RU195812U1 - PERMANENT MAGNETS SYNCHRONOUS GENERATOR - Google Patents

Abstract

The utility model relates to the field of electrical engineering, namely the design of high-speed electric machines, and can be used in high-speed electric machines with permanent magnets. The technical task is to prevent the rotor from touching the stator and protect the permanent magnets from destruction. The synchronous generator consists of rotor 1 with permanent magnets 2 and stator 3, and the rotor 1 is made in the form of a magnetically soft sleeve 4 of length L with permanent magnets 2 mounted on it, rings 5 mounted on both sides of the permanent magnets 2 and sleeves 6 with a thickness of h = 0.3 × b installed in the air gap between the rotor 1 and the stator 2, the value of b: where L is the length of the soft magnetic sleeve, L = 40 ... 100 mm, k is the empirical coefficient, k = 1 ... 0.3, n is the rotation speed of the electric motor, n = 100000 ... 40000 rpm, e is the Euler number, e = 2.718, while a lower value of L corresponds to a larger value of k and n.2 ill.

Description

The utility model relates to the field of electrical engineering, namely to the design of high-speed electric machines, and can be used in high-speed electric machines with permanent magnets.

A known design of a synchronous generator with an external rotor, consisting of a rotor with permanent magnets and a stator (magazine "Electricity", No. 9, 2018, p. 39).

The disadvantage of the analogue is that when the rotor rotates with a frequency of 100,000 ... 40,000 rpm, the rotor touches the stator and the permanent magnets are destroyed.

The technical task is to prevent the rotor from touching the stator and protect the permanent magnets from destruction.

The technical result is achieved by the fact that the synchronous generator consists of a rotor with permanent magnets and a stator, and the rotor is made in the form of a magnetically soft sleeve with permanent magnets mounted on it, rings installed on both sides of the permanent magnets, and a sleeve installed in the air gap between the rotor and stator.

In FIG. 1 shows a permanent magnet synchronous generator

In FIG. 2 shows a rotor of a permanent magnet synchronous generator

The synchronous generator consists of a rotor 1 with permanent magnets 2 and a stator 3 (Fig. 1). Rotor 1 consists of a magnetically soft sleeve 4 of length L with permanent magnets 2 mounted on it, rings 5 mounted on both sides of the permanent magnets 2, and a sleeve 6 of thickness h installed in the air gap between the rotor 1 and the stator 2 (Fig. 2) . When installing the stator on the rotor, the sleeve prevents the stator from impacting the permanent magnets due to the force of magnetic attraction of the permanent magnets. The thickness of the sleeve h = 0.3 × b mm.

When the generator rotor is rotated using a drive motor with a rotation speed n = 100000 ... 40000 rpm, bending vibrations occur, in which the inner surface of the rotor begins to approach the outer surface of the stator, after which the rotor touches.

To exclude such a touch, the air gap value is selected:

where L is the length of the soft sleeve, L = 40 ... 100 mm,

k is an empirical coefficient, k = 1 ... 0.3,

n is the speed of rotation of the electric motor, n = 100000 ... 40000 rpm,

e is the Euler number, e = 2.718,

In this case, a lower value of L corresponds to a larger value of k and n.

Generators were tested at JSC “LEPSE”, the result is positive.

Claims (7)

A synchronous generator consisting of a rotor with permanent magnets and a stator, characterized in that the rotor consists of a soft sleeve of length L with permanent magnets mounted on it, rings mounted on both sides of the permanent magnets, and a sleeve of thickness h = 0.3 × b installed in the air gap between the rotor and stator, value b

where L is the length of the soft sleeve, L = 40 ... 100 mm, k is an empirical coefficient, k = 1 ... 0.3, n is the speed of rotation of the electric motor, n = 100000 ... 40000 rpm, e is the Euler number, e = 2.718, in this case, a lower value of L corresponds to a larger value of k and n.

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