DE2122239A1 - Electromagnetically driven pump - Google Patents

Description

Dr. Ing. H. Neg "thanks

Dipl. Ing. H. Hauck Dipl. Phya. W. Schmitz

8 Μϋηώ & η i 5, Moxcrtstr. 23 Tel. S380586

Societe Anonymous STOP

25 rue des Rosiers, April 29, 1971

Saint-Q.uen 93 »France Lawyer File M-1570

Electromagnetically driven pump

The invention relates to an electromagnetically driven pump

with an elastically pretensioned membrane, which the fluid to be conveyed between an inlet valve and an outlet valve displaced, an electromagnet whose armature is connected to the membrane by a connecting rod and the membrane when excited deformed of the electromagnet, and a changeover switch which can be actuated by the connecting rod at the end of the armature movement and then interrupts the power supply to the electromagnet, so that the membrane is in its rest position due to the elastic bias is movable back.

In pumps of this type, which work with a high operating speed and a small stroke, the connecting rod of the diaphragm acts immediately on the trigger of the changeover switch, and the stroke of the trigger thus limits the stroke of the connecting rod.

The invention is intended to avoid this disadvantage. In particular, the invention is based on the object of providing a pump _ ₂ _ _|

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of the type indicated at the outset, the stroke of which can be of any size. This is achieved according to the invention in that the changeover switch an actuating element which can be displaced by the connecting rod and which is elastically supported on the pump housing in this way is assigned is that it is between two stable positions, one associated with the forward stroke of the rod and one associated with the backward stroke of the rod Position, can be switched over suddenly, the switch being closed in one position and in the other position is open.

Due to the training he made according to the invention, the stroke of the pump is independent from that of the switch.

Advantageous refinements of the invention are set out in the subclaims specified. In the pump according to the invention, the connecting rod takes has the stops, the actuating element with only until the end of the movement of the armature, and acts in this way the anchor on the connecting rod as long as the stop ^ which is used to move the actuating element, the actuating, element has not yet "switched".

Based on the drawings, a preferred embodiment de * · Invention explained in more detail. Show it:

1 shows an axial section through a pump according to the invention,

Pig. 2 shows an axial section through the pump along the line 2-2

in Pig. I,!

-3-

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Figure 3 is a cross-section along line 3-3 in Pig. I or Fig. 2,

4 shows a plan view of a spring leaf bulging suddenly, which carries the contact of the switch of the pump.

The electromagnetically driven one shown in the drawings The pump has a housing 10, in the lower section of which a displacement element in the form of an elastic membrane 12 is arranged is. The outer edge 14 of the membrane 12 is braced with a block 18 by an annular body 16. The block 18 has in his In the middle, a blind hole 20 which forms a chamber 22 with the membrane 12. The chamber 22 is through lines 24 and 26 with a Inlet 28 and an outlet 30 connected. Between inlet 28 and line 24 is an inlet valve 32 and between the outlet 30 and the line 26, an outlet valve 34 is arranged.

The pump described so far is of conventional design and has an intake and exhaust stroke. In the drawing, the membrane 12 is in its rest position, i.e. at the end of an intake stroke. In Fig. 2, the normal position is shown with dashed lines, which the membrane 12 at the end of an exhaust stroke occupies.

In the upper half of FIGS. 1 and 2 the electromagnetic drive of the pump is shown. The coil of an electromagnet is designated by 40, the "skeleton" of which is formed by a U-shaped component 42, a closure plate 44 and a tubular body 46. The tubular body 46 extends in a tubular u_

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Housing 48, which forms the carrier of the coil 40. The housing 48 is closed by a cover 50, on the inside of which a disk 52 made of elastic foam is glued. In the tubular housing 48, between the disk 52 made of foam and the magnetic tube body 46, a magnetic core 54 made of soft iron is slidably disposed, which is normally pressed elastically against the disk 52 by a connecting rod 56. The upper end "of the connecting rod 56 is located on the inner surface of the armature 54, and the lower end of the connecting rod, which is formed kegeistumpfförmig, 1st in a likewise frustoconical Ausneh- f mung the membrane 12 centered. At its upper end, the connecting rod 56 a larger diameter portion 58 forming a shoulder 60 and at its lower end portion a collar 62. In this way, the connecting rod 56 is passed through the section 58 in the tubular body 46 and through the collar 62 in the wall 64 of the housing 10 led.

