DE1728268A1 - Vane pump or motor - Google Patents

Description

Vo / Fu I6.9.I968

Attachment to

Patent and

Utility model registration

ROBERT BOSCH GMBH, 7 Stuttgart W, Breitscheidstrasse " Vane pump or motor

The invention relates to a vane machine which can be used as a pump or motor and has approximately radial slots the rotor connected to the drive shaft tightly and slidably movable vanes, which separate the individual conveyor cells from each other and the outer edges of which slide on a housing recess, in particular on a cam ring, and with at least one working space, in particular two diametrically opposite, sickle-shaped working spaces between the housing recess and the rotor, each containing a low pressure and a high pressure area, and in those of the inner edges of the blades limited spaces of the slots pressurized conveying liquid is passed when the associated wing a Run through the low pressure area of the machine.

Γ! 'S J3 documents (Art. 7 5 l para. 2 no. L sentence 3 of the amendment p. 4.9.19β7 |

2098U / 0287

Robert Bosch GmbH R. 9220

Stuttgart Vo / Fü I 6.9.68

From the American patent specification 2,631,540 a vane pump is known in which the inner edges of the Wings limited spaces of the slots via arcuate grooves on the smooth inside of the cover of the machine under high pressure standing fluid is passed when the vanes pass through the suction area of the pump, d. H. when the wings are up move outwards in the slots. In the pressure range of the pump, the blades in the slots are moved radially inwards again. In doing so, they displace the pumped liquid again from the spaces mentioned. This comes through other arcuate grooves and back into the high pressure chamber of the pump via a throttle point. This prevents the outer edges of the wings stand out from the inner wall of the conveying chamber.

This pump has the disadvantage that the hydraulic forces that push the blades outward in the suction area, which can become very large at high delivery pressures.

The resulting very high friction between the outer edges the wing and the inner wall of the conveying chamber causes a considerable Wear - it can even lead to seizure and thus a reduction in the service life of the pump.

The invention is based on the object of creating a vane machine of the type described above that can be used as a pump or motor, which achieves a long service life at very high delivery pressures with relatively little wear and good efficiency.

This is achieved according to the invention in that a pressure control valve is provided which controls a throttling passage from the high pressure side of the machine to the spaces delimited by the inner edges of the wings and generates an intermediate pressure in this which is lower than the pressure prevailing on the high pressure side of the machine is.

2098U / 0287 " ³ "

Robert Bosch GmbH R. 9220

Stuttgart ■. Vo / Pu I6.9.68

This has the advantage that the pressing force of the wings on the inner wall of the housing is limited to the amount necessary to reliably seal the individual conveyor cells against each other. Through this Further advantages over the known vane machines are required: A vane machine designed according to the invention has an increased overall efficiency and can also be loaded with very high pressures up to a maximum of 200 atmospheres. Another advantage is the lower wear, especially in the low-pressure areas, which increases the service life of the machine. Cheaper ™ Materials with less good wear properties are used will.

It is particularly advantageous that the intermediate pressure is controlled by a pressure regulating valve which is organically built into the housing of the vane machine is produced.

Further advantageous embodiments of the subject matter of the invention result from the following description and drawing.

An embodiment of the subject matter of the invention is shown in the drawing shown. Yy

This shows in:

Fig. 1 is a longitudinal section through a vane pump> Fig. 2 is a cross section according to II-II of. Fig. 1, FIG. J5 shows a cross section according to III-III of FIG. 1, 4 shows a schematic representation of a control circuit for a wing during a working stroke.

The housing of the vane pump shown consists of a low-pressure (or suction) side housing part 1 and one high-pressure side housing part 2, which is not shown by

- 4 _ 209a U / 0287

. Robert Bosch GmbH R. 9220

Stuttgart 'Vo / Fu I 6.9.68

Screws on a J5 fitting with sealant in between are connected. An inlet opening 4 opens into an annular channel 5 in the housing part 1.

At the bottom of the pot-shaped housing part 1 sits a cylindrical insert part 7 * which fits into its interior space 6 and in which a pressure control valve 8 is arranged. For this purpose, when inserted, a cylindrical blind bore 8 ′ is formed perpendicular to its axis and receives a piston-shaped control slide 9. The control slide 9 is supported on one end of a spring 10, the other end of which is seated on the bottom of the blind bore 8 '. The open side of the blind bore 8 ¹ is closed to the outside by a plug 11 provided with sealing means on which a stop pin directed into the bore is arranged, whereby a pressure chamber 11 'is created.

