DE102008056855A1 - Degassing device for liquid-filled rooms with rotating components - Google Patents

Abstract

The present invention relates to a degassing device which is composed of a housing with a chamber with a rotating component arranged therein, in particular a shaft, a bearing arrangement and/or a shaft seal. At least one rib, which extends with a free rib end up to the rotating component so as to form an axially parallel gap, is attached in the chamber. Positioned downstream of the gap is a degassing chamber for a liquid. A jet splitter wall surface (18) for splitting up a gap jet (17) is arranged in the chamber (2) at a distance from an acceleration gap (14) and opposite the acceleration gap (14). At a lateral distance from a gap projection (B) onto the jet splitter wall surface (18), said jet splitter wall surface (18) is provided with one or more connecting openings (15) to the degassing chamber.

Description

The The invention relates to a degassing device, consisting of a Housing with a space with a rotating component disposed therein, in particular a shaft, a bearing and / or a shaft seal, wherein in the room at least one with a free rib end below Forming an axis-parallel gap to the rotating component approaching Rib is attached, and that the gap is a degassing space for a liquid is arranged downstream.

By the EP 0 327 549 B1 is known for a centrifugal pump for conveying hot liquids with at least one shaft passage through a pump housing a degassing device for a pump shaft with mechanical seal. For this purpose, the mechanical seal is surrounded by a spaced within the space with concentric annular wall with outwardly and inwardly projecting radial ribs. The separated from the annular wall spaces are interconnected by holes. With this degassing a calming of the liquid circulation in distance from the mechanical seal should be done. This separated gases collects a large-volume, flow-calm and ventable receiving space, which is provided with means for removing accumulated gas. Such a solution requires a lot of space and is expensive to produce.

Another degassing device for a pump shaft is from the DE 198 34 012 C2 known. In this centrifugal pump with conveyed in a sealing space liquid for a therein provided mechanical seal of a pump shaft, the seal chamber provides two longitudinally approximately parallel to the pump shaft extending, blade-like and different length patches before. The blade-like surface pieces are arranged on the peripheral wall of the sealing space on both sides of a vent opening and attached to an end wall and preferably inclined at an angle of about 80 ° to each other. They form between them and the peripheral wall in an approximately triangular cross-section antechamber. At the location of the converging free ends of the patches these form between them a pump shaft approximately parallel intake nip for the vestibule. Through this gap, liquid flows radially into the vestibule, where it remains calm. The separated gas is removed via the vent.

The previously known, provided with sedatives degassing are reliant on a horizontal wave arrangement to in each case upper part of the seal spaces a vent for a gas.

Of the Invention is based on the problem for by gas-containing or outgassing liquids endangered shaft lead-through spaces a reliably acting in different mounting positions and easy to develop degassing.

The Solution to this problem looks for a degassing device that in the room in the direction of rotation of the rotating part and with Distance to the gap and the gap opposite a beam splitter wall surface is arranged and that at a lateral distance to a slit projection on the beam splitter wall surface these with one or more Connection openings is provided to the degassing. by virtue of the one or more parts rotating in space becomes one Fluid is set in rotation and flows through the gap cross section through. As a result forms accordingly the gap length and shape of a slit beam, the approximate tangent to the rotating part emerges from the gap. The slit beam meets the gap that is opposite the gap Beam splitter wall surface, in particular in the direction of a Normal, and it will be primarily in two on impact Directions dissipating partial flows decomposed. In Flow direction behind the rib forming the gap There is a vacuum chamber in which a vacuum zone is formed. Therein, at least one vortex roll forms, which is separated from the partial flow of the Slit beam is excited. This vacuum zone accelerates in previously unknown method a degassing in a liquid.

To Embodiments, the rib extends as a rotation axis-near housing rib forming an acceleration gap close to the rotating one Component zoom. Depending on its rotational speed and the gap width becomes a liquid passing therethrough accelerated and as a directed beam within the space formed liquid. As a result, the beam splitter wall surface arranged at an angle to the gap beam emerging from the gap is, depending on one opposite The beam angle selected angle of inclination beam splitting and influenced by a whirling roll produced thereby. The slit beam is mostly normal on the beam splitter wall surface. A selected tilt of the beam splitter wall surface is on the order of an acute angle opposite to the normal of the slit beam. Whose magnitude can in the range up to 25 °.

