KR102077745B1 - Isolation device having heat exchanger for recovery waste - Google Patents

Abstract

The present invention relates to a seismic apparatus placed in the lower part of a power generator with a detachable heat exchanger installed for the collection of waste heat produced during operation. The seismic apparatus includes: a plurality of support pillars; a seismic frame in which an apparatus is installed; a plurality of elastic bags installed between the support pillars and the seismic frame to absorb vibrations transferred between the support pillars and the seismic frame, and capable of being expanded by air; a compressor supplying high-pressure air to the elastic bags to enable the bags to be expanded to support the seismic frame; a supply pipe connected to lead the air supplied from the compressor to be injected into the elastic bags; a one-way check valve installed in the supply pipe to prevent a counterflow of air from the elastic bags; and a second seismic unit installed in one side of the seismic frame to support the heat exchanger.

Description

Isolation device having heat exchanger for recovery waste

The present invention relates to a seismic isolator of a generator provided with a heat exchanger for recovering waste heat, and more particularly, to absorb and offset the transmission of vibration from the floor to the device or from the device to the floor. The present invention relates to a seismic isolator of a generator provided with a heat exchanger for recovering waste heat that can be absorbed and offset.

If vibration is transmitted by an earthquake or other external shock, inertial force may be generated at major connections or elements in the mechanical equipment, and the equipment may not work properly or may be destroyed in severe cases. Severe vibrations such as floor cracks are caused by continuous vibrations to the ground. In order to reduce the damage to the vibration of these devices, a dustproof device is used.

Conventional dustproof devices use rubber feet, rubber pads or springs to prevent vibration from being transmitted.

In this case, there was a problem that the dustproof performance is lowered because it does not exhibit the effective dustproof performance.

Publication No. 10-2001-0049101 (published June 15, 2001) Registered Patent No. 10-1666166 (Registration date October 07, 2016)

The present invention can be equipped with devices such as engines, compressors, heat exchangers and other equipment that generates vibrations, and prevents vibrations from being transmitted in three-dimensional directions in the vertical direction as well as in the horizontal direction between the device such as the engine and the floor. It is possible to, and an object of the present invention is to provide a seismic isolator of a generator provided with a heat exchanger for the recovery of waste heat excellent in seismic performance.

In addition, an object of the present invention is to provide a seismic isolator of the generator provided with a heat exchanger for the recovery of waste heat can be detachably installed and the heat exchanger for the recovery of waste heat generated during operation.

In order to solve the above problems, the present invention provides a seismic isolator provided in the lower portion of the generator detachably installed heat exchanger for the recovery of waste heat generated during operation, wherein the seismic isolator is equipped with a plurality of support pillars, A base isolation frame, a plurality of elastic bags mounted between the support pillar and the base isolation frame to absorb vibrations transmitted between the base isolation frame and the support pillar, and which may be inflated with air; A compressor for supplying high-pressure air to the elastic bag so as to inflate the elastic bag for supporting, a supply pipe connected to inject air supplied from the compressor into the elastic bag, and air flows back from the elastic bag One-way check valve mounted on the supply pipe and one of the base isolation frame to prevent Installed on provides a seismic isolation system of the generator heat exchanger is provided for heat recovery, comprising a second base isolation unit for supporting the heat exchange group.

The second base isolation unit may include an end portion between a second base isolation frame supporting the heat exchanger, a second base frame installed under the second base isolation frame, and the second base frame and the second base isolation frame. A convex convex rod having a spherical shape, and a pair of vertically coupled at each end with a concave rod whose end is concave, and a plurality of pairs of positions of the convex rod and the concave rod are alternately arranged so that the second isolating frame Provides a seismic isolator of the generator provided with a heat exchanger for the recovery of waste heat, characterized in that the second column that can accommodate the rotation of the convex rod and the concave rod is composed of an elastic member to absorb the shock. .

In addition, it provides a base isolation device further comprises a base frame installed on the floor to support the plurality of support pillars.

In addition, the leveling device further comprises a plurality of the leveling valve mounted to the inlet of the supply pipe flowing into the respective elastic bag in order to level the base isolation frame.

In addition, the first interference protrusion coupled to the upper portion of the base frame, and the second interference coupled to the lower portion of the base isolation frame so as to prevent the base isolation frame from sliding up, down, left and right with respect to the first interference protrusion And an interference means having an interference protrusion and an impact absorbing pad mounted to at least one of the first interference protrusion and the second interference protrusion to prevent the first interference protrusion from directly colliding with the second interference protrusion. Provided is a seismic isolator characterized in that.

According to the present invention, since the base isolation frame supports the base isolation frame with an elastic bag filled with air, vibration can be prevented from being transmitted in the vertical direction between the base isolation frame and the base frame.

In addition, according to the present invention, the heat exchanger for desorption of waste heat can be detached and can be isolated against the vibration in the three-dimensional direction generated in the heat exchanger.

