DE19635458A1 - Membrane pump - Google Patents

Abstract

The pump comprises a motor-driven shaft (2) with a an eccentric connected to it, executing a reciprocating motion in the radial direction. The reciprocating motion is transmitted to the pump element (32) by a transmission element and an adjustment unit is operatable so as to change the eccentricity of the eccentric in the axial direction during operation of the pump. The drive shaft rotates an eccentric ring (24), the eccentricity of which is determined by an eccentric element (5).

Description

The invention relates to a diaphragm pump.

Diaphragm pumps basically have the advantage that the pump Penraum is completely separated from the drive room.

Diaphragm pumps, for example, have diaphragm pump elements which the membrane moves back and forth with the help of a bare piston are deformed. There are usually several such diaphragm pump elements in a diaphragm pump arranges. To drive the reciprocating pistons is For example, a swash plate provided by a rotating drive shaft is set in the wobble movement (DE 23 57 143 C2).

The piston arrangement and its direction of movement can be axial or take place radially to the rotatably mounted drive shaft. The swashplate or eccentric disc engages directly on the Piston.

The invention has for its object a simple to create built diaphragm pump, in which the stroke of the minde least one piston pump element can be changed.

To achieve this object, the invention proposes a membrane pump with the features listed in claim 1 before. Wei Further developments of the invention are the subject of dependent claims chen.

By adjusting the eccentricity of the eccentric the stroke of the individual diaphragm in the radial piston pump change pump elements in a simple way.

In particular, it can be provided that the adjusting device device can be actuated in the axial direction.

In particular, the invention proposes that the adjuster Direction for adjusting the eccentricity during operation bes of the diaphragm pump, i.e. while the drive is running shaft can be actuated. This makes it possible, even during make an adjustment during the running of the device.

In particular, the invention proposes that the drive shaft drives a ring element designed as a cam ring, whose eccentricity is determined by an eccentric element.

On the outside or a radially directed surface of this Hubringes can then attack the transmission element, so that it when the drive shaft rotates from the eccentric surface che of the cam ring is pressed outwards. The backward Movement can, for example, by a spring in the diaphragm pumps element.

In a further development it can be provided that the Cam ring a circular outer circumference or a radial ge directed surface with a circular outer circumference  and with the inside of a non-rotatable Au outer ring interacts, on the outside of which the transfer supply element of the pump element, for example with a Sliding shoe attacks.

The interaction can happen, for example, that two Bearing surfaces lie directly against each other. Very cheap but it is if there is not between the cam ring and the rotating outer ring a roller bearing or a ball bearing is arranged.

Such an arrangement has the advantage that a sliding shoe Transmission element is little worn because it is on a rotating ring, not a rotating one lies on.

The outer circumference of the outer ring also does not need to be circular, since it doesn't rotate.

In a further development of the invention it can be provided that the Adjustment device on an axially displaceable slide points, which is lying approximately in the axis of the drive shaft is arranged and rotates together with the drive shaft.

To adjust this slide, depending on the type of training For example, hydraulic pressure can be used, which the Slider, for example, in both axial directions strikes and thereby determines. It is also possible to use the To actuate slide under hydraulic pressure against a stop hit who determines the position.

In a development of the invention it can be provided that for Determine the axial position of the slide one with the Housing connected stop is provided on which an axi all face of the slide comes to rest. This one The solid stop does not turn, but can face to face  the housing can be adjusted. Of course he can at his Engagement surface with the axial end face of the slide also have a plain bearing or another bearing.

The eccentric element that the eccentricity, for example, the Hubringes adjusted, can be in a recess of the drive shaft arranged and radially displaceable. In In this case, the axially displaceable slide can be a wedge have slide element, d. H. an area that is at an angle to Axis runs and thereby with axial displacement of the Slider be a radial displacement of the eccentric element works.

Another possibility is that the eccentric ment is rotatably mounted on the drive shaft. Then can a twisting of this element to change the eccentric lead tricity.