The beam splitter wall surface is formed as part of a rotation axis-far housing wall or housing rib. In particular, the use of a housing rib facilitates the formation of the housing as a cast construction. Costly welding or assembly work is thus eliminated. The Beam splitter wall surface is considered as a passant with respect to the rotating member and viewed in cross-section or is formed as such. Their arrangement is chosen so that it does not even cut the rotating components. If the beam splitter surface has an inclination or a curved shape, then an extension of this surface can intersect the rotating components. In a spatial view of this degassing the gap limiting rotary axis-near housing rib and the beam splitter wall surface are arranged within a spatial housing quadrant of the room.

To other embodiments have the free ends of the housing ribs an opposite extension direction. In the space between the Casing rib and the beam splitter wall surface as well on the side of the jet that is far from the axis of rotation, there is a vacuum chamber educated. In this vacuum space forms one of the beam splitter wall surface outgoing part of a jet vortex roll, which within the Vacuum space a defined vacuum zone exists. Thereby a very fast degassing of the liquid is achieved. In complete contrast to the previously known solutions is a rotation in the room with the rotating internals not prevented but specifically to the formation of an accelerated slit beam used and thus an additional vortex roll for Degassing generated.

Farther The vacuum space extends in the direction away from the rotating Component. This spacing supports a degassing process. And the rotation axis remote housing wall or housing rib with the beam splitter wall surface can be a wall of the Form degassing space, if this as an integral part the degassing device is formed. In terms of the axis of rotation is the vacuum space between the axis close to the axis of rotation and the rotational axis-distant degassing space arranged.

To Further embodiments of the degassing space with a vent Mistake. For use with shafts with double seals are two or more degassing devices in the axial direction one behind the other arranged and each degassing space is provided with a vent. If in such a training only a shaft seal application finds, is between two degassing spaces a partition arranged and in the T-shaped connection area between partition and outer wall can become the vent are located. Due to their position in the crossing area between housing wall and dividing wall as well as over the dividing wall is made with just one machining operation made a connection between two rooms. With only A degassing opening can therefore consist of two rooms at the same time a gas accumulation are removed.

Around a safe degassing in both a horizontal, a vertical or to achieve a diagonal arrangement of the rotating parts, is at an axial end of a degassing one at an angle Arranged to the axis of rotation degassing. Furthermore, the degassing can be integral or separate part of the Be housing.

The Effect of degassing support further embodiments, according to which the space surrounding the rotating parts, in particular its peripheral wall surface, wholly or partially has a spiral formation. Thus, within a spiral space thus formed, a conversion of the velocity energy of the rotating liquid in pressure energy, which then at the acceleration gap on the slit beam interacts and reinforces it. In addition increased the pressure difference between the room or the trained therein Spiral space and the vacuum space, causing the degassing process accelerated in the vacuum chamber. This is the rotationsachsen-near housing rib in the spirally developed space in the area of the spatial Housing quadrants arranged in relation to the axis of rotation having the largest radial extent.

ever after the desired degassing time and inclination of the beam splitter wall surface opposite to the incident slit beam, are flowing therefrom partial streams to judge as a type of main and side stream. As the main stream Here is the gas-loaded, with the component rotating and around it around forming partial flow called. As a side stream is the from the beam splitter wall surface in the vacuum space overflowing Partial flow referred, which there used the degassing used for degassing generated. This vortex roll has a direction of rotation opposite to the rotating liquid ring in space. These held at the place of vacuum chamber vortex roller causes in no time Time an outgassing of the entire located in the degassing Liquid.

For this purpose, according to a further embodiment, the beam splitter wall surface and / or its arranged in the direction of the connection opening extension on a negative pressure space defining beam-dividing inner wall and along the beam dividing inner wall flows a partial flow of a rotating in the vacuum space vortex roll in the degassing. This partial stream originates from the gas-enriched multi-phase mixture flow rotating in the swirling roll. Their gas components flow from the vacuum chamber via one or more connecting openings in the degassing space over and are accumulated removable there. Due to the formation of a vacuum chamber with a whirl roll held therein, this solution is reliable in any shaft arrangement.

