DE102004005403A1 - Drive shaft connection for eccentric worm pump has disk on end of drive shaft with four small diameter pegs engaging in large diameter holes in disk on end of worm - Google Patents

Abstract

The worm rotor (5) turns in a profiled stator (3) made of an elastomer to define pumping chambers (4). The end of the rotor may move laterally with respect to the end of the drive shaft (6). The drive shaft runs in taper roller bearings (9) and passes through a seal (15). The shaft coupling (12) consists of a disk (13) on the end of the drive shaft with four small diameter pegs (17) engaging in large diameter holes (18) in a disk on the end of the worm rotor (14).

Description

The The invention relates to an eccentric screw pump with a drive, with a pump housing with a pump stator disposed therein, with one inside the surrounded by the stator pump chamber eccentrically rotating coil as a rotor and with a connecting element for torque transmission from a drive shaft of the motor to the rotor.

The The invention further relates to a shaft coupling for an eccentric screw pump with the above features.

Such an eccentric screw pump is known for example from Swiss Patent No. 439982. The CH 439982 describes a slurry pump as an eccentric screw pump in which the rotor, which moves eccentrically in the stator, is connected by means of a propeller shaft with a fixedly mounted drive shaft. The propeller shaft is connected on the one hand via a joint with the rotor, on the other hand via another joint with a ball bearing fixedly mounted drive shaft. The propeller shaft extends in a provided between a bearing housing and a pump housing suction housing. This results in a considerable design length of the eccentric screw pump, which proves to be disadvantageous in some applications.

A Eccentric screw pump of the type mentioned is, for example Also known from German Utility Model no. 1923821. There is the rotor over a universal joint, located in an anteroom on the pressure side of the Pump is connected to a drive shaft. Such a universal joint is not weary and maintenance free.

From the DE 19617213 C1 is known an eccentric screw pump with a so-called bending rod connection between the rotor and the drive. Although such flexural link joints, where the inherent elasticity of the flexure bar follows the eccentric motion, are wear and maintenance free, they also require a large distance between the shaft end of the drive and the rotor of the pump so as not to make the deflection angle too great. This results in a considerable length.

Of the Invention is therefore the object of an eccentric screw pump as well as a clutch for to provide an eccentric screw pump, the previously described Avoid disadvantages.

The Task is first solved by an eccentric screw pump of the type mentioned, the is characterized in that the connecting member as a disc clutch is formed, the at least one driven and a driving clutch disc comprises, wherein at least one clutch disc at least one driver element that has a transmission causes the output from the engine torque, wherein the driver element in the other disc is guided so that the driven Clutch disc an orbital movement about the longitudinal axis of the pump chamber or of the stator.

The Task is still solved through a shaft coupling for a Eccentric screw pump, which is characterized in that this comprises at least two clutch plates, one of which is driven as Clutch disc and the other designed as a driving clutch disc is, wherein at least one clutch disc at least one driver element having a transmission of the caused by the engine torque, wherein the driver element in the other disc is guided so that the driven clutch disc an orbital movement with respect to Can perform rotation axis of the driving clutch disc.

According to the invention, the transmission the torque of a rigid output or drive shaft an eccentrically rotating helix through an extremely small-sized, realized little space consuming disc clutch, the clutch is formed so that the clutch discs to each other a relative movement perform, that of eccentricity of the rotor or a multiple thereof and superimposed on the rotational movement. With the construction according to the invention is a considerable reduction in the overall length of the eccentric screw pump achieved.

Preferably are several driver elements provided as driving pins or driving pins are formed and in holes of each grasp other clutch disc, wherein the diameter of the holes is larger as the diameter of the driving pins, so that the driving pins transmit the torque of the drive to the clutch disc with holes, wherein each driving pin on the wall of its associated hole along and thus transmits at least a portion of the torque. to Avoidance of frictional resistance would it be conceivable if the driving pins in each case about a rotatable axis would be stored.

Alternatively, it would be possible, for example, on the driving pulley to provide each rotatable about an axis gears or pinion, in the on roll the holes provided with the other disc with internal teeth in the manner of a planetary gear.

at the preferred embodiment the eccentric screw pump according to the invention is provided that the holes are arranged in a clutch disc on a bolt circle and that the driving pins of the other clutch disc accordingly are arranged. It is of course also possible that the holes and the drive pins each on several concentric with each other arranged hole circles are arranged.

