EP3839260A1 - Centrifugal pump with automatic valve - Google Patents

Abstract

The invention relates to a centrifugal pump (10) for conveying a fluid with a pump housing (16) forming a pump chamber (14), an impeller (18) being provided in the pump chamber (14) and an impeller in the pump housing (16) Suction opening (26) is provided for sucking the fluid into the pump chamber (14), a vent opening (30) is provided in the pump housing (16) behind the impeller (18) in relation to the suction opening (26), and wherein at the vent opening ( 30) an automatic valve (32) is provided through which air can escape from the pump chamber (14).

Description

Technical area

The invention relates to a centrifugal pump for conveying a fluid with a pump housing forming a pump chamber, an impeller being provided in the pump chamber, a suction opening for sucking the fluid into the pump chamber being provided in the pump housing and in the pump housing based on the suction opening behind the impeller a vent is provided. The invention also relates to the use of the above centrifugal pump as a waste water and / or submersible waste water pump. The invention also relates to a lifting system comprising a collecting container and the above centrifugal pump.

Background of the invention

In centrifugal pumps, a rotary movement of an impeller is used to convey a fluid. The fluid to be conveyed enters a pump chamber of the centrifugal pump via a suction opening, is picked up by the rotating impeller and subsequently conveyed into a line section, which is also referred to as a pressure pipe.

Due to their robustness in relation to fluids mixed with solids, circular pumps are used as sewage pumps, in particular pumps for sewage lifting plants, in which the sewage is usually collected in a collecting tank for intermediate storage. The centrifugal pump must be vented so that the fluid can flow into the pump chamber after each pumping process and the centrifugal pump can deliver with high efficiency. For this purpose, it is customary to provide ventilation openings in the pump chamber through which the air can escape from the pump chamber. The vent opening is usually located at the highest point of the pump chamber, in vertically installed centrifugal pumps above the impeller.

When the centrifugal pump is delivering, the pressure difference between the higher pressure inside the pump chamber and the lower pressure on the side of the vent opening facing away from the pump chamber results in a leakage flow of the fluid through the vent opening that has to be accepted. The leakage flow of the fluid is usually routed away from the pump via a vent line or, in the case of wastewater lifting systems, returned to the collecting tank.

However, when the centrifugal pump is in operation, with low delivery heads and large volume flows of the fluid to be pumped, the effect can occur that the pressure conditions described above are reversed, so that the absolute pressure at the vent opening within the pump chamber is lower than the pressure on the side facing away from the pump chamber the vent. In the case of open systems, the pressure on the side of the vent opening facing away from the pump chamber generally corresponds to an ambient pressure of the pump or, in the case of closed sewage lifting plants, the pressure in the collecting tank of the sewage lifting plant.

The reverse pressure conditions mean that a reverse flow also occurs during the pump run, namely from outside the pump through the vent line and vent opening into the pump chamber. For sewage lifting systems, this means that, depending on whether the end of the vent line facing away from the vent opening is just above or below a filling level in the collecting tank, either air or fluid with the solids contained therein is conveyed through the vent line into the pump room.

An entry of air into the pump room leads to a drop in performance of the centrifugal pump. Furthermore, the entry of air leads to an undesirable increase in noise. Solids in the fluid can clog the vent line and / or the vent opening, so that the actual venting process can no longer or only insufficiently take place while the pump chamber of the pump is being filled, which also leads to a drop in performance.

Description of the invention

Based on this situation, it is an object of the present invention to improve a centrifugal pump and a lifting system of the type mentioned in such a way that the centrifugal pump or lifting system operates quietly and reliably without a drop in performance due to air entry and / or clogging of a hydraulic vent system the pump is working ..

This object is achieved by the features of the independent claims. Advantageous refinements are given in the subclaims.

Accordingly, the object is achieved by a centrifugal pump for conveying a fluid with a pump housing forming a pump chamber, an impeller being provided in the pump chamber and a suction opening for sucking the fluid into the pump chamber being provided in the pump housing, in relation to the suction opening a ventilation opening is provided behind the impeller, and an automatic valve through which air can escape from the pump chamber is provided on the ventilation opening.

