DE3920901A1 - SCREW PUMP - Google Patents

Abstract

A screw rotor pump (10) with drive spindle (18) arranged in a pump housing (12) and at least one sealed spindle (16), which on the intake side is/are arranged by means of a journal-like end (17) in a bearing recess (44) of a pump section, especially a pump cover (20), is to be improved in that on the internally supported screw rotor pump (10) bearing elements (46) are arranged in order to take up the axial thrust of the sealing spindle(s) (16), on which bearing elements the journal-like spindle end and/or a bearing journal (46) are arranged, which receive the journal-like spindle end and/or a bearing journal (17) and are connected to the pressure chamber (15) of the screw rotor pump. In addition the bearing recess (44) for the bearing journal (17) in a bearing bush (46) is proposed as bearing element and this rests in a recess (58a) of the pump cover (20). <IMAGE>

Description

The invention relates to a screw pump with in a pump housing arranged drive spindle and at least one sealing spindle, the suction side by means of a pin-like end in a bearing recess Pump part, in particular a pump cover, arranged is / are.

Such a screw pump with two die Drive spindle flanking sealing or running spindles can for example, be taken from DE-PS 7 16 161; the Bearing recesses for all spindles are there in the Pump cover attached as well as with the interior of the Pump housing connected.

In screw pumps of known design with two or The material to be conveyed becomes more through the spindles and the chambers surrounding the pump housing Rotation of the spindles moves axially. The as a result of Pressure build-up in the opposite direction is in usually through the spindles on the one hand and by means of a Abutment on the other hand added. This bearing has become more lubricating when pumping Proven fluids in the range of low delivery pressures, their Lubricating effect this just as simple as reliable Axial bearing enables.  

The delivery of non-lubricating fluids, in the range of higher Conveying pressures, such as water, bring for one Screw pump complicates with itself as the movement of the spindles with each other and with respect to the housing in the Usually requires a lubricant-effective funding; between the pump parts mentioned only have small gap widths to disposal.

The intervention is possible - for example to promote water of the spindles through outside the pump chamber in contact with the fluid control existing facilities. These Control devices and the inevitable additional shaft seals make construction and operation more expensive of such a machine, quite apart from that from the Efficiency principle due to lower efficiency in Range of higher delivery pressures.

It is known to promote low viscosity fluids otherwise very suitable centrifugal pumps with smaller and smaller ones specific speeds decrease in efficiency as well as other that at high pressures and low flow rate the Use of displacement machines is indicated. Especially in Performance range of very small specific speeds the performance and funding characteristics of a internal screw pump desired.

In view of these circumstances, the inventor did it Set the goal of using non-lubricating fluids internal screw pumps for the area very low specific speeds despite - as a result existing functionally large overall sliding surfaces - enable critical zones; belongs to these zones primarily the storage to accommodate the axial Thrust of the spindles.

To solve this problem that leads to the internal Screw pump for absorbing the axial thrust of the Sealing or running spindle / n bearing bodies are arranged, which the pin-like spindle end or a bearing pin record and in connection with the pressure chamber of the pump stand. It has also proven to be cheap To put bearing journals in a bearing bush and the latter in turn to be stored in a recess in the pump cover.

According to another feature of the invention, the free Face of the bearing bush with the bottom of the recess of the Pump cover one with the interior of the Screw pump connected tight gap, the preferably via a radial line to an extension of the Interior is connected.  

According to the invention surrounds the profile outlet of the sealing spindle a compensating sleeve with its pressure-side end one shoulder of the spindle. This compensating rifle forms a control edge with its suction end, which preferably a shell seated in the bearing bush low-wear material. Because this bowl is longer than the end of the Bearing pin, so the width of one between the End face of the trunnion and the bottom of the Bearing recess desired - connected to the pressure chamber - Forehead gap can be determined.

The front gaps of the trunnions should advantageously by means of at least one each the bearing bush enforcing line connected to a cross line be. It has proven to be cheap from the bottom of the Bearing bushing to bore a hole on one sleeve penetrating that gap as part of the line connects.

Thanks to the measures described, the pressure supply is in sealed the bearing bushes, but the bearing bushes themselves are radially movable.

According to the invention, it is usually possible for screw pumps designed for lubricating fluids a functionally crucial body - in particular the hydrostatic axial thrust compensation, for example at Water pumping - safe to control.  

