KR102579918B1 - Compressor Vibration Isolator - Google Patents

Abstract

The present invention provides a compressor vibration isolator for compressing and supplying refrigerant to an air conditioner equipped with a movement module and a dust removal module. According to the present invention, the compressor vibration isolator comprises a moving module for absorbing vibrations generated during operation of a compressor, and for moving or fixing a position of the compressor, in a lower part of the compressor which compresses a refrigerant by piston reciprocation for compressively supplying the refrigerant to an air conditioner. The moving module includes: a vibration-resistant part which is fixedly installed on a bottom surface of the compressor and absorbs vibration generated during operation of the compressor; a wheel part for moving or fixing the position of the compressor; and a mobile module body provided with two sliding rails along the longitudinal direction on the upper surface. The present invention duplicates the structure of the air conditioner refrigerant pipe which transports the refrigerant gas in relation to the compressor vibration isolator, so that even if one of the two duplicated pipes is damaged by an external force, the refrigerant gas can be prevented from leaking.

Description

Compressor Vibration Isolator}

The present invention relates to a compressor dust isolator. In relation to the compressor dust isolator, the structure of the air conditioner refrigerant pipe that transports the refrigerant gas is doubled, so that even if one of the two double pipes is damaged by an external force, the refrigerant gas is prevented from leaking. It can be prevented.

Even if the manager does not recognize the damage to the refrigerant pipe, the refrigerant gas does not leak out, so unnecessary overuse of the refrigerant gas can be prevented, which can also have the effect of preventing global warming caused by refrigerant gas.

In addition, the present invention includes a vibration isolation device to alleviate the impact on the compressor itself, thereby minimizing refrigerant gas leakage due to damage and solving the problem of excessive use of refrigerant gas that causes ozone layer destruction.

More specifically, it relates to a vibration isolation device for a compressor equipped with a movement module including a vibration resistance unit and a dust removal module.

Air conditioners use engine power directly to compress and expand refrigerant to lower the indoor temperature.

These air conditioners have a basic configuration of vents that supply cold air inside, a refrigerant circulation system for circulation of the refrigerant, and a compressor to compress the expanded refrigerant.

Among these, the compressor is a main device that is connected to the refrigerant circulation system and compresses the refrigerant by the driving force of the engine.

This compressor is driven by receiving power from the engine by driving an electric relay that is turned on/off in response to a signal from the air conditioner controller.

Conventional compressors inevitably generate tremendous noise and vibration when operating. The vibration causes the compressor's position to continuously change, causing problems with workers' hearing loss due to the noise.

Therefore, it is intended to improve the above problems with the compressor vibration isolator of the present invention.

The present invention duplicates the structure of the air conditioner refrigerant pipe that transports the refrigerant gas in relation to the compressor dust isolator, so that even if one of the two duplicated pipes is damaged by an external force, the refrigerant gas can be prevented from leaking.

Even if the manager does not recognize the damage to the refrigerant pipe, the refrigerant gas does not leak out, so unnecessary overuse of the refrigerant gas can be prevented, which can also have the effect of preventing global warming caused by refrigerant gas.

In addition, the present invention includes a vibration isolation device to alleviate the impact on the compressor itself, thereby minimizing refrigerant gas leakage due to damage and solving the problem of excessive use of refrigerant gas that causes ozone layer destruction.

The present invention was developed to solve the problem of shock damage caused by vibration as described above. The purpose of the present invention is to provide a compressor vibration isolator equipped with a compressor that compresses refrigerant to supply refrigerant to an air conditioner.

Another object of the present invention is to provide a compressor vibration isolation device equipped with a moving module including a vibration resistance unit.

Another object of the present invention is to provide a compressor dust isolator equipped with a dust removal module that removes dust from the vibration resistant part of the mobile module.

The object of the present invention is not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

A compressor vibration isolator according to an embodiment of the present invention for solving the above problem absorbs vibration generated during operation of the compressor at the lower part of the compressor that compresses the refrigerant by reciprocating piston movement to supply refrigerant to the air conditioner, and It may include a movement module that moves the compressor or fixes its position.