Further Embodiments of the invention are in the subclaims described.

embodiments The invention is illustrated in the figures and will be described in more detail below described. It show the

1 a longitudinal section through the degassing of a centrifugal pump,

2 & 3 Cross sections through the gap zone of the degassing, the

4 a degassing device for a horizontal, diagonal or vertical shaft arrangement and the

5 & 6 a degassing device for shaft seals in tandem or single arrangement.

In 1 a degassing device is shown using the example of a drive shaft for a centrifugal pump. The degassing device is in a housing 1 arranged and has a room 2 with a rotating component disposed therein 3 on. This is a wave 3.1 and a shaft seal mounted thereon 3.2 formed as part of a mechanical seal. In the sectional view, one is above the shaft 3.1 more attached, from the room 2 by an element explained below 26 delimited degassing room 4 recognizable. The in camps 5 held wave 3.1 Penetrates a pump cover 6 and carries an impeller 7 a centrifugal pump 8th , In Krei selpumpe befindliches fluid flows along the shaft 3.1 in the room 2 the degassing device.

There would be no degassing and would be in the room 2 or a gas within the liquid, the gas would be due to the differences in density and under the influence of centrifugal forces directly on the rotating component 3 accumulate. In contrast, the liquid rotates as a liquid ring on a larger diameter around the gas ring around. As a result, the liquid can no longer cool the shaft seal, causing it to be damaged by overheating or failing. For these reasons, a gas must be deposited and the room 2 be completely filled with liquid.

By means of the degassing device separated gases are in the degassing 4 accumulated and therefrom by a closure element 9 away. This can be done automatically or manually.

The 2 is a section along the line AA of 1 and shows a cross section through the degassing device. In terms of the axis of rotation 10 are inside the room 2 subdividing wall surfaces arranged, with their help for a gas auszuschcheidendes a kind of meandering flow path to storage in the degassing 4 is achieved. From the room 2 in which the rotating components 3 are arranged, there is a transition into a vacuum chamber 11 and a degassing space associated therewith 4 , Pressurized space 11 and degassing room 4 are indicated by dashed lines.

The rotation axis 10 of the rotating component 3 lies at the intersection of two orthogonal x and y planes. These limit four spatial quadrants I, II, III and IV. In the area of the I. spatial quadrant are the vacuum space 11 and its boundaries arranged. Likewise, there is a rotation axis near rib 12 that with a free rib end 13 an acceleration gap 14 to the rotating component 3 limited. The direction of rotation of the rotating component 3 is by a double arrow on the cut shaft 3.1 shown on which a shaft seal part 3.2 is mounted and rotates with it. Here above the rotation axis-near rib 12 and in the flow direction behind it is the vacuum space 11 , He stands over one or more connecting openings 15 with one of the axis of rotation 10 spatially further away arranged degassing 4 in connection. The connection opening 15 can - as shown - be slit-shaped or as a perforated wall surface. This depends on the forces of the housing to be transmitted 1 , The degassing room 4 can also be designed as an independent component and directly or as a separate element with the room 2 or with the housing 1 be connected. A connection between the degassing space 4 and one or more connection openings 15 can be done with the aid of additional known connecting means.

The 3 equals to 2 and shows with the help of stream files the course of the currents within the housing 1 , The rotating components 3 cause a drag effect on those in the room 2 located liquid. The space 2 can be described as an annular space with the same radius R or, as shown, with a spiral inner contour 16 be provided. Starting from the 4th quadrant, for example from the location of the radius R, the spiral contour develops 16 in the direction of rotation of the rotating component 3 outwards to the spatial I. quadrants arrange th axis close to the axis of rotation 12 , This is here as part of the cast housing 1 educated. It can also be designed as a separate component.

