EP1760317A2 - Positive displacement pump with variable capacity - Google Patents

Abstract

The displacement pump with variable delivery volumes, particularly a single stroke vane cell pump, produces a pressure medium flow for a user. It has a rotor in a housing and a freely accessibly held curve ring surrounded by a walling. The curve ring for altering the delivery volume is displaceable to the rotor. A spring component influences the position of the curve ring. The spring component (18) is arranged in a cavity (17) of the walling (22). The walling is formed by the housing (2) and an outer ring (3) inserted in the housing, facing the curve ring (6). The shape of the cavity and spring component are so matched that the spring component is comfortably positionable in the cavity. The last winding (20) of the spring component has a shape matching that of the cavity.

Description

Displacement pump with variable displacement

Technical area

1. 1. The invention relates to a positive displacement pump with variable displacement, in particular a single-stroke vane pump according to the preamble of claim 1.

State of the art

1. 1. A generic positive displacement pump is out of DE 199 42 466 A1 known.
2. 2. In practice, in work systems with hydraulic consumers, such as a power steering device of motor vehicles, usually worked with constant displacement pumps. The speed caused by the drive of the pump via the internal combustion engine of the vehicle resulting excess amounts are relaxed and returned to the suction side of the pump, which in particular at higher speeds significant losses and heat loads are connected. However, these are accepted in order to have at any time the maximum consumer demand corresponding, large volume flows available, thus ensuring a delay-free admission of the respective hydraulic consumers.
3. 3. In the generic positive displacement pump can be adjusted or adjusted by a displacement of the cam ring or the cam ring within the housing, the eccentricity between the rotor and the cam ring. Thus, the geometric displacement of the working chambers can be increased or decreased. The term "geometric" delivery volume refers to the per revolution funded volume of the positive displacement pump. In an adjustable vane pump, the geometric displacement is determined by the difference between the smallest and largest cell. The volume of a single working chamber or cell changes by the eccentricity between the rotor and the cam ring and / or by the rotation of the rotor.
4. 4. To adjust the cam ring is according to the DE 199 42 466 A1 provided that two mutually delimited and substantially opposite pressure chambers are formed between the housing and the cam ring. The pressure chambers can be acted upon with a fluid pressure. The cam ring is displaced accordingly as a function of the pressure chamber acted upon by a fluid pressure, so that the geometric delivery volume is reduced or increased. It is provided that the cam ring is shifted at high speeds such that the geometric delivery volume is reduced. Conversely, it is provided at low speeds that the cam ring is moved so that increases the geometric displacement.
5. 5. The displacement of the cam ring within the housing is essentially due to the fluid pressure, which, however, is generally not yet available when starting the pump. To ensure that the cam ring is in a position in which the positive displacement pump can be started, the use of a spring element is provided according to the generic document, which ensures that the geometric displacement is maximum.
6. 6. The spring element biases the cam ring from a pressure chamber and urges the cam ring in the direction of the Vollhubanschlagbereichs to keep the geometric displacement to the maximum value.
7. 7. For further prior art of variable displacement pumps is further on the DE 102 40 499 A1 as well as the DE 102 09 880 A1 directed.
8. 8. The known spring elements - which are also referred to as return springs - are also used to influence the position of the cam ring during operation of the positive displacement pump or to act on the cam ring. The spring elements can also serve as an end stop.
9. 9. The known spring elements for returning the cam ring are mounted laterally from the outside in the housing of the positive displacement pump and held with a screw. This creates a sealing point that would not be required for the function of the pump.