The specific arrangement of cylindrical ones serves this purpose Bearing body or bushings, in which the spindles up to immerse in a radial stop. The bearing body or -tins have an axial opening that defines the storage space - in which the spindle pin is immersed - with the Pressure chamber of the pump connects. The connection of the pressure-bearing connection of the bearing sleeve is designed that the fluid pressure only on the cross section of the Spindle pin is effective. So it can be through a minimal axial movement across the gap between the spindle and axial collar a balance between axial thrust and level off with hydraulic relief. The introduction of the Pump pressure to compensate for the axial thrust is like this designed that the pressure on only for the can concentrate the purpose described above.

So that all this is guaranteed, the bearing sleeve should move radially freely, d. H. adhere to the radial movement of the Can continuously adjust the spindle. According to the invention a non-positive rotation inhibition in the form of a elastic ring element ensures that the Bearing sleeve does not turn, otherwise the necessary Sealing between the bearing body and the pressure bearing Connection or line would not exist.

Of importance for the temperature conditions in the Screw pump according to the invention is that the line or the cross line to an annulus between Pump housing and one to the inner surface at a distance arranged tubular housing insert is connected; this annulus is on the suction side against the interior sealed and with radial openings on the pressure side Mistake.  

It has proven to be advantageous at the suction end of the Annular space to arrange at least one outlet and one inlet on the outside of the housing insert in the provide radial area of the spindle bearing; the fluid will i. w. over the entire effective spindle length and such a temperature equalization on the spindle package created prevents a temperature difference.

Further advantages, features and details of the invention result from the following description of a preferred embodiment and based on the Drawing; this shows in

Figure 1 shows the longitudinal section through an inventive screw pump.

Fig. 2 shows a longitudinal section at right angles to Fig. 1.

A screw pump 10 has in the interior 12 of a pump housing 14 screwed onto a pump base 11 a drive spindle 18 flanked by two sealing or running spindles 16 . The sealing or running spindles 16 are mounted on the suction side in a pump cover 20 , the drive spindle 18 is connected on the drive side to a coaxial drive shaft journal 22 .

The drive shaft journal 22 passes through roller bearings 28 arranged in a bearing cover 24 - between a labyrinth ring 25 and a support disk 26 with a downstream lubrication chamber 27 . That bearing cover 24 is screwed by means of cylinder screws 29 and with the interposition of a mechanical seal 30, 34 to a drive-side pump cover 31 , the mechanical seal 30, 34 being located in a seal space 32 . In addition, a compensating piston 36 surrounded by low-wear shells 35 and provided with roller grooves can be seen on a flange 38 . This rests partly in the pump cover 31 and partly in the pump housing 14 , the length a of which is approximately 270 mm.

A compensating bush is respectively shrunk 40 of length n on the suction side bearing pin 17 of the two drive spindles 16 which abuts against a shoulder-like shoulder 42 of the drive spindle sixteenth This compensating bushing 40 faces with its suction-side end a bearing recess 44 of a bearing body or a bearing bush 46 and forms a control edge there for regulating the hydrostatic pressure. The control edge here lies opposite the edge of a shell 41 seated in the bearing recess 44 and made of particularly wear-resistant material.

The length t of the shell 41 is greater than the free length of the bearing pin 17 and thus determines the width of an end gap 48 remaining between the suction-side end face 17 _{s of} the bearing pin 17 and the bottom 45 of the bearing recess 44 . An axial inlet bore 50 of the bearing bush 46; this inlet bore 50 is connected to a channel 54 of the suction-side pump cover 20 by means of a sleeve 53 , which has an axial bore 52 ; the channels 54 of the spindle bearings are connected to one another by a blind bore 56 provided radially in the pump cover 20 .

In particular, FIG. 1 shows that said sleeve 53 bridges a gap space 58 of the 46 one hand, between the suction-side end of the bearing bush and the bottom of _a pump cover 20 is formed 60 of a blind recess 58 receiving the same. This gap space 58 is connected via radial bores 59 to a cylindrical extension 13 of the interior 12 of the pump housing 14 .

Near the gap 58 , an O-ring 62 can be seen as a sealant in the periphery of the bearing bush 46 - other O-rings respectively provided in ring grooves are also designated by 62 .

The pump housing 14 is designed such that a tubular housing insert 64 of length b of, for example, 190 mm surrounding the spindles 16, 18 lies on both ends on housing ribs 66, 66 _{s in} such a way that an annular space 15 is formed between the housing insert 64 and the pump housing 14 suction-side housing rib 66 _s is sealed to the interior 12 by means of an O-ring 62 and has passages 68 in the area of the other housing rib 66 . Moreover, the housing insert 64 with its pressure-side edge 64 _d 38 held clamped between the housing rib 66 and the flange.

Material inserts 70 made of wear-resistant - preferably ceramic - material are provided between the housing insert 64 and the spindles 16, 18 . The material inserts 70 are in themselves disk-like and are provided with receiving bores (not shown for reasons of clarity) for the spindles 16, 18 passing through them. Several of these material inserts 70 are arranged coaxially in the pump housing 14 .

