KR20210000897A - A movable cradle for motor solo run test - Google Patents

Abstract

The present invention relates to a movable cradle for a motor solo run test and, more specifically, to a movable cradle for a motor solo run test, capable of increasing the integrity and reliability of a motor solo run test by enabling a motor to be firmly and stably held regardless of the type and size of the motor. To achieve the purpose, the movable cradle for a motor solo run test includes: a base frame; a horizontal frame placed above the base frame, and including a center hole penetrated vertically; a pair of motor support frames placed on both sides of the horizontal frame with respect to the center hole to be moved toward the center hole, and individually including an arc-shaped compression surface corresponding to the curvature of the outer circumference surface of a motor and formed toward the center hole; a confinement means installed to confine the movement of the motor support frames on the horizontal frame; and a height control means installed between the base frame and the horizontal frame to control the height of the horizontal frame with respect to the base frame.

Description

A movable cradle for motor solo run test}

The present invention relates to a portable cradle for a solo run test of an electric motor, and more particularly, to a portable cradle for a solo run test of an electric motor that can be stably and firmly fixed irrespective of the motor type.

Various types of high and low voltage motors are used to rotate pumps for water supply in power plants such as thermal power plants, hydroelectric power plants, and nuclear power plants, or to transmit rotational power to various equipment in general industrial facilities. High and low voltage motors are devices that convert mechanical rotational energy into electrical energy, and include synchronous high and low voltage motors and induction high and low voltage motors. It is important to maintain a lasting life while maintaining reliability by combining these motors with mechanical devices (couplings, gears, etc.). To this end, it is important to ensure the integrity and reliability of the motor through regular performance tests.

Let's take a brief look at how to test the performance of the motor as described above.

In the case of a vertical motor (1), as shown in Fig. 1, a sleeper (2) is used to secure a space under the motor for installation of the motor (1), and a chain block (3) is used to secure the motor (1). After supporting, perform a solo run test.

In addition, in the case of the horizontal flange-type motor 4, as shown in FIG. 2A, since it is impossible to perform a solo run test, the motor after combining the load 5 and the motor 4 as shown in FIG. 2B (4) test the performance.

However, the solo run test method for the vertical electric motor 1 and the horizontal flange type electric motor 4 has the following problems.

In the case of a vertical motor (1), the sleeper (2) for securing space not only provides a very unstable state due to the influence of vibration generated from the motor (1), but also the motor (1) is There is a problem that human/physical damage may be largely caused by falling and colliding with a mechanical device below the electric motor 1.

In the case of the horizontal flange type motor (4), it is difficult to verify the inherent integrity and reliability of the motor (4) because the solo run test is performed in combination with a separate load (5). 4) If a problem occurs after coupling, a problem of equipment damage may occur, such as having to reconnect the motor 4 to the load 5.

In order to solve this problem, a separate jig was prepared and tested for performance after fixing the motor by preparing a separate jig as disclosed in “Korea Registered Office No. 0117309” and “Korea Open Utility No. 2000-0011099”.

However, the conventional electric motor test jigs have a limitation in performing a solo run test only on a horizontal type electric motor.

Republic of Korea Registration Office No. 0117309 Republic of Korea Public Utility 2000-0011099

The present invention has been conceived to solve the above problems, and an object of the present invention is to provide a portable cradle for a solo run test of an electric motor to increase the soundness and reliability of a solo run test of an electric motor regardless of the type and size of the electric motor. I wanted to.

The present invention to achieve the above object, the base frame; A horizontal frame disposed above the base frame and having a central hole penetrating up and down; A pair of arc-shaped pressing surfaces corresponding to the curvature of the outer circumferential surface of the motor, respectively formed toward the central hole, disposed on both sides of the horizontal frame with respect to the central hole and installed to move toward the central hole Motor support frame of the; Restraining means installed to restrain the motion of the motor support frame on the horizontal frame; And a height adjusting means installed between the base frame and the horizontal frame to adjust the height of the horizontal frame with respect to the base frame.

