EP0480192A1 - Double-diaphragm pump - Google Patents

Abstract

Double-diaphragm pump with diaphragms dividing two diaphragm chambers and connected to one another by a connecting rod (22), a control slide valve (12) with sealing elements (13), displaceable as a function of the position of the diaphragms (24), for alternately opening and covering control ducts (2, 3, 4, 5, 6) arranged in a control slide valve housing (1) for alternately admitting propellant to a propellant chamber and relieving it of this, and an actuating element (16, 17; 22, 28) coupled to the diaphragm movement and magnetically to the control slide valve. <IMAGE>

Description

The invention relates to a double diaphragm pump with diaphragms connected by a coupling rod and dividing two diaphragm chambers, a control slide which can be displaced as a function of the diaphragms and an actuating element which is dependent on the diaphragm movement.

Such a double diaphragm pump is described in German Offenlegungsschrift 33 10 131. In this double diaphragm pump, the actuating element consists of an axially displaceable actuating rod, which protrudes from the control slide housing and is arranged coaxially in the control slide. This actuating rod acts in both directions via a compression spring on the control slide, which is held in its end positions by spring-loaded detent balls until the force of the spring arranged coaxially on the actuating rod exceeds the detent force. Then the control slide, driven by spring force, moves into the opposite control position and reverses the diaphragm movement. In this way, the control slide is moved back and forth between two stable end positions.

Since the movement of the control slide is mechanically controlled by the membranes rigidly connected to one another via a coupling rod, and a snap device moves the control slide between its two end positions by utilizing potential spring energy, the disadvantage arises that the control slide has a very low pump output tends to get caught in an intermediate position and with very high pump output due to fluttering in the spring mechanism, no exact valve control is possible. Furthermore, a large number of moving individual parts are required which slide on one another and therefore require appropriate lubrication. The spring on the operating rod is heavily loaded and usually has to be made of stainless steel. Nevertheless, it has a limited service life, so that there is a relatively high repair effort. In addition, the assembly effort is relatively high.

These disadvantages are to be remedied - according to German Offenlegungsschrift 33 10 131 - by replacing the actuating rod which acts directly on the control slide via the spring with a pilot valve which is controlled by the diaphragm movement, alternately pressurizing the control slide designed as a piston with pressure medium, so that only small forces are required to operate the pilot valve, while the control slide itself is moved by means of the pressure medium.

This design has the disadvantage that a large number of sealing surfaces with corresponding friction and leakage losses are required, and that there is also a risk of a non-functioning central position, which can lead to a standstill. A minimum pressure of the propellant is also required to switch the control slide, so that operation with pressures below 2 bar is not possible, particularly in the case of small double diaphragm pumps. In this embodiment, it is necessary to make a compromise between low pressure medium losses, but the associated stiffness or, conversely, ease of movement and the associated pressure medium losses. This double diaphragm pump also places high demands on manufacturing accuracy, requires a large amount of assembly work due to the large number of individual parts, and has to be predominantly made of metal.

The invention has for its object to provide a double diaphragm pump, which consists of a few parts, does not result in significant internal frictional forces, can be operated easily from low power to maximum performance and causes the lowest possible pressure medium losses.

The solution to this problem is that in a double diaphragm pump of the type mentioned at the outset, the actuating element or the diaphragms or diaphragm plates are magnetically coupled to the control slide. This coupling can be made contactless, so that no friction occurs in this area and no sealing surfaces are required, except where the actuating element is guided into the area of the membranes.

The actuating element can be coupled to the control slide by mutually repelling single-pole magnets. Likewise, the actuating element can also be coupled to the control slide by means of oppositely polarized magnets or a magnet and a ferromagnetic part, which attract each other.

Furthermore, one magnet or ferromagnetic part can be arranged on each membrane and at least one magnet or ferromagnetic part can be arranged in the control slide.

It is particularly advantageous if at least one magnet is arranged on the actuating element and one on the control slide so that, in the opposite end positions, the same poles face each other and repel each other.

The magnets can advantageously be designed as ring magnets.

Permanent magnets are preferably used which are strong enough to exert the actuating forces and which do not require any connection to the outside.