The material inserts 70 are fixed by means of a plastic layer indicated at 71 , which is introduced through bores 72 between the housing insert 64 and the material insert 70 .

The described annular space 15 is - as can be seen in FIG. 1 - connected to the blind bore 56 of the pump cover 20 by means of an axially parallel longitudinal bore 74 in the pump housing 14 .

In particular, FIG. 2 shows the suction space inlet 76 and - at the deepest of the annular space 15 - the outlet 78 ; that is between the housing insert 64 so that the fluid between the suction chamber inlet 76 and the outlet 78 is forced to flow through the passage 68 of the housing insert 64 into the annular space 15 and over almost the entire length b of the housing insert 64 to the outlet 78 .

Claims (16)

1. Screw pump with a drive spindle arranged in a pump housing and at least one sealing spindle which is / are arranged on the suction side by means of a pin-like end in a bearing recess of a pump part, in particular a pump cover, characterized in that on the internally mounted screw pump ( 10 ) for receiving the axial thrust the sealing spindle (s) ( 16 ) bearing body ( 46 ) are arranged, which receive the pin-like spindle end or a bearing pin ( 17 ) and are connected to the pressure chamber ( 15 ) of the screw pump. 2. Screw pump according to claim 1, characterized in that the bearing recess ( 44 ) for the bearing journal ( 17 ) in a bearing bush ( 46 ) is provided as a bearing body and this / r rests in a recess ( 58 _a ) of the pump cover ( 20 ). 3. Screw pump according to claim 1 or 2, characterized in that the free end face of the bearing body ( 46 ) or the bearing bush ( 46 ) with the interior ( 12 ) of the screw pump ( 10 ) is connected. 4. Screw pump according to one of claims 1 to 3, characterized in that the free end face ( 17 _s ) of the bearing bush ( 46 ) with the bottom ( 60 ) of the recess ( 58 _a ) of the pump cover ( 20 ) has a tight gap ( 58 ) limited, which is connected to the interior ( 12 ) of the screw pump ( 10 ). 5. Screw pump according to claim 3 or 4, characterized by at least one gap ( 58 ) with an extension ( 13 ) of the interior ( 12 ) connecting bore ( 59 ). 6. Screw pump according to one of claims 1 to 5, characterized in that the bearing pin ( 17 ) surrounds a compensating sleeve ( 40 ) which strikes with its pressure side end on a shoulder ( 42 ) of the spindle ( 16 ). 7. Screw pump according to at least one of claims 1 to 6, characterized in that the compensating sleeve ( 40 ) forms a control edge on the suction side. 8. Screw pump according to claim 7, characterized in that the control edge of the compensating sleeve ( 40 ) of the pressure-side edge of a seat in the bearing bush ( 46 ) seated shell ( 40 _a ) made of low-wear material or the bearing bush is opposite. 9. Screw pump according to at least one of claims 1 to 8, characterized in that an end gap ( 48 ) provided between the end face of the bearing journal ( 17 ) and the bottom ( 45 ) of the bearing recess ( 44 ) is connected to the pressure chamber ( 15 ). 10. Screw pump according to claim 9, characterized in that the end gaps ( 48 ) of the bearing journal ( 17 ) are connected to a transverse line ( 56 ) by means of at least one line ( 54 ) passing through the bearing bush ( 46 ). 11. Screw pump according to at least one of claims 1 to 10, characterized in that the pressure supply to the bearing bush ( 46 ) is sealed. 12. Screw pump according to at least one of claims 1 to 11, characterized in that from the bottom ( 60 ) of the bearing bush ( 46 ) a bore ( 50 ) extends to a gap ( 58 ) penetrating sleeve ( 53 ) as part of the Line ( 54 ) connects. 13. Screw pump according to at least one of claims 1 to 12, characterized in that the bearing bush ( 46 ) is arranged to be radially movable. 14. Screw pump according to at least one of claims 1 to 13, characterized in that the line ( 54 ) or the transverse line ( 56 ) to an annular space ( 15 ) between the pump housing ( 14 ) with a tubular housing insert ( 64 ) is connected, the annular space being sealed on the suction side against the interior ( 12 ) and provided on the pressure side with radial openings ( 68 ). 15. Screw pump according to claim 14, characterized in that at least one outlet ( 78 ) is provided at the suction end of the annular space ( 15 ). 16. Screw pump according to at least one of claims 1 to 15, characterized in that an inlet inlet ( 76 ) outside the housing insert ( 64 ) is arranged in the radial region of the spindle bearing.