DE1938446U - ELECTROMAGNETIC VIBRATOR PUMP. - Google Patents

Description

The fire "relates to a vibrating armature pump with an electromagnetic Exciter part and a piston pump equipped with a suction and pressure valve.

In the "known pumps of this type, the exciter part a magnetic core made of solid iron, the pump piston being articulated on the oscillating armature. Due to this fact the size or the performance of such pumps is limited, since above a certain size the electrical losses with alternating current excitation get so big that a usable solution is no longer possible.

In the known pumps, it is also common to use the suction valve to be provided with a compression spring, the cage of which serves as a stop and to limit the stroke of the piston »This creates on the one hand a relatively large harmful space, which allows only slight negative pressures, on the other hand causes the stop of the piston considerable noises at the spring cage »

The present innovation is now based on the task of creating an electromagnetic oscillating armature pump, the size of which with small electrical losses can be designed in any dimension within wide limits, extremely quiet works and has a particularly small harmful space so that it can also work as a vacuum pump =

According to the innovation, the proposal will be used to solve the task at hand made to use a U- or E-shaped stator core with magnet yoke and associated excitation coil as the excitation part, at least one leg of a package is kept shorter and accommodates a complete pump unit in a longitudinal bore, whose piston is made of magnetizable material and the interrupted magnetic against the action of a helical spring Flow of the package in synchronism with the excitation frequency closes and opens. The piston thus also serves as an anchor of the visual oscillation system.

In a further refinement of the subject of the fire is

the coil spring acting against the piston both on the piston, as well as attached to the element closing the cylinder and the valve disk of the suction valve by one on the pump piston tension or compression spring attached to the opposite side of the valve disk pressed onto its seat »

The following is the innovation on the basis of the drawings, the longitudinal sections by showing two exemplary embodiments of the proposed oscillating armature pump, explained in more detail.

According to i'ig. 1, the pump consists of a housing 1 in which a E-shaped stator core 2 with excitation coil 5 and one likewise packaged magnetic yoke 4 are housed. The middle leg 5 of the stator core is shortened, creating an air gap 6 is formed, and provided with a longitudinal bore 7, which also extends through the yoke 4 and the housing 1 »Through the A complete pump unit is pushed through the longitudinal bore. The pierced piston running in a thin-walled cylinder tube 8 9 is made of magnetizable material and is held by a helical spring 10 printed in its rest position »

On the side opposite the coil spring is in the piston a pressure valve 11 is installed, while a suction valve is installed in the adjoining cover plate 12 to which the housing 1 is screwed 13 is provided. The cover plate 12 also has a connection piece 14 for the suction line »

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At the upper end of the cylinder tube 8 is a threaded one Screw connector 15 arranged, which is screwed into a corresponding threaded hole of the cover 12, this lifted from the housing 1, the entire pump is pulled out of the stator core at the same time. In the lower part of the cylinder tube 8 is a closure member 16 which is provided with a connection pipe 17 for the delivery line. If an alternating voltage is applied to the excitation coil 3, the piston 9 tries to close the air gap 6 that is still present and is in interaction with the helical spring lU in oscillation offset. The liquid to be conveyed is sucked in via the suction valve 13 and through the pressure valve 11 and the connecting pipe 17 pressed into the delivery line.

The masses involved in the vibration, e.g. piston and screwdriver Springs do not need to be in resonance with the excitation oscillation, as is usually the case, as there is no interest in due to the already low electrical losses, some of the losses can be recovered through a gain in the resonance range. Compared to known solutions, this enables a larger area of application, above all a larger pressure range, because it is not limited to the relatively narrow resonance range.

As part of the innovation, several, e.g. the two outer legs of the stator core can be shortened and each with one

Pump unit are provided. Likewise, if the thickness is sufficient of the stator core in the shortened leg or legs, two or more pump units are used, for example work in opposite directions »They can then be connected either in series or in parallel with the same working direction.

In relation to a particularly favorable division of the pump elements on the laminated core, in particular to achieve as central a position of the piston as possible, two laminated cores 2 and 2 'with the same cut under the port case of the magnetic yoke against each other be set. Analogously to the exemplary embodiment according to FIG. 1, a pair of legs, for example the middle one, is also used here Leg pair 5 and 5 'shortened, whereby the air gap 6 is shifted into the middle of the laminated core. This is how it arises a cheaper installation space for the suction valve 13 'and it remains a sufficient space for the coil spring 10.

To achieve a noiseless running of the pump and a stop of the piston 9 on the suction valve side, the two ends of the helical spring are fixed. To this Purpose, a spring holder 18 is attached to the piston 9, which consists of non-magnetizable material, so that the air gap does not is disturbed. The other end of the helical spring is shown in FIG. 1 attached to the closure member 16 and, according to FIG. 2, to the pin 19 of the cover 20 closing off the cylinder 8. The screws-

spring acts as a tension spring when the piston is retracted and brakes the piston before a possible stop, e.g. on suction valve 13 or 13 '.

As already mentioned at the beginning, in order to achieve the smallest possible harmful space, the spring loading the suction valve is provided on the side of the valve disk facing away from the piston. In the embodiment according to FIG. 1, a tension spring 21 is used. A sleeve 23 provided with a collar 22 serves as the valve seat, at the upper end of which the tension spring is suspended. The suction valve shown in FIG. 2 has a compression spring 24, which is supported on inwardly bent tabs 25 of the bushing 23 and ^{transmits its iv} raft via a spring plate 26 to a rod 27 connected to the valve plate. The suction valve can thus be preassembled and pre-checked and inserted into the pump as a finished unit.

Claims (9)

Protection claims 1. Electromagnetic oscillating armature pump with an exciter part and a piston pump provided with a suction and pressure valve, characterized by a U- or E-shaped stator core with magnet yoke and associated excitation coil, whereby at least one leg of the package is shorter and accommodates the complete pump unit in a longitudinal bore Piston in a known manner made of magnetizable material exists and against the action of a helical spring the interrupted magnetic flux of the package closes and opens synchronously with the excitation frequency » 2. Electromagnetic oscillating armature pump according to claim 1, characterized marked that several legs of the stator core are shortened and each accommodate a pump unit, 3. Electromagnetic oscillating armature pump according to claim I _9, characterized in that the shortened leg or legs contain several pump units « 4. Electromagnetic oscillating armature pump according to claims 1 to 3, characterized in that two stator laminations ^ 2, 2 ') of the same size and thickness are set against one another, the shortened legs (5 ₅ 5') each in one or more coaxial pairs of holes Wear pump unit " 5. Electromagnetic Schwingankerpiuape according to claims 1 to 4, characterized in that the helical spring (lo) acting against the piston (9) both on the piston and on the cover (2ü) or closure member (16) closing off the cylinder ^ S) is attached. 6. Electromagnetic vibration pump according to claim 5 ₅ wherein is provided on the piston-mounted pen ^ 18) between helical spring (lo) and the piston (9) of non-magnetizable material existing. 7 «Electromagnetic oscillating armature pump according to claims 1 to 6, characterized in that the suction valve (l3, 13 ') through a side of the valve disk facing away from the piston (9) attached tension spring (.21) or compression spring (24) on its seat is pressed. 8ο Electromagnetic oscillating armature pump according to claim 7? through this characterized in that the valve seat and the abutment of the compression spring (24) or the suspension of the tension spring (2l) from a with a collar (22) provided sleeve (23) is formed and the complete suction valve is inserted into the cover (12) is. 9. Electromagnetic oscillating armature pump according to claims 1 to characterized in that the electromagnetic exciter part is pushed onto the complete pump unit.