In the tubular body 46, coaxial to the connecting rod 56, an actuating element in the form of a sleeve 66 is slidably mounted, which has an annular collar 68 approximately in its center. The annular collar 68 slides into a section of larger diameter of the tubular body 46 and can be moved against the shoulder 70 formed in this way in the tubular body 46. At its upper portion, the sleeve 66 is provided with a radially inwardly projecting collar 72, the inner diameter of which is smaller than the diameter of the section 58 of the connecting rod 56, so that the collar 72 forms a stop against which the shoulder 60 of the section 58 of Can attack connecting rod 56 to the sleeve 66 with a downward movement of the

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tie rod 56 to take with you. At its lower section, the sleeve 66 engages via a ring 74 on the collar 62 of the connecting rod. 56 at. The axial dimensions of the components just described are such that the membrane 12 in the rest position shown in Fig. 1 elastically presses the collar 68 of the sleeve 66 via the collar 62 of the connecting rod 56 against the shoulder 70 of the tubular body 46 and between the shoulder 60 of the Connecting rod 56 and the inner collar 72 of the sleeve 66 a game A is present.

On the lower section of the sleeve 66, two rectangular windows 76 are formed, the axes of symmetry of which lie essentially in the axial direction in the sectional plane of FIG. 1. The axial length of the window is somewhat smaller than the distance between the collar 68 of the sleeve 66 and the ring 74. Rectangular lamellae 78 made of elastic metal, for example spring steel, are arranged in the windows 76. The slats 78 have a length which is slightly greater than the length of the windows 76 and a width which is slightly smaller than the width of the windows so that they can be bent inwardly into the windows, as shown in the drawing.

The middle section of the lamellae 78 is connected to an abruptly bulging spring leaf 80, which is shown in more detail with reference to FIG is described.

The spring leaf 80 has the shape of a rectangular elongated frame, which has two long sides 82. The sides 82 are connected to one another on one side by an end portion 84 of the spring leaf connected, which sits in a transverse slot 86 of a part of the housing forming insulating body. The end portion 84 is on

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one side extended by an electric tongue 87 and inwardly by a protruding portion 88, the free The end of one of the two lamellae 78 is hinged to the middle section. The opposite of the end portion 84 The end of the peder sheet 80 has a spherical contact 90. The contact 90 is seated in a recess 92 which is formed in a section of the housing 10 made of insulating material is and has a contact 94 on its inside, which with the contact 90 interacts electrically. The end section of the peder blade 80, which carries the contact 90, is inwardly through one Extended section 95 of the Pederblatts, which extends parallel to the edge 82 and is hinged to the other lamella 78 is.

The contact 94 is carried by a rod-shaped conductor 96 which, as in the pign. 2 and 3, protruding from the housing and on electrical network can be connected.

On the left-hand side of FIG. 1, the connection between the other connection terminal 98 (FIG. 3) and are in dashed lines an input of the coil 40 and the connection between the tongue 87 of the spring leaf 80 and the output of the coil are indicated schematically.

The operation of the pump is as follows:

In Fig. 1, the pump is in its rest position, which it takes after an intake stroke. The chamber 22 is normally filled with liquid and the diaphragm 12 biases the connecting rod 56 and the armature 54 upwards. The Bund 62 of -7-

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Connecting rod 56 also holds the sleeve 66 in its upper position, in which it rests against the shoulder 66 of the tubular body 46 and the spring leaf 80 assumes the position shown in Fig. 1. The band portion 84 of the spring leaf 80 is below the normal plane of the spring leaf 80 in the free state, and the contact 90 rests against the contact 94. When the supply circuit of the pump is closed, electrical current passes from the connection terminal 96 to the contact 94, the contact 90, the spring leaf 80 and the coil 40 of the electromagnet, and the circuit is closed through the terminal 98. When the electromagnet is energized in this way, the armature 94 is slidably displaced in the tubular inner portion of the coil 48. The armature engages the head 58 of the connecting rod 56, the lower end of which acts on the membrane 12 in order to expel the liquid in the chamber 22 through the outlet valve ~ *> k .

