CN113708516B - Electromagnetic design method for high-speed permanent magnet synchronous motor additional inductor - Google Patents

Abstract

The invention relates to an electromagnetic design method of an additional inductor of a high-speed permanent magnet synchronous motor, which comprises the following steps: (1) stator yoke open slot opening b₀Designing; tooth width t of stator yoke open slot₀Designing; the groove shoulder depth of the opening groove of the stator yoke is h₀The stator yoke open groove depth h is designed.

Description

Electromagnetic design method for high-speed permanent magnet synchronous motor additional inductor

Technical Field

The invention relates to an electromagnetic design method of an additional inductor of a high-speed permanent magnet synchronous motor.

Background

The rotor of the high-speed permanent magnet synchronous motor is in a high-speed rotating state, and the high rotating speed and the high conductivity of the permanent magnet of the rotor enable the eddy current loss of the permanent magnet to become one of main losses of the high-speed motor. For this reason, it is necessary to reduce eddy current loss of the permanent magnet at the motor design stage. For a permanent magnet synchronous motor powered by a frequency converter, high-frequency harmonic current of a stator is a main cause for generating eddy current loss of a permanent magnet. The number of turns of the motor is usually small in the design of the high-speed motor, so that the inductance of the high-speed motor is small. The small inductor is not beneficial to filtering high-frequency harmonic current of the stator, and the high-frequency harmonic current of the stator of the high-speed motor is usually suppressed by connecting a reactor in series. This however clearly increases the cost and bulk of the motor.

Based on the reasons, the electromagnetic design method for the high-speed permanent magnet synchronous motor additional inductance is provided, and the design method can increase the inductance of the high-speed permanent magnet synchronous motor from the design link. The method has extremely high engineering value and practical engineering significance for the design of the high-speed permanent magnet synchronous motor.

Disclosure of Invention

The invention aims to provide an electromagnetic design scheme for increasing the inductance of a high-speed permanent magnet synchronous motor so as to increase the suppression capability of the high-speed permanent magnet synchronous motor on the high-frequency harmonic current of a stator. The technical scheme is as follows:

an electromagnetic design method for an additional inductor of a high-speed permanent magnet synchronous motor is characterized in that a stator yoke open slot is defined as b₀The depth of the groove shoulder of the open slot of the stator yoke is h₀The width of the open slot of the stator yoke is t₀The groove depth of the stator yoke open groove is h. The outer diameter of the motor is D, and the outer diameter of the stator yoke is D₁The width of the stator slot tooth is t₁The area of the stator slot is S, the number of winding turns is N, the diameter of the winding wire is d, and the number of the stator slot and the number of the stator yoke open slots are N. The electromagnetic design method comprises the following steps:

(1) stator yoke open slot opening b₀The design is carried out according to the following formula: b₀＝2d；

(2) Tooth width t of stator yoke open slot₀The design is as follows: t is t₀＝2t₁；

(3) The depth h of the stator yoke open slot is designed according to the following formula:

the invention is applied to increasing the electromagnetic design of the high-speed permanent magnet motor, and has the following advantages: the inductance of the high-speed permanent magnet synchronous motor is increased, so that the high-frequency harmonic current of the stator of the high-speed permanent magnet synchronous motor is reduced, and the loss of the rotor is reduced.

Drawings

The invention is further described with reference to the accompanying drawings and specific embodiments

FIG. 1 is a schematic structural diagram of the present invention

FIG. 2 is a diagram illustrating the dimensions of the slots of the stator yoke

FIG. 3 is a simplified front and rear stator yoke slot opening dimension

FIG. 4 is a simplified notched magnetic circuit

FIG. 5 shows a sector flux tube and its parameter definitions

FIG. 6 shows a semicircular flux tube and its parameter definitions

Detailed Description

The technical solutions of the embodiments of the present invention are explained and illustrated below with reference to the drawings of the embodiments of the present invention, but the following embodiments are only preferred embodiments of the present invention, and not all embodiments. Based on the embodiments in the implementation, other embodiments obtained by those skilled in the art without any creative effort belong to the protection scope of the present invention.

An example is shown in figure 1. The technical scheme of the invention is as follows: the motor comprises a stator core, wherein a stator slot is arranged on the inner circle of the stator core, and a stator yoke open slot is arranged on the outer circle of the stator core. The stator winding is closed with the stator yoke open slot through the stator slot to form a closed loop. The stator slot inner conductor and the stator core form a magnetic circuit to generate a main inductance of the high-speed permanent magnet synchronous motor; and the stator yoke open slot inner conductor and the stator core form a magnetic circuit to generate additional inductance of the high-speed permanent magnet synchronous motor. The magnetic circuit corresponding to the additional inductance does not participate in armature reaction, and when the electromagnetic design is carried out, the magnetic circuit completely generates the additional inductance, so that the additional inductance is far larger than the main inductance. When designing the magnetic circuit of the additional inductor, the method is also greatly different from the design of the main inductor. To explore the design principle of the additional inductance, the relationship between the additional inductance and each variable of the electromagnetic design should be studied first.