An essential point of the solution described in more detail below is that the automatic valve is arranged at the vent opening. The valve allows air to pass unhindered through the vent. When the valve is open, air can escape from the pump chamber via the ventilation opening, which leads to the pump chamber being vented. When the valve is closed, no air can pass through the valve and thus neither escape from the pump chamber via the ventilation opening nor enter the pump chamber via the ventilation opening. In the context of the invention, an automatic valve is understood to mean a valve which opens and closes automatically without auxiliary energy. In other words, the opening and closing process of the valve is not made possible by electrical energy, but by mechanically provided energy. The mechanical energy for opening and closing the valve can be provided by the valve itself and / or by the medium flowing through the valve. The automatic valve is preferably designed in such a way that it is due to of pressure differences between a valve inlet side and a valve outlet side opens and / or closes. In the present case, the valve inlet side is the side of the valve in the interior of the pump chamber at the vent opening.

The automatic valve enables air to escape from the pump chamber, which means that the centrifugal pump can properly ventilate the pump chamber so that fluid can flow through the suction opening into the pump chamber after each pumping process. The valve thus enables air to flow from the valve inlet side to the valve outlet side. The automatic valve ensures that the centrifugal pump can deliver with a high degree of hydraulic efficiency. Furthermore, the automatic valve prevents air from flowing in the opposite direction, i.e. from outside the pump, via the vent opening into the pump chamber. In other words, the valve prevents air from flowing from the valve outlet side to the valve inlet side. Compared to pumps without an automatic valve, the hydraulic efficiency of the centrifugal pump according to the invention is constantly high, even with low delivery heights and large volume flows of the fluid to be conveyed. Furthermore, undesirable noise development is avoided, so that the pump can be operated quietly. The centrifugal pump can preferably be used for a hydraulic system in a building, for example in a sewage lifting system. Accordingly, the fluid can also contain solids, wherein the solid contained in the fluid can include impurities of any kind, for example dirt, paper, feces or the like.

In the case of a centrifugal pump, the fluid is conveyed by rotating the impeller. In this context, it is preferably provided that the impeller is connected to a drive motor via a motor shaft extending in the axial direction. During operation, the fluid flows from outside the pump through the suction opening in the pump housing into the pump chamber in which the rotating impeller is located. In addition to tangential acceleration of the fluid, a centrifugal force occurring in the radial direction is used to convey the fluid, so that centrifugal pumps are also referred to as centrifugal pumps. The fluid is preferably conveyed from the pump chamber into a line section, which is also referred to as a pressure pipe. For the purpose of venting the pump chamber, the centrifugal pump has the Vent open. The vent opening is preferably located at the highest point in the pump chamber. The air escaping through the vent opening can have a fluid component.

In many cases, the suction opening of the centrifugal pump is located at the lowest point of the pump housing, so that the centrifugal pump can pump out the fluid as far as possible without large amounts of residual fluid remaining below the suction opening. In such vertically installed centrifugal pumps, the axial direction of the motor shaft corresponds to the vertical direction. In vertically installed centrifugal pumps, the vent opening is preferably above the height at which the impeller is attached to the motor shaft.

However, other constructions and setups of the centrifugal pump are also possible in which the motor shaft extends in the horizontal direction. When installed horizontally, the suction opening is usually not at the lowest point of the pump housing. When installed horizontally, the ventilation opening is preferably located next to the fastening point of the impeller on the motor shaft and on the side of the impeller facing away from the suction opening, based on the horizontal direction.

As already mentioned, the automatic valve enables air to escape from the pump chamber and prevents air from outside the pump from flowing into the pump chamber via the vent opening. In principle, it is therefore possible for the valve to open due to the flow of air out of the pump chamber. In this case, the valve would open when the pressure on the valve inlet side is greater than on the valve outlet side. However, according to a preferred development of the invention, it is provided that the valve is designed in such a way that it is open when the same or a higher pressure is present in the pump chamber at the vent opening than an ambient pressure on the valve outlet side. In other words, this means that the valve is preferably open at the same pressure on the valve inlet side and the valve outlet side. This enables the air to escape unhindered from the valve from the pump chamber when the pump is being conveyed. The venting of the pump room is therefore free of resistance, i.e. an overpressure does not have to build up in the pump room, which opens the valve before the air can escape from the pump room.

