Title of Invention

AN IMPROVED DEVICE FOR SEPARATING AN INTERIOR OF A SCREW PUMP AND A SCREW PUMP

Abstract The invention relates to a fluid-conveying machine, in particular, a pump having a component (7) rotating in a stationary housing part (16) inside an annular gap (17). The stationary housing part (16) separates an interior having a higher product pressure from an exterior having a lower pressure. A rotating component is mounted in an external bearing (13) which is sealed with respect to the interior via a sealing device. In order to improve the sealing, the invention provides that the annular gap (17) is formed between two sliding bearing shells (19) which comprise extremely hard, wear-resistant materials and, in accordance with the operating principle of a radial sliding bearing, form a first pressure-reducing stage (17, 19). A feedback means (21) which feeds back the leakage from this first sealing (17,19) into the conveying process of the machine, is connected downstream of the first pressure-reducing stage, A second sealing stage (22) is arranged axially downstream of the feedback means (21). The second sealing stage (22) may be constructed as a simple seal, such as a lip seal and/or a simple end face seal.
Full Text Background of the Invention
Field of the Invention
The invention relates to a fluid-conveying machine, particularly, a pump, having a component rotating in a stationary housing part inside an annular gap, the stationary housing part separating an interior having a higher product pressure from an exterior having a lower pressure, and in which the rotating component is mounted in an external bearing which is sealed with respect to the interior via a sealing system.
Description of Related Art
A related device is disclosed in DE 43 16 735 C2, which discloses a screw pump having at least one conveyor screw which is surrounded by a housing which has at least one suction connection and at least one pressure connection, the suction connection being connected to a suction chamber connected upstream of the conveyor screw, and the pressure connection being connected to a pressure chamber arranged downstream of the conveyor screw . The housing also has devices for separating the respective liquid phase from the gas phase of the liquid flow emerging from the conveyor screw, and a lower section for holding at least a portion of the separated liquid phase. A liquid short-circuiting line is connected to the lower pressure chamber section. The liquid-short circuiting line is also connected to the suction chamber and, together with the conveying elements, forms a closed circuit for a liquid quantity required for the permanent seal.
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Numerous sealing systems have been developed for sealing rotating shafts, but they have proven to be disadvantageous for machines of the aforementioned design. Contactless labyrinth seals are disadvantageous, because of their high rate of leakage resulting from the existence of relatively large gaps, and because no pressure differences can be tolerated at the shaft bushing. Lip seals tolerate only slight pressure differences up to a maximum of 5 bars on the shaft bushing. Soft packings likewise have relatively high rates of leakage, require a high level of outlay and maintenance, and develop a large amount of heat at high rotational speeds. The end face seals used in pumps of advanced design prove to be disadvantageous because of their complex structure and the difficulty of commissioning them.
The difficulties suggested in the preceding are not intended to be exhaustive but rather are among many which tend to reduce the effectiveness and desirability of the known seals. Other noteworthy problems may also exist; however, those presented above should be sufficient to demonstrate that such methods and apparatuses appearing in the past will admit to worthwhile improvement.
Summary of the Invention
Accordingly, it is therefore a general object of the invention to provide a sealing system for the rotating component that will obviate or minimize difficulties of the type previously described.
It is a specific object of the invention to provide a machine of the aforementioned design having an improved sealing system for the rotating component.
It is another object of the invention to provide a sealing system which reduces leakage as compared to those described above.
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It is still another object of the invention to provide a sealing system that is easy to manufacture and is cost-effective.
It is a further object of the invention to provide a sealing system that reduces required maintenance.
It is yet a further object of the invention to provide a sealing system that can withstand pressure differentials.
A preferred embodiment of the invention which is intended to accomplish at least some of the foregoing objects includes a sealing system comprising a first sealing stage having a two sliding bearing shells; and an annular gap formed between the two sliding bearing shells; wherein the two sliding bearing shells comprise a hard, wear-resistant material; and a feedback device located downstream from the first pressure reducing stage; and a second sealing stage located downstream of the feedback device, wherein the feedback device feeds a leakage from the first sealing stage into the pump interior.
Another preferred embodiment is a pump comprising a housing; a shaft rotating in a housing part, which separates an interior of the housing from an exterior of the housing; an external bearing for mounting the shaft; and a sealing system for sealing the external bearing from the interior of the housing, wherein the sealing system includes: two bearing shells mounted in a radial direction of the housing part; an annular gap formed between the two bearing shells; a feedback device connected downstream from the two bearing shells and the annular gap; and a seal located downstream of the feedback device; wherein the bearing shells comprise a hard, wear-resistant material; and wherein the feedback device feeds a leakage from the annular gap to the housing.