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In one embodiment, the moving module includes a vibration-resistant part that is fixedly installed on the lower surface of the compressor to absorb vibration occurring during operation of the compressor, a wheel part for moving the compressor or fixing its position, and an upper end. It includes a mobile module main body provided with two sliding rails along a longitudinal direction on its surface, wherein the earthquake-proof part includes an upper base plate and a lower base provided with a plurality of installation holes for fixing the lower surface of the compressor to the mobile module main body. A plate, a cylindrical main body integrally connected to the lower base plate, an insertion body having a diameter smaller than the main body and having a stepped upper end so as to be inserted into the main body, and being inserted into the stepped upper end of the insertion body to A holder body provided with a holder integrally connected to the base plate, a rod portion disposed inside the main body, a spring disposed inside the insertion body to generate elastic force, a portion is inserted into the lower end of the spring, and the spring It includes a piston part that performs piston movement, a cap part located at the lower end of the piston part and inserted into the rod part to support the piston part, wherein the piston part is perforated in the center and spaced at regular intervals along the circumference in the longitudinal direction of the bottom. A piston head split along a piston head, a piston fixture fixing the piston head and having a central hole, and a piston body with a front end protruding toward the top so as to be inserted into the piston fixture and the piston head, wherein the cap portion is inserted into the piston head. A fitting body formed with a perforated fluid hole so that the fluid remaining inside the body can flow, a cap body disposed at the lower end of the fitting body to support the piston unit and having a cylindrical shape with a hole in the center, and disposed at the lower end of the cap body a bearing-shaped cap plate with a hole in the center, a cap fixture with a hollow top and a hole in the center to accommodate the cap plate, and a cap insert with a stepped top and a hole in the center to be inserted into the cap fixture. It includes a sieve, and the rod portion is coupled to the cap portion and the piston portion through a hollow center, and an elastic force is generated in the spring due to vibration of the compressor, so that the piston portion vibrates as the piston moves up and down along the rod portion. It may include features that disperse.

In one embodiment, the wheel unit includes four wheels provided in parallel at a predetermined distance apart from the lower part of the mobile module main body and provided with a plurality of breaking grooves spaced at predetermined intervals along the center line of the cross-sectional width, and the moving unit provided with the wheels. A plurality of fixing members formed inside the lower part of the module body at a distance close to the wheel and having insertable holes in the center, a rotating shaft rotatably inserted into the plurality of apertured fixing members, and a rotating shaft wound around the center of the rotating shaft. An elastic member, a stopper body that is perforated so that one end is fastened to the rotating shaft and has a plurality of stopper protrusions protruding downward at regular intervals on the inner surface, and a coupling protrusion protruding upward on one end of the outer surface, the above of the stopper body It may include a housing that is engaged with the coupling protrusion to protect the stopper body.

In one embodiment, the movement module is fixed so that the stopper body prevents the wheel from rotating by inserting the stopper protrusion into the braking groove of the wheel to stop and fix the movement module, and the stopper It may include a feature that the body rotates and rotates along the rotation axis so that the stopper protrusion is detached from the braking groove and the wheel is rotated.

In one embodiment, the moving module further includes a dust removal module installed on the sliding rail of the moving module main body to remove dust laminated on the vibration-resistant portion, and the dust removal module is located on one side of the sliding rail. A dust removal unit rotatably installed on the other side of the sliding rail to remove dust accumulated in the dust removal unit, and a dust removal unit rotatably installed on the other side of the sliding rail to prevent malfunction of the dust removal unit by shaking off dust accumulated in the dust removal unit. A dust removal unit, a motor shaft, and a rotary motor provided to apply rotational force so that the dust removal unit and the dust removal unit can rotate, and extending to the dust removal unit and the dust removal unit, and removing the dust. The unit includes a removal unit rotation shaft rotatably disposed in contact with one side of the sliding rail, a removal unit rotation gear installed on one side of the sliding rail and fastened to one end of the removal unit rotation shaft and rotating integrally with the removal unit rotation axis. , comprising a plurality of removal wings spaced apart from each other at a predetermined distance along the longitudinal direction of the removal unit rotation axis, wherein the dust brushing unit includes a dust brushing unit rotatably disposed to rotatably contact the other side of the sliding rail, and the other side of the sliding rail. A fur part rotation gear is installed on and fastened to one end of the fur part rotation axis and rotates integrally with the fur part rotation axis, and rotates in engagement with the removal part rotation gear, and is spaced a certain distance along the longitudinal direction of the fur part rotation axis. A plurality of hair wings may be formed to correspond to the positions of the removal wings.