The armature 54 moves the connecting rod 56 vertically downwards (in the drawing) which progressively deforms the membrane 12. The shoulder 60 approaches the collar 72 protruding radially inward of the sleeve 66 and the sleeve 66 moves with the connecting rod 66 downwards when the play A is used up. The connecting rod 56 and the sleeve 66 then move together downward by an amount equal to the bulging of the spring leaf 80 is equivalent to. The bulging of the spring leaf 80 has the consequence that the contact 90 of the spring leaf 80 suddenly differs from that with the terminal 96 connected contact 94 is separated. The end of the exhaust stroke is hereby reached, and the membrane 12 now takes the position shown in FIG position shown with dashed lines.

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When the power supply is interrupted by disconnecting the contacts 90 and 94, the connecting rod 56 rises again, pushing the armature 54 upwards solely under the resilient action of the diaphragm 12, the liquid from the inlet 28 and the inlet valve as it moves upward 32 sucks into the chamber. Here, the outlet valve, which is provided at the end of the line 2.6 , is closed and it rests against its seat. During the upward movement of the connecting rod 56, the collar 62 of the connecting rod 56 approaches the ring 74 of the sleeve 66, and after it has covered a certain distance, it rests against the ring to move it into the position shown in FIG to move back the position shown. Shortly after the collar 62 has made contact with the ring 74, the spring 80 is "switched over" and the contact 90, which was in contact with the upper section of the recess 92, is abruptly moved against the contact 94. The end of the intake stroke is hereby reached and a new exhaust stroke begins when the interrupter provided in the supply circuit of the pump remains closed.

. As can be seen from the description above, the The pump according to the invention does not have a bistable trigger, the disadvantages of which have been described above. With the pump according to the invention rather, the magnetic impulse is retained during the entire working stroke of the piston (during the exhaust stroke).

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Claims (1)

Paier. ion »ν" J? ο
Dr. Ing. H. Νί.-ς> · ^ ·; 1 inc Dipl. Lr> £ H. ijck Dipl. Phys. VV. Melt β ^, Unch-rr. * 5. ·. * »··» -flpf ^. 75 Socilte Anonyme STOP w. ***: * rue des Rosiers, April 29, 1971 Saint-Quen 93, France Legal File M-1570 Claims Iy Electromagnetically driven pump with an elastically pretensioned membrane that displaces the fluid to be pumped between an inlet valve and an outlet valve, an electromagnet whose armature is connected to the membrane by a connecting rod and deforms the membrane when the electromagnet is excited, and a switch that at the end of the armature movement can be actuated by the connecting rod and then the power supply -the electromagnet interrupts, so that the membrane can be moved back into its rest position by the elastic bias, characterized in that the switch (80,90,9 ^) through the connecting rod (56) is assigned to a displaceable actuating element (66) which is elastically supported on the pump housing (10) in such a way that it can be suddenly switched between two stable positions, a position assigned to the forward stroke of the connecting rod and a position assigned to the backward stroke of the connecting rod, the switchover it is closed in one position and open in the other position. -10-109848 / 1303 2. Pump according to claim 1, characterized in that the actuating element from a surrounding the connecting rod (56) Sleeve (66) is made by provided on the connecting rod Stops, in particular collars (60,62), is biased into one or the other of the stable positions. 5. Pump according to claim 2, characterized in that the sleeve (66) is supported by a suddenly bulging spring leaf (80) which lies in a plane extending substantially perpendicular to the connecting rod (56) and the ends (84, 90) of which in Recesses (86,92) of the pump housing (10) sit. 4. Pump according to claim 3, characterized in that the spring leaf (80) consists of an electrically conductive material, and that one of the recesses (92) has an electrical contact (9 ^) has the switch together with the spring leaf (80) forms. 5. Pump according to claim 4, characterized in that the sleeve (66) extends through the central portion of the spring leaf (80), and that the sleeve with the spring leaf by longitudinally extending, elastic lamellae (78) are connected to one another, the are arranged on diametrically opposite sides of the sleeve (66) in such a way that they bend radially when the spring leaf (80) bulges. 109848/1303 ee rs e ι \ e