Additional objects and advantages of the invention will be set forth in the following description, and in part will be obvious from the description, or may be learned by practice of the invention. The objects and advantages of the
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invention may be realized and obtained by means of the instrumentalities and
combinations particularly pointed out in the appended claims.
accompanying
Brief Description of the/Drawings
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate a presently preferred embodiment of the invention, and, together with the general description given above and the detailed description of the preferred embodiment given below, serve to explain the principles of the invention.
Figure 1 is a prior art longitudinal section through a screw pump;
Figure 2 is, on a scale enlarged by comparison with Figure 1, a sealing system according to the invention in - referred to Figure 1 - the right-hand bearing region of a conveyor screw, and
Figure 3 is the screw pump in accordance with Figure 1 with a pressure-equalizing device according to the invention.
Detailed Description of the Preferred Embodiments
The objects of the invention are achieved, starting from the machine described at the beginning, by providing an annular gap that is formed between two sliding bearing shells, which consist of extremely hard, wear-resistant materials and, in accordance with the operating principle of a radial sliding bearing, form a first pressure-reducing stage. A feedback device, which feeds back the leakage from this first sealing stage into the conveying process of the fluid-flowing machine, is connected axially downstream from the first pressure-reducing stage. A second sealing stage is arranged axially downstream of the feedback device, which is constructed as a simple seal, e.g., a lip seal and/or a simple end face seal.
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A two-stage sealing system is therefore provided. The first stage reduces pressure and employs the operating principle of a radial sliding bearing with build-up of a hydrodynamic oil wedge. The sliding bearing shells may comprise solid industrial ceramic (e.g., aluminum oxide based or zirconium oxide based), solid hard metals (e.g., silicon carbide based or tungsten carbide based), or coated metals (e.g., hard-chrome plated, tungsten carbide coated or chromium oxide coated). The structure of this first sealing stage is advantageous, because an effective hydrodynamic oil wedge builds up from the liquid of the conveyed medium conveyed and any particles penetrating the annular gap are pulverized between the sliding bearing shells due to the extreme hardness and wear resistance of the shells. To correct alignment errors, it is preferable to mount the sliding bearing shells elastically in the radial direction, e.g., the sliding bearing shells may be mounded in O rings.
The feedback of the leakage, which leaks from the first sealing stage, is achieved, e.g., as a result of a suitable pressure gradient between the outlet and inlet sides of the machine (when the seal is arranged on the outlet side) or, e.g., via an external aid such as a pump (when the seal is arranged on the inlet side). In a screw pump of the design described at the beginning, it is particularly advantageous to connect the leakage feedback device to the liquid short-circuiting line.
The second sealing stage minimizes the leakage resulting from the slightest pressure differences to protect the environment or the mechanical elements of the fluid-flowing machine. In this case, the second sealing stage can be constructed as a simple sealing system in the form of a lip seal or an end face seal. Depending on the application required, the second sealing stage may be constructed also as a multipartite system of sealing systems of conventional design, e.g., a lip seal with an end face seal connected downstream or a V ring with a lip seal connected downstream and an end face seal connected downstream from there.
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Referring now to the drawings, wherein like numerals indicate like parts, and initially to Figure 1, there will be seen a previously known (see DE 43 16 735 C2) screw pump having two oppositely rotating pairs of conveyor screws as conveying elements. The two oppositely rotating pairs of conveyor screws intermesh without contact and, in each case, comprise a right-hand conveyor screw 1 and a left-hand conveyor screw 2. Together with the housing 3 surrounding them, the inter-engaging conveyor screws form individually sealed conveying chambers. A gear train 4, which is arranged outside the pump housing, transmits torque from the drive shaft to the driven shaft. The pump housing 3 has a suction connection 5 and a pressure connection 6. The medium 9 flowing to the pump through the suction connection 5 is fed in the pump housing 3 in two partial currents to the respective center suction chamber 10, which is connected upstream of the assigned conveyor screw 1 or 2. A pressure chamber 11 is connected downstream of each of the conveyor screws 1 or 2. The pressure chamber 11 is sealed axially from the outside by a shaft seal 12 which seals an external bearing 13.
A liquid short-circuiting line 14 is connected to the lowest point of the pressure chamber 11. The liquid short-circuiting line is also connected to the suction chamber 10. The partial liquid volumetric flow separated from the conveyed liquid/gas mixture and fed back in a metered fashion into the suction region is marked by the arrow 15 and is conveyed again from the suction chamber 10 into the pressure chamber 11 as a liquid circulation.
Generally, the liquid level in the pump housing 3 or pressure chamber 11 may be maintained at a level that is below the shafts 7, 8. Generally the direct incident flow, which wets the shaft seals 12, is sufficient to lubricate adequately the shaft seals 12.
Figure 2 shows an exemplary embodiment of the invention. The shaft 8 rotates inside a stationary housing part 16. An annular gap is locate inside the

