DE102008022279B4 - Jet pump and method for operating a jet pump - Google Patents

Abstract

A jet pump (10) comprising a suction region (16) having a first pump inlet (20) for a suction fluid and a second pump inlet (22) for a drive fluid deliverable to a drive nozzle (24), a pressure region (18) having a pump outlet (34) for a mixed fluid of suction fluid and drive fluid, and a fluid introduction device (36) for introducing an additional fluid into the suction region (16), characterized by a fluid return device (38) for returning at least a portion of the additional fluid from the pressure region (18) into the suction region (16) wherein the fluid return means (38) is fluidly connected or connectable to the fluid introduction means (36) and the fluid return means (38) comprises fluid delivery means (40) for delivering at least a portion of the additive fluid from the pressure region (18).

Description

The invention relates to a jet pump, comprising a suction region having a first pump inlet for a suction fluid and a second pump inlet for a drive fluid to be supplied to a motive nozzle, a pressure region having a pump outlet for a mixed fluid of suction fluid and motive fluid, and a fluid introduction device for introducing an additional fluid into the suction region ,

Jet pumps exist in many different sizes and can be designed accordingly for the promotion of different large volume flows. Jet pumps are low maintenance and reliable. In the case of jet pumps, however, there is the risk that, when a nominal delivery rate is undershot, fluid flows back from the pressure region of the jet pump into the suction region of the jet pump and from there to the suction region of the jet pump upstream components, whereby these components can be damaged in the worst case. Known jet pumps, which are designed so that these Rückströmeffekte not occur even with a complete interruption of the promotion of the intake fluid, so "zero flow-stable" or "blind stable" jet pumps, have an increased Treibfluidbedarf.

From the DE 33 28 912 A1 an exhaust jet suction pump is known for driving through the exhaust gases of an engine leaving the exhaust pipe, which is a marine engine having a suction port leading to the exhaust jet suction pump for exhausting various media from inside the boat or ship.

From the DE 42 01 037 B4 a suction jet pump is known in which the size of a nozzle outlet opening is adjustable in dependence on pressure.

From the DE 101 19 553 A1 is a suction jet pump with a arranged in front of a mixing tube, connectable to a propellant conduit, a nozzle channel having nozzle known. The nozzle has a nozzle insert in the region of the nozzle channel.

From the US 2004/0105760 A1 For example, an injector is known which has nozzles for propellant gas.

On this basis, the present invention seeks to provide a jet pump of the type mentioned, which is zero flow stabilizer with the lowest possible Treibfluidbedarf.

This object is achieved with a jet pump of the type mentioned above in that a fluid return device is provided for returning at least a portion of the additional fluid from the pressure range in the suction region, wherein the fluid return means fluidly connected to the Fluideinbringeinrichtung or is connectable, and the fluid return means for a fluid delivery Spreading at least a portion of the additional fluid from the pressure range comprises.

With the aid of the fluid introduction device, an additional fluid can be introduced into the suction region, so that a flow direction reversal in the jet pump can be excluded even with low intake fluid flows. In this way, if necessary, the "net delivery rate", ie the delivery rate of the freshly aspirated intake fluid, can be reduced to very low values. Thus, it is also possible to realize a "zero flow state" in which no intake fluid is conveyed at all without this being accompanied by an increase in the drive fluid requirement.

A fluid return device is provided for returning at least a portion of the additional fluid from the pressure region into the suction region. In this way, a self-stabilizing jet pump can be created.

The fluid return device can be connected to the fluid introduction device in a fluid-effective manner. This allows a particularly simple return of the additional fluid in the suction area.

The fluid return device comprises a fluid delivery device for discharging at least a portion of the additional fluid from the pressure region.

Preferably, the fluid introduction device is arranged in the flow direction of the suction fluid in front of an outlet of the motive nozzle or approximately at the level of the outlet of the motive nozzle. This allows a reliable suction of the additional fluid by means of the driving fluid, which is introduced through the second pump inlet into the suction region of the jet pump.