In one embodiment, the dust removal module operates the rotation motor to generate rotational force, so that the connected removal unit rotation shaft rotates and the removal unit rotation gear rotates at the same time, and engages with this to rotate the fur unit rotation shaft and the fur unit. The gear rotates, the rotation shaft of the removal unit rotates so that the removal blade removes dust accumulated on the surface of the circumference of the vibration-resistant section, and the rotation shaft of the brush portion rotates so that the dust blade dusts off the removal blade. Additional features may be included.

According to the present invention, there is provided a vibration isolation device for a compressor equipped with a movement module including a vibration resistance unit and a dust removal module. According to the present invention, the structure of the air conditioner refrigerant pipe through which the refrigerant gas is transported in relation to the compressor dust isolator is doubled, so that even if one of the two double pipes is damaged by an external force, the refrigerant gas can be prevented from leaking.

Even if the manager does not recognize the damage to the refrigerant pipe, the refrigerant gas does not leak out, so unnecessary overuse of the refrigerant gas can be prevented, which can also have the effect of preventing global warming caused by refrigerant gas.

In addition, the present invention includes a vibration isolation device to alleviate the impact on the compressor itself, thereby minimizing refrigerant gas leakage due to damage and solving the problem of excessive use of refrigerant gas that causes ozone layer destruction. The effects according to the present invention are not limited to the details exemplified above, and further various effects are included within the present invention.

Figure 1 shows an embodiment of a conventional compressor according to the present invention.
Figure 2 shows another embodiment of a conventional compressor according to the present invention.
Figure 3 shows the entire moving module of the compressor vibration isolator according to the present invention.
Figure 4 shows an assembly diagram of the vibration-proof portion of the moving module of the compressor vibration-isolation device according to the present invention.
Figure 5 shows a coupling diagram of the vibration-proof portion of the moving module of the compressor vibration-isolation device according to the present invention.
Figure 6 is a side view showing the wheel portion of the moving module of the compressor vibration isolator according to the present invention.
Figure 7 shows an assembly diagram of the wheel portion of the moving module of the compressor vibration isolator according to the present invention.
Figure 8 shows the overall configuration and embodiment of the dust removal module of the compressor dust isolator according to the present invention.
Figure 9 shows an embodiment of the dust removal module of the compressor dust isolator according to the present invention from another angle.

Hereinafter, various embodiments will be described in more detail with reference to the attached drawings. The embodiments described herein may be modified in various ways. Specific embodiments may be depicted in the drawings and described in detail in the detailed description. However, the specific embodiments disclosed in the attached drawings are only intended to facilitate understanding of the various embodiments. Therefore, the technical idea is not limited to the specific embodiments disclosed in the attached drawings, and it should be understood that all equivalents or substitutes included in the spirit and technical scope of the invention are included.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but these components are not limited by the above-mentioned terms. The above-mentioned terms are used only for the purpose of distinguishing one component from another.

In this specification, terms such as “comprise” or “have” are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof. When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Meanwhile, a “module” or “unit” for a component used in this specification performs at least one function or operation. And the “module” or “unit” may perform a function or operation by hardware, software, or a combination of hardware and software. Additionally, a plurality of “modules” or a plurality of “units” excluding a “module” or “unit” that must be performed on specific hardware or performed on at least one processor may be integrated into at least one module. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In addition, when describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof is abbreviated or omitted.