At this time, it is preferable that a rolling means is installed on the base frame.

In addition, an unevenness is formed in any one of the horizontal frame and the electric motor support frame, and the restraint means is installed on the other one of the horizontal frame and the electric motor support frame, and is inserted into the concave portion. It is preferable that it is installed so as to restrict the motion of the motor support frame.

In addition, the electric motor support frame is preferably divided into a first motor support frame installed to be movable on the horizontal frame and a second motor support frame installed to be movable on the first motor support frame.

The mobile cradle for a solo run test of an electric motor according to the present invention has the following effects.

First, since the mobile cradle for the electric motor solo run test can be adjusted in height upward, and can be fixed on both sides of the motor while spreading or constricting on both sides of the motor based on the motor, the motor can be operated regardless of the type or size of the motor. Can be mounted.

In addition, since the motor support frame supports the motor by compressing it from both sides, the motor can be firmly supported.

Accordingly, since the mobile cradle for the electric motor solo run test can stably perform the electric motor mounting, there is an effect of improving the soundness and reliability of the electric motor solo run test.

Second, since the mobile cradle for the electric motor solo run test can be moved through wheels, it can easily cope with a horizontal flange type motor suspended in the air.

Accordingly, the mobile cradle for the electric motor solo run test can increase the efficiency of the solo run test work of the horizontal flange type electric motor.

1 is a view showing a conventional technique for performing a solo run test by seating a vertical electric motor on a sleeper.
2A and 2B are diagrams illustrating a prior art for performing a performance test of an electric motor by coupling a horizontal flange-type electric motor suspended in the air to a load.
3 is a perspective view showing a mobile cradle for a solo run test of an electric motor according to a preferred embodiment of the present invention.
4 is a side view showing a mobile cradle for a solo run test of an electric motor according to a preferred embodiment of the present invention.
5A and 5B are plan views showing the motion of the motor support frame of the mobile cradle for a solo run test of an electric motor according to a preferred embodiment of the present invention.
6 is a view showing a state in which an electric motor is fixed to a mobile cradle for a solo run test of an electric motor according to a preferred embodiment of the present invention.

Terms and words used in the present specification and claims are not limited to the usual or dictionary meanings, and the inventor is based on the principle that the concept of terms can be appropriately defined in order to explain his or her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Hereinafter, a mobile cradle for a solo run test of an electric motor according to a preferred embodiment of the present invention (hereinafter referred to as a'movable cradle') will be described with reference to FIGS. 3 to 6.

Regardless of the type and size of the motor, the movable cradle can effectively mount the motor, thereby increasing the reliability of the motor solo run test.

The movable cradle includes a base frame 100, a horizontal frame 200, an electric motor support frame 300, a restraint means 400, and a height adjustment means 500, as shown in FIG. 3.

The base frame 100 constitutes the lower portion of the movable cradle, and is configured to support the upper portion of the movable cradle on the ground. The base frame 100 is preferably provided in a rectangular shape, and includes a rolling means 110 to facilitate movement of the movable cradle. The rolling means 110 may be configured to roll the ground, and is preferably provided with a caster 110 as shown in FIG. 3. A stopper (not shown) capable of restraining the rolling action is installed on the caster 110 to restrain the movement of the movable cradle during the solo run test of the electric motor, so that the solo run test may be performed in a stable state.

The horizontal frame 200 is provided for installing an electric motor support frame, and is disposed above the base frame 100. The horizontal frame 200 is preferably provided in a shape corresponding to the base frame 100. The horizontal frame 200 is formed with a central hole 210 penetrating up and down. The central hole 210 is configured such that the shaft of the electric motor M is passed and faces downward of the horizontal frame 200. With this configuration, the motor M is mounted on the upper surface of the horizontal frame 200 by passing the shaft through the central hole 210.