The actuating element can consist of a rod arranged coaxially in the control slide hen. This rod can be the coupling rod itself or can consist of an axially displaceable actuating rod which extends from the control slide and extends parallel to the coupling rod.

Furthermore, two magnets can be arranged at a distance from one another on the actuating element and in the control slide with mutually facing poles of the same name if the facing poles of the same name on the actuating element and in the control slide are polarized in the same way. This tandem arrangement of the magnet pairs results in a precise, load-independent switching point with double switching force and stable end positions of the control slide, based on an axial magnetization direction.

This version is particularly suitable for relatively small reversing valves. However, if there is more space for larger magnets, radial magnetization is possible. this is cheaper since the actuating forces are greater in this case. The outer surfaces of the magnets on the actuating element have the same polarity as the inner surfaces of the magnets in the control slide.

The double diaphragm pump according to the invention can be produced particularly easily if the distances between the magnets on the actuating element and in the control slide are the same and are dimensioned with respect to their distances from housing stops such that the actuating element and the control slide strike against opposite housing stops and when the actuating element is actuated according to a predetermined one Reverse the actuation path in the opposite position.

The switching forces at the closest approximation can be significantly increased if three magnets are arranged at a distance from each other on the actuating element and in the control slide with poles of the same name facing each other and the poles facing each other in the end positions on the actuating element and in the control slide are each of the same name. The distances between the magnets on the actuating element and in the control slide can be the same. With regard to their distance from the housing stops, the magnets can be arranged such that the actuating element and the control slide abut opposite housing attachments and two pairs of magnets each lie in a plane perpendicular to the axis of the actuating element, so that when the actuating element is actuated in a predetermined actuation path jump around the opposite end position in opposite directions. With this arrangement, there is a better distribution of force over the entire switching path of the control slide and a power reserve even when the drive air is contaminated. The attractive interaction of the central magnets on the actuating element and in the control slide with external magnets in the end positions results in a very stable, vibration-proof end position of the control slide and the actuating element.

Three radially magnetized magnets can also be arranged at a distance from one another on the actuating element and in the control slide. In this case, the outer magnets are polarized in the same way and face each other with the same poles, while the middle magnets are polarized in opposite directions but also face each other with the same poles. In the end positions, adjacent magnets on the actuating element and in the control slide are then polarized in opposite directions and attract each other, while the magnets on the actuating element and in the control slide, which are opposite each other, repel each other. In the middle position, in which all three radially magnetized magnet pairs face each other, poles of the same name face each other with each magnet pair, so that in this position the actuating element and the control slide suddenly change over to the opposite end position.

The ring-shaped permanent magnets arranged on the actuating rod moved by the diaphragms pass under the ring-shaped permanent magnets arranged in the concentric control slide and repel them after exceeding the point of greatest proximity in the opposite direction, so that the control slide moves suddenly into its opposite working position. The control spool and the actuating rod each require only two moving sealing surfaces and only one closely tolerated counter surface for the control spool. Friction only occurs on these four sealing surfaces. Apart from the control spool and the operating rod, there are no moving parts; in addition, there is no friction between the actuating rod and the control slide, since these slide into one another without contact. Furthermore, there are no pressure medium losses and no pressure medium profile as in a control slide controlled by a pilot valve, and the changeover force has a constant variable that is independent of the pressure of the pressure medium.

A pressure down to 0.3 bar is sufficient to operate the double diaphragm pump if the pressure medium consists of compressed air. The double diaphragm pump starts very easily and has a significantly higher efficiency than pilot valve controlled double diaphragm pumps, especially in the important part-load range.

The double diaphragm pump according to the invention is also less susceptible to contamination, can work without lubrication and fatigue and accordingly has reduced wear.

Since the end positions of the control spool correspond to stable end positions of the magnets, magnetic end position damping results with a corresponding reduction in the switching noises.

The use of mutually repelling permanent magnets ensures absolutely dead center freedom and constant self-centering of the control spool with very low radial forces. The spool floats on its two seals, so to speak.

The control slide and the actuating rod can be produced in a particularly simple manner if they consist of plastic and the magnets and other metal parts are encapsulated with plastic. This manufacturing method requires practically no post-processing. The control spool housing can also be manufactured as a plastic injection molded part. so that the double diaphragm pump according to the invention consists in its essential, in particular the moving parts, of plastic and is metal-free in this respect, which is particularly important for use in the semiconductor industry.