1 and 2 show an embodiment of a conventional compressor 100 according to the present invention.

In one embodiment related to the compressor vibration isolator, the structure of the air conditioner refrigerant pipe that transports the refrigerant gas is doubled to prevent the operation of the compressor or the transmission of vibration due to external shock, so that one of the two pipes doubled by external force Even if it is damaged, refrigerant gas can be prevented from leaking.

In addition, even if the manager does not recognize the damage to the refrigerant pipe, the refrigerant gas does not leak, so unnecessary overuse of the refrigerant gas can be prevented, which can also have the effect of preventing global warming caused by the refrigerant gas.

In addition, the present invention includes a vibration isolation device to alleviate the impact on the compressor itself, thereby minimizing refrigerant gas leakage due to damage and solving the problem of excessive use of refrigerant gas that causes ozone layer destruction.

The compressor vibration isolator absorbs the vibration that occurs during operation of the compressor at the lower part of the compressor 100, which compresses the refrigerant by reciprocating piston movement in order to compress and supply the refrigerant to the air conditioner, and moves or fixes the position of the compressor. It may include a movement module 200.

At this time, the refrigerant pipe connected to the compressor 100 is not shown in the drawing, but can be presented in a dual structure as described above, thereby minimizing the outflow of refrigerant gas due to impact.

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Figure 3 shows the entire movement module 200 of the compressor vibration isolator according to the present invention.

Referring to FIG. 3, the compressor vibration isolator absorbs vibration occurring when the compressor 100 operates at the lower part of the compressor 100, and includes a movement module 200 that can move or fix the position of the compressor 100. ) may further be included.

The movement module 200 is fixedly installed on the lower surface of the compressor 100 and includes a vibration-resistant part 300 that absorbs vibration occurring when the compressor 100 operates, and moves the compressor 100 or fixes its position. It may include a wheel unit 400 for moving the mobile module body 210, and a mobile module body 210 provided with two sliding rails 520 along the longitudinal direction on the upper surface.

Figures 4 and 5 show an assembly and combination diagram of the vibration-resistant portion 300 of the moving module 200 of the compressor vibration isolator according to the present invention.

Referring to FIGS. 4 and 5, the earthquake-resistant portion 300 includes an upper base plate 310a and a lower base plate 310b, a main body 320, an insertion body 330, a holder body 340, and a rod portion ( 350), a spring 360, a piston unit 370, and a cap unit 380.

The upper base plate 310a and the lower base plate 310b may be provided with a plurality of installation holes 311 for fixing the mobile module main body 210 and the tank 110.

Additionally, the upper base plate 310a and the lower base plate 310b may have a disk shape as shown, but are not limited to this and may be formed in various shapes.

The main body 320 may be provided in a cylindrical shape integrally connected to the lower base plate 310b.

The insertion body 330 may have a smaller diameter than the main body 320 and may be provided with a stepped upper end so that it can be inserted into the main body 320.

The holder body 340 may be provided with a holder 341 that is inserted into the stepped upper part of the insertion body 330 and is integrally connected to the upper base plate 310a.

The load unit 350 may be disposed inside the main body 320.

The spring 360 may be disposed inside the insertion body 330 to generate elastic force.

The piston part 370 is partially inserted into the lower end of the spring 360 and can perform piston movement by the spring 360.

In addition, the piston portion 370 includes a piston head 371 that is perforated in the center and split along the longitudinal direction of the bottom at regular intervals along the circumference, and a piston fixture 372 that fixes the piston head 371 and is perforated in the center. ), and may include a piston body 373 with a front end protruding toward the top so as to be inserted into the piston fixture 372 and the piston head 371.

The cap part 380 is located at the lower end of the piston part 370 and can be inserted into the rod part 350 to support the piston part 370.

