EP0188730A2 - Diaphragm pump with a hydraulically actuated rolling membrane - Google Patents

Abstract

In the case of a diaphragm pump with a diaphragm designed as a rolling diaphragm, which separates a delivery chamber from a liquid-filled pressure chamber and is firmly clamped with its peripheral edge between a housing body and a pump cover, and with an oscillating hydraulic piston which is located in a bore in the housing body between the pressure chamber and a hydraulic reservoir is movable for membrane actuation, the rolling membrane rolls alternately on an outer roll cylinder formed by the wall of the pressure chamber and an inner roll cylinder which is formed by the circumferential surface of an axially displaceable support piston for the roll membrane, the end face of which is assigned Surface section of the rolling membrane is connected. Here, the inner roll cylinder of the support piston, which is designed as a support mushroom, merges in the rear limit position of the roll membrane with a support shoulder in the outer roll cylinder, which together with the two roll cylinders for completely mechanical support of the roll membrane, provides a completely gap-free, natural deformation and roll geometry of the roll membrane adapted support surface forms.

Description

The invention relates to a diaphragm pump with a membrane designed as a rolling diaphragm, which separates a delivery chamber from a liquid-filled pressure chamber and is firmly clamped with its peripheral edge between a housing body and a pump cover, and with an oscillating hydraulic piston, which is located in a bore of the housing body between the pressure chamber and a hydraulic reservoir for membrane actuation is displaceable, the rolling membrane alternately rolling or rolling on an outer rolling cylinder formed by the wall of the pressure chamber, which is formed by the peripheral surface of an axially displaceable support piston for the rolling membrane, the end face with the associated surface section the rolling membrane is connected.

In the known diaphragm pumps, differently shaped and supported diaphragms are used, a maximum permissible delivery pressure being able to be determined depending on the diaphragm shape and the type of support.

Flat or pre-formed plate-shaped flat membranes are used for high-pressure diaphragm pumps, the diaphragms of which are actuated exclusively hydraulically. These can either be made of plastic with an operating limit of up to approx. 350 bar delivery pressure or of metal with an application limit of up to 3000 bar delivery pressure.

In contrast to the metal membrane, the flat membrane made of plastic is the advantage a high elasticity and thus a large deflection, so that such plastic flat membranes have relatively small diameters. However, they still result in much larger pump head diameters than a piston pump with the same power. The price difference between piston pump and diaphragm pump is correspondingly large.

It is therefore desirable to use diaphragm shapes in diaphragm pumps, particularly those for high delivery pressures, which allow larger deflections and thus smaller diameters than flat diaphragms.

A diaphragm pump of the aforementioned type with a diaphragm designed as a rolling diaphragm is now known, the rolling diaphragm alternately rolling on and off an outer rolling cylinder formed by the wall of the pressure chamber and an inner rolling cylinder which is axially defined by the circumferential surface of an Pressure chamber displaceable support piston for the rolling membrane is formed, the end face of which is connected to the associated surface section of the rolling membrane.

In such a known roll membrane, a so-called liquid support for the roll membrane is provided at the transition point between the outer and inner roll cylinder. However, such a liquid support disadvantageously disregards the fact that a rolling membrane is relatively sensitive to pressure differences that occur and therefore always requires adequate support. This applies in particular to the rear limit position of the rolling diaphragm at the end of the piston suction stroke, since it is in this rear limit position, the leakage supplementation, which is brought about via the snifting valve of the pump, and possibly also ventilation or degassing, is carried out. In this state of sniffing the pump, however, the rolling diaphragm must be supported in a flawless manner or be able to put it on at a suitable point, since the sniffer valve only responds when there is a sufficient pressure difference between the hydraulic pressure chamber and the delivery chamber. However, this means that the rolling diaphragm is relatively heavily stressed at this moment if it is not properly supported. In an extreme case, a pressure difference can act on the diaphragm in its rear limiting position, which corresponds to the full delivery pressure of the pump, for example 350 bar. This can occur if, for example, when the pump is at a standstill due to slight leakage, the pressure valve in the pump work space sets the system pressure equal to the delivery pressure of the pump. For safety reasons, the roll membrane must be able to withstand this stress.

As practice has shown, however, the known fluid support is not able to adequately meet the aforementioned requirements. As a result, it has so far not been possible to use a rolling diaphragm in diaphragm pumps in which higher delivery pressures have to be mastered and in which a hydraulic diaphragm drive is advantageous in order to ensure a balanced pressure prevailing on both sides of the diaphragm.