Of the Diameter of the holes is expediently about twice the eccentricity of the rotor greater than the diameter of the driving pins.

at the preferred variant of the eccentric screw pump according to the invention an even number of holes and driving pins is provided, each at equal intervals over the Scope of the clutch discs are distributed.

The Clutch discs can each having mutually facing support surfaces, which abut against each other, so that over against each other supporting Clutch discs largely the axial force of the rotor in the direction transferred to the drive becomes. The diameter of the end face of the driving pulley suitably corresponds that of the driven disk plus twice the eccentricity.

The Invention will be described below with reference to one of the drawings embodiment explained become.

It demonstrate:

1 a partial longitudinal section through the eccentric screw pump,

2 a side view of the shaft coupling, partially in section,

3 - 5 schematic views of the shaft coupling from the side of the rotor connection,

6 a section through the driving clutch disc and

7 a section through the driven clutch disc.

1 shows the eccentric screw pump 1 according to the invention in section, wherein the drive for reasons of simplicity is not shown. The eccentric screw pump 1 includes a pump housing 2 , one in the pump housing 2 arranged stator 3 from an elastomeric body containing a pumping chamber 4 encloses, and a rotor 5 formed as a metal helix and eccentrically within the stator 3 is stored. The conveying process of the eccentric screw pump 1 is based on the rotation of the rotor in a known manner 5 in the stator 3 made of elastomer, wherein the stator 3 the double pitch of the helical rotor 5 and wherein the rotor 5 in addition to its own rotation, a synchronous orbit around the imaginary axis of the stator 3 takes place. The drive of the rotor 5 follows over with 6 designated drive shaft, which is within a shaft housing 7 in a bearing block 8th about two with 9 designated roller bearing is held.

The drive shaft 6 can be inside the bearing block 8th perform only a rotational movement about the imaginary longitudinal axis.

Between the shaft housing 7 and the pump housing 2 on the suction side or inlet side of the eccentric screw pump is a flowed through by the medium to be pumped intermediate housing 10 provided with an inlet pipe 11 is provided to which, for example, a conveyor line is flanged.

The intermediate housing is due to the design of the shaft coupling according to the invention 12 relatively squat trained. The shaft coupling 12 includes a driving clutch disc 13 and a driven clutch disc 14 , where the driving clutch disc 13 rigid with the drive shaft 6 connected is. The seal of the shaft housing 7 opposite the intermediate housing 10 via a with 15 designated shaft seal. Both the driving clutch disc 13 as well as the driven clutch disc 14 are formed as circular discs, extending over the support surfaces 16 support each other. The rotor 5 the eccentric screw pump 1 generated in the operation of the same axial thrust force acting in the direction of the engine, not shown. This axial force is transmitted via the support surfaces 16 and over the drive shaft 6 on the bearing block 8th transmitted and recorded by this.

The driving clutch disc 13 is, as already mentioned, rotationally fixed to the drive shaft 6 whereas the driven clutch disc 14 rotatably with the rotor 5 connected is. The driving clutch disc 13 is with driving pins 17 provided in holes 18 the driven clutch disc 15 intervene or enforce this. Both the driving pins and the holes are each on a bolt circle of the respective clutch disc 13 . 14 arranged, where the diameter of the holes 18 larger than that of the driving pins 17 is.

How this particular the 3 to 5 it can be seen in the described embodiment in the driven clutch disc 14 four holes provided in the four over the circumference of the driving clutch disc 13 distributed arranged driving pins 17 intervention. It will be apparent to those skilled in the art that both the driving and the driven clutch disc 13 . 14 each with holes 18 and / or driving pins 17 can be provided. The diameter of the holes 18 is about twice the eccentricity of the rotor 5 with respect to the stator 3 larger than the diameter of the driving pins 17 , The torque of the drive shaft 6 is about the driving pins 17 the driving clutch disc 13 as well as over the inner wall of the holes 18 the driven clutch disc 14 transferred, with the driving pins 17 on the inner wall of the holes 18 Walk along when the driving clutch disc 14 makes a rotational movement. Because of this, there is an orbital motion of the driven clutch disc 14 with respect to the imaginary axis of the stator 3 possible. The rotational movement of the drive and the orbital motion of the rotor 5 overlap due to the relative mobility of the driving clutch disc 13 and the driven clutch disc 14 to each other. The relative movement of the clutch discs 13 . 14 to each other corresponds to the double eccentricity of the rotor 5 with respect to the stator 3 and is therefore relatively low.

