KR102644305B1 - Rotor - Google Patents

Abstract

The present invention relates to rotors.
The rotor according to the present invention includes a shaft that transmits power, a rotor core that is coupled to the outer ring of the shaft and allows the magnetic member to be spaced apart from the shaft, and a fixing means that is coupled to the rotor core and accommodates the magnetic member therein. and, at least one magnetic member coupled to the fixing means and allowing the shaft to be rotated by the stator.
According to the present invention, the magnetic member is fixed in place on the surface of the rotor core without damage.

Description

Rotor {Rotor}

The present invention relates to a rotor, and more specifically, to a rotor that allows a magnetic member to be fixed in place by a fixing means and prevents damage to the magnetic member.

In general, an electric motor is a device that uses electrical energy and converts it into mechanical energy.

Among these, the synchronous motor includes a stator composed of a coil wound around the stator core, and a rotor located inside the stator with a permanent magnet fixed to the rotor core.

At this time, conventionally, it is common to use an adhesive to fix the permanent magnet to the rotor core, or as disclosed in Korean Patent No. 10-0921243, a wire is used to fix the permanent magnet to the rotor core.

However, when a permanent magnet is fixed to the rotor core using a method such as the prior art, there is a problem in that the position of the permanent magnet fixed to the rotor core is not uniform.

As such, if the direction of the permanent magnet fixed to the rotor core does not match the direction of the shaft, there is a problem in that the performance of the electric motor deteriorates.

Korea Registered Patent No. 10-0921243

Therefore, the purpose of the present invention is to solve the problems of the prior art as described above, and to prevent damage to the magnetic member in addition to fixing the magnetic member in the correct position by a fixing means. The rotor is provided.

According to the features of the present invention for achieving the above-described object, a shaft for transmitting power, a rotor core coupled to the outer ring of the shaft and allowing the magnetic member to be spaced apart from the shaft, and coupled to the rotor core, It is characterized by comprising a fixing means for accommodating a magnetic member therein, and at least one magnetic member coupled to the fixing means and allowing the shaft to be rotated by the stator.

The fixing means includes a fixing body that is coupled to the rotor core and forms an external shape, a plurality of insertion holes formed along the periphery of the fixing body into which a magnetic member is inserted, and a plurality of insertion holes formed along the periphery of the fixing body. It is located between two adjacent insertion holes, respectively, to prevent damage to the magnet member inserted into the adjacent insertion hole during the process of inserting the magnet member into the insertion hole, or to prevent damage to the magnet member inserted into the insertion hole. It is characterized by including a deformation hole that prevents damage to the magnetic member inserted into.

The insertion hole is characterized in that its width gradually increases as it penetrates from the outer ring of the fixing body in the inner direction.

Both sides of the magnetic member are characterized in that they are inclined.

The rotor core is further provided with a cover that blocks the rotor core from the outside.

The rotor according to the present invention has the following effects.

The present invention has the advantage that it is easy to fix the magnetic members divided into the rotor core in position by providing a fixing means.

The present invention has the advantage that the process for fixing the magnetic member is shortened as the fixing means is provided.

The present invention has the advantage of preventing damage to the magnet member by forming a deformation hole in the fixing means.

In the present invention, there is an advantage that the fixing force of the magnetic member is improved as the insertion hole is formed at an angle.

1 is an exploded view of the configuration of a preferred embodiment of the rotor according to the present invention
Figure 2 is a perspective view showing the configuration of a fixing means constituting a preferred embodiment of the rotor according to the present invention.
Figure 3 is a cross-sectional view showing the configuration of the fixing means constituting a preferred embodiment of the rotor according to the present invention.
Figure 4 is a cross-sectional view showing an example of combination of a fixing means and a magnetic member constituting a preferred embodiment of the rotor according to the present invention.

Hereinafter, a preferred embodiment of the rotor according to the present invention will be described with reference to the drawings.

1 to 4 show an embodiment of a rotor according to the present invention. That is, Figure 1 shows an exploded view of the configuration of a preferred embodiment of the rotor according to the present invention, and Figure 2 shows a perspective view showing the configuration of the fixing means constituting the preferred embodiment of the rotor according to the present invention. 3 shows a cross-sectional view showing the configuration of the fixing means constituting a preferred embodiment of the rotor according to the present invention, and Figure 4 shows an example of a combination of the fixing means and the magnetic member constituting a preferred embodiment of the rotor according to the present invention. A cross-sectional view is shown.