Presentation of the invention

1. 1. The invention has for its object to provide a positive displacement pump with variable delivery, in which a spring element for acting on the cam ring is structurally simple and advantageous, and the variety of components is reduced.
2. 2. According to the invention, this object is achieved by claim 1.
3. 3. The fact that the spring element is arranged in a recess of the wall, no additional external sealing of the pump in this area is required. Problems that have arisen or could arise over the life of the pump due to the previously required sealing point are thus avoided. The variety of components is reduced because neither appropriate sealing material is needed, nor a screw is necessary to hold the spring element. In addition, errors during assembly, for example by a wrong screwing the screw or damage to the seal, avoided.
4. 4. The recess may be arranged in various ways in the wall. In a particularly simple embodiment, the wall may be formed by the housing of the positive displacement pump. In this case, the recess may be arranged directly in the housing. However, displacement pumps according to the prior art generally have an outer ring, which is inserted into the housing and facing the cam ring. The wall is thus formed in the usual embodiment by the housing and the outer ring used.
5. 5. The outer ring can ensure both the free movement of the cam ring and lateral forces from the cam ring in the housing transfer. The cam ring is displaceable within the outer ring. As a rule, the outer ring forms an elliptical space within which the cam ring can be moved.
6. 6. The recess for receiving the spring element may be formed as a recess or depression in the outer ring. In one embodiment of the recess for receiving the spring element as a recess in the outer ring, the spring element is thus at one end on a bottom of the outer ring formed by the recess or based on this.
7. 7. Insofar as the recess for receiving the spring element is formed as a recess in the outer ring, the spring element thus penetrates the outer ring and is supported on the housing or the housing wall. As a rule, the housing will have no further depression. However, it can also be provided that the housing wall also has a depression, so that the recess according to the invention in the wall (formed by housing and outer ring) is formed by a recess in the outer ring and a recess in the housing.
8. 8. It has been found to be particularly suitable if only the outer ring has a recess for receiving the spring element.
9. 9. It is advantageous if the shape of the recess and the spring element are adapted to one another or matched to one another such that the spring element can be reliably positioned in the recess. In a simple way, this can be achieved in that the recess facing the end of the spring element has a shape adapted to the recess or the bottom of the recess. Preferably, it is provided that only the last turns or the last turn of the spring element has a correspondingly adapted shape.
10. 10. A rectangular shape of the last turn (and thus the depression) has been found to be particularly suitable for this purpose. Of course, other forms are conceivable, wherein it is to prevent twisting of the spring element as suitable has chosen to choose a shape that deviates from a circular shape.
11. 11. In a structural embodiment of the invention can be provided that the last turn or the last turns of the spring element can be pressed into the recess and / or clamped. Thus, a reliable positioning or arrangement of the spring element in the depression is achieved in a simple manner without further aids.
12. 12. In a further development of the invention it can be provided that the spring element is a preferably conical spiral spring whose last turn is adapted to the course of the depression, for example rectangular.
13. 13. In an alternative embodiment can also be provided that the spring element comprises a plurality, preferably two, coil springs. The coil springs can also be designed conical. The end region of the spring element formed from the spiral springs facing the depression can preferably be adapted again to the shape of the depression. A particularly suitable embodiment of the spring element results from a design with two conical spiral springs, which are integrally connected to each other or made of a wire element. In each case, the tips of the two conical spiral springs represent the beginning or the end of the wire element. The connection between the two conical spiral springs - usually the middle of the wire element - may be formed as a common last turn of the spring element, which on the mold or is adapted to the bottom of the depression.
14. 14. The spring element may have a round or rectangular or square wire cross-section. With regard to the arrangement of the last turn of the spring element at the bottom of the depression, a rectangular wire cross section may be advantageous.
15. 15. In an alternative embodiment, the spring element may also be formed as a leaf spring. The leaf spring can also be in a simple way to have a shape that is adapted to the recess or the bottom of the recess and optionally used accordingly or clamped.
16. 16. The recess for receiving the spring element may also be formed by a projection or an increase, which rises from the migration towards the cam ring and having a recess for receiving the spring element.
17. 17.Vorteilhafte refinements and developments of the invention will become apparent from the dependent claims. Hereinafter, embodiments of the invention are shown in principle with reference to the drawing.