Furthermore, it is preferred if the additional fluid can be supplied to the suction region through the first pump inlet. As a result, the additional fluid can be introduced into the suction area in a particularly simple manner. The additional fluid can also be supplied out of a container for intake fluid and in particular via the first pump input to the suction region.

It is advantageous if at least a portion of the additional fluid is formed by driving fluid. In this way, the jet pump, an additional fluid to be supplied, which for the operation of the Jet pump is kept ready to convey the intake fluid.

It is particularly preferred if at least a portion of the additional fluid is formed by mixed fluid. In this way, a process-compatible fluid can be used as additional fluid, which is also provided in a nominal operation of the jet pump.

It is particularly preferred if at least a portion of the additional fluid can be removed from the pressure region and fed to the fluid introduction device. This allows a particularly simple provision of the additional fluid. By removing the additional fluid from the pressure region, a boundary layer of a flow of the mixed fluid or of the driving fluid present there can be sucked off, as a result of which a separation of the flow is displaced further in the direction of the pump outlet. The return of the removed additional fluid in the suction region in turn allows the generation of a stable, directed to the pressure region flow of a fluid, which is composed of the recirculated additional fluid and supplied with the aid of the second pump input driving fluid.

In particular, the fluid discharge device is arranged in the flow direction of the additional fluid before the pump outlet. In this way, the additional fluid can be removed in a section of the pressure region, so that a collapse of a fluid flow present there can be prevented.

According to one embodiment of the invention, it is provided that the jet pump comprises a mixing nozzle, which has a convergent nozzle section, a narrowest nozzle section and a divergent nozzle section, and that the fluid discharge device is arranged at the level of the divergent nozzle section and / or the narrowest nozzle section. This allows a particularly effective discharge of an additional fluid in a region which is particularly at risk for a collapse of the fluid flow.

In particular, the fluid dispensing device is arranged in the region of a transition between the divergent nozzle section and the narrowest nozzle section or adjacent thereto. This allows a particularly favorable influence on the flow can be achieved.

Preferably, the fluid discharge device comprises a separation device for separating additional fluid from the pressure region. In this way, a partial flow of the fluid flowing through the jet pump can be taken from the pressure region and in particular fed to the suction region. Preferably, the fluid discharge device comprises a fluid collection device for collecting additional fluid which can be separated from the pressure region. This allows a distributed over the flow cross-section of the fluid or over a circumference of the flow cross-section deposition of the additional fluid. In particular, the fluid collection device is designed in the form of a ring collector.

The jet pump preferably comprises a fluid line for the fluid-effective connection of the fluid delivery device to the fluid introduction device. In this way, a direct connection between the Fluidausbringeinrichtung and the Fluideinbringeinrichtung be prepared.

According to an advantageous embodiment of the invention, the jet pump comprises a fluid flow control device, by means of which a fluid flow between the Fluidausbringeinrichtung and the Fluideinbringeinrichtung is controllable and / or optionally a fluid effective connection between the Fluidausbringeinrichtung and the Fluideinbringeinrichtung can be produced or interrupted. In this way, the return rate of the additional fluid can be controlled in dependence on a delivery rate of the intake fluid. For example, the fluid connection between the Fluidausbringeinrichtung and the Fluideinbringeinrichtung be prepared when the jet pump to be operated in idle or in the zero flow state. The connection between the fluid delivery device and the fluid delivery device may be interrupted if the jet pump is to be operated at a nominal mass flow of the intake fluid.

The fluid flow control device may comprise an on / off valve and / or a particularly continuously adjustable control valve. Alternatively or additionally, the fluid flow control device may also include a throttle device, in particular in the form of a diaphragm.

It is further preferred if the jet pump comprises a condensate separator for the separation of condensate from the additional fluid. In this way, the introduction or the return of condensate can be prevented in the suction region of the jet pump. This is particularly advantageous when operating the jet pump at low ambient temperatures. The condensate can be removed continuously, or the condensate can be collected in a condensate collector, which is then emptied if necessary. The removal of the condensate or emptying of the condensate collector can be done by acting a pressure difference ("barometric") and / or with the aid of a condensate pump.