The contour of the room 2 is formed in analogy to a spiral housing of a centrifugal pump. Due to the increasing in the circumferential direction cross-sectional area increases during operation, the static pressure in space 2 easy on and reaches a pronounced maximum pressure in the area of the largest area cross-section at the stagnation point on the pressure side of the near-axis rib 12 , By the subsequent acceleration of the fluid in the acceleration gap 14 becomes the vacuum space 11 imprinted a slight static negative pressure. The static pressure difference between space 2 and vacuum space 11 causes a vacuum in the room 11 rotating secondary vortex enriches with gas. In the vacuum room 11 turns the flow against the direction of movement in space 2 ,

The distance between the free end 13 the rib 12 and the opposite rotating component 3 defines the width of the acceleration gap 14 through which in the room 2 must flow through rotating fluid. As a result, forms in and after the acceleration gap 14 a slit beam 17 out in the tangential direction of the rotating components 3 flows away. He is on a beam splitter wall surface 18 directed and is disassembled on impact. This beam splitting takes place in the area of an in 3 projection B of the acceleration gap represented by ≡ 14 on the beam splitter wall surface 18 , On the one hand in a secondary or secondary flow, which is a vortex roll 19 in the vacuum chamber 11 forms. And second, in a main stream, in the direction of rotation of the rotating component 3 back to the room 2 flows and continues to rotate there.

By the acceleration of the liquid in the acceleration gap 14 forms behind the gap in the vacuum chamber 11 the negative pressure zone, in which an extremely intense enrichment of the gaseous components takes place. A gas enriched multiphase flow exits the vacuum space 11 through the connection opening 15 in the degassing room 4 above. There is the complete outgassing, the removable accumulation of gases and, if necessary, the excretion of gases. The degassing room 4 can also be designed as a separate component and via lines with one or more connection openings 15 be connected.

This is the flow in the vacuum chamber 11 Guided so that they follow the course of the beam splitter wall surface 18 follows and in the area of the connection opening 15 adjacent and also beam dividing inner wall 18.1 of the housing 1 rebounds. This beam dividing inner wall 18.1 simultaneously limits the vacuum space 11 and causes a flow split from the swirl roll 19 , As a result of that in the vacuum chamber 11 rotating, gas-enriched multi-phase mixture a smaller partial flow 28 through the connection opening 15 and along the inner wall 18.1 in the degassing room 4 diverted. This gas-enriched substream 28 degas there. A gas-free return flow flows along the back 29 from the beam splitter wall surface 18 and over the vacuum chamber 11 back to the room 2 , This Rückströmumg he also follows through the connection opening 15 and this return flow becomes part of the main flow again.

In the 3 runs the beam splitter wall surface 18 opposite to the splitting beam impinging thereon 17 at a slight angle of inclination α. This angle of inclination deviates from the normal to the slit beam 17 by about 10 degrees and can be up to 25 degrees. It opens, starting from a limiting edge of the connection opening 15 , in the direction of the spatial IV. quadrant. Thus, a balanced ratio of flow distribution for in the main stream within the room 2 rotating liquid ring 20 and in addition to the bypass in the negative pressure zone 11 rotating vortex roll 19 created.

The angle of inclination α depends on the application-finding liquid and its gas content and the rotational speed of the rotating parts 3 , In a beam splitter wall surface 18 perpendicular to the slit beam 17 stands, the ratio of liquid amount in the main and secondary flow is approximately equal. The beam splitter wall surface 18 may be flat and / or curved, thus forming the vortex roll 19 to influence within the vacuum space. This depends on the selected size and an application manufacturing process.

The degassing function also takes place in a concentric with the axis of rotation and arranged space 2 in the form of an annular space with a radius R, but accelerates a spiral formation of the peripheral contour of the room 2 the degassing process to a considerable extent.

The limit for the vacuum chamber 11 is also representable as a kind of separated wall surface of the degassing. It will be at the connection opening 15 adjacent and the beam splitter wall surface 18 carrying wall as a rotation axis-distant rib 26 considered. Thus, in space 2 two case ribs 12 . 26 arranged with opposite direction of extent, the vacuum space between them 11 ausbil the. The ribs are spaced apart in the opposite direction. Geometric extensions of these ribs 12 . 26 in the direction of their free rib ends have no intersection.

