JPH077910A - Linear synchronous motor - Google Patents

Abstract

PURPOSE:To provide a synchronous motor, in which heat generation on the secondary side is reduced and which can be manufactured at low cost. CONSTITUTION:A field winding 8 is mounted on the primary side in addition to an armature winding 7 on the primary side, and magnetic bodies 5 capable of properly generating magnetic fields by the field winding 8 are installed on the secondary side. The shapes and structure of the primary side and the secondary side are deformed, thus constituting a linear synchronous motor having a plate shape 1, a cylindrical shape, a plane shape, etc.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a linear synchronous motor having an armature winding and a field winding both provided on the primary side.

[0002]

2. Description of the Related Art Conventionally, a linear induction motor or a permanent magnet field type linear synchronous motor has been used as a conveying device, a positioning device, and a linear servomotor using a linear motor. In addition, a linear induction motor has been put into practical use as a vertical transfer device such as an elevator.

[0003]

However, the conventional linear motor as described above has the following problems. That is, in a linear induction motor used in a transportation or positioning device or the like, since thrust is obtained by an induced current, efficiency and power factor are poor, positioning accuracy is poor, and problems such as heat generation occur. There is.

Further, in the conventional permanent magnet type linear synchronous motor, the thrust is generated by the repulsive action of the magnetic field generated by the armature winding and the magnetic field generated by the permanent magnet. Or permanent magnets must be placed over the entire stroke. Therefore, in the case of a short stroke, there is no problem in terms of cost, but there is a problem in that the winding and the permanent magnet are arranged as the stroke becomes longer, which makes it very expensive.

Therefore, the present invention does not require a winding or a permanent magnet on the secondary side, can be manufactured at a low cost, and can achieve a performance equal to or higher than that of a conventional permanent magnet type synchronous motor. The purpose is to provide.

[0006]

In order to solve the above problems, the present invention constitutes a linear synchronous motor as set forth in the claims.

[0007]

In the linear synchronous motor of the present invention, a magnetic field similar to that provided with a permanent magnet is generated on the secondary magnetic body by the field winding provided on the primary side.

Therefore, a long stroke linear synchronous motor can be manufactured at low cost, and heat generation on the secondary side can be extremely reduced.

[0009]

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is an explanatory view of a flat linear synchronous motor,
FIG. 3 is an explanatory diagram of a cylindrical linear synchronous motor, and FIG. 4 is an explanatory diagram of a planar type linear synchronous motor. FIG. 2 is an explanatory diagram showing currents and phase relationships common to each embodiment.

In FIG. 1, a plate-shaped linear synchronous motor 1 of this example is reciprocally moved on a belt-shaped linear orbit (secondary side acting body) 2 constituting the secondary side of the linear motor and on this orbit 2. It is composed of a flat plate-shaped moving body (primary side acting body) 3. The reciprocating direction is indicated by A.

The linear track 2 has a plurality of magnetic members 5 along the moving direction A on the surface of the main body 4 formed of a non-magnetic member in a band shape.
Are fixed with bolts 6. Although the magnetic body 5 is shown as an example of a rectangle, it may have an arbitrary shape. The magnetic body 5 is
It can also be fixed to the main body 4 by using an adhesive or the like.

The moving body 3 is composed of 4 poles and 12 slots, and each slot is provided with a 3-phase armature winding 7 and a field winding 8 as shown in the drawing. In the figure, armature windings are shown in uppercase letters U, V, W, and field windings are shown in lowercase letters u, v, w.
Each winding is a distributed winding that is shifted by an electrical angle of 120 degrees.

FIG. 2 shows the exciting currents flowing through the windings 7 and 8. The armature winding currents are shown with uppercase letters U, V, W, and the field winding currents are shown with lowercase letters u, v, w. The armature winding currents I _U , I _V , and I _W each have a phase difference of 120 degrees. The field winding currents I _u , I _v , and I _w are also 1
It has a phase difference of 20 degrees.

There is a 90-degree phase difference between the armature winding currents I _U , I _V , and I _W and the field winding currents I _u , I _v , and I _w .

Therefore, regardless of the position of the moving body 3 as the mover, if the phase control is performed so that the current phase angle of the two windings shown in FIG. 2 becomes 90 degrees, the armature current I _U ,
I _V, I _W and field winding current I _u, I _v, thrust by Furemingunohousoku between flux magnetic body 5 is generated by I _w occurs.