As shown in these drawings, the rotor according to the present invention is coupled to a shaft 100 that transmits power and the outer ring of the shaft 100, and is configured to allow the magnet member 400 to be spaced apart from the shaft 100. a rotor core 200, a fixing means 300 coupled to the rotor core 200 and accommodating a magnet member 400 therein, and at least one stator (not shown) coupled to the fixing means 300. ) and a magnet member 400 that allows the shaft 100 to rotate.

The shaft 100 is formed in the shape of a circular pillar that is long in the longitudinal direction, and is configured to transmit power.

The shaft 100 is provided with a rotor core 200.

The rotor core 200 is provided on the central outer ring of the shaft 100 and is configured to allow the magnet member 400 to be spaced apart from the shaft 100.

It would be desirable for the rotor core 200 to have a diameter larger than the diameter of the shaft 100.

In the present invention, as an example, the magnetic member 400 is used to form a stationary magnetic field in the rotor core 200, but it can also be replaced by winding a coil around the rotor core 200 without using the magnetic member 400. will be.

As such, the rotor core 200 is a part that is coupled with the shaft 100 and rotates together.

And, a fixing means 300 is coupled to the outer ring of the rotor core 200.

The fixing means 300 includes a fixing body 310 that is coupled to the rotor core 200 and forms an external shape, and is formed in plural pieces along the circumference of the fixing body 310, into which the magnet member 400 is inserted. It is located between the insertion hole 320 and two adjacent insertion holes 320, which are formed in plural numbers along the circumference of the fixing body 310, and in the process of inserting the magnet member 400 into the insertion hole 320. To prevent damage to the magnet member 400 inserted into the adjacent insertion hole 320, or to prevent the magnet member 400 from being inserted into the insertion hole 320 during the process of inserting the magnet member into the insertion hole 320. It is configured to include a deformation hole 330 to prevent damage.

The fixed body 310 has a shape similar to a circular pillar with a portion of the upper surface and a portion of the lower surface open and a hollow interior, and is a portion that is coupled to the rotor core 200 by being press-fitted into the rotor core 200.

An insertion hole 320 is formed on the peripheral surface of the fixing body 310.

The insertion holes 320 are formed through the outer ring of the fixing body 310 toward the inner ring, and are formed in plural numbers on the circumferential surface of the fixing body 310.

In this way, as a plurality of insertion holes 320 are formed in the fixing body 310, the fixing body 310 takes a pus-shaped shape.

As such, it is preferable that the insertion hole 320 be formed to gradually widen in width as it penetrates from the outer ring of the fixing body 310 in the inward direction.

That is, as shown in FIG. 3, the insertion hole 320 has a wider width (right and left in FIG. 3) on the inner ring side of the fixed body 310 than on the outer ring side.

In this way, the insertion hole 320 has a wider width on the inner ring side than the outer ring side of the fixing body 310, thereby preventing the magnet member 400 inserted into the insertion hole 320 from being separated.

In addition, the insertion hole 320 is preferably formed in the fixed body 310 at a height corresponding to the height of the rotor core 200.

To explain once more, the fixing force of the magnet member 400 is improved by forming the insertion hole 320 at an angle.

In addition, a deformation hole 330 is formed on the peripheral surface of the fixing body 310.

The deformation hole 330 is formed through the outer ring of the fixing body 310 toward the inner ring. In the process of inserting the magnet member 400 into the insertion hole 320, a part of the fixing body 310 is deformed. It is a configuration that allows this to happen.

This deformation hole 330 is formed in a portion of the peripheral surface of the fixing body 310 where the insertion hole 320 is not formed.

That is, the deformation hole 330 is formed between two adjacent insertion holes 320.

In addition, the deformation hole 330 is preferably formed in the fixing body 310 at a height lower than the height of the insertion hole 320.

To explain one more time, when looking at the circumferential surface of the fixed body 310, the insertion hole - deformation hole - insertion hole - deformation hole are located sequentially.

As such, the deformation hole 330 is configured to provide a spare area that allows the fixing body 310 to be deformed during the process of press-fitting the magnet member 400 into the insertion hole 320.

In more detail, when the deformation hole 330 is not formed in the fixing body 310, in the process of press-fitting the magnet member 400 into the insertion hole 320, the magnet member 400 is first inserted. This is because a deforming force is applied to the nearby insertion hole 320, and at this time, damage to the magnet member inserted into the nearby insertion hole 320 may occur.