The 4 shows in analogy to the representation in 1 a section through a vertically arranged degassing. To ensure a safe function even with such installation positions, is a vent 21 in that end region or corner region of the degassing space 4 attached, which is aligned at a later assembly of the degassing upwards. Such a vent 21 can be used for horizontal, diagonal or vertical waves 3.1 to be used.

In the embodiment, two possible arrangements are shown for this purpose. The up here arranged degassing 21 is arranged on a diagonal plane to the axis of rotation. This is done by attaching the vent in an angle to the axis of rotation inclined plane. Thus, both in horizontal and vertical arrangement of the shaft through the opening of the sealing plug degassing take place.

In a reverse arrangement with downwardly facing shaft 3.1 the lower degassing opening would be used in the embodiment shown. Their radial arrangement in the end region of the degassing space 4 possibly has the advantage of easier production. For a different installation length of the shaft 3.1 would be the degassing room 4 at each axial end with a vent 21 and a closure element 9 fitted.

5 shows for a wave 3.1 with a double-seal also a double-formed degassing. The design of their housing ribs and the arrangements of the vacuum zones were carried out analogously to the representations of 2 and 3 , The difference is that two degassing in the axial direction are arranged one behind the other and consequently the degassing 4 through a partition 22 are delimited against each other. Every degassing room 4 is with vent 21 and sealing plugs 9 Mistake. The room is in the area of the partition wall level 23 through an insert 24 in two rooms 2.1 and 2.2 , divided. This can be done with a uniform housing blank by simple machining. For the - not visible here - rotation axis-near rib 12 of the room 2.2 this requires a radial shortening to the insert 24 from the room 2.1 to mount. With the help of a simple extension of the rib, the necessary gap width can be adjusted.

In the shaft seals used here in the form of mechanical seals, the stationary housing ring is in use 24 held. The shaft seal closest to the drive side has a housing-fixed sealing ring in one insert 25 is held with a leakage discharge opening.

6 shows an embodiment of the degassing, in which the same housing of 5 equipped with only a single-acting shaft seal. As a result, it will work on the partition 22 in the area of the liquid-carrying space 2 waived. The two degassing rooms 4 be using one in the partition wall level 23 attached hole 26 connected and thus to a large common degassing 4 converted. About this by a closure element 9 controllable drilling 26 the gas can be removed.

One The main advantage of this solution is that It can be easily manufactured as a casting and a Machining only in the area of the housing openings necessary for bearing caps, connections or degassing holes is. In addition, a single shaft design for two various embodiments find use.

1

casing

2, 2.1, 2.2

room

3

rotating component

3.1

wave

3.2

shaft seal

4

degassing

5

camp

6

pump cover

7

Wheel

8th

rotary pump

9

closure element

10

axis of rotation

11

Pressurized space

12

rotationally Saxony-close rib

13

free rib end

14

accelerating gap

15

connecting opening

16

spiral inner contour

17

slit beam

18 18.1

Beam splitter wall surface

19

eddy roll

20

liquid ring

21

vent

22

partition wall

23

partition level

24

commitment

25

commitment with leakage removal

26

rotation axis distant rib

27

drilling

28

partial flow

29

back

α

tilt angle

B

projection of the axis-parallel gap

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 0327549 B1 [0002]
• - DE 19834012 C2 [0003]

Claims (20)