According to one embodiment of the invention, the jet pump has a substantially vertical with respect to the direction of gravity pump axis. This allows a fluid conveying direction, which is vertical relative to the direction of gravity, and, in particular, a return of an additional fluid from the pressure region to the suction region of the jet pump that is vertical in relation to the direction of gravity. Such an arrangement is particularly advantageous when condensate is to be separated from the mixing fluid.

According to a further embodiment of the invention, the fluid introduction device can be fluid-effectively connected to a reservoir for receiving an additional fluid. Such an additional fluid can be a fluid which is also used as a drive fluid and / or as an intake fluid during the delivery operation of the jet pump. However, it is also possible to use a fluid other than the driving fluid and the suction fluid.

According to a development of the invention, the fluid introduction device can be fluid-effectively connected to an environment of the jet pump. As a result, the additional fluid can be taken from the surroundings of the jet pump so as to ensure reliable operation of the jet pump at low or nonexistent intake fluid flows.

In particular, it is preferred if at least a portion of the additional fluid is formed by ambient air. This allows a particularly simple and cost-effective provision of the additional fluid.

According to a further advantageous embodiment of the invention, at least one mixing fluid delivery device is connected downstream of the pump outlet of the jet pump. This makes it possible to create a multi-stage conveyor ("cascade"). The at least one downstream mixing fluid delivery device can likewise be stabilized, since the additional fluid supplied to the suction region of the upstream jet pump is supplied via the pump outlet of this jet pump to the downstream mixing fluid delivery device. This is particularly advantageous if the mixing fluid delivery device is also designed in the form of a jet pump.

In addition, a condenser and / or a cooling device can be provided between the jet pump and the at least one downstream mixing fluid delivery device.

It is advantageous if the mixing fluid delivery device comprises a mixing fluid delivery device which can be connected in a fluid-effective manner to the fluid introduction device of the (upstream) jet pump. In this way, the additional fluid can be provided by removal from a downstream of the jet pump conveyor.

The invention further relates to a method of operating a jet pump using a driving fluid.

The invention has the further object to provide a method for operating a jet pump, which is zero flow stabilizer with the lowest possible Treibfluidbedarf.

This object is achieved in a method for operating a jet pump using a driving fluid according to the invention that by means of the driving fluid instead of a suction or in addition to the suction fluid, an additional fluid is conveyed and at least a portion of the additional fluid taken from a pressure range of the jet pump and in a suction of the Jet pump is returned.

Particular embodiments and advantages of the method according to the invention have already been explained above in connection with the particular embodiments and the advantages of the jet pump according to the invention.

The jet pump described above is particularly suitable for carrying out a method described above.

The jet pump according to the invention and the method according to the invention can be used in particular in production plants or in test stands, in particular in height simulation plants.

The intake fluid is preferably a gaseous medium, in particular steam.

The driving fluid is preferably a gaseous medium, in particular steam.

Further features and advantages of the invention are the subject of the following description and the diagrammatic representation of a preferred embodiment.

In the drawings show:

1 a schematic section of a first embodiment of a jet pump according to the invention;

2 : one in 1 With II designated section in an enlarged view; and

3 FIG. 2: a schematic section of a suction region of a second embodiment of a jet pump according to the invention. FIG.

Identical or functionally equivalent elements are denoted by the same reference numerals in all figures.

One in the 1 illustrated embodiment of a jet pump 10 extends along a pump axis 12 , The jet pump 10 has a along the pump axis 12 extending flow channel 14 on.

The steel pump 10 includes an inlet-side suction area 16 and an output side print area 18 ,

The suction area 16 includes a first pump input 20 , by means of which an intake fluid is sucked.

