DE3102032A1 - Diaphragm pump - Google Patents

Abstract

Diaphragm pump involving a minor outlay in terms of construction, for achieving a large delivery rate at the same time as adequate delivery pressure. A diaphragm clamped between two casing halves carries an armature made of magnetic material. The diaphragm divides the casing interior into two pump chambers. At both sides of the diaphragm electromagnets are arranged, to which current is applied alternately. The inflow and outflow lines have non-return valves provided therein. Continuous back-and-forth movement of the diaphragm alternately effects filling of the pump chambers and ejection of the medium therefrom, and thus results in delivery of the fluid concerned by the diaphragm pump.

Description

Diaphragm pump

The invention relates to a diaphragm pump for pumping liquids and gaseous media.

Diaphragm pumps of the type mentioned are known.

However, they have the disadvantage of a low degree and can only process low flow rates and generate low pressure.

It is the object of the present invention to convey liquid and gaseous media to create a diaphragm pump, despite the low construction costs can achieve a large flow rate with sufficient pressure.

The task is cited in the characterizing part of claim 1 Features solved.

The invention has the advantages over the known that a significantly higher funding volume can be achieved with justifiable construction costs than this was previously possible. The pressure on the discharge side of the pump is accordingly higher than with known pumps. There is only a slight pumping noise, which is at risk of corrosion Parts of the pump are encapsulated with insulating material and are therefore the ones to be pumped Medium not exposed.

Further advantageous features of the invention emerge from the subclaims emerged.

The invention is based on an exemplary embodiment by means of a Drawing explained. The drawing shows a cut through the pump according to the invention.

The housing 1 of the pump is formed by two housing halves 5, 6. Appropriately, the two housing halves 5, 6 are identical in shape, to keep manufacturing costs down. At one point 23 ring surfaces abut the two housing halves 5, 6 together and can be glued or welded together e.g. by mirror welding. This will remove the interior of the pump hermetically sealed from the outside.

But it is also for the connection of the two housing halves 5, 6 conceivable to insert a ring seal at the point 23 and the two housing halves 5, 6 to be screwed together for later repair work inside to enable the pump.

A membrane 2 is clamped between the two housing halves 5, 6, which carries an armature 3 made of magnetic material. The membrane 2 is expediently made made of a rubber material. The armature 3 is in the embodiment in the membrane 2 injected so that the armature 3 is not accessible to the medium to be conveyed. If less aggressive media are being promoted, anchor 3 even be buttoned into the membrane 2 (not shown in the drawing). The membrane can also consist of a plastic material.

The membrane 2 divides the interior of the housing 1 into two pump chambers 7, 8. An electromagnet 13 with a winding 15 is assigned to the pump chamber 7. An electromagnet 14 with a winding 16 is assigned to the pump chamber 8. the Electromagnets 13, 14 are injected into the respective housing half 5 or 6, so that they are also not accessible to the medium to be conveyed.

A check valve 9 leads to one pump chamber 7, the is in communication with a feed line 18.

Another check valve also leads from the pump chamber 7 11 away, which is connected to a drain line 20. To the other pump chamber 8 leads a check valve 10 which is connected to an inlet line 19. A check valve 12, which is connected to a drain line, also leads away from the pump chamber 8 21 is connected.

To operate the diaphragm pump, the two electric magnets 13 and 14 alternately energized, whereby the armature 3 and thus the essential area of the membrane 2 to the electromagnet which is currently having a magnetic field 13 or 14 are drawn. If the membrane 2 is moved in the direction of the electromagnet 13, an overpressure arises in the pump chamber 7, the check valve 9 closing and the check valve 11 opens. The medium to be conveyed is via the drain line 20 pressed out of the pump chamber 7. At the same time arises in the other pump chamber 8 a negative pressure, whereby the check valve 12 closes and the check valve 10 opens, through which the medium flows into the pump chamber 8. Now moves the Membrane 2 in the direction of the electromagnet 14, then arises in the pump chamber 8 an overpressure, the check valve 10 closes, the check valve 12 opens, and the medium becomes. from the pump chamber 8 in the drain line 21 pushed out. At the same time, the check valve 9 opens, but the check valve 11 closes » whereby the now existing in the pump chamber 7 negative pressure an inflow of Medium in this pump chamber 7 causes.

By constantly moving the membrane 2 back and forth follows thus alternately filling the pump chambers 7, 8 from the supply lines 18 or 19 as well as ejection of the medium from the pump chambers 7, 8 into the discharge line 20 or 21.

The electromagnets 13, 14 can be sinusoidal, rectangular with a current or other, expedient course.

The power supply for the two electromagnets 13, 14 is one (not shown in the drawing) taken from the electronic device is known per se.

Such an electronic control or switching device can also can be accommodated in the housing 1.

Different media can be conveyed with the two pump chambers 7, 8 will. But it can also convey the same medium with both pump chambers 7, 8 are: in this case the two feed lines 18, 19 are expediently connected to a common inlet 17, the two discharge lines 20, 21 are connected to a common drain 22. The medium to be conveyed flows the diaphragm pump in the direction of an arrow 4 and leaves it in the direction of a Arrow 24 again. If the two feed lines 18, 19 over the Inlet 17 and also the two outlet lines 20, 21 via the outlet 22 merged, then the conveyed medium is almost free of disruptive pressure surges.

Claims (10)

Requirements of membrane pumps for handling liquid and gaseous media, characterized in that an armature (3) made of magnetic Material-bearing membrane (2) made of flexible material is provided, the two pump chambers (7, 8) hermetic. separates from each other, each of which is assigned an electromagnet (1314) is, and each of which has a feed line (18, 19) each with a check valve (9, 10) and a drain line (20, 21) each with a check valve (11, 12) leads away, 2. Pump according to claim 1, characterized g e k e n n z e i c h -n e t that the electromagnets (13, 14) are cast into the housing (1) of the pump. 3 pump according to claim 1 or claims 1 and 2, characterized g e k It is noted that the armature (3) is cast into the membrane (2). 4. Pump according to claim 1 or according to claims 1 and 2, characterized I do not acknowledge that the anchor buttoned into the membrane is. 5. Pump according to one or more of the preceding claims 1 to 4, characterized in that the inlet lines (18, 19) are connected to one common inlet (17) are connected. 6. Pump according to one or more of the preceding claims 1 to 4, characterized in that the drain lines (20, 21) are connected to one common drain are connected. 7. Pump according to one or more of the preceding claims, characterized It is not noted that the housing (1) consists of two identical ones Housing halves (5, 6) is assembled. 8th. . Pump according to one or more of the preceding claims, characterized It is noted that an electronic control device is located in the housing (1) is intended to control the pump. 9. Pump according to one or more of the preceding claims, characterized it is noted that the two housing halves (5, 6) with one another welded are. 10. Pump according to one or more of claims 1 to 8, characterized it is noted that the two housing halves (5, 6) are screwed together are.