The invention is therefore based on the object of eliminating the diaphragm pump of the generic type to design the disadvantages described in such a way that the rolling diaphragm withstands the high stresses that may occur there, caused in particular by large pressure differences, even in its rear limiting position.

This object is solved by the features of claim 1. Advantageous refinements of this are described in the further claims.

The diaphragm pump according to the invention with a hydraulically driven rolling diaphragm is also advantageously suitable for high delivery pressures, with the rolling diaphragm being properly supported in the rear limiting position; this reliably prevents damage to the roller membrane when pressure is applied to the conveyor side.

Due to the fully mechanical support of the roll membrane in its rear limit position, it is possible to supplement the small leakages occurring in the pressure chamber with the usual snifting valve, without the risk that the roll membrane will be damaged in this position due to the pressure difference then prevailing .

A completely gap-free contact surface is thus provided for the rolling membrane, which is formed by the corresponding surfaces of the pressure chamber and the support mushroom for the rolling membrane when the rolling membrane is in its rear limiting position. Such a surface naturally has no bores. This is from be of particular importance in order to prevent the roller diaphragm from contacting such bores with a prevailing pressure difference when the pump is in the sniffing state.

The invention also makes it possible to use much smaller membrane diameters. This has the advantage of an extremely inexpensive construction, since a significantly smaller space is required. This is not least due to the fact that due to the much larger deflection of a rolling membrane compared to a flat membrane, the hydraulic cylinder used for the membrane drive can also have a significantly smaller diameter, so that the area under pressure is thereby smaller. In addition, the screw forces required for the pump are significantly reduced. This also makes a significant contribution to reducing the cost of a diaphragm pump with a rolling diaphragm.

As is known, a rolling membrane is basically a stocking-shaped rubber membrane that has an extremely long service life, since it can roll up and down with great frequency without breaking. The rolling membrane, which is made of a rubber-like material, accordingly rolls alternately on the outer rolling cylinder formed by the wall of the pressure chamber and on the inner rolling cylinder which is formed by the outer peripheral surface of the axially displaceable support mushroom. This rolling up and down of the rolling membrane takes place like the movement of a stocking or a sock when putting on and taking off.

The invention makes it possible for the first time to use rolling diaphragms in diaphragm pumps in which, in particular, higher delivery pressures have to be mastered and thus a hydraulic diaphragm drive is advantageous in order to ensure that a balanced pressure prevails on both sides of the diaphragm.

In the diaphragm pump according to the invention, the configuration is such that the end faces of the support mushroom are firmly connected to the assigned surface section of the rolling diaphragm. The inner unrolling cylinder is designed in such a way that in the rear limiting position of the rolling membrane, together with the outer unrolling cylinder, it forms a completely gap-free support surface which is adapted to the natural deformation and rolling geometry of the rolling membrane.

This creates a clear position limitation or support in the rear dead center position of the rolling membrane, so that it is possible in this rear limiting position of the membrane to supplement the small leakages occurring in the pressure chamber with the usual snifting valve, without the risk that the rolling membrane is damaged in this position due to the then prevailing pressure difference.

According to the invention it is further provided that the support mushroom in the rear limiting position is at least partially immersed in a pressure chamber section of smaller diameter, which adjoins the pressure chamber section of the larger diameter forming the outer rolling cylinder to form a support shoulder for the rolling membrane.

This makes it possible in a further embodiment of the invention to arrange radially extending flow channels, which are provided in the circumferential wall of the supporting mushroom and serve to connect the pressure chamber and the snifting valve, in such a way that they are completely immersed in the pressure chamber section of smaller diameter in the rear limiting position.

The stop for limiting the rear position of the support mushroom is expediently formed by an annular shoulder in the housing body, which is provided at the end of the _' pressure chamber section of smaller diameter. In a practical embodiment of the invention, the support mushroom has a guide rod which ensures an exactly central axial movement of the support mushroom.

Due to the intended hydraulic actuation of the rolling membrane, the support mushroom or its guide rod has no mechanical connection with the hydraulic piston. This means that the support mushroom is only moved back and forth by the rolling membrane. The support mushroom, which is therefore independent of the kinematics of the hydraulic piston, fulfills two functions. On the one hand, it allows the rolling membrane to roll, which, when rolling, requires an outer roll cylinder formed by the wall of the pressure chamber and an inner roll cylinder formed by the outer circumferential surface of the support mushroom. On the other hand, the support mushroom fulfills the function of supporting the roll membrane.