The motor support frame 300 serves to support the motor M seated on the horizontal frame 200 from both sides of the motor M and is provided on the horizontal frame 200. The motor support frame 300 is provided as a pair that can move toward the central hole 210 from both sides of the central hole 210 with respect to the central hole 210 of the horizontal frame 200. The opposing surface of the motor support frame 300 forms an arc-shaped pressing surface 310 that can correspond to the curvature of the outer circumferential surface of the motor M. It is preferable that a contact member 311 made of a rubber material is further installed on the pressing surface 310 to increase adhesion to the motor M and prevent damage to the motor M.

It is preferable that the electric motor support frame 300 is divided up and down. This is to increase the efficiency of supporting the motor (M), so that when the outer peripheral surface diameter of the motor (M) is formed differently, the divided motor support frame (300) corresponds to each position of the motor (M) to support it. It is for sake. In this specification, for convenience of description, it is assumed that the motor support frame 300 is divided into two parts.

The motor support frame 300 is composed of a first motor support frame 320 that can move on the horizontal frame 200 and a second motor support frame 330 that is installed to move on the first motor support frame 320. . The motor support frame 300 having such a configuration compresses the outer circumferential surface of the motor M located in the central hole 210 while moving toward the central hole 210 of the horizontal frame 200 to form the motor on the horizontal frame 200. (M) can be fixed. Although the configuration for the movement of the motor support frame 300 is not shown, the configuration is not specified. A known sliding configuration may be applied to enable movement of the motor support frame 300.

The restraint means 400 serves to restrain the motion of the motor support frame 300. That is, the restraint means 400 restrains the movement of the first motor support frame 320 on the horizontal frame 200 and restrains the movement of the second motor support frame 330 on the first motor support frame 320. will be.

The restraint means 400 is composed of an uneven portion formed along a path in which the motor support frame 300 moves, and a convex portion formed in the motor support frame 300 corresponding to the uneven portion of the uneven portion. desirable. In detail, the restraining means 400 is preferably composed of a wedge 410, a wedge pin 420, and a spring 430, as shown in FIG. 4. The wedge 410 is provided on a path providing movement of the motor support frame 300, and is formed in plurality along the path. The wedge pin 420 is provided on the motor support frame 300 corresponding to the path in which the wedge 410 is formed, and is provided in a form capable of engaging the wedge 410. The wedge pin 420 is elevated above the wedge 410, and a ring is preferably formed at the upper end of the wedge 410 for easy gripping by the operator. The spring 430 provides an elastic force to the lifting action of the wedge pin 420. When the operator lifts the wedge pin 420 upward, the wedge pin 420 acts on a force to descend by the elastic force of the spring 430.

The restraint means 400 is installed to limit the movement of each of the dividedly configured first motor support frame 320 and the second motor support frame 330. The wedge 410 is installed on the horizontal frame 200 and the upper surface of the first motor support frame 320, and the wedge pin 420 is installed on the first motor support frame 320 and the second motor support frame 330 It becomes.

The height adjustment means 500 serves to adjust the height of the horizontal frame 200 based on the ground. An electric motor (M) is supported on the horizontal frame 200, and by adjusting the height of the horizontal frame 200, the height of the electric motor (M) relative to the ground is adjusted to optimize the solo run test environment of the electric motor (M). There is.

Height adjustment means 500, as shown in Figure 4, the linker 510 installed at an intersection between the base frame 100 and the horizontal frame 200, and a fixing hole 520 formed in the horizontal frame 200, It includes a fixing pin (530). The linker 510 supports the horizontal frame 200 on the base frame 100 and is provided as a pair intersecting with each other. One end of the linker 510 is hinged on the base frame 100, and the other end of the linker 510 forms a corresponding hole 511 corresponding to the fixing hole 520 of the horizontal frame 200. The fixing pin 530 serves to fix the other end of the linker 510 to the horizontal frame 200. That is, the fixing pin 530 is inserted into the fixing hole 520 of the horizontal frame 200 and the corresponding hole 511 of the linker 510 to constrain the movement of the linker 510.