As is also known from the prior art, when the centrifugal pump is conveyed, a leakage flow of the fluid from the pump chamber through the ventilation opening that has to be accepted occurs. If - as is usual with sewage lifting plants - the leakage flow of the fluid is returned from the pump to a collecting tank of the sewage lifting plant via a vent line, the ambient pressure on the valve outlet side corresponds to the pressure in the collecting tank of the sewage lifting plant. In open systems, the ambient pressure on the valve outlet side corresponds to the ambient pressure outside the pump, i.e. usually normal pressure.

With regard to the closing of the valve, a preferred development of the invention provides that the valve is designed in such a way that it closes when the pressure in the pump chamber at the vent opening is lower than the ambient pressure on the valve outlet side. In other words, the valve closes as soon as the pressure on the valve inlet side is lower than on the valve outlet side. Thus, when the pump is operating in the right-hand range of the characteristic curve, i.e. with a low delivery head and large volume flows of the fluid to be pumped, the valve can prevent air from entering the pump chamber from outside the pump via the vent opening. The valve preferably closes due to the briefly established volume flow of air from the valve outlet side to the valve inlet side. More preferably, the kinetic energy of the volume flow is used to close the valve. In particular, it is provided that the valve closes as soon as a lower pressure is established on the valve inlet side than on the valve outlet side and remains closed as long as these pressure conditions remain. In this way, the valve prevents air from flowing back into the pump chamber.

According to a preferred development of the invention it is provided that the valve is designed as a self-closing flap valve. The self-closing flap valve is preferably at least partially open when the pressure on the valve inlet side corresponds to the pressure on the valve outlet side. It is furthermore possible that a flap of the flap valve is caused by the air passing through from the valve inlet side to the valve outlet side when the pump is vented and / or as a leakage flow penetrating fluid is opened further during operation of the pump. If, for example, when the pump is operating in the right-hand range of the characteristic curve, i.e. with a low delivery head and large volume flows of the fluid to be pumped, a situation occurs where the pressure on the valve inlet side is lower than on the valve outlet side, the volume flow is briefly reversed, which leads to closure of the flap valve leads. The valve preferably has a dimensional stiffness such that the valve opens completely at the same pressure upstream and downstream of the valve. The self-closing flap valve has the advantage that it is very robust due to its simple structure and can be produced without great effort.

As an alternative to the flap valve, according to a preferred development of the invention, the valve is designed as a duck bill valve. The duck bill valve is preferably a valve made of elastic material, the shape of which is modeled on the beak of a duck. The end of the duck bill valve corresponding to the valve inlet side preferably has a shape corresponding to the vent opening. The other end of the duckbill valve, that is to say the end corresponding to the valve outlet side, preferably has a flattened shape. The duck bill valve is preferably designed in such a way that it allows the air flow from the pump chamber through the vent opening without restriction. If, on the other hand, there is a flow reversal, so that air briefly flows from outside the pump through the vent opening into the pump chamber, the valve closes and thus prevents the backflow of any fluid contaminated with solids as well as air into the pump chamber. The duckbill valve has the advantage that it closes at very low pressure differences between the valve inlet side and the valve outlet side and has a very short response time.

In this context, according to a preferred development of the invention, it is provided that the valve is designed as a tubular valve with two tabs which are placed against one another in the event of a backflow and / or in the event of a backflow. In other words, the end of the valve corresponding to the valve inlet side preferably has a tubular shape and the end corresponding to the valve outlet side has two tabs. The flaps are preferably two opposite flap-like end pieces of the hose jacket. Closing the valve is preferably achieved by In the case of backflow, the tabs of the valve lie against one another and thus close a cross-section of the hose. In the event of a backflow, the flaps remain next to one another and the cross-section is closed, so that the valve prevents air from flowing into the pump chamber when the pressure conditions are reversed. The valve has the advantage that it responds to very small pressure differences between the valve inlet side and the valve outlet side and closes the cross-section very quickly.