stationary housing part 16. The stationary housing part 16 separates an interior having higher product pressure, which is the pressure chamber 11 of Figure 1, from an external space 18 having a lower pressure. The shaft 8 is mounted in an external bearing 13 in the external space 18.
The external bearing 13 is sealed with respect to the pressure chamber 11, via the following sealing system. The annular gap 17 is formed between two sliding bearing shells 19 which are comprised of extremely hard, wear-resistant materials and are elastically mounted, to correct alignment errors, in the radial direction with the aid of O rings 20. A feedback device 21, which feeds back the leakage that flows through the annular gap 17 from, the first sealing stage into the conveying process of the fluid-flow machine, is connected in the axial direction downstream of the first pressure-reducing stage. The first pressure-reducing stage is formed by the sliding bearing shells 19. A separate pump 23 preferably is provided for the feedback device 21. If the sealing system according to the invention is used in a screw pump as shown in accordance with Figure 1, it is preferable for the leakage feedback device 21 to be connected to the liquid short-circuiting line 14.
A second sealing stage 22 is arranged axially downstream from the feed back device 21. The second sealing stage 22 may be constructed as a simple seal, such as a Up seal.
Figure 3 shows a screw pump in accordance with Figure 1 and having a sealing system (indicated only diagrammatically) according to the invention and in accordance with Figure 2, and an additionally provided pressure-equalizing device 24 according to the invention. The pressure-equalizing device is connected into a line 25, which connects the installation space of the external bearing 13 to the suction chamber 10. The pressure-equalizing device 24 preferably may be a diaphragm a bag-type accumulator. The pressure-equalizing device 24 ensures that the same pressure level exists in the entire installation
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space as in the suction chamber 10. This arrangement is particularly advantageous to minimize pressure differences at the second sealing stage 22 when changing pressures in the suction chamber 10.
Preferably, the thickness of the annular gap 17 formed between the sliding bearing shells 19 is approximately 0.3 to 1.5% of the sliding surface diameter. Also, preferably, the length of the sliding bearing shells 19 is approximately 20 to 60% of the sliding surface diameter.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details, and representative devices, shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
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WE CLAIM:
1. Fluid-conveying machine, in particular pump, having a
component (8) which rotates in a stationary housing part (16)
within an annular gap (17), the stationary housing part (16>
separating an inner compartment (11), which is at a higher
product pressure, from an outer compartment (18), which is at a
lower pressure and in which the rotating component (8) is mounted
in an outer bearing (13) which is sealed with respect to* the
inner compartment (11) by means of a sealing system (17,19,22),
characterized in that the annular gap (17) is formed between two
sliding bearing shells (19), which consists of extremely hard,
wear-resistant materials, and, in accordance with the operating
principle of a radial sliding bearing, form a first pressure
reduction stage, downstream of which, in the axial direction,
there is a return device (21) which returns the leakage from this
first sealing stage into the delivery process of the machine and
downstream of which, in the axial direction, there is a second
sealing stage (22), which is designed as a simple seal in the
form of a lip sealing ring and/or a simple sliding ring seal.
2. Machine as claimed in claim 1, wherein the sliding bearing
shells (19) are mounted elastically in the radial direction in
order to compensate for alignment errors.
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3. Machine as claimed in claim 1 or 2, wherein the gap thickness of the annular gap (17) formed between the sliding bearing shells (19) is approximately 0,3 to 1.5% of the sliding-surface diameter.
4- Machine as claimed in claim 1, 2 or 3, wherein the length of the sliding bearing shells (19) is approximately 20-60% of the sliding surface diameter.
5. Machine as claimed in one of the preceding claims, wherein the second sealing stage (22) is designed as a multiple connection of seals which comprises a V ring, a lip sealing ring and a sliding ring seal.
6. Screw pump having at least one delivery screw (1, 2) which is surrounded by a housing (3) which has at least one suction connection piece (5) and at least one pressure connection piece (6) , the suction connection piece (5) being in communication with a suction compartment (10) connected upstream of the delivery screw (1,2) and the pressure connection piece (6) being in communication with a pressure compartment (11) which is arranged downstream of the delivery screw (1,2) and has devices for separating the respective liquid phase from the gas phase of the flow of medium emerging from the delivery screw (1,2) and a lower section for holding at least a partial quantity of the separated liquid phase, a liquid short-circuit line (14), which is in communication with the suction compartment (10) and, altogether
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with the delivery elements, forms a closed circuit for a quantity
of liquid required for permanent sealing, being connected to this
lower pressure-compartment section, according to one of the
preceding claims characterized in that the return device (21) is
connected to the liquid short-circuit line (14).
7. Machine as claimed in claim 6, wherein a pressure-compensation
device (24) which produces a uniform pressure level, is provided
between the installation compartment for the outer bearing and the suction compartment (10).
8. Machine as claimed in claim 7, wherein the pressure
compensation device (24) is formed by a diaphragm.
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9. Machine as claimed in claim 7, wherein the pressure
compensation device (24) is formed by a bubble store.
10. Machine as claimed in any one of the preceding claims
wherein the return device (21) has a separate pump (23).
The invention relates to a fluid-conveying machine, in particular, a pump having a component (7) rotating in a stationary housing part (16) inside an annular gap (17). The stationary housing part (16) separates an interior having a higher product pressure from an exterior having a lower pressure. A rotating component is mounted in an external bearing (13) which is sealed with respect to the interior via a sealing device. In order to improve the sealing, the invention provides that the annular gap (17) is formed between two sliding bearing shells (19) which comprise extremely hard, wear-resistant materials and, in accordance with the operating principle of a radial sliding bearing, form a first pressure-reducing stage (17, 19). A feedback means (21) which feeds back the leakage from this first sealing (17,19) into the conveying process of the machine, is connected downstream of the first pressure-reducing stage, A second sealing stage (22) is arranged axially downstream of the feedback means (21). The second sealing stage (22) may be constructed as a simple seal, such as a lip seal and/or a simple end face seal.