The control slide 9 has an annular groove 12 in the middle. The annular surface of the annular groove 12 facing away from the spring 10 has a fine control bevel 13, which together with a control bore 14 'forms a throttle point 14 forms. In the space formed by the annular groove 12 opens a bore 15 connected to the high pressure side. A throttle bore 16 runs from the bottom of the blind bore 8 'to the annular channel 5 ·

The control bore 14 ′ opens into a trough-like recess 17 in the bottom of the housing part 1, which is secured against the interior 6 by a sealing ring l8 inserted into a groove in the insert part 7 is sealed. The space between the. Plug 11 and the control slide 9 is also with a throttle bore I9 the recess 17 connected.

A cam ring 20 with an inner bore 21 adjoins the insert 7 in the interior 6. At this there are two of each other diametrically opposite, sickle-shaped cavities that form working spaces 22. The cam ring 20 is through a pin connection 25 secured against twisting in the interior 6.

209814/0287

Robert Bosch GmbH 'R. 922O

Stuttgart Vo / Fu 16.9.68

From the ring channel 5 extend two opposite, approximately rectangular recesses 24 up to the end of the housing part 1 facing the housing part 2. The housing part has an outlet opening 25, which opens into an annular channel 26, and a large bore 27, the diameter of which corresponds to that of the interior 6 in the housing part 1 is equivalent to. It is used to receive a fitted insert part 28, which on the one hand extends to the cam ring 20, on the other hand with an extension 29 engages in a bore 30 adjoining the bore 27 with a smaller diameter. On the side of the insert part 28 facing the cam ring 20, two are mutually exclusive opposing recesses 3I formed coaxially with ™ the recesses 24 of the housing part 1, and have approximately the same width as this. They run radially inwards and end somewhat inside the bore 21 of the cam ring 20.

To seal the annular channel 26, sealing rings 32 and 33 are inserted into annular grooves running around the outer circumference of the insert part 28.

A drive shaft 3 ^ is passed through a bore 35 in the housing part 2 and through a central bore 36 in the insert part 28. The drive shaft has two bearings. A first ball bearing 37 secured by a snap ring in the housing part 2 forms a fixed bearing. A second ball bearing 38 is arranged in a central bore 39 in the M insert part 28. This bearing is designed as a floating bearing.

The exposed inner end of the drive shaft 3 ^ is -with a spline 40 provided; it carries a rotor 41 with the same inner wedge gearing. In the rotor 4l there are several approximately radially extending Slits 42 formed which extend over its entire width. The slots 42 have cylindrical spaces 43 at their inner end. Wings 44 are tightly and slidably guided in the slots.

The working spaces 22 in the cam ring 20 form together with the outer circumferential surface of the rotor Conveying rooms with one suction (or low pressure) and one Iloch pressure area each.

- 6 -209814/0287

Robert Bosch GmbH R. 9220

Stuttgart Vo / Pu 16.9.68

Offset by 90 ° with respect to the recesses J51, are in the The side of the insert part 28 facing the lifting ring 20 has two oval high-pressure slots 45 arranged. DAe corresponds to the length of the high pressure slots about the width of the recesses JJl, their width is about half as large. The high pressure slots 45 are with bores 46 the annular channel 26 connected.

In the insert part 7 are in the diameter range of the spaces 4} of the rotor 4l two diametrically opposed arcuate grooves 47 and 48, which are open to the rotor. The grooves 47, 48 extend over an angle of 45 ° in the arc areas, in which the sickle-shaped working spaces 22 - seen in a clockwise direction - expand radially. The grooves 47, 48 are over Bores 49, 50 which are arranged in the insert part 7 parallel to its longitudinal axis; with the trough-like recess 17 in the Housing part 1 connected.

On the same diameter range as the grooves 47, 48 are located in the insert part 28 in the arch areas in which - in the same way as considered above - the working spaces 22 narrow, again arcuate grooves 51 and 52 * they are so 90 ° against each other the grooves 47, 48 offset. The grooves 51, 52 extend over an angular range of approx. 90 °. About inclined throttle bores 53 and 54, these grooves are connected to the bores 46. Between the arc-shaped, each belonging to a sickle-shaped working space 22 Grooves 47, 51 and 48, 52 are at the ends of the grooves 51 and 52 each have a tapered pilot groove facing the groove 47 and 48, respectively 55 * 56 attached.