When the magnetic flux densities of the field windings at the U-phase, V-phase, and W-phase coil positions are B _U , B _V , and B _W , the electrical angle is θ, and B _m is the maximum magnetic velocity density, B _U = B _m cos θ B _V = B _m cos (θ-120 °) B _W = B _m cos (θ-240 °) (1)

The armature winding currents I _U , I _V and I _W are I _m
Is the maximum current, I _U = I _m cos θ _IV = I _m cos (θ-120 °) I _W = I _m cos (θ-240 °) (2) Therefore, the generated thrust F is

The Equation 1] _{F = K (B U · I} U + B V · I V + B W · I W) = K 1 B m I m ... (3).

As described above, in the flat plate linear synchronous motor 1 of this example, the field winding 8 can appropriately generate a magnetic field in the magnetic body 5, and the magnetic field generated by the armature winding 7 acts on it. Thus, the moving body 3 can be driven in the arbitrary direction in the direction A by the thrust F. If a position detector such as an encoder is appropriately provided on the moving body 3 and the position and speed are managed, feedback control of the position and speed can be performed, and it can be used as a highly accurate positioning control device.

In the example of FIG. 1, the acting body 3 on the primary side is a moving body, but the acting body 3 may be fixed and the acting body 2 on the secondary side may be a moving body.

Referring to FIG. 3 showing another embodiment, a cylindrical linear synchronous motor 9 of this embodiment has a rod-shaped secondary acting body 10
And a primary-side acting body 11 that penetrates through the acting body 10 and is relatively movable along the extending direction B of the acting body 10. The movement in the direction B is relative, but in this example, the primary-side acting body 11 moves,
This is called a moving body 11.

The secondary-side acting body 10 includes a shaft 12 formed of a rod-shaped non-magnetic material, a doughnut-shaped magnetic material ring 13 having a relatively wide width, and a donut-shaped non-magnetic material ring 14 having a relatively narrow width. Are alternately fitted and tightened and fixed by a nut 15. On the other hand, the movable body 11 has an armature winding 16 and a field winding 1 similar to those shown in FIGS.
7 is wound, and the inner surface of the magnetic pole magnetized by the armature winding 17 is arranged to face the outer peripheral surface of the magnetic ring 13 with a gap G. For this reason, bearings 18 such as ball bushes are provided on both end surfaces of the cylindrical moving body 11 so that the moving body 11 can be moved along the outer peripheral surface of the primary acting body. The moving body 11 is provided with a position detector such as an encoder for detecting its moving position.

Therefore, the exciting currents I _U , I _V , I _W , I _u , I _v , and I _w as shown in FIG. 2 are applied to the windings 16 and 17, and the magnetism is changed in accordance with each moving position of the moving body 11. Body ring 13
Can be appropriately magnetized to move the moving body 11 in the direction B in any direction.

In FIG. 4 showing still another embodiment, a planar linear synchronous motor 1 _XY of this embodiment is shown in FIG.
The moving body 19 as the secondary acting body is arranged on the plane track 20 as the secondary acting body shown in FIG. (C) figure is CC sectional drawing of (b) figure.

As shown in the figure, the plane track 20 is formed by arranging magnetic materials 22 in a grid pattern on a flat plate 21 made of a non-magnetic material. Each magnetic body 22 may be fixed to the flat plate 21 with a bolt or an adhesive agent.
The moving body 19 includes two flat-plate-like moving bodies (motors) shown in FIG. 1 in the X-axis direction (19-1, 19-).
2), 2 in the Y-axis direction (19-3, 19-4), total 4
They are arranged in the shape of individual wells and are mechanically connected. The air gap between the primary side and the secondary side is maintained by an air bearing or a mechanical bearing (not shown). The arrangement of each motor 19-1, 19-2, 19-3, 19-4 is
Although not limited to the illustrated one, on the XY plane, the X direction,
They are symmetrically arranged so that the operations in the Y direction are even. In the arrangement of this example, for example, the nine magnetic bodies 22-1 of the plane plate 20 are
22-9, there are magnetic bodies 22-2 and 22-3 below the moving body 19-1 and magnetic bodies 22-7 and 22-8 below the moving body 19-2. , There are magnetic bodies 22-6 and 22-9 below the moving body 19-3.
There are magnetic bodies 22-1 and 22-4 below.