The suction area 16 further includes a second pump input 22 , by means of which a drive fluid of a motive nozzle 24 can be fed. The motive nozzle 24 has an exit 25 on. The exit 25 flows into the flow channel 14 ,

The jet pump 10 includes a mixing nozzle 26 , which has a convergent nozzle section 28 , a narrowest nozzle section 30 and a divergent nozzle section 32 includes. The nozzle sections 28 . 30 and 32 go into each other.

The convergent nozzle section 28 is cone-shaped. The narrowest nozzle section 30 is cylindrical and is also referred to as a "neck". The divergent nozzle section 32 is cone-shaped.

The divergent nozzle section 32 can also be referred to as a diffuser and opens at a pump outlet 34 , from which suction fluid and / or driving fluid from the jet pump 10 is dissipated.

The jet pump 10 comprises a fluid introduction device 36 , by means of which an additional fluid in the suction area 16 of the flow channel 14 can be introduced. The fluid introduction device 36 is seen in the flow direction of the suction between the first pump inlet 20 and the second pump input 22 arranged.

The fluid introduction device 36 is fluid effective with a fluid return device 38 connected, by means of which an additional fluid from the pressure range 18 the jet pump 10 in the suction area 16 can be returned.

The fluid return device 38 includes a fluid delivery device 40 which are in the area of a transition 42 between the divergent nozzle section 32 and the narrowest nozzle section 30 is arranged. The fluid delivery device 40 is by means of a fluid line 44 fluidly effective with the fluid introduction device 36 connectable.

The flow channel 14 is at the height of the narrowest nozzle section 30 by means of a cylindrical wall section 46 limited. The flow channel 14 is at the level of the divergent nozzle section 32 by means of a divergent wall section 48 limited.

At least one of the wall sections 46 . 48 For example, the divergent wall section 48 , Has along its circumferentially distributed perforations arranged 50 by means of which a fluid connection between the flow channel and the fluid line 44 can be produced. The breakthroughs 50 are formed for example in the form of holes or slots.

The fluid delivery device 40 further comprises a separator 52 , which in particular in the form of a separation wall 54 is trained. The separation wall 54 is inside the flow channel 14 arranged and limited together with at least one of the wall sections 46 . 48 a separation room 56 , The separation room 56 is by means of the openings 50 with an annular collecting space 58 fluidly connected. The collection room 58 is outside the flow channel 14 intended. The collection room 58 is through a fluid collection device 60 in the form of a ring collector 62 limited. The collection room 58 is in fluid communication with the fluid line 44 ,

The jet pump 10 further comprises a fluid flow control device 64 , which has a return rate of the additional fluid through the fluid line 44 controls and in particular is designed as a valve.

The jet pump 10 further comprises a condensate separator 66 , which with respect to the direction of gravity in a lower region of the fluid return device 38 is arranged. The condensate cutter 66 is optional.

Additionally or alternatively to the fluid return device 38 includes the jet pump 10 a suction device 68 which is in fluid communication with the fluid introduction means 36 stands. By means of the suction device 68 is an environment 70 the jet pump 10 fluidly effective with the fluid introduction device 36 and thus with the suction area 16 the jet pump 10 connectable.

The jet pump 10 works as follows.

To promote a suction fluid is by means of the motive nozzle 24 a driving fluid in the flow channel 14 initiated. By means of the motive nozzle 24 the driving fluid is expanded so that at the outlet of the motive nozzle 24 a negative pressure is created. With the help of this negative pressure, a suction fluid is sucked, which via the first pump input 20 in the flow channel 14 flows. The kinetic energy of the motive fluid is transferred to the intake fluid such that the intake fluid is propelled by the motive fluid toward the pump exit 34 is encouraged. During the flow through the mixing nozzle 26 mix the suction fluid and the driving fluid.