In addition, the cap portion 380 is disposed at the lower end of the insert 381 and the insert 381 through which a fluid hole 3811 is formed to allow the fluid remaining inside the insert body 330 to flow. A cylindrical cap body 382 that supports the piston unit 370 and has a hole in the center, a cap plate 383 in the shape of a bearing disposed on the lower part of the cap body 382 and a hole in the center, and the cap plate 383 ) includes a cap fixture 384 with an empty upper interior and a hole in the center to accommodate the cap fixture 384, and a cap insert 385 with a stepped protruding top and a hole in the center to be inserted into the cap fixture 384. can do.

The assembly relationship of the above components and the effects according to the embodiment are described in detail as follows.

A lower base plate (310b) is installed on the upper surface of the mobile module body 210, and the main body 320 is coupled thereto.

The rod portion 350 may be disposed inside the main body 320, and the insertion body 330 may be inserted into the main body 320.

At this time, the holder body 330 with the holder 341 connected to the stepped upper part is inserted.

The rod portion 350 is coupled through the hollow center of the cap portion 380 and the piston portion 370, and an elastic force is generated in the spring 360 due to the vibration of the compressor 100, thereby causing the piston portion 370 to The piston moves up and down along the part 350, which has the effect of dispersing vibration.

Figures 6 and 7 show the wheel portion 400 of the moving module 200 of the compressor vibration isolator according to the present invention in a side view and an assembled view.

Referring to Figures 6 and 7, the wheel unit 400 includes four wheels 410, a plurality of fixing members 420, a rotating shaft 430, an elastic member 440, a stopper body 450, and a housing 460. ) may include.

The wheels 410 may be provided in parallel at a predetermined distance apart from the lower end of the mobile module main body 210 and may be provided with a plurality of breaking grooves 411 at regular intervals along the center line of the cross-sectional width.

The fixing member 420 may be formed inside the lower end of the mobile module body 210 equipped with the wheel 410 at a distance adjacent to the wheel 410 and may be formed with a hole in the center so as to be insertable.

The rotation shaft 430 may be rotatably inserted into the perforated fixing member 420.

The elastic member 440 is wrapped around the center of the circumference of the rotating shaft 430 and can add elastic force to the rotation of the stopper body 450, which will be described later.

The stopper body 450 is perforated so that one end is fastened to the rotating shaft 430, and is provided with a plurality of stopper protrusions 451 protruding downward at regular intervals on the inner surface, and a coupling protrusion 452 protruding upward on one end of the outer surface. may be provided.

The housing 460 may be engaged with the coupling protrusion 452 of the stopper body 450 to protect the stopper body 450.

The assembly relationship of the above components and the effects according to the embodiment are described in detail as follows.

A groove may be formed on the inner bottom surface of the mobile module body 210 to arrange four wheels 410, and a fixing member 420 may be formed to protrude at an adjacent distance in contact with the wheels 410 arranged as shown. And the stopper body 450 may be coupled to the rotating shaft 430 to be inserted into the fixing member 420.

A housing 460 is assembled on top to protect the combined shape.

In one embodiment, the stopper body 450 moves by inserting a stopper protrusion 451 into the braking groove 411 of the wheel 410 to stop and fix the movement module 200 to prevent the wheel 410 from rotating. The module 200 is fixed, which has the effect of performing stable operation of the compressor 100.

In one embodiment, in order to drive the movement module 200, the stopper body 450 rotates and rotates along the rotation axis 430 so that the stopper protrusion 451 is detached from the breaking groove 411 as shown in the drawing. The wheel 410 can be driven to rotate.

Figures 8 and 9 show the overall configuration and embodiments of the dust removal module 500 of the compressor dust isolator according to the present invention.

Referring to Figures 8 and 9, the moving module 200 is installed on the sliding rail 520 of the moving module main body 210 and further includes a dust removal module 500 that removes dust accumulated on the earthquake-resistant portion 300. It can be included.

The dust removal module 500 is rotatably installed on one side of the sliding rail 520 and is rotatable on the other side of the sliding rail 520. A dust removal unit 540 is installed to shake off dust accumulated on the dust removal unit 530 to prevent the dust removal unit 530 from malfunctioning, and a dust removal unit 530 is provided by a motor shaft 551. It is provided to apply rotational force so that the dust removal unit 540 can rotate, and may include a rotation motor 550 extended to the dust removal unit 530 and the dust removal unit 540.