Overall, therefore, the design according to the invention is made such that in the rear limiting position of the rolling membrane such an overall contour of the supporting mushroom including the pressure chamber is formed such that a gap-free area has been created and the rolling membrane is therefore only pressed against completely smooth surfaces when a pressure difference occurs and accordingly not is at risk of damage.

It has thus become possible through the invention to use hydraulically driven rolling diaphragms in diaphragm pumps, which are provided in particular for high delivery pressures, which allows a considerable reduction in the diameter of the diaphragm pump. The diameter of the rolling membrane can be of the order of magnitude Diameter of the hydraulic piston, so that the screw forces required for the diaphragm pump are much smaller. For example, reducing the diaphragm diameter to half the previous diameter results in a reduction of the screw forces to a quarter of the previous effort.

• Fig. 1 im Schnitt eine erfindungsgemäß ausgestaltete Membranpumpe mit der Rollmembran in der vorderen Begrenzungslage;
• Fig. 2 mit der Rollmembran in einer mittleren Lage und
• Fig. 3 mit der Rollmembran in der hinteren Begrenzungslage.

The invention is explained in more detail below with reference to the drawing. Show it:

• 1 shows in section an inventive diaphragm pump with the rolling diaphragm in the front limiting position;
• Fig. 2 with the rolling membrane in a middle position and
• Fig. 3 with the rolling membrane in the rear limit position.

As can be seen from the drawing, the diaphragm pump shown has a pump housing in the form of a housing body 2 which is closed at the end by a pump cover 1 and in which an oscillating hydraulic piston 3 operates as a hydraulic diaphragm drive. This can be pushed back and forth in a bore 4 of the housing body and separates a pressure chamber 5 from a hydraulic reservoir 6.

Between the housing body 2 and the pump cover 1, a rolling membrane 7 is firmly clamped with its peripheral edge, which separates the pressure chamber 5 from a delivery chamber 8 in the manner shown in the drawing. The pressure chamber 5 is completely hydraulic liquid filled, so that when the hydraulic piston 3 is pushed back and forth the rolling diaphragm 7 is actuated in a corresponding manner and acts on the delivery chamber 8 in the sense of a suction stroke or pressure stroke.

The pump cover 1 has a spring-loaded suction valve 9 and a spring-loaded pressure valve 10. These valves 9, 10 are connected via an inlet channel 11 or an outlet channel 12 to the delivery chamber 8 in such a way that the conveying medium during the suction stroke of the rolling membrane 7 to the right as shown in the drawing in the direction of arrow A via the suction valve 9 and the inlet channel 11 is sucked into the delivery chamber 8. In contrast, when the pressure stroke of the rolling membrane 7 to the left as shown in the drawing, the pumped medium is pressed out of the pump chamber 8 in a metered manner in the direction of arrow B via the outlet channel 12 and the pressure valve 10.

A support mushroom 13 is arranged axially displaceably within the pressure chamber 5 and has a guide rod 14 projecting axially backwards in the direction of the hydraulic piston 3. This is guided in an eye 15 arranged centrally in the pressure chamber 5 in such a way that an exactly central axial movement of the supporting mushroom 13 is ensured.

The support mushroom 13 is connected on its end face to the assigned surface section of the rolling membrane 7, so that the support mushroom 13 thereby follows the axial displacement movement of the rolling membrane 7.

The rolling surface required for the rolling membrane 7 is by an outer rolling cylinder and a inner roll cylinder formed. Here, the peripheral wall 16 of the pressure chamber 5 represents the outer rolling cylinder, while the inner rolling cylinder is formed by the outer peripheral surface 17 of the support mushroom 13.

As can be seen, a pressure chamber section 5 'of smaller diameter adjoins the actual pressure chamber 5 axially rearwards in the direction of the hydraulic piston 3, a support shoulder 18 for the rolling membrane 7 being formed between the two pressure sections 5, 5'. In the exemplary embodiment shown, this support shoulder 18 is concave and has a radius of curvature which corresponds to the radius of curvature of the rolling membrane 7 in its rolling region.

The diameter and the depth of the smaller pressure chamber section 5 'are held in such a way that the support mushroom 13 in the rear boundary position according to FIG. 3 is for the most part immersed in this smaller pressure chamber section 5'. Here, the front part of the support mushroom 13 protrudes only so far out of the smaller pressure chamber section 5 'that only the rounded surface section 19 of the support mushroom 13, which forms the transition between the end face and the outer peripheral surface 17 of the support mushroom 13, is located in the larger pressure chamber section 5.