The jet pump 10 can be operated so that little or no intake fluid is sucked. To collapse the flow within the flow channel 14 and a backflow of a fluid toward the first pump inlet 20 is prevented by means of the fluid introduction device 36 an additional fluid in the suction area 16 of the flow channel 14 brought in. The additional fluid is by means of Fluidausbringeinrichtung 40 from the printing area 18 taken by a part of the fluid flow over the separation chamber 56 and the breakthroughs 50 the collection room 58 and from there via the fluid line 44 the fluid introduction device 36 is supplied. Depending on the delivery rate of the intake fluid, the additional fluid is formed by propellant gas or by a mixed fluid of propellant gas and intake fluid.

To control the out of the pressure range 18 in the suction area 16 recirculated additional fluid, the fluid flow control device 64 be operated accordingly. For high intake fluid flows, the additional fluid flow through the fluid return device 38 shut off. At low or zero flow rates of intake fluid, by means of the fluid flow control device 64 a fluid effective connection between the fluid delivery device 40 and the fluid introduction device 36 produced. For controlling a return rate of the additional fluid, it is preferred if the fluid flow control device 64 Intermediate positions between a fully open position and a fully closed position allows.

By means of the fluid return device 38 recycled additional fluid is using the condensate 66 freed from condensate, so that in particular a gaseous additional fluid in the suction area 16 can be introduced.

Alternatively or in addition to the return of the additional fluid from the pressure range 18 in the suction area 16 An auxiliary fluid may also be provided by the suction device 68 is opened, so in the area 70 the jet pump 10 existing ambient air in the suction area 16 can be introduced.

In the in the 1 and 2 illustrated first embodiment of a jet pump 10 is the first pump input 20 arranged such that the suction fluid in to the pump axis 12 parallel direction in the flow channel 14 flows. The second pump input 22 is arranged laterally so that the motive nozzle 24 the driving fluid is supplied in the radial direction. In contrast to this are in the in the 3 illustrated second embodiment of a jet pump 10 the first pump input 20 and the second pump input 22 arranged such that the suction fluid from the radial direction and the driving fluid in to the pump axis 12 parallel direction is supplied.

The additional fluid may alternatively be used in the 1 to 3 shown supply from a radial direction also in to the pump axis 12 parallel direction in the flow channel 14 be introduced, in particular concentric with the pump axis 12 , A distributed over the circumference of the suction area introduction of the additional fluid in the suction area is possible.

Claims (29)