The dust removal unit 530 may include a removal unit rotation shaft 531, a removal unit rotation gear 532, and a removal wing 533.

The removal unit rotation shaft 531 may be rotatably installed on the sliding rail 520.

Additionally, the removal unit rotation axis 531 may be installed to be able to slide along the sliding rail 520.

The removal unit rotation gear 532 may be inserted into one end of the removal unit rotation shaft 531 and rotate integrally with the removal unit rotation shaft 531.

Additionally, the removal unit rotation gear 532 may be installed to slide along the sliding rail 520.

A plurality of removal wings 533 may be formed at a certain distance apart along the longitudinal direction of the removal unit rotation axis 531.

Additionally, the material of the removal wing 533 is not particularly limited, and any material capable of surface adsorption to remove dust is preferable.

The rotation motor 550 may be installed to be built into the movement module main body 210.

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Additionally, the rotation motor 550 may generate rotational force through control to rotate the removal unit rotation shaft 531.

The dust fur unit 540 may include a fur rotation axis 541, a fur rotation gear 542, and a fur wing 543.

The hair part rotation axis 541 may be rotatably installed in parallel with the removal part rotation axis 531 on the sliding rail 520.

The hair portion rotation gear 542 is inserted into one end of the fur portion rotation shaft 541 and rotates integrally with the fur portion rotation shaft 541, and may rotate in engagement with the removal portion rotation gear 532.

That is, as the removal part rotation gear 532 rotates, the hair part rotation gear 542 can rotate.

Additionally, the fur rotation gear 542 may be installed to be slidably movable on the sliding rail 520.

A plurality of hair wings 543 may be formed at a certain distance apart along the longitudinal direction of the hair rotation axis 541 and may be formed to correspond to the position of the removal wings 533.

Additionally, the material of the hair wing 543 is not particularly limited, but a material containing elasticity is preferable for brushing the removal wing 533.

The assembly relationship of the above components and the effects according to the embodiment are described in detail as follows.

In the dust removal module 500, the removal unit rotation axis 531 is assembled to the sliding rail 520 installed on the mobile module main body 210 so that it can slide under control.

The removal unit rotation gear 532 is rotatably assembled to the lower end of the removal unit rotation shaft 531, and the removal unit rotation gear 532 is rotatably assembled to enable sliding movement by engaging along the sliding rail 520.

A plurality of removal wings 533 are assembled along the circumference of the removal unit rotation axis 531 at regular intervals.

The removal wing 533 may be extended to a length capable of contacting the surface of the vibration-resistant portion 300 and removing dust accumulated on the surfaces of the main body 320 and the insertion body 330, in particular.

In one embodiment, the removal wing 533 may rotate according to the rotation of the removal unit rotation shaft 531 to remove dust accumulated on the surface of the vibration-resistant unit 300.

The hair part rotation axis 532 is assembled to the sliding rail 520 in line with the removal part rotation axis 531 so as to be able to slide.

The hair part rotation gear 542 is rotatably assembled to the lower end of the hair part rotation shaft 532, and the hair part rotation gear 542 rotates the removal part rotation gear 532 along the sliding rail 520. It is assembled so that sliding movement is possible.

A plurality of fur wings 543 are assembled at regular intervals along the circumference of the fur rotation axis 532.

At this time, the hair wing 543 may be extended to a length that can shake off the removal wing 533.

In one embodiment, the hair wing 543 may be rotated by the rotation of the hair part rotation shaft 541 to shake off dust from the removal wing 533.

In one embodiment, the dust removal module 500 generates rotational force by operating the rotation motor 550, so that the connected removal unit rotation shaft 531 rotates and the removal unit rotation gear 532 rotates at the same time, and engages with this to remove the hair. The sub-rotating shaft 541 and the hair rotating gear 542 can rotate.