In addition, when the deformation hole 330 is not formed in the fixing body 310, in the process of press-fitting the magnet member 400 into the insertion hole 320, a part of the fixing body 310 is not deformed, so that the magnet member 400 is not deformed. This is because it may cause damage to (400).

Therefore, in the rotor according to the present invention, the two problems described above can be solved by forming the deformation hole 330 in the fixed body 310.

Of course, the fixing body 310 is preferably made of a material that has ductility so that it can be deformed and have elasticity so that it can return to its original form.

In addition, the deformation of the fixing body 310 by the deformation hole 330 is not large, but allows the magnet member 400 to be inserted into the insertion hole 320 without damage and the insertion hole 320. It would be desirable to deform the magnet member 400 inserted inside into a narrow width so that it does not come off.

By the fixing means 300 configured in this way, the magnet member 400 is fixed and installed in the same direction as the shaft 100.

That is, the magnetic member 400 is fixed and installed in the correct position without change by the fixing means 300.

Here, the correct position means that the magnetic member 400 is parallel to the shaft 100.

In addition, the process of applying adhesive to the magnetic member or waiting for the adhesive to harden by the fixing means 300 is eliminated, thereby greatly reducing the time required to fix the magnetic member 400.

In this way, the magnetic member 400 is inserted into the fixing means 300.

The magnet member 400 is configured to allow the shaft 100 to rotate by a rotating magnetic field, and is provided in plural numbers.

In addition, the magnet member 400 is preferably formed in a shape similar to an arc so as to be in close contact with the outer ring of the rotor core 200 and fills the inside of the insertion hole 320.

That is, the magnet member 400 has a shape corresponding to the insertion hole.

In more detail, the outer ring side of the magnet member 400 has a shape with a shorter length than the inner ring side.

To explain once more, as shown in FIG. 4, the width gradually increases from the inner ring side of the magnet member 400 (right or left in FIG. 4) to the outer ring side of the magnet member 400 (left or lower in FIG. 4). This is to prevent the magnet member 400 from being separated from the inside of the insertion hole 320 by being inclined to narrow it.

That is, the magnet member 400 has a shape corresponding to the insertion hole 320 and is formed so that it can be fixed inside the insertion hole 320.

In addition, the rotor core 200 is further provided with a cover 500 that blocks the rotor core 200 from the outside.

The cover 500 is designed to block the rotor core 200 from the outside, so as to protect the rotor core 200 and the magnet member 400 and to ensure a beautiful appearance of the rotor according to the present invention. It is for this purpose.

In other words, since the rotor according to the present invention is provided with a fixing means, it becomes easy to fix the magnetic members divided into the rotor core in position (fixing them in a direction parallel to the shaft).

In addition, since the rotor according to the present invention is provided with a fixing means, the process for fixing the magnetic member is shortened.

Additionally, in the rotor according to the present invention, damage to the magnet member is prevented by forming a deformation hole in the fixing means.

At the same time, in the rotor according to the present invention, the fixing force of the magnetic member is improved as the insertion hole is formed at an angle.

The scope of the present invention is not limited to the embodiments illustrated above, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

100. Shaft 200. Rotor core
300. Fixing means 310. Fixing body
320. Insertion hole 330. Transformation hole
400. Magnet member 500. Cover

Claims (5)

A shaft that transmits power;
a rotor core coupled to the outer ring of the shaft and allowing the magnetic member to be spaced apart from the shaft;
A fixing means coupled to the rotor core, accommodating a magnetic member therein, and made of a material having ductility and elasticity;
At least one magnetic member coupled to the fixing means and allowing the shaft to be rotated by the stator;
The fixing means is,
A fixed body coupled to the rotor core and forming an external shape;
A plurality of insertion holes are formed along the circumference of the fixing body and are gradually widened in an inward direction from the outer ring of the fixing body, through which a magnetic member is inserted.
It is formed at a height lower than the height of the insertion hole between two adjacent insertion holes, which are areas on the circumferential surface of the fixing body where no insertion hole is formed, so that a part of the fixing body may be deformed during the process of press-fitting the magnet member into the inside of the insertion hole. Includes a deformation hole that allows
The rotor is characterized in that the magnet member is formed so that the outer ring side has a shorter length than the inner ring side to correspond to the insertion hole. According to claim 1,
The rotor core is further provided with a cover that blocks the rotor core from the outside. delete delete delete

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