Brief description of the drawings

1. 1. It shows:
2. 2 is a schematic representation of a section through a displacement pump with a variable delivery volume in one embodiment as a single-stroke vane pump;
3. 3 is a section along the line II-II of Fig. 1;
4. 4 shows a spring element for influencing the position of the cam ring in a first embodiment;
5. 5 shows a spring element for influencing the position of the cam ring in a second embodiment;
6. 6 shows a spring element for influencing the position of the cam ring in a third embodiment; and
7. 7. Fig. 6 is a spring element for influencing the position of the cam ring in a fourth embodiment.

Way (s) for carrying out the invention

1. 1. The figures show an embodiment of a positive displacement pump 1 according to the invention with variable delivery volume in an embodiment as a single-stroke vane pump. Single-stroke vane pumps are well known in terms of their basic operation from the general state of the art, including only for example on the DE 199 42 466 A1 as well as the DE 102 40 499 A1 is referenced. Below, therefore, only the features essential to the invention are shown in more detail.
2. 2. As can be seen from the figures, the vane pump 1 has a housing 2. In the housing 2, an outer ring 3 is inserted. In principle, the housing 2 of the vane pump 1 can assume the function of the outer ring 3 (also referred to as intermediate ring). However, the formation of an outer ring 3 has been found to be useful for mass production. In the outer ring 3, a rotor 4 is mounted via a shaft 5. The rotor 4 is surrounded by a cam ring 6. The cam ring 6 can swing freely through an oscillating pivot pin 7 serving as a support shaft into an elliptical space 8 formed in the outer ring 3.
3. 3. The cam ring 6 is adjustable or displaceable within the elliptical space 8. Between the rotor 4 and the cam ring 6 are delimited by wings 9 working chambers 10 are formed. By shifting the cam ring 6, the eccentricity between the rotor 4 and the cam ring 6 changes, whereby the volume of the working chambers 10 and thus the geometric displacement of the vane pump 1 is determined.
4. 4. When the rotor 4 is driven, the vanes 9 are advanced and retracted in slots of the rotor 4. For this purpose, a Hinterflügelfluiddruck is used in a known manner, which acts essentially on the ends of the guided in the slots of the rotor 4 wings 9.
5. 5. In a known and not shown manner, the fluid supply of the rear wing area and generally the fluid inlet and outlet is ensured by kidney-shaped slots in a control plate. Provided is usually also a bearing cap with a flat surface, which faces the set of rotors (rotor 4, wing 9 and cam ring 6) and ensures the frontal seal. The bearing cap is provided with corresponding to the control plate kidney-shaped slots. This is in the embodiment also not shown. In the exemplary embodiment, the outer ring 3 ensures the free movement of the cam ring 6 and transmits lateral forces from the cam ring 6 into the housing 2.
6. 6. Between the outer ring 3 and the cam ring 6 crescent-shaped cross sections 11, 12 are arranged. These cross sections are separated by suitable sealing elements. This can be brought about a pressurization of the two cross sections 11, 12, a displacement of the cam ring 6.
7. 7. A non-illustrated control piston 13 is connected via bores 14, 15 with the crescent-shaped cross sections 11, 12. The crescent-shaped cross sections 11, 12 can be mutually connected by the control piston 13 both with the operating pressure of the pump and with a container port 16. Due to the resulting pressure difference in the crescent-shaped cross sections 11, 12, the displacement of the cam ring 6 is achieved.
8. 8. According to the invention, a cam ring 3 surrounding wall 22, which is formed in the embodiment by the outer ring 3 and the housing 2, a recess 17. The recess 17 in the wall 22 is formed as a recess in the outer ring 3. The recess 17 may also be a recess, recess, groove or the like.
9. 9. A spring element 18 acts on the cam ring 6 or affects its position. As can be seen from FIG. 1 and FIG. 2, the spring element 18 is supported, on the one hand, on the outer ring 3 or a bottom 17a of the recess 17 and, on the other hand, on the outer side of the cam ring 6.
10. 10. Fig. 3 shows an embodiment of the spring element 18 as a conical spiral spring 19, wherein the last turn 20 is designed so that a positioning within the recess 17 of the outer ring 3 is ensured. The last turn 20 has in the embodiment of FIG. 3 on a rectangular course.
11. 11. According to the embodiment of the spring element 18 shown in FIG. 4, this has two conical spiral springs 19. The Spring element 18 according to the embodiment shown in Fig. 4 is adapted to the profile of the bottom 17 a of the recess 17. The spring element 18 with the two conical spiral springs 19 is made of a wire element. The two coil springs 19 shown in FIG. 4 are connected to each other at their ends remote from the tip (one piece), wherein the connecting piece, which is adapted to the course of the bottom 17 a of the recess 17 last turn 20. The spring element 18 according to the embodiment shown in Fig. 4 starts at the top of one of the two coil springs 19, then opens conically until the beginning of the last turn 20 is reached, then adapted to the course of the bottom 17 a, thereby forming the last turn 20 of both the first and the second coil spring 19 and then extends from there tapered to the top of the second coil spring 19th
12. 12. FIG. 5 shows an alternative embodiment to FIG. 3, which differs from the embodiment according to FIG. 3 in that the wire cross section is not round but rectangular, preferably square. Similarly, the embodiment shown in Fig. 4 may have a rectangular, for example square, wire cross-section.
13. 13. Fig. 6 shows a further alternative embodiment of the spring element 18. The spring element 18 is formed as a leaf spring 21. The leaf spring 21 has a base part 21 a, which is adapted to the shape of the bottom 17 a of the recess 17, rectangular in the embodiment, is formed. From the base part 21 a, the spring of the leaf spring 21, which is provided for engagement with the cam ring 6 rises.
14. 14. The illustrated spring element 18 serves in the exemplary embodiment for returning the cam ring 6.
15. 15. The displacer or vane pump according to the invention is particularly suitable for use in a power steering device of motor vehicles.