• Fig. 1 eine ausschnittsweise, schnittbildliche Darstellung einer Doppelmembranpumpe mit Koppelstange und Betätigungselement für den Steuerschieber,
• Fig. 2 eine entsprechende ausschnittweise, schnittbildliche Darstellung mit einer Koppelstange als Betätigungselement,
• Fig. 3 den Steuerschieber nach Fig. 1, jedoch mit anders magnetisierten Magneten,
• Fig. 4 eine Ventilsteuerung mit Stirnmagneten am Steuerschieber,
• Fig. 5 eine Doppelmembranpumpe entsprechend Fig. 1, jedoch mit je drei Magneten auf dem Betätigungselement und dem Steuerschieber.

The invention is explained below with reference to two exemplary embodiments shown in the drawing. The drawing shows:

• 1 is a partial, sectional view of a double diaphragm pump with a coupling rod and actuating element for the control slide,
• 2 is a corresponding detail, sectional view with a coupling rod as an actuating element,
• 3 shows the control slide according to FIG. 1, but with differently magnetized magnets,
• 4 shows a valve control with face magnets on the control slide,
• Fig. 5 shows a double diaphragm pump according to Fig. 1, but with three magnets on the actuating element and the control slide.

A control slide housing 1 with control channels 2, 3, 4, 5, 6 is shown in FIG. 1 by a double diaphragm pump. These control channels lead into a reversing block 9. The control channel 2 is connected to a pressure source, the control channel 3 with a propellant chamber, not shown, the control channel 5 with the other propellant chamber, not shown, the control channel 4 with a propellant outlet and the control channel 6 also with a propellant outlet . Compressed air is usually used as the blowing agent. The control channels 2, 3, 4, 5, 6 are sealed to one another and to the outside by means of O-ring seals and fixed in the reversing block 9 by means of snap rings 8. Furthermore, there are 1 further O-ring in the lid areas of the control slide housing, which acts as a damping element for the reciprocating control slide 12. The O-rings 10 and the end faces 21 each form stop faces.

A control slide 12 is arranged axially displaceably in the housing 1. Radially projecting closure members 13 with sliding seals 14 are arranged in the end regions of the control slide 12.

In the position shown in FIG. 1, there is a connection to the pressure medium supply via the channels 5, 2 for one propellant chamber and a connection to a pressure medium relief via the channels 3, 4 for the other propellant chamber. If the control slide 12 moves to the left, reversely acted upon or relieved of the propellant chambers. The control slide 12 is made of plastic and has annular permanent magnets 15 which are encapsulated with plastic. The ring magnets 15 are spaced from each other so that their poles of the same name are adjacent, for example north poles on the left and south poles on the right.

In the control valve housing 1, an actuating rod 16 with end pins 17 of smaller diameter is also axially displaceable and guided in a sealed manner by means of sliding seals 11. Shoulders 19 on the actuating rod 16, in conjunction with corresponding end faces 20 in the cover area of the control slide housing 1, form stop faces for the movement of the actuating rod 16.

The actuating rod 16 consists of a plastic injection molded part, in which ring magnets 18 are also embedded. These ring magnets 18 are arranged at the same distance as the ring magnets 15 and also face each other with poles of the same name, in the same way as the ring magnets 15, i.e. North poles on the left and south poles on the right.

In the position shown, all magnets attract each other equally. This has the consequence that the control slide 12 is in a stable end position.

The axial residual force in the end positions can be influenced by changing the axial distance between the two ring magnet pairs while maintaining the paths for the control slide and the actuating rod. If the distance is reduced, there is an attractive resulting force between the control slide and the actuating rod, and if the distance is enlarged, a repulsive force results. These can either be used to secure the end positions (repulsive) or as braking force for reversing (attractive).

The tax remains in the stable end position slide 12 and the actuating rod 16 until the actuating rod 16 is shifted to the right and the ring magnets 15, 18 come to cover. A slight further movement of the actuating rod to the right is then sufficient to bring the rectified poles of the ring magnets 15, 16 into effect in such a way that the control slide 12 suddenly flips to the left and the actuating rod 16 to the right in order to reach the opposite stable end position .

