FI105805B - Lifting machinery for a lift - Google Patents

Abstract

Lifting machinery for a lift, comprising a disc-shaped stator chassis 2 resting against a guide 1 positioned in the lift shaft, a disc-shaped rotor body and a driving disc 3 forming a solid unit, the driving disc being journalled such that it may rotate relative to the stator body, magnetising devices resting against the rotor body, such as permanent magnets, stator windings resting against the stator body and also a bracing structure 4 extending across the stator body essentially in the direction of the guide. In the embodiment according to the invention, at least one mass body 5 is connected to the stator body such that its mass distribution and/or bending stiffness becomes essentially asymmetric. <IMAGE>

Description

105805

LIFT LIFTING MACHINE

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The invention relates to an elevator hoisting machine as defined in the preamble of claim 1.

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Prior art in the field of the invention is disclosed in EP 0688735. This publication discloses a flat machine solution for use in elevators, which is placed in the elevator shaft without the need for separate engine rooms. The machine is attached directly or by means of a suitable auxiliary frame to the guide in the shaft of the lift, either to the guide of the bodywork or to the guide of the counterweight. Such an elevator machine enables the arrangement of various structures very advantageous in terms of space use, both for the building as a whole and for the elevator itself.

Such an elevator machine is relatively silent and vibration-free at low speeds. However, as the driving speed increases, due to the periodic nature of the field variations in the electric motor, it will soon be possible to reach an area where the excitation frequency generated by the motor is of the specific oscillation frequency of the stator casing of the machine. In this way, the force effects between the rotor and the stator can cause the • stator frame to oscillate in such a way that interfering noises are produced in the shaft, basket and outside the shaft. Depending on the basic design of the motor, the characteristic oscillation frequency can be achieved with the smallest disc drives already at very low speeds, that is, already at a peripheral speed of about 30 m / s, measured from the drive wheel.

Traditionally, vibrations and noises caused by elevator hoisting machinery have been sufficiently eliminated 35 only by adding sound insulation to separate engine rooms. On the other hand, when the hoisting machinery is located in the elevator shaft, there is no space around it to implement significant sound insulation and arrangements to prevent sound passage in the structures. Therefore, instead of noise-suppression, the lifting machinery itself must be made so quiet in structure and function that it does not cause interference to persons traveling in the basket or to persons in the vicinity of the shaft.

Thus, it is an object of the invention to provide a hoisting machine based on a wafer motor, which is as quiet and vibration-free as possible, i.e. which, regardless of the speed of the car, causes minimal vibration and sound effects in the shaft, the car and outside the shaft. It is a further object of the invention to provide an elevator hoisting machine based on a wafer motor, which, despite its vibration and silence, is still extremely small in the shaft and can thus be mounted in the elevator shaft like existing known wafer motors.

20 With respect to the features characterizing the invention, reference is made to the preamble.

The elevator lifting apparatus according to the invention comprises a disc-like stator body 25 supported on a guide in the shaft of the elevator shaft, on which the stator windings are supported. Likewise, the hoisting machinery comprises a disc-shaped rotor body and a drive wheel, which together form a fixed unit. The rotor body is rotatable with respect to the fixed stator body. At positions corresponding to the stator windings of the stator body 30, the rotor body has suitable magnetizing devices such as, for example, τ permanent magnets. In addition, a stiffener, which may be integral with the stator body, i.e. the same casting member with the stator body, or may be a separate body to be attached to the stator body, is provided substantially in the direction of the guide, i.e. substantially vertically. According to the invention, at least one pulp body is connected to, or is integral with, a stator body in accordance with the invention 3 105805, arranged to form a mass distribution or bending stiffness of the stator body substantially asymmetric.

Thus, the basic idea of the invention is to remove the stiffness symmetry of the stator body so that the axial movements of the stator body, i.e. the surfaces perpendicular to the 10 axis, do not oscillate in substantially the same area over their entire surface area. Thus, the asymmetric mass distribution or bending stiffness according to the invention breaks the oscillation symmetry of the stator body so that the acoustic monopole radiators become higher-order radiators, the specific oscillation frequency of the stator body increases and the resonance frequency decreases.

In the embodiment of the invention, the hoisting machine may be directly attached from the stator body to the guide and the substantially vertical stiffener associated with the stator body is attached or supported to the stator body. In another embodiment of the invention, the stator body is supported and secured to a stiffener and the stiffener is secured to a guide. Of course, it is also possible that both the stator body and the stiffener are both supported on the guide.