On the other hand, it is preferable that the motor fixing block 340 is installed on the second motor support frame 330 of the motor support frame 300. The motor fixing block 340 is a configuration for further reinforcing the restraint of the motor M supported on the horizontal frame 200 by the motor support frame 300. It is preferable that the motor fixing block 340 is provided as a chain block. One side chain of the chain block 340 is caught and fixed by the second motor support frame 330, and the other side chain of the chain block 340 is caught and fixed by the electric motor (M). ) The binding force can be further strengthened.

Hereinafter, a process of fixing the electric motor to the mobile cradle having the above-described configuration will be described.

In consideration of the size of the electric motor M and other test environments, the operator adjusts the height of the horizontal frame 200. The operator rotates one end of the linker 510 to correspond the other end of the linker 510 to the fixing hole 520 of the horizontal frame 200, and then restrains the movement of the linker 510 using a fixing pin 530 Let it. Accordingly, the height adjustment of the horizontal frame 200 is completed based on the base frame 100.

By releasing the restraint means, the operator moves the first motor support frame 320 and the second motor support frame 330 to increase the gap between the pressing surfaces 310 as shown in FIGS. 5A and 5B. The operator places the motor M in the horizontal frame 200 with the shaft of the motor M inserted into the central hole 210. Thereafter, the operator moves the first motor support frame 320 and the second motor support frame 330 to compress the outer circumferential surface of the electric motor M. At this time, the contact member 311 is in close contact with the outer peripheral surface of the electric motor (M).

The operator engages the wedge pin 420 with the wedge 410, thereby restraining the motion of the motor support frame 300. Accordingly, the electric motor M is fixed to the mobile cradle as shown in FIG. 6. At this time, the wedge pin 420 is elastically supported by the elastic force of the spring 430, and the motor support frame 300 can be maximized by the contact member 311 so that the electric motor M is stably supported by the movable cradle. Can be mounted.

As described so far, the mobile cradle for a solo run test of an electric motor according to the present invention is capable of stably and firmly mounting the electric motor for performing the solo run test. Accordingly, the soundness and reliability of the solo run test of various electric motors can be improved.

In the above, the present invention has been described in detail with respect to the described embodiments, but it is obvious to those skilled in the art that various modifications and modifications are possible within the scope of the technical idea of the present invention, and it is natural that such modifications and modifications fall within the scope of the appended claims.

100: base frame 110: rolling means
200: horizontal frame 210: central hole
300: motor support frame 310: crimp surface
311: contact member 320: first motor support frame
330: second motor support frame 340: motor fixing block
400: restraint means 410: wedge
420: wedge pin 430: spring
500: height adjustment means 510: linker
511: response hole 520: fixed hole
530: fixing pin

Claims (4)

Base frame;
A horizontal frame disposed above the base frame and having a central hole penetrating up and down;
A pair of arc-shaped pressing surfaces corresponding to the curvature of the outer circumferential surface of the motor, respectively formed toward the central hole, disposed on both sides of the horizontal frame with respect to the central hole and installed to move toward the central hole Motor support frame of the;
Restraining means installed to restrain the motion of the motor support frame on the horizontal frame; And
A mobile cradle for a solo run test of an electric motor comprising a height adjusting means installed between the base frame and the horizontal frame to adjust the height of the horizontal frame with respect to the base frame. The method of claim 1,
A mobile cradle for a solo run test of an electric motor, characterized in that rolling means is installed on the base frame. The method according to claim 1 or 2,
Any one of the horizontal frame and the electric motor support frame is provided with an unevenness (凹凸),
The restraint means is installed on the other one of the horizontal frame and the motor support frame, and is inserted into the concave portion to restrain the motion of the motor support frame. . The method according to claim 1 or 2,
The electric motor support frame,
A mobile cradle for a solo run test of an electric motor, characterized in that it is divided into a first motor support frame installed to be movable on the horizontal frame and a second motor support frame installed to be movable on the first motor support frame.

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