DE102015205061A1 - Motor pump unit with a membrane unit - Google Patents

Abstract

The invention relates to a motor pump unit (1) for supplying negative pressure to a pneumatic brake booster, wherein the motor pump unit (1) is designed as a diaphragm pump, preferably a double diaphragm pump with at least one membrane unit (2) with an elastomeric membrane (3) a connecting rod (4) by an electric motor driven eccentric drive (5) is moved. In order to offer an improved motor pump unit, which in particular works reliably at low temperatures and requires no increased engine load, it is proposed according to the invention that the membrane unit (2) and the connecting rod (4) are resiliently biased against each other along a longitudinal axis (L) of the connecting rod (4) ,

Description

The invention relates to a motor pump unit for the vacuum supply of a pneumatic brake booster, in particular for a hydraulic car brake system. In modern motor vehicles with pneumatic brake booster often separate motor pump units are used to generate the required negative pressure. Among them, motor pump units are known, which are designed as double diaphragm pumps with two opposite elastomeric membranes. The membranes are driven by an electric motor, whereby the rotational movement of the motor axis is converted by an eccentric drive into a translatory and transmitted by means of connecting rods to the membranes.

The flexible membrane is usually attached to a rigid membrane holder made of plastic.

At low temperatures, elastomeric materials tend to harden. As a result, the forming or flexing forces increase significantly in the membrane, which makes a higher engine load and consequently a stronger and heavier engine required with the same requirements for startup times.

It is therefore the object to provide an improved, cost and weight-efficient motor pump unit, which works reliably especially at low temperatures and does not require increased engine load.

The object is achieved by the combination of features according to the independent claim 1. Subclaims specify further embodiments and refinements of the invention.

By the membrane unit and the connecting rod are arranged resiliently biased against each other, there is the possibility in the power flow between the two structural components interpose a separate Elastoelement. The elastomeric element should preferably be formed from a material which retains its elastic properties as unchanged as possible in a temperature range (in particular -40 ° C. to 120 ° C.) which is relevant for the engine compartment of a passenger vehicle. Spring steel is particularly suitable for this purpose.

The elastomeric element can be designed so that it only degrades the unwanted force peaks at low temperatures and thereby allows the use of a light and cheap engine with a lower starting torque. At higher temperatures, as the diaphragm becomes more resilient and requires less force, the biasing force on the elastomeric element prevents it from deforming so that there is no degradation in the efficiency of the motor pump assembly and the diaphragm is operated at full amplitude of motion.

In an advantageous embodiment, the membrane unit and the connecting rod are slidably disposed against each other limited, whereby the ability to break down the force peaks is further increased.

The elastomeric element can be arranged in a blind hole within the membrane unit. Preferably, the membrane unit is designed in several parts with a flexible membrane made of an elastomer material which is slipped over a rigid membrane holder. In such embodiments, the blind hole and devices for mounting and guiding the connecting rod are arranged in the membrane holder.

Connecting rod is inserted and locked under biasing the Elastoelements in the blind hole.

Locking occurs either without a twisting connecting rod against the diaphragm unit or with a twist of less than 180 ° (thread connection with complex manufacturing tools is avoided).

Locking without twisting can be realized particularly efficiently by a snap lock. As a locking element are, for example, locking lugs with chamfers, which are integrally formed on the connecting rod and engage in corresponding openings or recesses in the membrane unit.

In order to simplify the assembly and increase the process reliability, longitudinal slots can additionally be provided in the membrane holder which lie in a plane orthogonal to the plane in which the locking lugs are arranged. As a result, the diaphragm holder during assembly can be pressed against each other without damage by the locking lugs.

Locking without rotation, for example, by means of a separate, present as a separate component locking element, which is used after the mesh of the connecting rod and the membrane unit transverse to the longitudinal axis of the connecting rod.

The locking element may be designed as a pin, which is provided after assembly to simultaneously guide in a slot.

Slot can be formed in the connecting rod, so that the locking element is inserted through openings in the membrane holder and the slot and fixed in the membrane holder. The openings in the membrane holder can thus simultaneously serve as storage locations for the locking element. The connecting rod is secured against rotation by the locking element and also guided in their movement relative to the membrane unit. In addition, further guide elements may be provided in the blind hole in the membrane holder, which are suitable for guiding and / or preventing rotation of the connecting rod - for example, internal grooves in the blind hole.

The locking element can also be firmly anchored in the connecting rod. In this embodiment, the membrane holder has two opposite slots on the guide and anti-rotation, in which the locking element is performed after assembly with its outer ends. A breakthrough, such as a hole in the connecting rod serves as the storage point for the locking element.

Locking with rotation during assembly can be carried out particularly effective as a bayonet lock, the connecting rod for this purpose has at least one locking shoulder (preferably two).

The locking shoulder may extend both parallel or in the same plane as the connecting rod eye. In such an embodiment, the connecting rod can be created as a simple stamped part. The locking shoulder can also be arranged at an angle to this plane.

