DE615603C - Electromagnetically driven diaphragm pump - Google Patents

Description

Electromagnetically Driven Diaphragm Pump The invention relates to an electromagnetically driven diaphragm pump. It is known in diaphragm pumps radially arranged pressure pieces are to be provided for centering the movable armature, which have spherical surfaces on the one hand against a shoulder of a cylindrical one Pole piece or the like and on the other hand against the armature acting on the membrane place.

According to the invention, the anchor has to achieve an even pull When the magnet coil is energized, in its center there is a recess on the magnet core facing side. The cylindrical pole piece has an annular step to Guiding the anchor on its circumference, the gradation and the recess in such a way are arranged to each other that the core enters the recess before the anchor has ended its path when passing its outer edge on the gradation.

The movement of the anchor lets the core into the recess of the anchor enter. As a result, the pull exerted by the flux is mainly in the gap between the flat end of the core and the bottom of the recess. This pull is essentially the same as that originally at the outer edge of the anchor and the ruling course at the edge of the depression. In this way it becomes after of the invention, the fil> -like strong increase in tension that occurs with the reduction of the air gap an electromagnet is connected, avoided.

In the drawing, the subject of the invention is for example shown; They show: FIG. r a central longitudinal section of a fuel pump according to FIG Invention for a motor vehicle, Fig. A is a section along line 1-J of Fig. T and FIG. 3 shows a section along line 3-q. from Fig. r.

In the illustrated embodiment of a gasoline pump, an electromagnet is used, the winding of which sits on a hollow cylindrical iron core b. It is surrounded by a hollow cylindrical iron pole piece c. At the open end of the pole piece is a disc-shaped armature d, which will be described in more detail later. A contact breaker sits at the closed end e of the cylindrical pole piece. It consists partly of a toggle lever device in order to effect rapid actuation of the movable contact member. In the illustrated embodiment, the device consists of a pair of levers. One lever has two rigidly connected side parts f, F and the other two rigidly connected side parts g, ä, which lie between the parts f, f. The two levers are hinged at one end at h, at their other ends they are connected by means of a helical spring. The lever formed by the depth f, f has a contact piece j which can cooperate with another contact piece k of a leaf spring l. The contact pieces j, k control the circuit in which, as usual, the winding a of the electromagnet is located. The lever formed by parts g, g is connected to a bumper nv. The rod goes through core b and is attached to anchor d. In the position shown in Fig. I, the parts j, k are in contact, and the circuit is closed.

When the parts g are moved to the left by the rod m, the spring i is tensioned first. If the parts g are on the other side of the parts f, the latter are moved to the right by the aforementioned spring, and the contacts j, k are separated. The circuit is interrupted. If the rod m moves to the right, the parts g move again with respect to the parts f and tension the spring until a certain position is exceeded. Then the spring brings the parts back into the starting position and closes the circuit again. The contact breaker can be encapsulated by means of a housing.

At the open end of the hollow cylindrical pole piece c sits a flange o, to which a hollow cylinder p is attached, which accommodates the inlet valve q and the outlet valve r . One side of the cylinder p- is designed so that a pump chamber s is formed. The chamber s is bounded on one side by a wall t and on the other side by an elastic membrane u, which separates the disc-shaped armature d from the pump chamber. The membrane is made of an impermeable, flexible, thin material and is attached to the disc-shaped armature by a plate 13 of the rod m. On the opposite side of the wall t of the pump chamber there is a chamber v in the hollow cylinder p which is closed by a detachable cover w. Gasoline enters the chamber v through an inlet port 2. Before it can enter the inlet valve q, it must pass through a filter y. After passing through the inlet valve, which is pressed onto its seat by a spring z, the gasoline flows through an opening 2 in the wall t into the pump chamber. The gasoline goes out of the pump chamber through the opening and from there through the outlet valve r to the outlet pipe 3. The adjustment of the valve r is made by a snap ring q. limited, which is attached to the part 5 that carries the valve r.

In order to be as uniform as possible on the armature d when the magnet is excited To exert traction is a shoulder 7 on the inside of the open end of the cylindrical Pole pieces c formed to concentrate the flux on the adjacent edge of the anchor. In the middle of the anchor is a flat recess 8 for receiving the adjacent End of the core b formed. First, the flux is in the air gaps between the Outer edge of the armature and the shoulder of the surrounding pole piece as well as through the Edge of the core and the edge of the recess of the anchor concentrated. On it goes the anchor beyond the end of the core, and eventually the pull becomes main by the flux in the air gap between the flat end of the core and the sole of the aforementioned recess exercised. This design of the parts makes it possible to avoid the usual steep increase in the train, which is a consequence of the downsizing of the air gap, and one gets during the whole movement of the armature approximately uniform pull.

The suction stroke of the pump takes place through the movement of the armature underneath the influence of magnetic pull; this movement is quick. As soon as the hub is completed, the circuit breaker is operated to interrupt the magnetic circuit. . The delivery stroke takes place by means of a spring 9 on the magnet side of the armature. At the At the end of the delivery stroke, the circuit breaker is closed and the cycle begins all over again.

Since the air gap between the circumference of the armature d and the cylindrical Pole piece c is small, imprecise centering of the armature results in a strong one side pull, which can interfere with the proper functioning of the pump. To prevent this, is between a shoulder io on the pump side of the anchor and a shoulder ii of the surrounding pole piece, a plurality of pressure pieces are provided. Appropriate they are designed as rollers i2 with spherical circumference, so that each around the point of contact can oscillate with the armature or your outer pole piece.

In the position of the armature according to FIG. I, the pressure pieces are somewhat obliquely to the plane of the anchor, and its position approaches the plane of the anchor if this after moved left. So you are practicing a toggle-like effect that prevents the anchor from tilting.

Claims (1)

PATENT CLAIM: Electromagnetically driven diaphragm pump with radial arranged, for "centering the movable armature serving pressure pieces, the with spherical surfaces on the one hand against a shoulder of a cylindrical pole piece and on the other hand place it against the anchor engaging the membrane, thereby secretly signed, that the armature (d) to achieve a uniform pull when the magnet coil is energized (a) in its center a recess (8) on the side facing the magnetic core (b) and the cylindrical pole piece (c) has an annular step (7) for guiding the Anchor has on its circumference, the gradation (7) and the recess (8) in such a way are arranged to one another that the core (b) enters the recess (8) before the anchor ends its way when passing its outer edge on the gradation (7) Has.