According to a further preferred development of the invention it is provided that the valve is made from an elastomer, preferably from a fluorinated elastomer. Since the valve for closing and opening preferably changes its shape, it has been shown to be advantageous if the valve is made from an elastomer. In particular, rubber, particularly preferably fluororubber (FKM), has proven to be advantageous. Alternatively, it is also possible to use other fluorinated elastomers, such as perfluorinated rubber (FFKM), tetrafluoroethylene / propylene rubbers (FEPM) and / or fluorinated silicone rubber (FVMQ). The materials mentioned have the advantage that they are particularly resistant to chemicals, which is particularly favorable for sewage lifting plants due to the faeces. Furthermore, the mechanical properties, in particular the deformability and processability of the materials, are particularly suitable for producing the automatic valve. In addition, the elastomer can be made from other elastic materials.

With regard to the design of the automatic valve, a preferred development of the invention provides that a wall thickness of the valve decreases from the valve inlet side to the valve outlet side. The decreasing wall thickness gives the valve material the flexibility it needs to close or open. The wall thickness on the valve inlet side is preferably 2 mm and on the valve outlet side 0.4 mm, more preferably 0.2 mm. Furthermore, it is preferably provided that the cross section of the valve is circular on the valve inlet side and circular, elliptical, almond shaped and / or lenticular on the valve outlet side. The diameter of the circular valve outlet side is preferably greater than the diameter of the elliptical, almond-shaped and / or lenticular valve outlet side. Furthermore, it is preferably provided that the valve has a conically decreasing shape, in which the diameter of the Valve inlet side to valve outlet side steadily reduced. The conical shape preferably has a slope angle of 3 degrees.

In principle, the valve can be attached directly to the side of the vent opening facing away from the pump chamber. Alternatively, according to a preferred development of the invention, provision is made for a ventilation channel integrated into the pump housing or a ventilation hose connected to the pump housing to be provided between the valve and the ventilation opening. A ventilation hose between the ventilation opening and valve increases the flexibility of the centrifugal pump. The ventilation hose is preferably flexible, so that, in particular in the case of sewage lifting plants, the leakage flow can be returned to the collecting tank of the sewing lifting plant through a separate opening in the collecting tank. Alternatively, the ventilation channel integrated in the pump housing simplifies the handling and robustness of the pump. The integrated vent channel preferably leads away from the vent opening to an outside of the centrifugal pump. Due to the integration of the ventilation channel in the pump housing, the ventilation channel can hardly break away from the pump housing.

According to a preferred development of the invention, the centrifugal pump has a drive motor, the impeller being in operative connection with a motor shaft of the drive motor. The rotary movement of the impeller, which is responsible for conveying the fluid, is preferably passed on from the drive motor to the impeller via a motor shaft extending in the axial direction. In this context, it has proven to be advantageous if the suction opening is designed concentrically to the axis of the motor shaft. The suction opening is thus also arranged concentrically to the impeller. The pump housing is also preferably attached to a motor flange of the drive motor.

The centrifugal pump according to the invention is basically suitable for pumping any fluid. Due to its robustness against solids and chemicals, the centrifugal pump is particularly suitable for use as a waste water and / or submersible sewage pump. Dirty water and / or sewage submersible pumps are used in particular For pumping dirty water, for example from floods, in flooded construction pits, in laundry rooms, in muddy pits, in biotopes and / or garden ponds, from seepage shafts and in basements, and in particular for pumping water with various degrees of contamination such as stones, mud or rubble Feces. The proposed use makes it possible to ensure low-noise operation and reliable venting of the pump chamber of the dirty water and / or sewage submersible pump. In addition, the centrifugal pump can also be used for heating with radiators, radiator heating, underfloor heating, ceiling cooling, water circulation in a drinking water system or a drinking water system with a storage tank charging system, whereby the above list is not exhaustive, but includes other types of systems not mentioned here can.