Jet pump ( 10 ), comprising a suction area ( 16 ) with a first pump input ( 20 ) for an intake fluid and a second pump input ( 22 ) for a drive nozzle ( 24 ) deliverable drive fluid, a pressure range ( 18 ) with a pump outlet ( 34 ) for a mixed fluid of suction fluid and motive fluid, and a fluid introduction device ( 36 ) for introducing an additional fluid into the suction area ( 16 ), characterized by a fluid return device ( 38 ) for returning at least a portion of the additional fluid from the pressure range ( 18 ) in the suction area ( 16 ), wherein the fluid return device ( 38 ) fluidly with the fluid introduction device ( 36 ) or connectable, and the fluid recycling device ( 38 ) a fluid delivery device ( 40 ) for discharging at least a portion of the additional fluid from the pressure region ( 18 ). Jet pump ( 10 ) according to claim 1, characterized in that the fluid introduction device ( 36 ) in the flow direction of the intake fluid before an exit ( 25 ) of the motive nozzle ( 24 ) or approximately at the level of the exit ( 25 ) of the motive nozzle ( 24 ) is arranged. Jet pump ( 10 ) according to one of the preceding claims, characterized in that the additional fluid through the first pump inlet ( 20 ) through the suction area ( 16 ) can be fed. Jet pump ( 10 ) according to one of the preceding claims, characterized in that at least a portion of the additional fluid is formed by driving fluid. Jet pump ( 10 ) according to one of the preceding claims, characterized in that at least a portion of the additional fluid is formed by mixing fluid. Jet pump ( 10 ) according to one of the preceding claims, characterized in that the fluid delivery device ( 40 ) in the flow direction of the additional fluid seen in front of the pump outlet ( 34 ) is arranged. Jet pump ( 10 ) according to one of the preceding claims, characterized in that the jet pump ( 10 ) a mixing nozzle ( 26 ) comprising a convergent nozzle section ( 28 ), a narrowest nozzle section ( 30 ) and a divergent nozzle section ( 32 ), and that the fluid delivery device ( 40 ) at the level of the divergent nozzle section ( 32 ) and / or the narrowest nozzle section ( 30 ) is arranged. Jet pump ( 10 ) according to claim 7, characterized in that the fluid delivery device ( 40 ) in the area of a transition ( 42 ) between the divergent nozzle section ( 32 ) and the narrowest nozzle section ( 30 ) or adjacent thereto. Jet pump ( 10 ) according to one of the preceding claims, characterized in that the fluid delivery device ( 40 ) a separation device ( 52 ) for separating additional fluid from the pressure region ( 18 ). Jet pump ( 10 ) according to one of the preceding claims, characterized in that the fluid delivery device ( 40 ) a fluid collection device ( 60 ) for collecting from the printing area ( 18 ) comprises separable additional fluid. Jet pump ( 10 ) according to one of the preceding claims, characterized by a fluid line ( 44 ) for the fluid-effective connection of the fluid delivery device ( 40 ) with the fluid introduction device ( 36 ). Jet pump ( 10 ) according to one of the preceding claims, characterized by a fluid flow control device ( 64 ) for controlling a fluid flow between the fluid delivery device ( 40 ) and the fluid introduction device ( 36 ). Jet pump ( 10 ) according to one of the preceding claims, characterized by a condensate separator ( 66 ) for the separation of condensate from the additional fluid. Jet pump ( 10 ) according to one of the preceding claims, characterized in that the jet pump ( 10 ) a relative to the direction of gravity vertical pump axis ( 12 ) having. Jet pump ( 10 ) according to one of the preceding claims, characterized in that the fluid introduction device ( 36 ) is fluidically connectable with a reservoir for receiving an additional fluid. Jet pump ( 10 ) according to one of the preceding claims, characterized in that the fluid introduction device ( 36 ) with an environment ( 70 ) of the jet pump ( 10 ) is fluideffectively connectable. Jet pump ( 10 ) according to one of the preceding claims, characterized in that at least a portion of the additional fluid is formed by ambient air. Jet pump ( 10 ) according to one of the preceding claims, characterized by at least one pump outlet ( 34 ) downstream mixing fluid conveyor. Jet pump ( 10 ) according to claim 18, characterized in that the mixing fluid delivery device is designed in the form of a jet pump. Jet pump ( 10 ) according to claim 18 or 19, characterized in that the mixing fluid delivery device comprises a mixing fluid delivery device, which fluid-effectively with the fluid introduction device ( 36 ) is connectable. Method for operating a jet pump using a driving fluid, in which by means of the driving fluid instead of a suction or in addition to the suction fluid, an additional fluid is conveyed and at least a portion of the additional fluid is taken from a pressure range of the jet pump and returned to a suction region of the jet pump. A method according to claim 21, characterized in that at least a portion of the additional fluid is formed by driving fluid. A method according to claim 21 or 22, characterized in that at least a portion of the additional fluid is formed by mixed fluid of the suction fluid and the driving fluid. Method according to one of claims 21 to 23, characterized in that at least a portion of the additional fluid is formed by mixed fluid, which is taken from a mixing fluid conveyor, which is connected downstream of a pump outlet of the jet pump. Method according to one of claims 21 to 24, characterized in that a return rate of the additional fluid is controlled in dependence on a delivery rate of the intake fluid. Method according to one of claims 21 to 25, characterized in that at least a portion of the additional fluid is removed from a reservoir for receiving the additional fluid. Method according to one of claims 21 to 26, characterized in that the suction region of the jet pump is fluidly connected to the environment of the jet pump. Method according to one of claims 21 to 27, characterized in that at least a portion of the additional fluid is formed by ambient air. Use of a jet pump according to one of Claims 1 to 20 for carrying out a method according to one of Claims 21 to 28.

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