A slide element can be provided for this rotation be that has a spline profile with a slope. The spline profile is used for a firm connection between the Slider element and the eccentric element during the slope leads to a rotation of the eccentric when moving element is effected.

Further characteristics, details and advantages result from the claims, the wording of which by reference to Content of the description is made of the following description exercise of a preferred embodiment of the invention as well based on the drawing. Here show:

Figure 1 is a schematic, greatly simplified partial longitudinal section through a diaphragm pump with a diaphragm pump element.

FIG. 2 shows a cross section through the arrangement according to FIG. 1;

Fig. 3 is a view corresponding to Figure 1 in a second embodiment.

FIG. 4 shows a representation of the second embodiment corresponding to FIG. 2;

Fig. 5 schematically shows the arrangement of the eccentric adjustment in the first embodiment at maximum stroke;

Fig. 6 is the same view with a zero stroke;

FIGS. 7 and 8 are corresponding views of the second guide die off.

In a pump housing 1 shown only hinted, a drive shaft 2 is rotatably gela with the help of bearings 3 . At the left end in FIG. 1, the drive shaft 2 protrudes from the pump housing 1 , so that the drive can take place there via an electric motor or the like, not shown. The drive shaft 2 has a stepped outer circumference and an inner bore 4 .

Approximately in the middle of its length, the drive shaft 2 contains a transverse recess in which a cross-sectionally rectangular eccentric element 5 is arranged transversely to the longitudinal axis bar. The eccentric element rests with its axial end faces on corresponding counter surfaces of the recess in the drive shaft 2 , so that it is fixed in the axial direction of the drive shaft 2 .

In the inner bore 4 of the drive shaft 2 , a slide element 6 is fixed radially but axially slidably angeord net. The slide element 6 contains at its one end in FIG. 1 left a shaft extension 7 which is mounted and guided in the inner bore 4 of the drive shaft 2 there.

At the shaft end 7 there is a piston section 8 with a circumferential groove 9 , which serves to receive an O-ring. An annular space 12 is formed between the end face 10 of the piston section facing the free end of the shaft section 7 and a corresponding shoulder surface 11 formed by an enlarged diameter, which is connected to a schematically illustrated pressure medium line 13 .

In its central region, the slide element 6 contains an elongate strip 15 , which extends obliquely to the longitudinal axis of the drive shaft 2 and has parallel side walls 16 . The bar 15 engages in a corresponding recess of the eccentric element 5 , the side walls 16 of the bar 15 lying flat against the corresponding side walls of the Leistar term recess of the eccentric element 5 . The radial position of the eccentric element 5 is thus determined by the axial position of the slide element 6 .

In the opposite in Fig. 1 left drive end of the drive shaft 2 engages with a radial clearance a cylinder element 17 which is fixed in the pump housing 1 , for example with the help of a thread and a nut ter. At the end 18 engaging in the drive shaft 2 , the slide element 6 can be supported via bearings 22 .

If hydraulic pressure is entered into the annular space 12 via the pressure medium line 13 , the slide element 6 is acted on to the right in FIG. 1 until the end face of the piston section 14 abuts the end face 20 of the element 17 via the bearing 22 . Since the element 17 is fixed relative to the housing, the element 17 thus determines the position of the slide element 6 . The end face 20 thus forms a stop which limits the axial displacement of the slide element 6 and thus defines its position. By more or less pushing the element 17 into the drive shaft 2 , the actual position of the slide 6 and thus the eccentric element 5 can therefore be changed or adjusted.

This type of adjustment is preferably used when several pumps with the same delivery rate setting are to be driven by a common motor. It is also possible, instead of hydraulic actuation, to design the bearing 22 in such a way that there is a rotary connection between the slide element 6 and the cylinder element 18 , but movement can be transmitted axially in both directions.