Furthermore, the object is achieved by a lifting system comprising a collecting container and a centrifugal pump as described above, wherein the centrifugal pump can be connected to the collecting container in such a way that the suction opening faces an interior of the collecting container and wherein the automatic valve can be connected to the collecting container.

In lever systems, in particular, it can be advantageous if the automatic valve is not attached directly to the ventilation opening, but instead the ventilation channel integrated into the pump housing or the ventilation hose connected to the pump housing is provided between the valve and the ventilation opening. In this way, the valve is easily accessible and can be easily guided back into the collecting container and attached to it.

In principle, it is possible for the collecting container of the lifting system to have an opening which is designed to correspond to the pump housing. The opening of the collecting container can be closed by applying the pump to the opening, the suction opening of the centrifugal pump advantageously facing the interior of the collecting container. In this form in particular, it is advantageous if the flexible ventilation hose is provided between the valve and the ventilation opening. This enables the valve to be attached to a further opening on the collecting container and thus to guide the leakage flow back into the collecting container.

Alternatively, it is possible that at least a part of a container wall of the collecting container is formed by the pump housing having the suction opening. In this case it can be provided that the container wall is shaped in such a way that it forms a lower part of an at least two-part pump housing. The opening in the container wall is therefore the suction opening of the centrifugal pump. In this form in particular, it is advantageous if the ventilation channel integrated into the pump housing is provided between the valve and the ventilation opening. The integrated ventilation channel preferably leads away from the ventilation opening to an outside of the centrifugal pump, which is preferably also formed by the container wall. In this way, the automatic valve can be mounted directly on the container wall and the leakage flow can be fed back into the collecting container. Due to this construction, the lifting system has a very compact shape.

According to a preferred development of the invention it is provided that a drive motor of the centrifugal pump is arranged at least partially outside of the collecting container. It has proven to be advantageous, in particular with regard to the maintenance of the lifting system, if the drive motor is arranged at least partially outside the collecting container. The drive motor is preferably positioned completely outside the collecting container.

Further embodiments and advantages of the use of the centrifugal pump and / or the lifting system result for the person skilled in the art in analogy to the centrifugal pump described above.

Brief description of the drawings

The invention is explained in more detail below with reference to the accompanying drawings using a preferred exemplary embodiment.

Fig. 1

eine schematische Schnittansicht einer Kreiselpumpe in einer Hebeanlage gemäß einem bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 2

eine perspektivische Ansicht eines selbsttätigen Ventils der Kreiselpumpe aus Fig. 1,

Fig. 3

eine schematische Schnittansicht einer Kreiselpumpe in einer Hebeanlage mit einer alternativen Ausführungsform des Ventils gemäß einem weiteren bevorzugten Ausführungsbeispiel der Erfindung, und

Fig. 4

eine schematische Schnittansicht einer Kreiselpumpe in einer Hebeanlage gemäß einem weiteren bevorzugten Ausführungsbeispiel der Erfindung.

Show in the drawings

Fig. 1

a schematic sectional view of a centrifugal pump in a lifting system according to a preferred embodiment of the invention,

Fig. 2

a perspective view of an automatic valve of the centrifugal pump Fig. 1 ,

Fig. 3

a schematic sectional view of a centrifugal pump in a lifting system with an alternative embodiment of the valve according to a further preferred embodiment of the invention, and

Fig. 4

a schematic sectional view of a centrifugal pump in a lifting system according to a further preferred embodiment of the invention.