In the above structure, when moving the movable body 19 in the X-axis direction, the X-axis motors 19-1, 19-
Only 2 needs to be moved. Similarly, when it is desired to move the moving body 19 in the Y-axis direction, Y-axis motors 19-3, 19
Only -4 needs to be moved. Further, in order to move in arbitrary X and Y directions, X-axis motors 19-1, 19-
2 and the moving speeds of the Y-axis motors 19-3 and 19-4 may be changed.

It should be noted that the moving body 19 has one plane trajectory 20.
A plurality can be provided for each. By doing so, it is possible to construct a robot system in which a plurality of moving objects move to arbitrary positions on a wide plane at arbitrary speeds. Further, since the planar linear synchronous motor 1 _XY of this example has a structure in which the magnetic members 22 are simply arranged on the flat plate 21 in a grid pattern, the magnetic members 22 are attached in a grid pattern on the passage, and By moving the self-propelled motor 19 above, various transport systems and the like can be constructed.

The present invention is not limited to the above embodiments, but can be carried out in appropriate modes by making appropriate design changes.

[0028]

As described above, since the present invention is the linear synchronous motor as set forth in the claims, the field winding and the armature winding are provided only on the primary side, and further, the secondary side. Since it has a simple structure, a long stroke linear synchronous motor can be constructed at low cost. Further, since the heat generation on the secondary side is extremely small, it is possible to operate with high efficiency and perform highly accurate positioning.

[Brief description of drawings]

FIG. 1 is a cross-sectional explanatory view of a flat linear synchronous motor according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a phase relationship of three-phase currents flowing through an armature winding and a field winding.

FIG. 3 is a sectional explanatory view of a cylindrical linear synchronous motor according to another embodiment of the present invention.

4A and 4B are explanatory views showing a structure of a flat plate type linear synchronous motor according to still another embodiment of the present invention, wherein FIG. 4A is a plan layout view of a primary side acting body (moving body), and FIG. Is a plan view of the secondary-side acting body (orbit), (c) is a cross-sectional view taken along the line CC of (b).

[Explanation of symbols]

1 Flat Linear Synchronous Motor 2 Linear Trajectory (Secondary Working Body) 3 Moving Body (Primary Working Body) 5 Magnetic Body 7 Armature Winding 8 Magnetic Field Winding 9 Cylindrical Linear Synchronous Motor 1 _XY Planar Linear Synchronous Motor motor

Claims (4)

[Claims] 1. A repulsion of magnetic force that interacts with each other according to Fleming's left-hand rule, having a primary-side acting body having an n-phase armature winding and a secondary-side acting body that appropriately generates a magnetic field. In a linear synchronous motor that linearly moves a primary or secondary side acting body with respect to another acting body by a suction action, in order to cause the primary side acting body to generate the magnetic field in the secondary side acting body. The n-phase field winding is provided, and the secondary-side acting body is provided with a magnetic body for generating the magnetic field according to energization of the field winding of the primary-side acting body. Characteristic linear synchronous motor. 2. The linear synchronous motor according to claim 1, wherein the linear synchronous motor is composed of a belt-shaped secondary-side acting body and a flat plate-shaped primary-side acting body capable of relatively linear movement on the acting body. A flat plate linear synchronous motor characterized by the above. 3. The linear synchronous motor according to claim 1, wherein the linear synchronous motor is penetrated by a rod-shaped secondary side action body and the action body.
And a cylindrical primary-side acting body that is relatively movable along the extending direction, and the secondary-side acting body has a magnetic ring and a non-magnetic ring on an axis made of a non-magnetic body. A linear synchronous motor, which is formed by being fitted alternately. 4. The linear synchronous motor according to claim 1, wherein the linear synchronous motor has a planar orbit as a secondary side acting body having two orthogonal axes and a flat plate as a primary side acting body that moves in a plane on the orbit. A linear synchronous motor comprising a moving body, wherein the planar orbit is formed by arranging magnetic bodies of arbitrary shape on a non-magnetic plate in a grid pattern.