If the rotor 4l of the pump is rotated clockwise (with reference to FIG. J>) by a drive machine (not shown), the vanes 44 move along the bore 21 of the cam ring 20. After they have passed the concentric part of the bore, they move following the rising part of the bore 21 in the work spaces 22 to the outside. The cells delimited between each two wings 44 expand and suck as a result of the in the cells

2098U / 0287 - 7 -

Robert Bosch GmbH R. 9220

Stuttgart. ■. Vo / Fu 16.9-68

resulting increase in volume and negative pressure formation of the pumped liquid via the recesses j51 ini insert part 28, from the recesses 24, the annular channel 5 and ultimately the inlet opening 4 after.

In the further rotation of the rotor, the cells are again reduced in size by the radial narrowing of the working spaces 22. The included The pumped liquid experiences a pressure increase and is released through the high pressure slots 45 is pushed out again and comes through the holes into the annular channel 26 and from there to the drain opening 25. This mode of operation is known per se.

Under the influence of inertia forces occurring on the wing 44, the friction between the wing and rotor 41 and hydrodynamic Forces on the wing head, the wing can both radially expanding, as well as in the narrowing part, so in the suction and Lift the pressure area of the working chamber 22 from the inner wall of the stroke ring. Leakage of the cells and thus a reduction in the Funding volume would be the result.

In order to remedy this problem, the spaces kj> at the slots are filled from the arcuate grooves 47, 48 with conveying liquid under a regulated intermediate pressure.

The control process is explained using FIG. 4, in which the control circuit a wing 44 for a working stroke, .that is the passage of the wing through a working space 22 in the stroke ring 20, is shown schematically.

A pump denoted by 57 represents the actual working part of the vane pump, which is described above. The pump feeds a consumer 58 shown as a controllable throttle point

The pressure control valve arranged in use, part 7, is shown in FIG. 4 also shown with the reference numbers already introduced.

209814/0287 - ⁸ -

Robert Bosch GmbH R. 9220

Stuttgart

The throttle point 59 symbolizes the throttle bore 16; the throttle point _v 60 corresponds to the throttle bore 19. The 3/2-way valve 61 shown symbolizes in switching position I a connection from space 43 of the rotor to groove 47 in insert part 7, in the other switching position II a connection from the pressure chamber 43 to the groove 51 after rotating the rotor 41 by about 45 ° clockwise (Fig. 3)

The eccentric wheel 61 represents the bore 21 of the cam ring 20 on which the wing 44 slides. It also rotates clockwise. The throttle 62 corresponds to a bore 53 or 54.

The effect of the control loop is as follows:

A wing is considered which is located at the beginning of a working space 22, which is just entering the suction area.

If there is a consumer pressure "zero" at 58, the throttle point is 14 completely open, since the spring 10 pushes the control slide completely to the right without resistance. Under neutral circulation pressure Standing fluid reaches the pressure chamber 43 without resistance.

With increasing pump load by the consumer 58, the control slide 9 moves as a result of increasing pressure in the Pressure chamber 11 'against the spring 10 via the throttle point 14 until the delivery fluid flowing to the chamber 43 becomes effective The control slide 9 now always regulates the throttle point 14 to such a cross-section in which a Balance of forces on the control slide 9 prevails between the Force of the spring 10 and the force which acts on the control slide from the pressure chamber 11 '. This force is proportional to that intermediate pressure also acting in space 43. The pump load increases furthermore, the cross section of the throttle point 14 is further reduced until the intermediate pressure increases again adjusts. With decreasing pump load n_

2098U / 0787

Robert Bosch GMBH . . R. 9220

Stuttgart Vo / Fu 16.9.68

the reverse occurs. The throttles 59 and 60 (or the throttle bores 16 and 19) cause a regulation necessary damping of the control spool.

The conveying liquid under the intermediate pressure enters the space 43 via an arcuate groove 47, 48. The intermediate pressure there generates a force acting on the lower edge of the vane 44, which forces the vane against the clockwise rotating eccentric (i.e. against the inner wall of the cam ring 20) presses. The intermediate pressure acting under the wing in space 43 must always be greater than half the pressure acting on the corresponding wing head. M.