Degassing device, consisting of a housing with a space with a rotating component arranged therein, in particular a shaft, a bearing and / or a shaft seal, wherein in the space at least one with a free rib end to form an axis-parallel gap to the rotating component zoom reaching rib is attached , and that the gap is followed by a degassing space for a liquid, characterized in that in space ( 2 ) at a distance from the gap and the gap opposite a beam splitter wall surface ( 18 ) for splitting a gap beam ( 17 ) and that in a lateral distance to a gap projection (B) on the beam splitter wall surface ( 18 ) with one or more connecting openings ( 15 ) is provided to the degassing space. Degassing device according to claim 1, characterized in that the rib ( 12 ) as a rotation axis near housing rib to form an acceleration gap ( 14 ) close to the rotating component ( 3 ). Degassing device according to claim 1 or 2, characterized in that the beam splitter wall surface ( 18 ) at an angle (α), in particular in the direction of a normal, to one from the acceleration gap ( 14 ) leaving gap beam ( 17 ) is arranged. Degassing device according to claim 3, characterized in that a selected inclination of the beam splitter wall surface on the order of an acute angle (α) relative to the normal of the slit beam ( 17 ) lies. Degassing device according to claim 1, 2, 3 or 4, characterized in that the beam splitter wall surface ( 18 ) as part of a rotational axis-far housing wall or housing rib ( 26 ) is trained. Degassing device according to one of claims 1-5, characterized in that the beam splitter wall surface ( 18 ) with respect to the rotating component ( 3 ) and viewed in cross-section as a passante is formed. Degassing device according to one of claims 1-6, characterized in that the acceleration gap ( 14 ) limiting rotary axis-close housing rib ( 12 ) and the beam splitter wall surface ( 18 ) within a spatial housing quadrant (I.) of the space ( 2 ) are arranged. Degassing device according to one of claims 1-7, characterized in that free ends of the housing ribs ( 12 . 26 ) have an opposite extension direction. Degassing device according to one of claims 1-8, characterized in that in space ( 2 ) between the housing rib ( 12 ) and the beam splitter wall surface ( 18 ) as well as on the rotation axis-far side of the slit jet ( 17 ) a vacuum chamber ( 11 ) is formed. Degassing device according to claim 9, characterized in that the vacuum chamber ( 11 ) of the rotating component ( 3 ) extends away. Degassing device according to one of claims 1-10, characterized in that the rotation axis-distant beam splitter wall surface ( 18 ) or the housing wall or housing rib provided therewith ( 26 ) a wall of the degassing space ( 4 ). Degassing device according to one or more of claims 1-11, characterized in that with respect to the axis of rotation ( 10 ) the vacuum chamber ( 11 ) between the axis close to the axis of rotation ( 12 ) and the rotational axis-distant degassing space ( 4 ) is arranged. Degassing device according to one or more of claims 1-12, characterized in that the beam splitter wall surface ( 18 ) and / or in the direction of the connection opening ( 15 ) arranged extension on a vacuum space ( 11 ) limiting beam splitting inner wall ( 18.1 ) and that along the beam splitting inner wall ( 18.1 ) a partial flow ( 28 ) one in the vacuum chamber ( 11 ) rotating swirling roller ( 19 ) in the degassing space ( 4 ) flows. Degassing device according to one or more of claims 1-13, characterized in that the degassing space ( 4 ) with a degassing opening ( 21 ) is provided. Degassing device according to one or more of claims 1-14, characterized in that two or more degassing means are arranged in the axial direction one behind the other and each degassing space ( 4 ) with a degassing opening ( 21 ) is provided. Degassing device according to claim 15, characterized in that between two degassing spaces ( 4.1 . 4.2 ) a partition wall ( 22 ) is arranged and in the T-shaped connection region between the partition ( 22 ) and outer wall of a degassing opening ( 21 ) is arranged. Degassing device after one or several of claims 1-16, characterized in that at an axial end region of a degassing space ( 4 . 4.1 . 4.2 ) one at an angle to the axis of rotation ( 10 ) extending degassing opening ( 21 ) is arranged. Degassing device according to one or more of claims 1-17, characterized in that the degassing space ( 4 . 4.1 . 4.2 ) integral or separate component of the housing ( 1 ). Degassing device according to one or more of claims 1-18, characterized in that the rotating components ( 3 ) surrounding space ( 2 ), in particular its peripheral wall surface, wholly or partially a spiral contour ( 16 ) having. Degassing device according to claim 19, characterized in that the axis close to the axis of rotation ( 12 ) in the spirally developed space of the inner contour ( 16 ) is arranged in the region of the spatial housing quadrant (I.), which with respect to the axis of rotation ( 10 ) has the largest radial extent.