It makes sense the number of driving pins 17 and holes 18 as high as possible, so that the transmitted torque as evenly as possible over the circumference of the clutch discs 13 . 14 is distributed to the surface pressure between the inner wall of the holes 18 and the wandering on this driving pins 17 keep as low as possible.

1

Cavity Pump

2

pump housing

3

stator

4

pump chamber

5

rotor

6

drive shaft

7

shaft housing

8th

bearing block

9

roller bearing

10

intermediate housing

11

flowguide

12

shaft coupling

13

driving clutch disc

14

driven clutch disc

15

shaft seal

16

support surfaces

17

driving pins

18

holes

Claims (12)

Eccentric screw pump ( 1 ) with a drive, with a pump housing ( 2 ), with a stator ( 3 ), with one inside of the stator ( 3 ) surrounded pump chamber ( 4 ) eccentrically rotating helix as a rotor ( 5 ), with a connecting member for transmitting torque from a drive shaft ( 6 ) of the drive on the rotor ( 5 ), characterized in that the connecting member is formed as a disc clutch, the at least one driven and a driving clutch disc ( 13 . 14 ), wherein at least one clutch disc ( 13 . 14 ) has at least one driver element which causes a transmission of the torque output by the drive, wherein the driver element in the respective other clutch disc ( 13 . 14 ) is guided so that the driven clutch disc ( 14 ) an orbital movement about the longitudinal axis of the pump chamber ( 4 ). Eccentric screw pump according to claim 1, characterized in that the driver element as entrainment pin ( 17 ) or driving pin is formed in a hole ( 18 ) of the respective other clutch disc ( 13 . 14 ), wherein the diameter of the hole is larger than the diameter of the driving pin ( 17 ). Eccentric screw pump according to one of claims 1 or 2, characterized in that a plurality of driving pins ( 17 ) and associated holes ( 18 ) are provided that the holes ( 18 ) in the one clutch disc ( 14 ) are arranged on a bolt circle and that the driving pins ( 17 ) of the other clutch disc ( 13 ) are arranged accordingly. Eccentric screw pump according to one of claims 1 to 3, characterized in that the diameter of the holes ( 18 ) by twice the eccentricity of the rotor ( 5 ) is greater than the diameter of the driving pins ( 17 ). Eccentric screw pump according to one of claims 1 to 4, characterized in that an even number of holes ( 18 ) and driving pins ( 17 ) equidistant over the circumference of the clutch discs ( 13 . 14 ) are arranged distributed. Eccentric screw pump according to one of claims 1 to 5, characterized in that the clutch discs ( 13 . 14 ) each mutually facing support surfaces ( 16 ) which abut against each other. Shaft coupling for an eccentric screw pump, comprising at least two clutch discs ( 13 . 14 ), one of which is a driven clutch disc ( 14 ) and the other is designed as a driving clutch disc, wherein at least one clutch disc ( 13 . 14 ) has at least one driver element which causes a transmission of the torque output by a drive, wherein the driver element is guided in the respective other clutch disc so that the driven clutch disc ( 14 ) an orbital movement with respect to the axis of rotation of the driving clutch disc ( 13 ). Shaft coupling according to claim 7, characterized in that a plurality of driver elements are provided, that the driver elements as driving pins ( 17 ) or driving pins are formed in holes ( 18 ) of the respective other clutch disc ( 13 . 14 ), whereby the diameter of the holes ( 18 ) is greater than the diameter of the driving pins ( 17 ). Shaft coupling according to one of claims 7 or 8, characterized in that the holes ( 18 ) in the one clutch disc ( 13 . 14 ) are arranged on a lock circle and that the driving pins ( 17 ) of the other clutch disc ( 13 . 14 ) are arranged accordingly. Shaft coupling according to one of claims 7 to 9, characterized in that the diameter of the holes ( 18 ) by twice the radius of the orbital movement of the driven clutch disc ( 14 ) is greater than the diameter of the driving pins ( 17 ). Shaft coupling according to one of claims 7 to 10, characterized in that an even number of holes ( 18 ) and driving pins ( 17 ) equidistant over the circumference of the clutch discs ( 13 . 14 ) are arranged distributed. Shaft coupling according to one of claims 7 to 11, characterized in that the clutch discs ( 13 . 14 ) each having mutually facing support surfaces which bear against each other.