As the vane 44 continues to rotate in the cam ring (FIG. 3), the space 43 finally comes with one of the pilot control grooves 55, 56 in Connection which open into the arcuate grooves 51, 52. They are filled with conveying liquid under high pressure, which can now overflow into the room 42. This ensures that the system pressure (high pressure) is below the wing 44 builds up earlier than at the wing head and thus also in the cell in front of the wing in question. The wing 44 is thus always pressed against the inner wall of the cam ring 20, even if the pressure in the groove 47, 48 is less than. is half the system pressure. the Pilot grooves 55 also reduce the pressure pulsation ..

If the wing 44 is now moved by the eccentric (or by the falling Curve of the cam ring 20) is pushed back into the slot 42, so the high pressure conveying liquid is via the In the meantime, as mentioned above, the 3/2-way valve in switch position II has been displaced from space 43 again. The thrush or the bore 53, 54) causes a pressure that is slightly higher than the system pressure. So it will be a resilient resistance to the movement of the wings 44 exerted radially inward. The fluid then reaches the high pressure side the pump.

- 10 -

0 98U / n? 87

Robert Bosch GmbH R. 9220

Stuttgart Vo / Pu 16.9.68

Of course, the arrangement described here can be just as advantageous can also be used in plow cell machines with only one work area. The design of the wings also has no effect on applicability of the subject matter of the invention ..

2098U / 0287

Claims (8)

Robert Bosch GmbH ■ / j / j R. 9220 Stuttgart · '' Vo / Fu I6.9.68 Claims: 1. As. Vane machine which can be used for a pump or a motor and has approximately radial slots in one connected to the drive shaft Rotors tightly and slidingly movable blades, which separate the individual conveyor cells from each other and whose outer edges on a ■ Housing recess, particularly slide on a cam ring, and with at least one working space, in particular two diametrically opposite one another, between the housing recess and the rotor lying sickle-shaped work spaces, each containing a low-pressure and a high-pressure area, and in the by the inner edges of the blades bounded spaces of the slots conveying liquid under pressure is passed when the associated wing pass through a low-pressure area of the machine, characterized in that a pressure control valve (8) is provided is that has a throttling passage (14) from the high pressure side of the machine to the inner edges of the blades (44) limited spaces (4j) controls and in these an intermediate pressure which is lower than the pressure prevailing on the high pressure side of the machine. 2. Vane machine according to claim 1, characterized in that the pressure control valve (8) organically in the housing of the vane machine, in particular is built into an insert part (7) *. Documents (/ "1-" * 1 Abc. 2 '.ir. I 3:' ..: 3 nasty Aridsrungsgea. V. 4. 9.1987) ^ 2098U Robert Bosch GmbH 11 ^R 9220 Stuttgart * " . Vo / Fu I 6.9.68 5. Vane machine according to claim 1 or 2, characterized in that that the pressure regulating valve (8) has a control slide (9) sliding in a bore, on the one hand by a spring (10) is loaded, on the other hand by the intermediate pressure prevailing in space (43). 4. Vane cell machine according to one of claims 1 to 3, characterized in that the space receiving the spring (10) extends over W a throttle (16) is in communication with a pressureless space. 5. Vane machine according to one of claims 1 to 4, characterized in that the intermediate pressure prevailing in the space (43) prevails in a pressure space (II ¹ ) bounded by the control slide (9) and these two spaces are connected via a throttle (19). 6. Vane machine according to one of claims 1 to 5 * thereby characterized in that arranged in the by one on the control slide ^ Ring groove (12) formed space a hole (15) opens, which with the high pressure side of the vane machine is connected, and that a second bore (14 *) opens into this space, which together forms the throttle point (14) with a fine control bevel (13). 7. Vane machine according to one of claims 1 to 6, characterized in that on one of the rotor (4l) facing Housing parts in the diameter range of the spaces (43) two arcuate, diametrically opposed grooves (51 # 52) whose line of symmetry coincides with that of the high pressure - 3 -2098U / 0287 slots (45) coincides that. on the same diameter area two other arcuate grooves (47, 48) are arranged whose line of symmetry is offset by 90 ° with respect to that of the grooves (51, 52) is, and that on the grooves (51 * 52) in each case between the grooves (47 and 51) 'and (48 and 52) a pointed pilot groove (55 * 56) is arranged. 8. Vane machine according to one of claims 1 to 7 *, characterized in that that the grooves (51, 52) are connected to the high pressure side of the vane machine via throttle bores (53 * 54) / φ 209814/028 Blank page