The elastomer element may be formed, for example, as a plate spring or a plate spring package which is clamped between the bottom of the blind hole and the end face of the connecting rod. This combination is particularly inexpensive and allows a relatively small relative small amplitude of movement between the membrane unit and the connecting rod.

The elastomeric element can also be designed as a spiral spring. This is a relative to disc spring significantly greater amplitude of motion can be realized.

The coil spring can be arranged in the blind hole or radially on the outside of the membrane holder.

In the arrangement in the blind hole, the coil spring can be arranged analogously to the plate spring between the blind hole bottom and the end face of the connecting rod or to support a separate stop.

In the arrangement radially outward, the coil spring can be supported on the connecting rod side on a separate stop element or on the connecting rod, on the membrane side on a separate stop on the membrane unit.

The spiral spring can also be arranged in a region between the end face of the membrane unit and the connecting rod eye and clamped, for example, between the end face of the membrane unit and the connecting rod eye or a separate stop on the connecting rod.

The stiffness of the elastomeric element and biasing force are preferably designed such that the relative movement between the connecting rod and the membrane unit only takes place when the material of the membrane is hardened due to low temperatures and an increased force required to deform the membrane relative to other modes. The quantitative interpretation depends very much on the particular factual conditions such as material selection, membrane geometry, motor torque, inertia, etc.

In other operating modes and under other environmental conditions, on the other hand, relative motion should no longer take place because this would lower the effective coefficient of the motor pump unit.

Other objects, features, advantages and applications of the invention will become apparent from the dependent claims together with the description and with reference to the figures. Matching components and construction elements will be given the same reference numbers if possible.

On detailed description of basic functions of a generic motor pump unit is largely omitted, since sufficiently known.

Fig. 1

1 shows a known embodiment of a motor pump unit 1 , An electric motor 15 drives over an eccentric drive 5 two connecting rods 4 indicating the movement on two oppositely arranged membrane units 2 to transfer. The connecting rods 4 are made in several parts with a head 16 that with the membrane holder 7 friction welded.

Fig. 2

2 shows a first embodiment according to the invention in different views. The coupling of the membrane unit 2 with the connecting rod 4 is designed as a snap closure.

The membrane unit 2 is in two parts with a membrane 3 made of an elastomeric material and a membrane holder 6 from a preferably thermoplastic material. The connecting rod 4 has two locking lugs acting as an integral locking element 10 Acts by being in the assembled state in two recesses 17 in the membrane holder 6 intervention. In a plane orthogonal to the plane in which the locking element 10 extends, the membrane holder has 6 a longitudinal slot 19 on, the assembly of the connecting rod 4 by springing apart of the membrane holder 6 should facilitate.

An elastomeric element designed as a diaphragm spring 6 is in a blind hole 11 in the membrane holder 6 arranged and between the ground 18 the blind hole 11 and the front side 12 the connecting rod 4 clamped.

Fig. 3

3 shows a second embodiment of the invention, also in different views.

In contrast to the embodiment described above, the coupling of the membrane unit takes place 2 with the connecting rod 4 by means of a separate locking element designed as a pin 8th ,

The Elastoelement 6 is a coil spring, which is between the front side 12 the connecting rod 4 and the bottom of the blind hole 11 is clamped.

Furthermore, the connecting rod has a slot 9 on. After inserting the Elastoelements 6 in the blind hole 11 and the insertion of the connecting rod 4 becomes the locking element 8th transverse to the longitudinal axis L through the slot 9 plugged through and in the storage locations 20 permanently fixed.

The connecting rod 4 is under the tensioning of the Elastoelements 6 relative to the membrane unit 2 movable, while the slot works 9 together with the locking element 8th as a guide and anti-twist device.

The guide and anti-rotation are additionally by two internal grooves 21 in the membrane holder 7 supports, in which the connecting rod 4 intervenes.

Fig. 4

4 shows a further embodiment of the invention. In contrast to the one described above, the spiral spring is located radially on the outside of the membrane holder 7 arranged. The pin-shaped connecting rod 4 engages in a hole in the membrane holder 7 and has storage facility 20 for fixing the pin-shaped locking element 8th ,

Two long holes 9 in the membrane holder 7 act together with the locking element 8th as a guide and anti-twist device.

In the embodiment shown, the elastomeric element 6 between the membrane unit 2 and a separate stop element 13 at the connecting rod 4 clamped. In further embodiments, not shown, it is possible within the invention, the elastomeric element 6 also directly on the connecting rod eye 14 support.

Likewise, it is conceivable according to the invention in other embodiments, not shown, the elastomer element 6 membrane unit side of the connecting rod eye 14 facing end face of the membrane holder 7 support so that the Elastoelement completely in the area between the membrane unit 2 and the connecting rod eye 14 or the stop element 13 is arranged. In this case, the elastomer element 6 be designed as a plate spring or disc spring package.

Fig. 5

5a shows a further embodiment of the invention with a bayonet between the membrane unit 2 and the connecting rod 4 ,

The locking element 10 is here designed as two shoulders by the connecting rod 4 stand out and in assembled condition in the recesses 17 in the membrane holder 7 intervention.