In the embodiment shown in Fig. 2, the spool housing 1 with the spool 12 are constructed in the same way as in Fig. 1, so that the same reference numerals apply. The coupling rod 22 serves here as an actuating rod. Accordingly, the control slide housing 1 and the control slide 12 are arranged coaxially to the coupling rod 22. The coupling rod 22 is also made of plastic. Ring magnets 18 are accordingly encapsulated with plastic as in FIG. 1.

Overmolded sleeves 28 are arranged in the end regions of the coupling rod 22, which are used to fasten one membrane 25 each by means of an embedded membrane core 24. In this case, the outer surfaces 26 of the control slide housing 1 form stop surfaces for inner surfaces 27 of the diaphragms 25; they therefore serve as a stroke limitation. If the left diaphragm 25 moves with the coupling rod 22 to the right, the control slide 12 remains in the position shown until the ring magnets 18 reach the area of the ring magnets 15. At this moment, the repulsive effect of the ring magnets 15 and 18 causes the control slide 12 to jump suddenly to the left. As already described, a reversal of movement is hereby initiated. The process is thus repeated at the end of the path of the coupling rod 22.

If a contactless take of the control slide 12 by the actuating rod 16 or the coupling rod 22 is sufficient, an opposite movement of the control slide 12 and the actuating rod 16 or the coupling rod 22 can be achieved by arranging a ring magnet in the control slide 12 and a ferromagnetic part in the actuating rod 16 or the coupling rod 22 reach. Likewise, a further ring magnet can be arranged in the actuating rod 16 or the coupling rod 22 if its polarity is opposite to that of the ring magnet in the control slide 12.

3 corresponds to the embodiment of FIG. 1, but with radially magnetized inner and outer magnets. This version is particularly suitable for larger control valves, since, based on the same magnetic mass, the actuating force is higher here than with axial magnetization.

The reversing of the control slide can also take place according to FIG. 4 by correspondingly strong axially acting end magnets 30 at the ends of the control slide 12, which interact directly with a ferromagnetic membrane core or membrane plate 25 and trigger the reversal when tightening a membrane. The actuating rod is then also omitted. The side wall of the spool housing is then as thin as possible.

In the embodiment of FIG. 4, the coupling rod 22 is also provided with two seals 29 on both sides of the control channel 2. The course of the control channel 2 allows cooling of the coupling rod, which is preferably guided in a plastic block 9.

In the embodiment of FIG. 5, three magnets 15, 31; 18, 32 at a distance from one another on the actuating element 16, 17 and in the control slide 12. The magnets 15, 31 in the control slide 12 and the magnets 18, 32 on the actuating element 16, 17 are arranged so that the poles of the same name face each other.

The distances between the magnets 15, 31 in the control slide 12 and the magnets 18, 32 on the actuating element 16, 17 are each the same. The magnets 15, 31 are arranged with respect to their distances from the housing stops 10 so that the actuating element 16, 17 and the control slide 12 bear against opposite housing stops 10, two pairs of magnets 15, 32; 31, 18 lie in a plane perpendicular to the axis of the actuating element 16, 17 and, when the actuating element 16, 17 is actuated, jump in opposite directions into the opposite end position after a predetermined actuation path.

The magnets 15, 31; 18, 32 can also be radially magnetized, as shown in FIG. 3. In this case, the middle magnets 31, 32 are polarized in opposite directions to the outer magnets 15, 18, so that in the end positions magnets 15, 32 and 31, 18 with opposite polarity lie opposite each other and thereby define a stable end position, while switching over in the middle position the magnets 15, 18, 31, 32 and again 15, 18 are opposite each other, poles of the same name face each other and cause an immediate change in the opposite end position.

