 2 is not available anymore. The membrane 6 moves against the direction of the arrow A back to the in 1 shown starting position with the valve body 2 in the closed position.

Through the aperture 11 is the activator chamber 13 connected to the environment of the valve such that through the aperture 11 Air from the valve environment into the activator chamber 13 can flow in and thus reduce the negative pressure formed therein. In particular, who activator chamber 13 is no longer connected to the vacuum line and the activator valve is closed again, the activator chamber fills 13 again with air and the pressure level in the activator chamber again assumes the outlet pressure or the ambient pressure.

If at the water outlet 21 and the vacuum line 8th no vacuum source is connected, ie in particular when stopping a train or when decommissioning a vacuum system, the valve body is located 2 only loose on the gasket 3 at the water outlet 21 on, so still in the valve chamber 12 located water between the valve body 2 and the seal 3 through the water outlet 21 can pass through. The buoyancy force of the valve body 2 supports this effect. In this way it is ensured that the valve 100 always runs empty and no frost damage can occur (defrosting) even if no vacuum source is connected or in operation.

Claims (15)

Valve for liquid disposal in a vacuum system, in particular for water disposal in a permanent vacuum system comprising a valve chamber having a water inlet, a connectable to a vacuum source water outlet and a valve body which is formed and arranged to close the water outlet in a closed position and in a Open position to release the water outlet, characterized by an activator chamber which is coupled to the valve chamber such that an increase in pressure in the valve chamber leads to a pressure drop in the activator chamber, wherein the activator chamber is coupled to the valve body such that the valve body at a pressure drop in the Activator chamber occupies the open position. Valve according to the preceding claim, characterized in that the activator chamber is formed adjacent to the valve chamber. Valve one of the preceding claims, characterized in that the activator chamber is coupled to a vacuum line such that at a pressure increase in the valve chamber, the activator chamber for generating a pressure drop in the activator chamber with the vacuum line is connectable. Valve according to one of the two preceding claims, characterized in that between the valve chamber and the activator chamber, a pressure-elastic element, preferably a membrane, arranged and designed such that increases in an increase in pressure in the valve chamber, the volume of the valve chamber and reduces the volume of the activator chamber becomes. Valve according to the preceding claim, characterized in that the valve body is connected to the pressure-elastic element such that at least one movement of the pressure-elastic element in a first direction leads to a movement of the valve body. Valve according to the preceding claim, characterized in that the valve body is connected to the pressure-elastic element such that the at least one movement of the pressure-elastic element in a first direction leads to a movement of the valve body in the same direction and / or by the same path. Valve according to one of the two preceding claims, characterized in that the valve body is connected to the pressure-elastic element via a rod-shaped element. Valve according to one of the preceding claims, characterized by an activator valve which is arranged and designed to connect the activator chamber to a vacuum line in an active position and to separate the activator chamber from the vacuum line in a passive position. Valve according to the preceding claim, characterized in that the activator valve is arranged and designed such that the activator valve assumes the active position at a pressure increase in the valve chamber. Valve according to one of the two preceding claims, characterized in that the pressure-elastic element is coupled to the Aktivatorventil such that the activator valve occupies the active position in a movement of the pressure-elastic element in at least one direction. Valve according to one of the three preceding claims, characterized in that the activator valve is connected via an activator lever with the pressure-elastic element. Valve according to one of the four preceding claims, characterized in that the activator valve has a valve seat and a plunger, wherein the plunger is arranged and designed to close the valve seat in the passive position and release it in the active position. Valve according to one of the preceding claims, characterized in that the valve body is designed as a floating body. Valve according to one of the preceding claims, characterized in that the activator chamber comprises a throttle valve, which is designed and arranged to supply the activator chamber with a fluid such that a pressure drop in the activator chamber can be compensated, in particular by the throttle valve is formed and arranged to supply the activator chamber with air from an environment of the valve. Valve according to one of the preceding claims, characterized in that the valve body sealingly abuts a valve seat for closing the water outlet in a vacuum in the suction line and at least partially releases the water outlet for discharging water from the valve chamber without a vacuum in the suction line.

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