Further, according to the present invention, the plurality of elastic bags have a height that is increased by the leveling valve.

Since it remains the same, the device mounted on the base isolation frame can be kept horizontal.

Further, according to the present invention, since the base isolation frame can be prevented from sliding horizontally by the interference means, vibration can be prevented from being transmitted horizontally.

1 is a front view of an embodiment of a seismic isolator of a generator provided with a heat exchanger for waste heat recovery according to the present invention.
FIG. 2 is a partial plan view of a seismic isolator of a generator provided with a heat exchanger for recovering waste heat shown in FIG. 1.

Hereinafter will be described with reference to the accompanying drawings, an embodiment of the present invention. The following description and the accompanying drawings are presented for the overall understanding of the present invention, and thus, the technical scope of the present invention is not limited thereto, and detailed descriptions of well-known structures and functions that may unnecessarily obscure the subject matter of the present invention are provided. It will be omitted.

1 and 2 will be described an embodiment of a seismic isolator of a generator provided with a heat exchanger for recovering waste heat according to the present invention.

The seismic isolator of a generator provided with a heat exchanger for recovering waste heat according to the present invention includes a base frame 100, a support pillar 150, a seismic isolation frame 200, an elastic bag 250, a compressor 300, And a supply pipe 350, a check valve 400, a leveling valve 500, and an interference means 550.

Base frame 100 is installed on the floor. A plurality of support pillars 150 are mounted on the base frame 100. In this example, six were mounted.

The base isolation frame 200 is equipped with a device such as the engine (1).

The elastic bag 250 is mounted between each support pillar 150 and the base isolation frame 200 to absorb the vibration transmitted between the base isolation frame 200 and the base frame 100, it may be inflated with air. . The elastic bag 250 is inflated with air and may be formed of rubber or the like to support the base isolation frame 200.

The compressor 300 supplies high pressure air to the elastic bag 250 so that the elastic bag 250 can inflate the elastic bag to support the base isolation frame 200. Since the device having a weight load is fixed to the base isolation frame 200, air is continuously supplied to the elastic bag 250 supporting the base bag 200 through the compressor 300.

The supply pipe 350 is connected to the elastic bag 250 in the compressor 300 so that the air supplied from the compressor 300 is injected into the elastic bag 250.

The check valve 400 is mounted to the supply pipe 350 to allow air to flow in only one direction to the supply pipe 350 in order to prevent backflow of the air from the elastic bag 250.

The second isolation unit 450 is installed at one side of the isolation frame 200 to support the heat exchanger 2 for recovering the waste heat of the engine, that is, the equipment generated during operation.

Here, the second isolation unit 450 includes a second isolation frame 460, a second base frame 470, a second pillar 480, and an elastic member 490.

The second isolation frame 460 is a frame supported by the heat exchanger 2.

The second base frame 470 is a frame installed at the bottom of the second isolation frame 460.

The second pillar 480 is installed between the second base frame 470 and the second seismic frame 460, and has a convex bar 482 having a convex end in a spherical shape, and a concave bar having a concave end. 484 and a pair that is vertically coupled at each end, and a plurality of positions of the pair of the convex bar 482 and the concave bar 484 are alternately arranged to accommodate the rotation of the second isolation frame 460. Can be.

For example, the convex bar 482 is installed in the second base frame 460 on the left side and the second base frame 470 on the right side, and the concave bar 484 on the second base frame 470 on the left side. And installed on the right side to be installed on the second seismic frame (460). By changing the positions of the convex bar 482 and the concave bar 484 in this way, the maximum movement and the maximum rotation angle of the second vibration isolation frame 460 can be limited, and the rotation can be stably supported.

In detail, the second pillar 480 has a convex rod 482 and a concave rod 484 closely coupled to each other, so that the second seismic isolation frame 460 on the upper side is spherical to rotate in the horizontal direction and the movement and the vertical direction. Since it can return to an initial position by accommodating, it can receive all the vibration directions of the heat exchanger 2 eventually.

The elastic member 490 is installed between the convex bar 482 and the concave bar 484 can absorb the shock generated by the heat exchanger (2), the embodiment of the present invention was carried out by a rubber pad with a curved surface .

By installing the second column 480 and the elastic member 490, the heat exchanger can be protected by accommodating movement and rotation generated in the heat exchanger, and vibration and noise generated in the heat exchanger by the elastic member 490. Can be further reduced.

The leveling valve 500 is mounted at the inlet of the supply pipe 350 introduced into each elastic bag 250 in order to level the seismic isolation frame 200. The elastic bag 250 is provided with a level sensor (not shown) to adjust the leveling valve 500 when the height of the elastic bag 250 does not match to adjust the amount of air flowing into the elastic bag 250. So the height of the elastic bag 250 can be tailored to match each other. Therefore, the seismic isolation frame 200 may be maintained horizontally by the leveling valve 500.