Documents:

00125-cal-1999-abstract.pdf

00125-cal-1999-claims.pdf

00125-cal-1999-correspondence.pdf

00125-cal-1999-description(complete).pdf

00125-cal-1999-drawings.pdf

00125-cal-1999-form-1.pdf

00125-cal-1999-form-18.pdf

00125-cal-1999-form-2.pdf

00125-cal-1999-form-3.pdf

00125-cal-1999-letters patent.pdf

00125-cal-1999-p.a.pdf

125-CAL-1999-FORM-27.pdf


Patent Number 205829
Indian Patent Application Number 125/CAL/1999
PG Journal Number 15/2007
Publication Date 13-Apr-2007
Grant Date 13-Apr-2007
Date of Filing 17-Feb-1999
Name of Patentee JOH.HEINR.BORNEMANN GMBH
Applicant Address INDUSTRIESTRASSE 2, D-31683 OBERNKIRCHEN,
Inventors:
# Inventor's Name Inventor's Address
1 GERHARD ROHLFING HILFERDINGSEN 15, D-32479 HILLE,
2 JENS-UWE BRANDT LEMGOER STRASSE 59, D-31737 RINTELN,
3 VEJEN HRISTOV WALLSTRASSE 28, D-31675 BUCKEBURG,
PCT International Classification Number F04C 15/00
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 98106690.5 1998-04-11 EUROPEAN UNION