CS237058B1 - Device for sealing of parts of linear electric motor - Google Patents

Abstract

The wall provides a hermetic seal between components in an oscillating linear electric motor comprising a stator (10) and an armature (20), whose ferro-magnetic parts are located in the stator tracks (11) so that a function air gap (13) is formed. Also in the stator tracks are windings (12). The separating wall (29) is of ferro-magnetic or non-ferro-magnetic material (32).

Description

SUMMARY OF THE INVENTION The present invention relates to a device for hermetizing between components of an oscillating linear electric motor, characterized in that the stator part of the winding electric motor is separated by a suitable partition from an aggressive, toxic or flammable environment, possibly from a space under increased or reduced pressure. then only the ferromagnetic armature of the electric motor moves ·

In various industries, mixing with the aid of the oscillating movement of the rigid assemblies is preferably used to intensify processes taking place in homogeneous or heterogeneous systems containing liquids or mixtures of liquids and gases or liquids and granular solids. Cam mechanisms driven by rotary or hydraulic motors are often used as sources of oscillating motion. It has been newly proposed to use an oscillating linear electric motor for this purpose. In many cases, the agitated system is required to be well sealed to the environment, burning. This is the case, for example, in the treatment of volatile aggressive substances, flammable, explosive or toxic, in nuclear technology, but also in cases where contact of the batch with air oxygen is undesirable or when it is necessary to work at elevated or reduced pressure.

The use of linear oscillators with rotary motors has a number of disadvantages in terms of hermetization. It is practically impossible to enclose the entire drives in the hermetic space. Either gaskets with oscillating installation at its outlet from the hermetized space, or immersion of the entire cam mechanism in the hermetized space and sealing of the rotating shaft of the rotary electric motor or hydropower can be considered. In these cases, sealing with conventional seals requires extensive maintenance. In the case of oscillating motion, a bellows seal may also be used, but its service life is limited and the reliability is problematic. The demands on the seal increase even when the hermetically sealed space is under pressure. In some applications, eg in nuclear technology, extraordinary equipment reliability as well as long periods of trouble-free operation are required. In such cases, these solutions are completely unsatisfactory.

Surprisingly, these drawbacks can be eliminated by using an oscillating linear electric motor and a hermetizing device between its components according to the invention. SUMMARY OF THE INVENTION An immovable hermetizing barrier of non-ferromagnetic material is disposed between the armature and the stator of the oscillating linear electric motor.

The progress achieved by the invention consists in reliably separating the hermetized space from the external environment by means of a stationary, mechanically simple hermetizing barrier, enabling the non-contact transmission of electromagnetic energy to the armature of the oscillating linear electric motor, which transforms this energy into mechanical one to generate motion. The simple design of the oscillating linear electric motor can be easily placed in any hermetic environment, so that the whole arrangement is technically easy and efficient to implement.

This arrangement is particularly well suited to practical applications requiring an amplitude of the oscillation path of the driven mechanism of up to several cm and an operating frequency of up to about 8 Hz. When using a reluctance-type oscillating linear electric motor that allows to select half the supply frequency than the mechanical oscillation frequency, the additional losses from the eddy currents induced in the massive hermetizing housing are irrelevant. In order to reduce the energy efficiency losses of the sealed motor, the gap between the stator and the motor armature may advantageously be reduced.

passing a portion of the hermetizing cover of ferromagnetic and a portion of non-ferromagnetic material.

Thus, the inclusion of a hermetic device in the structure of an oscillating linear electric motor will not reduce its energy efficiency.

Specific embodiments of the hermetization arrangement between the oscillating linear electric motor components are shown in Figures 1, 2, wherein Fig. 1 shows an embodiment of a hermetizing barrier at an oscillating linear electric reluctance electric motor having a planar functional air gap and Fig. 2 an alternative of a hermetizing device. a non-symmetrical reluctance oscillating linear electric motor with a functional diameter between the stator and an anchor embedded in its groove.

In case of oscillating linear design. of a reluctance electric motor with a plane functional air gap (e.g., for very small amplitudes of the oscillation path), the hermetic barrier passing through the electric motor is planar, as shown in the example in Figure 1.

In the groove 11 of the oscillating linear reluctance electric motor 1, there is a winding 12 to which the ferromagnetic portions 21, 22 of the armature 20 approach through the functional air gap 13. In the gap 13, the hermetization barrier 29 is printed on the stator 10. It consists of a peripheral portion 40, a supernatant portion 41 lying above the stator winding 12, a residual portion 32 in the functional air gap 11 outside the coil. 12 and from the central part 11 ·

Fig. 2 shows an alternative of a hermeizing device on an asymmetrical reluctance oscillating linear electric motor with a functional gap between the stator and the anchor embedded in its groove.

In the grooves 11 of the oscillating linear reluctance electric motor 1, a winding 12 is mounted. The ferromagnetic portions 21 and 22 of the armature 20 extend into the grooves 11, creating a functional air gap. Ц. Between the anchor 20- and the stator 10 is located a hermeal barrier 29 of non-ferromagnetic material consisting of a peripheral portion 40, a supernatant portion 11 lying above the stator winding 12, a residual portion 32 in the functional air gauge 13 outside the coil 12, and From the middle section

The residual portion 32 of the hermeal barrier 29 in the functional air meter 13 may be ferromagnetic. In this case, the ferromagnetic part of the stator becomes part and narrows - thus narrowing the width of the functional air meter 11. If the residual portion 32 of the diaphragm 29 is non-ferromagnetic, the functional air chamber increases by its thickness, which is usually unfavorable.

The peripheral portion 60, the overflow portion 60 and the central portion 33 of the hermeal barrier 29 may always be of non-ferromagnetic material.

237 058

The hermetizing device between the components of the oscillating linear electric motor according to the invention can be advantageously used in the construction of low frequency oscillating mechanisms driven by the oscillating linear electric motors, if it requires hermetic separation of the technological space from the external environment. The arrangement according to the invention is simple, stationary and reliable and virtually eliminates the need for operational control.

Claims (3)

SUBJECT OF THE INVENTION 237 058 A device for hermetizing between components of an oscillating linear electric motor, the armature of which carries two ferromagnetic parts, between which a functional air gap is formed between the motor and the stator, and at least one winding is arranged in the stator grooves. 10) a hermetizing partition (29) of non-ferromagnetic material is provided, wherein the hermetizing partition (29) consists of an edge portion (30), a supernatant portion (31) lying above the winding (12) of the stator (10), and residual portions (32). ) in the functional air gap (I3) outside the coil (12) and from the central part (33) · Device according to claim 1, characterized in that the residual parts (32) of the hermetizing barrier (29) are made of ferromagnetic material. Device according to Claims 1 and 2, characterized in that the hermetically sealed partition (29) follows the supernatant portion (31) of the coil surface (12) and the residual wall portion (32) of the groove (11) of the stator (10).