Local mass concentrations in the stator body as well as thinnings or gaps in the stator body structure can be used as the mass body causing the mass and stiffness asymmetry of the invention. Likewise, various substantially vertical or horizontal or oblique elongated supports may be used as a mass body, the reach of which may vary in the stator body. Similarly, these may be integral parts of the stator body 105805 only of the casting, or they may be separate and attached to the stator body.

Essential for the stator body according to the invention. the un-5 symmetry is that the structure cannot resonate or oscillate to produce disturbing noises. Thus, the asymmetry of the stator body can be realized in many different ways. For example, the bending stiffness of the stator body may be asymmetric with respect to the vertical line defined by the vertical stiffener, i.e. the guide used for attachment. Likewise, asymmetry may exist in addition to or instead of the foregoing with respect to the horizontal line through the rotor axis. Similarly, the asymmetry may take the form of 15 point asymmetry, i.e. the stator body is asymmetric with respect to the rotor axis.

Thus, the stiffness stiffness symmetry of the stator body according to the invention can be implemented in a variety of ways. The pulp bodies used may be of different mass sizes and may vary in location. The position of the additional supports used may vary, their lengths may vary, and their rigidities may also vary.

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In one embodiment of the invention, a disk-like plate can be used as the pulp causing stiffness asymmetry, which can be attached asymmetrically to the stator body. It is also possible in addition to or instead of the asymmetrical fastening 30 that the stiffness of the plate used is suitably asymmetrical.

The elevator hoisting machine according to the invention has significant advantages over the prior art. The asymmetry structure of the Kek-35 invention provides virtually no increase in the outside dimensions of the hoisting machine. so it is still easy to install into the guides in shaft i 5 105805. Furthermore, the structure of the invention eliminates the vibrations of the hoisting machine so that, regardless of the running speed and the frequencies used, the stator frame 5 of the hoisting machine cannot vibrate strongly and cause harmful and disturbing noises in the elevator shaft, elevator hoist or outside the shaft.

In the following, the invention will be described in detail with reference to the accompanying drawings, in which Figure 1 illustrates an embodiment of the invention, Figure 2 illustrates another embodiment, Figure 3 illustrates a third embodiment, Fig. 4 illustrates a fourth embodiment, and

Figure 1 illustrates an embodiment of the invention in which a vertical straight stiffener 4 is attached to the vertical guide 1 via dampers 9 and 10 20. The stiffener has a stator frame 2 of the elevator hoisting machine by means of fastening members 11 and 12. , which can be any vertical guide in the ta-25 hans hoistway.

The stator body is further supported by opposing brakes 15. Similarly, the stator body is supported by stator windings 30 on the side opposite to the plane shown in the drawing. Likewise, the hoisting machine includes a disc-shaped rotor body with a drive wheel 3 and a magnetizing device behind the static frame and rotatable therewith. These structures are described in more detail, for example, in EP 0688735.

An integral and rigid part is attached to the stiffener 4 a mass piece 5, i.e. a stiff beam extending from the edge of the stator body 35 * 6 105805 to one another and forming a stiff skew that is integral with the stiffener 4. Preferably, the entire skew is a single casting piece. The beam-like mass body is rigidly attached at its 5 ends by fasteners 13 to the edges of the stator body 2. The beam-like mass piece 5 is at an angle of about 45 ° to the direction of the stiffener 4 and the guide 1, so that the stiffener 4 and the mass piece 5 together form a rigid support structure which is asymmetric with respect to both .

Figure 2 illustrates another embodiment of the invention, wherein the basic structure of the hoisting machine with respect to guide 1, stiffener 4, stator body 2 and fasteners 11 and 12 is the same as figure 1. In this embodiment, a solid body 6 having three static 20 additional radial supports 16, 17 and 18 extending radially from the center of the body 2.

at 2 o'clock, the second auxiliary strut 17 extends about 5 o'clock and the third auxiliary strut extends about 10 o'clock. Each additional support is rigidly secured to the edge of the stator body 2 by suitable fasteners, for example bolts. The additional supports 16, 17 and 18, together with the stiffener 4, form a single and uniform, five-branched rigid piece which is attached to the stator body 2 at ten different points. The structure significantly stiffens the stator body and is asymmetrically unbalanced with respect to the vertical, horizontal and stator body centers.