Detailed description of the working examples

Figure 1 shows a schematic sectional view of a centrifugal pump 10 in a lifting plant 12 according to a preferred embodiment of the invention. The centrifugal pump 10 has a pump housing 16 that forms a pump chamber 14. An impeller 18 is arranged within the pump chamber 14. The impeller 18 is connected to a drive motor 24 of the centrifugal pump 10 via a motor shaft 22 extending in the axial direction 20. The pump housing 16 has a suction opening 26 concentric to the axis 20 of the motor shaft 22, through which a fluid can flow into the pump chamber 14. Detected by the rotation of the impeller 18, the fluid is discharged into a pressure port 28 (only in Figure 4 shown) promoted. The suction opening 26 of the centrifugal pump 10 is located at the lowest point of the pump housing 16, and the axial direction 20 of the motor shaft 22 corresponds to the perpendicular direction. In addition, the pump housing 16 of the centrifugal pump 10 has a ventilation opening 30 behind the impeller 18 in relation to the suction opening 26. For the centrifugal pump 10 in Figure 1 is the vent 30 at the highest point of the Pump chamber 14 and above the height at which the impeller 18 is attached to the motor shaft 18. An automatic valve 32 through which air can escape from the pump chamber 14 is provided at the ventilation opening 30. In the present case, the valve 32 connects to the vent opening 30 via a flexible vent hose 34.

The lifting system 12 also has a collecting container 36 which can be connected to the centrifugal pump 10. To connect the centrifugal pump 10 to the collecting container 36, a container wall 38 of the collecting container 36 has an opening which is designed to correspond to the pump housing 16. In the exemplary embodiment preferred here, the centrifugal pump 10 and the collecting container 36 are connected in such a way that the suction opening 26 of the centrifugal pump 10 faces an interior of the collecting container 36. Furthermore shows Figure 1 that the valve 32 is mounted in a further opening of the collecting container 36, so that the ventilation opening 30 is connected to the interior of the collecting container 36 via the ventilation hose 34 and the valve 32. In the present case, the side of the valve 32 which faces the vent opening 30 corresponds to a valve inlet side 40 and the side of the valve 32 which faces the interior of the collecting container 36 corresponds to a valve outlet side 42.

Figure 2 FIG. 14 shows a perspective view of the valve 32 from FIG Figure 1 . The valve 32 is designed as a duck bill valve 32b, wherein Figure 2 represents the valve 32b in the open state. The cross section of the valve 32b on the valve inlet side 40 is cylindrical in the present case and configured to correspond to the cross section of the vent hose 34. The cross section of the valve 32b on the valve outlet side 42 is in the present case almond-shaped and somewhat smaller than the cross section of the valve inlet side 40. The valve 32b thus has a conical shape, with an angle of inclination being 3 degrees. Furthermore, a wall thickness 44 decreases from the valve inlet side 40 to the valve outlet side 42 from 4 mm to 0.4 mm. On the valve outlet side 42, the valve 32b has two mutually opposite flaps 46 which are formed from a lateral surface of the valve 32b. The present valve 32b is made of FKM.

Figure 3 shows a schematic sectional view of the centrifugal pump 10 in the lifting system 12 with an alternative embodiment of the valve 32 according to a further preferred one Embodiment of the invention. Compared to duck bill valve 32b Figures 1 and 2 , the valve is 32 in Figure 3 designed as a self-closing flap valve 32a. The cross section of the valve 32a in Figure 3 is circular for the valve inlet side 40 as for the valve outlet side 42, the diameter being the same. A circular flap 48 is located on the valve outlet side 42.

How further on Figure 3 As can be seen, the valve 32a is not attached to a flexible ventilation hose 34, but rather to a ventilation channel 50 integrated into the pump housing 16. Analogous to FIG Figure 1 the valve 32a also opens into the collecting container 36 of the lifting system 12. In contrast to FIG Figure 1 is at the collector 36 in Figure 3 at least a part of the container wall 38 is formed by the pump housing 16 having the suction opening 26. The container wall 38 is shaped in such a way that it forms a lower part of the at least two-part pump housing 16. The ventilation channel 50 integrated in the pump housing 16 leads away from the ventilation opening 30 in the pump chamber 14 to an outside of the centrifugal pump 10, which is also formed by the container wall 38.

Figure 4 shows a schematic sectional view of the centrifugal pump 10 in the lifting system 12, according to a further preferred embodiment of the invention. The valve 32 is in Figure 4 analogous to Figures 1 and 2 designed as a duck bill valve 32b. Analogous to Figure 3 the valve 32b is mounted on the ventilation channel 50 integrated in the pump housing 16. The collecting container 36 is also analogous to the lifting system 12 in FIG Figure 3 built up. In Figure 4 it can be seen that the impeller 18 is an impeller 18 that is open on one side and the centrifugal pump has a generous pump chamber 14 with a large suction opening 26. It can also be seen that the fluid sucked into the pump chamber 14 through the suction opening 26 is mainly conveyed into the pressure connection 28 by radial flow. Because of the impeller 18 which is open on one side, the spacious pump chamber 14 and the generous diameter of the pressure port 28, the circular pump 10 is particularly suitable for pumping fluids mixed with solids.