The eccentric element 5 , with its radial end faces 22 running parallel to one another, bears against inwardly facing counter faces 23 of a cam ring 24 . The radial position of the cam ring 24 is thus also determined by the position of the slide element 6 . The cam ring 24 has a cylindrical outer peripheral surface 25 , which is enclosed by two flanges 26 in the axial direction. One of the two flanges can be removed. The outside 25 is connected via a roller bearing 27 to the inside of an outer ring 28 , which also has a cylindrical outer surface 29 . On this outer surface 29 of the outer ring 28 is a slide shoe 30 , which is connected via a not shown Darge, radially back and forth movable transmission element with the membrane 31 of the pump element 32 in connec tion.

The mode of operation of the device can best be seen from the schematic FIG. 2. The drive shaft 2 , which deviates from the circular shape in its central region, engages in an inner opening 33 of the cam ring 24 . It lies in the area of its four corners on a total of four surfaces 34 at the inner opening 33 . As a result, it can transmit its torque to the cam ring 24 during its rotation. The radial position of the cam ring 24 is determined by the eccentric element 5 , which, as already mentioned, rests with its axial end surfaces 22 on the inner surfaces 23 of the cam ring 24 . In the example shown, the cam ring 24 is eccentric to the axis of rotation of the drive shaft 2 . Although this is non-rotatably connected to the cam ring 24 , its eccentricity is determined by the position of the eccentric element 5 .

The secured against rotation outer ring 28 makes in the ex centrically rotating movement of the cam ring 24 only an Ex center movement, so does not revolve. This eccentric movement leads to a to-and-fro movement of the sliding block 30 , where this to-and-fro movement is transmitted to the diaphragm 31 via the transmission element 35 indicated by dashed lines.

Figs. 1 and 2, therefore, provide a diaphragm pump is changed the eccentricity of the lifting ring 24 and thus the outer ring 28 in the low during operation with application who can the thus therefore also the stroke and thus the delivery rate of the pump element 32.

The different position of the cam ring 24 compared to the drive shaft 2 can best be seen by comparing FIGS. 5 and 6. Fig. 5 shows the case of Fig. 2. The slide 6 is displaced so that the outer ring 24 has the greatest possible eccentricity. In Fig. 6, the case is shown where the slide 6 is axially displaced ben that the eccentric element 5 has assumed zero eccentricity. This means that the cam ring 24 rotates centrally, so that the diaphragm pump 32 does not perform a stroke.

FIGS. 3 and 4 show a second embodiment in which a different type of adjustment is given to the eccentricity.

The drive shaft 2 is formed in its left area in a manner similar to that of the drive shaft 2 of the embodiment in FIG. 1.

In this case, the eccentric element 40 is designed in the manner of a shaft with an eccentric central part 41 . In both end regions, the eccentric element 40 is formed centrally, so that it can be mounted with the help of the bearing 3 relative to the housing 1 or with a second bearing 42 relative to the drive shaft. The eccentric element 40 is rotatably supported with respect to the drive shaft 2 , the rotation resulting in the central eccentric part 41 taking up a different angular position with respect to the drive shaft 2 .

A sliding block 44 is in full contact with the circular cylindrical outer surface 43 of the eccentric part 41 . The Ku lissenstein lies with two of its outer surfaces 45 on the inside of an opening of the lifting ring 46 .

In the inner bore 4 of the drive shaft 2 , a slide element 47 is arranged, which is axially displaceable relative to the drive shaft 2 . The slide element 47 has a section with a wedge profile, which at the same time forms a steep thread. This leads to the fact that when the slide 47 is displaced, the eccentric element 40 rotates around the axis, so that the degree of eccentricity changes.

The cam ring 46 in turn has a cylindrical outer surface 48 which, as in the previous embodiment, is operatively connected to a non-rotating outer ring 28 via a roller bearing 27 . The sliding shoe 30 then rests on the outside of the outer ring 28 .

The only one-sided stop element 17 in the embodiment of FIG. 1 is here via a screw bolt 49 with the slide element 47 in connection, so that the axial position of the wedge slide 47 rotating with the drive shaft 2 changes in both directions through the element 17 can be.

FIG. 4 shows a representation corresponding to FIG. 2 in the second embodiment.