In order to solve the problem that the armature inductance value of the existing high-speed permanent magnet synchronous motor is small, from the electromagnetic design angle, the additional inductance of the high-speed permanent magnet synchronous motor is obtained. From the definition of inductance, the calculation of the additional inductance of the stator yoke part is the same as the calculation method of the inductance of the common motor, and can be classified into the calculation of the air gap permeability of the notch.

Neglecting the nonlinearity of the ferromagnetic material in the calculation, considering that the magnetic permeability of the ferromagnetic material is much larger than that of the air gap, the magnetic permeability of the air gap can be calculated by the following formula:

wherein G is the air gap permeability, S is the permeability area, and L is the length of the magnetic circuit. μ is the permeability of the vacuum.

This is now simplified due to the irregular shape of the stator yoke slots. The simplified front and rear stator yoke slot opening dimensions are shown in fig. 3. The simplified slotted magnetic circuit may be equivalent to 5 flux tubes as shown in figure 4. They can be divided into three categories, 1 and 5 are sector flux tubes, 2 and 4 are semicircular flux tubes, and 3 is a parallel flux tube.

For a fan-shaped flux tube, the magnetic permeability can be calculated according to the following formula:

in the formula I_efIs the axial length of the motor, mu₀The remaining formulas are defined as shown in FIG. 5 for magnetic permeability in vacuum.

For a semi-circle, the permeability can be calculated as follows:

l_efthe remaining definitions of the axial length of the motor are shown in FIG. 6.

For a parallel flux tube, the permeability can be calculated by the following formula

In the formula I_efIs the axial length of the motor, h₀ b₀The definitions are shown in fig. 3.

From this, the total permeability per slot can be calculated as:

G_add＝G₁+G₂+G₃+G₄+G₅

in the formula, G₁Air gap permeability, G, for region 1 in FIG. 4₂Air gap permeability, G, for region 2 in FIG. 4₃Air gap permeability, G, for region 3 in FIG. 4₄Air gap permeability, G, for the 4 region in FIG. 4₅The air gap permeability is shown in the region 5 of fig. 4.

The value of the stator yoke additional inductance is then

L_add＝nNG_add

In the formula: n is the number of open slots of the stator yoke, and N is the number of winding turns.

To obtain the maximum additional inductance value, the stator yoke open slots are electromagnetically designed.

The design steps are as follows:

the main design dimensions of the stator yoke open slots are shown in fig. 2. Defining the opening of the stator yoke open slot as b₀The depth of the groove shoulder of the open slot of the stator yoke is h₀The width of the open slot of the stator yoke is t₀The groove depth of the stator yoke open groove is h. The outer diameter of the motor is D, and the outer diameter of the stator yoke is D₁The width of the stator slot tooth is t₁The area of the stator slot is S, the number of winding turns is N, the diameter of the winding wire is d, and the number of the stator slot and the number of the stator yoke open slots are N.

The additional inductance is derived from the previous formula and can be approximated as:

wherein L is_addFor additional inductance, N is the number of winding turns, μ₀Is a vacuum permeability,. l_efC is a constant and is the effective iron core length of the motor.

To obtain a larger additional inductance, a larger h can be designed₀And b₀The ratio of (a) to (b).

1. Stator yoke open slot opening b₀In (2) design

The design is carried out according to the following formula:

b₀＝2d

2. tooth width t of stator yoke open slot₀Design (2) of

Tooth width t of stator yoke open slot₀The design is as follows:

t₀＝2t₁

3. the depth of the groove shoulder of the open slot of the stator yoke is h₀Design (2) of

Due to h₀＝(D-D₁) 0.5-h, want to get the maximum h₀Design value, the value of h should be designed to be minimum.

The depth h of the stator yoke open slot is designed according to the following formula:

in the formula, n is the number of the open grooves of the stator yoke, and the minimum design value of h can be realized according to the design of the formula.

So far, the design is completed, and a larger additional inductor can be obtained according to the design.

Claims (1)

1. An electromagnetic design method for an additional inductor of a high-speed permanent magnet synchronous motor is characterized in that a stator yoke open slot opening is defined as b₀The depth of the groove shoulder of the open slot of the stator yoke is h₀The width of the open slot of the stator yoke is t₀The groove depth of the open slot of the stator yoke is h, the outer diameter of the motor is D, and the outer diameter of the stator yoke is D₁The width of the stator slot tooth is t₁The area of the stator slot is S, the number of turns of the winding is N, the diameter of the winding wire is d, the number of the stator slot and the number of the stator yoke open slots are N, and the electromagnetic design method comprises the following steps:

(1) stator yoke open slot opening b₀The design is carried out according to the following formula: b₀＝2d；

(2) Tooth width t of stator yoke open slot₀The design is as follows: t is t₀＝2t₁；

(3) The design of the groove depth h of the open groove of the stator yoke is designed according to the following formula:

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