The interference means 550 prevents the base isolation frame 200 from horizontally shaking. To this end, the interference means 550 includes a first interference protrusion 551, a second interference protrusion 553, and an impact absorption pad 555.

The first interference protrusion 551 is coupled to the upper portion of the base frame 100. In the present embodiment, the first interference protrusion 551 includes a vertical protrusion 551a and a horizontal protrusion 551b on the upper portion of the base frame 100.

The second interference protrusion 553 is interfered with the first interference protrusion 551 and is coupled to the bottom of the isolation frame 200 to prevent the isolation frame 200 from sliding up, down, left, and right with respect to the base frame 100. In the present embodiment, the second interference protrusion 553 is formed in a 'b' or 'b' shape and coupled to the base isolation frame 200 so as to be located next to the orthogonal vertical protrusion 551a and the horizontal protrusion 551b.

The shock absorbing pad 50 is mounted on the second interference protrusion 553 so that the first interference protrusion 551 and the second interference protrusion 553 directly collide with each other to prevent vibration from occurring. That is, the shock absorbing pad 555 is positioned between the first interference protrusion 551 and the second interference protrusion 553 to absorb the shock. In the present embodiment, the shock absorbing pad 555 is mounted on the second interference protrusion 553, but may be mounted on the first interference protrusion 551.

In the present embodiment, when the high-pressure air is supplied to the elastic bag 250 using the compressor 300, the elastic bag 250 is inflated to support the base isolation frame 200. At this time, since the check valve 400 is mounted to the supply pipe 350 and air is continuously supplied through the compressor 300, the elastic bag 250 may maintain a constant height.

When the vibration is introduced through the floor due to an earthquake or the like or the vibration is transmitted through the base isolation frame 200 by the operation of the engine 1, the elastic bag 250 absorbs the vibration in the vertical direction. In addition, the base frame 100 and the base isolation frame 200 is limited in the horizontal vibration by the interference means 550 having the first interference protrusion 551 and the second interference protrusion 553, the shock absorbing pad ( 555 absorbs vibration. Therefore, according to the present embodiment, it is possible to prevent vibration from being transmitted between the base frame 100 and the base isolation frame 200.

The present invention described above is not limited to the above-described embodiments, and various changes can be made by those skilled in the art without departing from the gist of the present invention as claimed in the following claims. It should be regarded as falling within the protection scope of the claims to the extent that it can be implemented.

1: engine 100: baseframe
150: support pillar 200: base isolation frame
250: elastic bag 300: compressor
350: supply pipe 400: check valve
450: second base isolation unit 460: second base isolation frame
470: second base frame 480: second pillar
482: convex bar 484: concave bar
490: elastic member 500: leveling valve
550 interference means 551 first interference protrusion
553: second interference protrusion 555: shock absorbing pad

Claims (5)

In the seismic isolator provided in the lower portion of the generator detachably installed heat exchanger for recovery of waste heat generated during operation,
The seismic isolator,
Plural support columns,
A base isolation frame to which the device is mounted,
To absorb the vibration transmitted between the base isolation frame and the support pillar
And a plurality of elastic bags mounted between the support pillar and the base isolation frame, which can be inflated with air,
The elastic bag can inflate the elastic bag to support the base isolation frame
A compressor for supplying high pressure air to the elastic bag,
A supply pipe connected to inject air supplied from the compressor into the elastic bag;
A one-way check valve mounted to the supply pipe to prevent backflow of air from the elastic bag;
A second isolation unit installed on one side of the isolation frame to support the heat exchanger;
The second isolating unit,
A second isolation frame supporting the heat exchanger;
A second base frame installed below the second isolating frame,
Between the second base frame and the second seismic frame, a convex rod whose end is convex in shape and a pair of concave rods whose ends are concave are vertically coupled at each end, and the convex rod and the concave rod A second column having a plurality of positions alternately arranged to accommodate rotation of the second base isolation frame;
A seismic isolator of a generator provided with a heat exchanger for recovering waste heat, characterized in that it is configured between the convex rod and the concave rod to absorb an impact. delete The method of claim 1,
A base isolation device of a generator provided with a heat exchanger for recovering waste heat, further comprising a base frame installed on a floor to support the plurality of support columns. The method of claim 3,
And a plurality of leveling valves mounted at inlets of the supply pipes flowing into the elastic bags so as to level the base isolation frame. The method of claim 4, wherein
A first interference protrusion coupled to an upper portion of the base frame, and the first interference protrusion
A second interference protrusion coupled to a lower portion of the base isolation frame to prevent the base isolation frame from sliding up, down, left, and right with respect to the base frame, and to prevent the first interference protrusion from directly colliding with the second interference protrusion. And an interference means having an impact absorbing pad mounted on at least one of the first interference protrusion and the second interference protrusion.

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