Claims (19)

1. Double diaphragm pump with two mem. Connected by a coupling rod diaphragms dividing the combustion chamber, a control slide which can be displaced as a function of the membranes and an actuating element which is dependent on the membrane movement, characterized in that the actuating element (16, 17; 22, 28) is magnetically coupled to the control slide (12). 2. Double diaphragm pump according to claim 1, characterized in that the actuating element (16, 17; 22, 28) is coupled to the control slide (12) by mutually repelling, equipolar magnets (15, 18). 3. Double diaphragm pump according to claim 1, characterized in that the actuating element (16, 17; 22, 28) with the control slide (12) by mutually attracting, oppositely polarized magnets (15, 18) or a magnet and a ferromagnetic part is coupled . 4. Double diaphragm pump according to one of claims 1 to 3, characterized in that each have a magnet (15, 18) or a ferromagnetic part on each membrane (24) and at least one magnet (15, 18) or ferromagnetic part on the control slide (12th ) is arranged. 5. Double diaphragm pump according to one or more of claims 1 to 4, characterized by the use of permanent magnets (15, 18). 6. Double diaphragm pump according to one or more of claims 1 to 5, characterized in that the actuating element consists of a rod (16, 22) arranged coaxially in the control slide (12). 7. Double diaphragm pump according to claim 6, characterized in that the coupling rod (22) is arranged coaxially in the control slide (12). 8. Double diaphragm pump according to claim 6, characterized in that the control slide (12) is arranged parallel to the coupling rod (22) and the actuating rod (16, 17) protrudes axially displaceably from the control slide housing (1). 9. Double diaphragm pump according to one of claims 6 to 8, characterized in that on the actuating element (16, 17; 22, 28) and on the control slide (12) at least one magnet (15, 18) is arranged, the same poles in the opposite End positions are opposite to each other. 10. Double diaphragm pump according to claim 9, characterized in that the magnets (15, 18) are designed as ring magnets. 11. Double diaphragm pump according to claim 9 or 10, characterized in that two magnets (15, 18) are arranged at a distance from each other on the actuating element (16, 17; 22, 28) and in the control slide (12) facing poles of the same name and the opposite poles of the same name on the actuating element (16, 17; 22, 28) and in the control slide (12) are polarized in opposite directions. 12. Double diaphragm pump according to claim 11, characterized in that the distances between the magnets (15, 18) on the actuating element (16, 17; 22, 28) and in the control slide (12) are the same and with respect to their distances from the housing stops (10, 20th , 26) are dimensioned such that the actuating element (16, 17; 22, 28) and the control slide (12) bear against opposite housing stops (10, 20, 26) and when the actuating element (16, 17; 22, 28 ) jump in opposite directions after a given actuation path. 13. Double diaphragm pump according to one or more of claims 1 to 12, characterized in that the control slide (12) and / or the actuating element (16, 17; 22, 28) consist of plastic. 14. Double diaphragm pump according to claim 13, characterized in that the magnets (15, 18) and / or the ferromagnetic material are extrusion-coated with plastic. 15. Double diaphragm pump with a coupling rod with interconnected, two membrane chambers dividing membranes and a slider depending on the diaphragm control slide, characterized in that the control slide (12) is magnetically coupled to the diaphragms (24) or diaphragm plates (25). 16. Double diaphragm pump according to claim 15, characterized in that the control slide (12) with face magnets (30) and the membranes (24) are provided with a ferromagnetic core. 17. Double diaphragm pump according to claim 9 or 10, characterized in that three axially magnetized magnets (15, 31; 18, 32) are arranged at a distance from each other on the actuating element (16, 17) and in the control slide (12) with mutually facing poles of the same name and the poles facing each other in the end positions on the actuating element and in the control slide are each of the same name. 18. Double diaphragm pump according to claim 9 or 10, characterized in that three radially magnetized magnets (15, 31; 18, 32) are arranged at a distance from one another on the actuating element (16, 17) and in the control slide (12), the outer magnets (15; 18) are each of the same name and face each other with the same poles, while the middle magnets (31; 32) have the opposite polarity, but also face each other with the same poles, and the magnets (15, 32 and 31, 18) are polarized in opposite directions on the actuating element and in the control slide. 19. Double diaphragm pump according to claim 17 or 18, characterized in that the distances between the magnets (15, 31; 18, 32) on the actuating element (16, 17) and in the control slide (12) are the same, the magnets with respect to their distances from the housing stops (10) are arranged so that the actuating element and the control slide bear against opposite housing stops (10), two pairs of magnets (15, 32; 31, 18) each lying in a plane perpendicular to the axis of the actuating element and the actuating element and the control slide an operation of the actuating element after a predetermined actuation path in the opposite end position.

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