SU1534639A1 - Dc electrical machine - Google Patents

Abstract

The invention relates to electrical engineering. The purpose of the invention is to reduce vibration and noise. The electric machine contains a magnetic system with poles 1 and measles 2. Groove 3 divides the pole into parts 4 and 5. Each part of the pole contains an integer number of groove divisions of the core 2. The depth of the groove 3 must not be less than the depth of the groove 6 core, and its width is determined according to the formula. 1 il.

Description

The invention relates to electrical engineering and relates to electrical DC machines with a low level of vibration.

The purpose of the invention is the reduction of vibration and noise.

The drawing shows a fragment of an electric DC machine.

Electric standing machine | the current contains a magnetic system with poles 1 and a toothed anchor 2. Pole 1 Dimes along the axis of the groove 3, which divides it iia parts 4 and 5. For each part 4, 5 of the Julius there is an integer number of pae divisions of the armature 2. The width of the groove 3 ^ is determined by the expression

C = qt _A + b _x , where C is the width of the groove;

q is a positive integer (including zero), q = 0, 1, 2; · t, is the groove division of the anchor;

B _x - the width of the tooth of the anchor.

The depth of the groove 3 should not be less than the depth of the groove in the anchor, however, at; this pole must retain its inherent rigidity.

If there is a groove along the axis of the pole from the side of the air gap, the magnetic flux passes from the anchor to the pole, mainly through two halves of the pole located on both sides of the groove. In this case, the effect of alternating magnetic forces and moments at the tooth frequency on the pole as a whole will consist of forces and moments acting ^on $ ³ each of the half poles. Moreover, if the width of each of the halves is equal to an integer number of groove divisions of the anchor, then when the armature rotates at any moment of time under each of the halves of the pole, the number of teeth is not. changes and, thus, the total radial force acting on the pole is constant in time. 45

With the groove width determined by the indicated formula, the moments acting on each of the half poles will be strictly in antiphase, and thus, the total moment of magnetic forces acting on the pole at the tooth frequency will be zero. Thus, a sharp decrease in vibration of the machine at the gear frequency is achieved.

The machine operates as follows.

When you turn on the machine in the network between the armature 2 and pole 1, a magnetic field occurs. At each time moment, under parts 4 and 5 of the pole there will be the same integer number of groove divisions of the armature 2 and, consequently, alternating radial forces acting on the pole will not arise. On the other hand, the alternating bending moments appearing acting on the pole parts 4 and 5 will be in antiphase, and the resulting alternating bending moment acting on the pole Г will theoretically become zero.

Thus, the use of the proposed machine will eliminate the occurrence of electromagnetic vibration at the gear frequency due to the dentation of the armature.

Claims (1)

Claim An electric DC machine containing a magnetic system with poles and a gear anchor, characterized in that, in order to reduce the vibrations and noise of the electric machine, an axial groove is made along the axis of each pole from the air gap, the width of which is determined by the expression C = qt <+ b _z , and the depth of this groove is not less than the depth of the anchor groove, and under each part of the arc of the pole, divided by the axial groove, there is an integer number of groove divisions of the anchor, where C is the width of the groove; q is an integer; t ₍ - groove division of the anchor; B _r is the width of the tooth of the anchor.