Figure 3 shows a third embodiment of the invention in which the basic structure is rigid in the stator body 2 of the guide 1. for point 4 and the attachments between them, «· i 7 105805 remains similar to the preceding figures. In this embodiment, three sector-shaped mass pieces 7 are connected to the stiffener 4. The sectorial mass pieces may be flat or of variable thickness and / or stiffness, and together with the vertical stiffener 4, form a uniform and rigid casting. The sector-like pieces are fastened, e.g. bolted, rigidly to the static-10 tower frame at the edges of their outer periphery. golle 2.

Fig. 4 shows a fourth embodiment of the invention, in which there is no separate stiffener 4 according to Figs. 1-3, but the entire stator body 2 is covered by a circular 20-shaped plate body or mass body 8. The mass body 8 is secured is rigidly supported on the mass member 8. The edges of the circular plate structure of the mass member 8 have a plurality of attachment points 19, 25, which are random or asymmetrical, at indefinite intervals. Also, one anchorage point 20 is arranged centrally to the mass member 8. From its attachment point, a plate-like mass member 8 is bolted to the stator body 2, for example.

Thus, the circular plate-like mass body 8, which may additionally vary in thickness and stiffness, forms a highly asymmetric stiffener on the stator body 2. It is also possible that the mass body 8, its outer surface 35 has ribs, flanges or similar support and stiffening structures.

99 · 105805 8

Figure 5 shows a fifth embodiment of the invention in which the basic structure of the hoisting machine with respect to guide 1, stiffener 4, stator body 2 and fasteners 11 and 12 is the same as figure 1. In this embodiment, stator body 5 is directly stiffened. transverse support 21. Traditionally, both ends of such supports have been provided with a symmetrical attachment to the longitudinal direction of the support, that is, two support arms 22 and 10 23, of which the support is secured to a stator body 2.

In the invention, unlike the prior art the second support legs 23 are removed, the support 21 is rigidly attached to only one side of the support legs 22.

Thus, the mass body, or support 21, provides a stiffener 4 with an asymmetrical support for the static body 2 relative to the longitudinal direction.

It is also possible that the second support legs 23, shown in broken lines in Figure 5, are not removed, but that the support is merely attached asymmetrically. Thus, the ends of the support arms 22 have fasteners 24, bolts or the like, and the support arms 23 are left without fastening, i.e. only resting on the surface of the stator body 2.

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The invention has been described above by way of example with reference to the accompanying drawings, in which various embodiments of the invention are possible within the scope of the claimed inventive concept.

30 • m m

Claims (11)

A lifting machine for an elevator, comprising a circular shaped stator body (2) supporting a guide (1) located in the elevator shaft, a circular rotor frame and a drive disc (3) forming a fixed unit, which drive disk is stored so that it can rotating in relation to the stator body, magnetizing devices supporting the rotor body, such as permanent magnets, stator windings supporting the stator body and a stiffening (4) running substantially in the direction of the stator body, characterized in that at least one mass body (5, 6, 7, 8) ) is connected to the stator body (2) so that its mass distribution / bending stiffness becomes substantially asymmetrical. Lifting machinery according to claim 1, characterized in that the mass body (5,6,7,8,21) is formed by a stiffening extra support 20 which runs in a direction deviating from the direction of the guide (1). Lifting machinery according to claim 1, characterized in that the lifting machine is attached to the guide (1) via the stiffener (4). ; 25 Lifting machinery according to claim 1, characterized in that the lifting machine is attached to the stator body (2) at the guide (1), the stiffening (4) supporting the stator body. Lifting machinery according to claim 1, characterized in that the mass body (s) (5,6,7,21) are asymmetrically positioned relative to the vertical stiffness (4) of the vertical. Lifting machinery according to claim 1, characterized in that the mass body (s) (5,6,7,21) are arranged asymmetrically in relation to a horizontal line through the axis of the rotor. 12 105805 Lifting machinery according to claim 1, characterized in that the mass body (s) (6,7) are arranged asymmetrically in relation to the axis of the rotor. 5 Lifting machinery according to any one of claims 1 to 7, characterized in that the mass bodies have different masses. Lifting machinery according to claim 2, characterized in that the extra supports have different stiffness. Lifting machinery according to claim 2, characterized in that the lengths / distances of the extra support between the attachment points of the stator body and the center of the stator body vary. 15 Lifting machinery according to claim 1, characterized in that the mass body consists of a circular disc (8) which is asymmetrically attached to the stator body. »· · I 1 m • · • i>