The Elastoelement 6 is in the blind hole 11 between the ground 18 the blind hole 11 and the stopper element 13 clamped. The stop element 13 This can be done both as a separate grading of the connecting rod 4 exist as well as an additional function of the locking element 10 ,

To lock the connecting rod 4 under prestressing of the Elastoelements 6 according to the classic bayonet principle in the membrane holder 7 introduced to the longitudinal axis L twisted and released, leaving the locking element 10 in the recess 17 engages and by the spring force of the Elastoelements 6 is pushed back into its final rest position and strained.

5b shows an alternative embodiment of the connecting rod according to the invention 4 , Unlike the connecting rod after 5a The shoulders of the locking element extend 10 in the same plane as the connecting rod eye 14 , causing the connecting rod 4 For example, by simple punching would be produced.

Fig. 6

6 shows a simplified force-displacement diagram during startup of a motor pump unit at low temperatures to illustrate the effect of the invention.

The force curve X corresponds to the known motor pump unit with pronounced force peaks, which in a motor pump unit according to the invention - force Y - by the action of the elastomer element 6 are significantly mitigated.

LIST OF REFERENCE NUMBERS

1

 A motor pump assembly

2

 membrane unit

3

 membrane

4

 connecting rod

5

 eccentric

6

 Elastoelement

7

 membrane holder

8th

 Separate locking element

9

 Long hole

10

 Integrated locking element

11

 blind

12

 face

13

 stop element

14

 connecting rod

15

 electric motor

16

 head

17

 recess

18

 ground

19

 slot

20

 storage place

21

 inner groove

L

 longitudinal axis

X

 Power flow not optimized

Y

 Power flow optimized

Claims (14)

Motor pump unit ( 1 ) for the negative pressure supply of a pneumatic brake booster, wherein the motor pump unit ( 1 ) as a membrane pump, preferably a double membrane pump with at least one membrane unit ( 2 ) with an elastomeric membrane ( 3 ), the membrane unit ( 2 ) by means of a connecting rod ( 4 ) of an electric motor driven eccentric drive ( 5 ), characterized in that the membrane unit ( 2 ) and the connecting rod ( 4 ) along a longitudinal axis (L) of the connecting rod ( 4 ) are arranged resiliently biased against each other. Motor pump unit ( 1 ) according to claim 1, characterized in that the membrane unit ( 2 ) and the connecting rod ( 4 ) are arranged displaceably limited to each other along the longitudinal axis (L). Motor pump unit ( 1 ) according to claim 1 or 2, characterized in that an elastomer element ( 6 ) in the flow of force between the membrane unit ( 2 ) and the connecting rod ( 4 ) and between the membrane unit ( 2 ) and the connecting rod ( 4 ) is clamped. Motor pump unit ( 1 ) according to claim 3, characterized in that the elastomer element ( 6 ) has at least one plate spring or is designed as such. Motor pump unit ( 1 ) according to claim 3, characterized in that the elastomer element ( 6 ) is formed as a coil spring. Motor pump unit ( 1 ) according to claim 2, characterized in that the membrane unit ( 2 ) and the connecting rod ( 4 ) by means of a locking element ( 8th ) are coupled together, which is provided as a separate component. Motor pump unit ( 1 ) according to claim 6, characterized in that the locking element ( 8th ) in addition to the guide and / or rotation of the membrane unit ( 2 ) and the connecting rod ( 4 ) is formed to each other. Motor pump unit ( 1 ) according to claim 7, characterized in that the guide with at least one slot ( 9 ) is realized, in which the locking element ( 8th ) is guided. Motor pump unit ( 1 ) according to claim 1 or 2, characterized in that the membrane unit ( 2 ) and the connecting rod ( 4 ) by means of an integrated locking element ( 10 ) are releasably connected together. Motor pump unit ( 1 ) according to claim 9, characterized in that the lock is designed as a snap closure. Motor pump unit ( 1 ) according to claim 9, characterized in that the lock is designed as a bayonet closure. Motor pump unit ( 1 ) according to claim 3, characterized in that the elastomer element ( 6 ) between the membrane unit ( 2 ) and a membrane-directed end face ( 12 ) of the connecting rod ( 4 ) or a membrane-directed stop element ( 13 ) on the connecting rod ( 4 ) is clamped. Motor pump unit ( 1 ) according to claim 3, characterized in that the membrane unit ( 2 ) an elastic membrane ( 3 ) made of an elastomeric material and a rigid membrane holder ( 7 ), for the transmission of power between the connecting rod ( 4 ) and the membrane ( 3 ) is provided and the Elastoelement ( 6 ) in a blind hole ( 11 ) in the membrane holder ( 7 ) is arranged. Motor pump unit ( 1 ) according to claim 5, characterized in that the membrane unit ( 2 ) an elastic membrane ( 3 ) made of an elastomeric material and a rigid membrane holder ( 7 ), for the transmission of power between the connecting rod ( 4 ) and the membrane ( 3 ) is provided and the coil spring radially on the outside of the membrane holder ( 7 ) and / or in a region between the membrane unit ( 2 ) and a connecting rod eye ( 14 ) at the connecting rod ( 4 ) is arranged.

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