The exemplary embodiments described are merely examples that can be modified and / or supplemented in many ways within the scope of the claims. Every feature that has been described for a specific exemplary embodiment can be used on its own or in combination with other features in any other exemplary embodiment. Each feature that has been described for an exemplary embodiment of a specific category can also be used in a corresponding manner in an exemplary embodiment of another category. List of references Centrifugal pump 10 Lifting station 12th Pump room 14th Pump housing 16 Wheel 18th Axial direction 20th Motor shaft 22nd Drive motor 24 Suction opening 26th Discharge port 28 Vent 30th Valve 32 Flap valve 32a Duck bill valve 32b Ventilation hose 34 Collection container 36 Container wall 38 Valve inlet side 40 Valve outlet side 42 Wall thickness 44 Rag 46 flap 48 Ventilation duct 50

Claims (14)

Centrifugal pump (10) for conveying a fluid with a pump housing (16) forming a pump chamber (14), wherein an impeller (18) is provided in the pump chamber (14), a suction opening (26) is provided in the pump housing (16) for sucking the fluid into the pump chamber (14), a ventilation opening (30) is provided in the pump housing (16) behind the impeller (18) in relation to the suction opening (26), and an automatic valve (32) through which air can escape from the pump chamber (14) is provided at the ventilation opening (30). Centrifugal pump (10) according to the preceding claim, wherein the valve (32) is designed such that it is open when the same or a higher pressure is present in the pump chamber (14) at the vent opening (30) as an ambient pressure on a valve outlet side (42). Centrifugal pump (10) according to one of the preceding claims, wherein the valve (32) is designed such that it closes when a lower pressure is present in the pump chamber (14) at the vent opening (30) than an ambient pressure on a valve outlet side (42) . Centrifugal pump (10) according to one of the preceding claims, wherein the valve (32) is designed as a self-closing flap valve (32a). Centrifugal pump (10) according to one of the preceding claims, wherein the valve (32) is designed as a duck bill valve (32b). Centrifugal pump (10) according to one of the preceding claims, wherein the valve (32) is designed as a hose-shaped valve (32) with two tabs (46) which lie against one another in the event of a backflow and / or in a backflow. Centrifugal pump (10) according to one of the preceding claims, wherein the valve (32) is designed from an elastomer, preferably from a fluorinated elastomer. Centrifugal pump (10) according to one of the preceding claims, wherein a ventilation channel (50) integrated into the pump housing (16) or a ventilation hose (34) connected to the pump housing (16) is provided between the valve (32) and the ventilation opening (30) . Centrifugal pump (10) according to one of the preceding claims, with a drive motor (24) and wherein the impeller (18) is in operative connection with a motor shaft (22) of the drive motor (24). Centrifugal pump (10) according to one of the two preceding claims, wherein the suction opening (26) is designed concentrically to the axis (20) of the motor shaft (22). Use of a centrifugal pump (10) according to one of the preceding claims as a waste water and / or waste water submersible pump. Lifting plant (12) comprising a collecting container (36) and a centrifugal pump (10) according to one of the preceding centrifugal pump claims, wherein the centrifugal pump (10) can be connected to the collecting container (36) in such a way that the suction opening (26) corresponds to an interior of the collecting container (36) ) and wherein the automatic valve (32) can be connected to the collecting container (36). Lifting plant (12) according to the preceding claim, wherein at least part of a container wall (38) of the collecting container (36) is formed by the pump housing (16) having the suction opening (26). Lifting plant (12) according to one of the preceding lifting plant claims, a drive motor (24) of the centrifugal pump (10) being arranged at least partially outside of the collecting container (36).

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