Claims (15)

Displacement pump with variable displacement, in particular one-stroke vane pump for generating a pressure medium flow to a consumer, with a rotor mounted in a housing, surrounded by a wall and freely held cam ring, wherein the cam ring for changing the delivery volume to the rotor is displaceable and with a spring element for influencing the position of the cam ring, characterized in that the spring element (18) in a recess (17) of the wall (22) is arranged. Positive displacement pump according to claim 1, characterized in that the wall (22) through the housing (2) is formed. Positive displacement pump according to claim 1, characterized in that the wall (22) through the housing (2) and one in the housing (2) inserted and the cam ring (6) facing outer ring (3) is formed. Positive displacement pump according to claim 3, characterized in that the recess (17) for the arrangement of the spring element (18) as a recess or depression in the outer ring (3) is formed. Positive displacement pump according to one of claims 1 to 4, characterized in that the shape of the recess (17) and the spring element (18) are adapted to each other such that the spring element (18) is reliably positionable in the recess (17). Positive displacement pump according to claim 5, characterized in that the recess (17) facing the end of the spring element (18) has a shape adapted to the recess (17). Positive displacement pump according to claim 6, characterized in that the last turn (20) of the spring element (18) has a shape adapted to the depression (17). Positive displacement pump according to claim 7, characterized in that the last turn (20) has an at least approximately rectangular shape. Positive displacement pump according to claim 7 or 8, characterized in that the last turn (20) in the recess (17) can be pressed and / or clamped. Positive displacement pump according to one of claims 1 to 9, characterized characterized in that the spring element (18) is a spiral spring (19). Positive displacement pump according to claim 10, characterized in that the spiral spring (19) is conical. Positive displacement pump according to one of claims 1 to 11, characterized in that the spring element (18) has two or more conical spiral springs (19). Positive displacement pump according to claim 10, 11 or 12, characterized in that the spiral spring (19) has a round, rectangular or square wire cross-section. Positive displacement pump according to one of claims 1 to 9, characterized in that the spring element (18) is designed as a leaf spring (21). Positive displacement pump according to one of claims 1 to 14, characterized in that the consumer is a power steering device of a motor vehicle.

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