This forms a completely gap-free support surface 16, 18, 19 (and possibly 17) in the rear limiting position of the rolling membrane 7 shown in FIG. 3, which is adapted to the natural deformation geometry or rolling characteristics of the rolling membrane 7 is. In the exemplary embodiment shown, this gap-free support surface is composed of the outer roll cylinder, formed by the peripheral wall 16 of the pressure chamber 5, the support shoulder 18 and the rounded surface section 19 or the inner roll cylinder 17 of the support mushroom 13 including the support mushroom end face.

An annular shoulder 20 is provided as a stop to limit the rear position of the support mushroom 13, which is formed in the housing body 2 at the axially rear end of the pressure chamber section 5 'of smaller diameter.

As can be seen, a combined gas discharge and pressure limiting valve 21 is connected to the hydraulic reservoir 6, which in turn opens via a channel 22 into the pressure chamber section 5 'of smaller diameter. For this purpose, 13 radial flow channels 26 are provided in the peripheral wall 25 of the support mushroom. These are arranged such that they are completely immersed in the pressure chamber section 5 'of smaller diameter in the rear limiting position of the rolling membrane 7 or the support mushroom 13 according to FIG. 3. This also ensures that a completely gap-free support surface is formed in the rear boundary position of the rolling membrane 7.

Furthermore, a sniffer valve 23 is also provided, which connects the hydraulic reservoir 6 via a channel 24 to the pressure chamber section 5 'of smaller diameter. As a result, in the rear limiting position of the rolling diaphragm 7, ie at the end of the suction stroke of the hydraulic piston 3, the necessary leakage supplementation from the hydraulic storage space can be made via the sniff Field valve 23 and the channel 24 take place. This channel 24 is arranged so that the connection to the hydraulic reservoir 6 via an annular groove 27 and a bore 28 in the mushroom guide rod 14 is only made when the mushroom 13 has reached the rear limit position, as shown in Fig. 3. As a result, it is only possible to supplement the pressure chamber 5 in the desired manner in this position of the support mushroom 13, which in other words means that an early leakage supplement cannot take place.

Claims (6)

1.Diaphragm pump with a membrane designed as a rolling diaphragm, which separates a delivery chamber from a liquid-filled pressure chamber and is firmly clamped with its peripheral edge between a housing body and a pump cover, and with an oscillating hydraulic piston, which is located in a bore in the housing body between the pressure chamber and a hydraulic reservoir is displaceable for membrane actuation, the rolling membrane alternately rolling or rolling on an outer rolling cylinder formed by the wall of the pressure chamber, which is formed by the peripheral surface of an axially displaceable support piston for the rolling membrane, the end face of which with the assigned surface section of the rolling membrane connected is,
characterized,
that the inner rolling cylinder (17) of the supporting piston designed as a supporting mushroom (13) in the rear limiting position of the rolling membrane (7) is supported shoulder (18) passes into the outer rolling cylinder (16), which, together with the two rolling cylinders (17, 16) for completely mechanical support of the rolling membrane (7), is a completely gap-free, adapted to the natural deformation and rolling geometry of the rolling membrane (7) Support surface (16,18,17,19) forms. 2. diaphragm pump according to claim 1,
characterized,
that the support mushroom (13) in the rear limiting position of the rolling membrane (7) is at least partially immersed in a pressure chamber section (5 ') of smaller diameter, which on the outer rolling cylinder (16) forming the pressure chamber section (5) of larger diameter to form the support shoulder (18) for the rolling membrane (7) connects. 3. diaphragm pump according to claim 1 or 2,
characterized,
that the support shoulder (18) provided in the pressure chamber (5) is concave and has a radius of curvature which corresponds to the radius of curvature of the rolling membrane (7) in its rolling region. 4. diaphragm pump according to claim 1 or 2,
characterized,
that radially extending flow channels (26) are arranged in the peripheral wall (25) of the supporting mushroom (13) so that they are completely immersed in the pressure chamber section (5 ') of smaller diameter in the rear limiting position of the rolling membrane (7). 5. diaphragm pump according to one of claims 1 to 4,
characterized,
that the stop to limit the rear position of the support mushroom (13) is formed by an annular shoulder (20) in the housing body (2). 6. diaphragm pump according to one of claims 1 to 5,
characterized ,
that the support mushroom (13) has a guide rod (14) which ensures an exactly central axial movement of the support mushroom (13).

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