The spline 47 in the form of a steep thread pointing to slide 47 engages in the central eccentric section 41 of the eccentric element. This lies with its cylindrical lateral surface 43 over the entire surface of the inner opening of the sliding block 44 . The sliding block 44 has two mutually parallel engagement surfaces 50 which are connected over the entire area to the corresponding counter surfaces 51 of the cam ring 46 . The sliding block 44 can therefore slide horizontally in FIG. 1 in relation to the inner opening of the cam ring 46 , but not in a direction perpendicular to it.

The torque transmission between the drive shaft 2 and the cam ring 46 takes place with strip-like projections 52 which are formed on the axial end face 53 of the drive shaft 2 facing the cam ring 46 and which engage in corresponding radial grooves of the cam ring 46 .

FIGS. 7 and 8 show the FIGS . 5 and 6 corresponding representations in the adjustment. Fig. 7 shows the position of the maximum eccentricity. Fig. 8 shows the position of the mini paint stroke, the eccentricity is arranged so that it is perpendicular to the drive direction of the associated pump element, which is to be thought in the illustration of FIGS. 7 and 8 above.

Claims (14)

1. Diaphragm pump containing

• 1.1 a rotatably mounted drive shaft ( 2 ) which can be driven by a drive motor,
• 1.2 one with this rotationally connected eccentric,
• 1.3 at least one diaphragm pump element ( 32 ) with a transmission element ( 35 ) actuating this, the
• 1.3.1 is arranged such that it is arranged approximately radially with respect to the drive shaft ( 2 ) back and forth and
• 1.3.2 is radially movable by the eccentric, and with
• 1.4 an adjusting device for adjusting the eccentricity of the eccentric.

2. Diaphragm pump according to claim 1, in which the adjustment direction can be actuated in the axial direction. 3. Diaphragm pump according to claim 1 or 2, in which the Ver adjusting device during operation of the diaphragm pump can be actuated.   4. Diaphragm pump according to one of the preceding claims, in which the drive shaft ( 2 ) rotates a cam ring ( 24 , 46 ), the eccentricity of which is determined by an eccentric element ( 5 , 41 ). 5. Diaphragm pump according to claim 4, wherein the transmission element ( 35 ) of the diaphragm pump element ( 32 ) with the outside ( 25 , 48 ) of the cam ring ( 24 , 46 ) cooperates. 6. diaphragm pump according to claim 4 or 5, wherein the lifting ring ( 24 , 46 ) has a circular outer circumference and cooperates with the inside of a non-rotatably arranged outer ring ( 28 ), on the outside of which the transmission element ( 35 ) of the diaphragm pump element ( 32 ) attacks with a sliding block ( 30 ). 7. Diaphragm pump according to claim 6, in which a roller bearing or ball bearing ( 27 ) is arranged between the hub ring ( 24 , 46 ) and the outer ring ( 28 ). 8. Diaphragm pump according to one of the preceding claims, in which the adjusting device has an axially displaceable slide ( 6 , 47 ) which is arranged approximately in the axis of the drive shaft ( 2 ) and rotates with the drive shaft ( 2 ). 9. diaphragm pump according to claim 8, in which for fixing the axial position of the slide ( 6 , 47 ) at least one stop connected to the housing ( 1 ) is provided, on which an axial end face of the slide ( 6 , 47 ) is located. 10. A diaphragm pump according to claim 8 or 9, in which hydraulic pressure is provided for sliding the slide ( 6 , 47 ). 11. Diaphragm pump according to one of claims 4 to 10, in which the eccentric element ( 5 ) is arranged in a recess of the drive shaft ( 2 ) and is formed so as to be radially displaceable. 12. Diaphragm pump according to claim 11, wherein the slide ( 6 ) has a wedge slide element. 13. Diaphragm pump according to one of claims 4 to 10, in which the eccentric element ( 40 ) is rotatably mounted on the drive shaft ( 2 ). 14. Diaphragm pump according to claim 13, in which for rotating the eccentric element ( 40 ) the slide element ( 47 ) has a spline profile with a steep thread.