In one embodiment, the removal unit rotation axis 531 rotates so that the removal wings 533 remove dust accumulated on the peripheral surface of the earthquake-resistant unit 300, and the fur rotation axis 541 rotates to remove the dust wings 543. ) has the effect of shaking off the dust on the removal wing 533 and preventing the problem of dust being piled up on the dust removal part 530 and dust not being able to be shaken off the vibration-resistant part 300.

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Although preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and may be used in the technical field to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

Compressor(100)
Compressor Housing(150)
Mobile module (200)
Mobile module body (210)
Earthquake resistance (300)
Top base plate (310a)
Bottom base plate (310b)
Installer (311)
Main body (320)
Insert Body (330)
Holder body (340)
Holder(341)
Rod part (350)
Spring(360)
Piston part (370)
Piston head(371)
Piston fixture (372)
Piston body(373)
Cap part (380)
Insert (381)
Fluid Ball (3811)
Cap Body(382)
Cap Plate(383)
Cap fixture(384)
Cap Insert(385)
Wheel part (400)
wheels(410)
Breaking groove(411)
Fixing member (420)
Rotation axis (430)
Elastic member (440)
Stopper body (450)
Stopper projection (451)
Combined protrusion (452)
Housing(460)
Dust removal module (500)
Sliding rail(520)
Dust removal unit (530)
Removal part rotation axis (531)
Removal part rotation gear (532)
Removal Wing(533)
Dust hair part (540)
Fur part rotation axis (541)
Hairy rotating gear (542)
Fluffy Wings (543)
Rotation motor (550)
Motor shaft (551)

Claims (3)

A compressor comprising a moving module at the bottom of a compressor that compresses the refrigerant by reciprocating piston motion to compress and supply the refrigerant to the air conditioner, absorbing vibrations generated during operation of the compressor, and moving or fixing the position of the compressor. In the vibration isolation device,
The movement module is,
A vibration-resistant part that is fixedly installed on the lower surface of the compressor to absorb vibrations generated during operation of the compressor, a wheel part for moving the compressor or fixing its position, and two sliding rails along the longitudinal direction on the upper surface A mobile module body provided with this;
Including,
The seismic department,
An upper base plate and a lower base plate provided with a plurality of installation holes for fixing the lower surface of the compressor to the mobile module body;
a cylindrical main body integrally connected to the lower base plate;
an insertion body whose diameter is smaller than that of the main body and whose upper end is stepped so as to be inserted into the main body;
a holder body including a holder inserted into the stepped upper part of the insertion body and integrally connected to the upper base plate;
a rod portion disposed inside the main body;
a spring disposed inside the insertion body to generate elastic force;
A piston part that is partially inserted into the lower end of the spring and performs piston movement by the spring;
a cap portion located at the lower end of the piston portion and inserted into the rod portion to support the piston portion;
Including,
The piston part,
A piston head that is perforated in the center, spaced at regular intervals along the circumference, and split along the lower length direction;
A piston fixture that fixes the piston head and has a central hole;
a piston body with a front end protruding toward the top to be inserted into the piston fixture and the piston head;
Including,
The cap part,
an insert having a fluid hole formed therein to allow fluid remaining inside the insertion body to flow;
a cap body disposed at the lower end of the insert to support the piston unit and having a cylindrical shape with a central hole;
a bearing-shaped cap plate disposed at the lower end of the cap body and having a central hole;
a cap fixture having a hollow upper interior and a central hole to accommodate the cap plate;
a cap insert having a stepped upper portion and a hole in the center to be inserted into the cap fixture;
Including,
The rod portion is coupled through a hollow center of the cap portion and the piston portion,
An elastic force is generated in the spring due to the vibration of the compressor, and the piston unit moves the piston up and down along the rod unit to disperse the vibration,
The wheel part,
Four wheels provided in parallel at a predetermined distance apart from the lower part of the mobile module main body and provided with a plurality of breaking grooves at predetermined intervals along the center line of the cross-sectional width;
A plurality of fixing members formed inside the lower end of the mobile module body equipped with the wheels at a distance close to the wheels and having a hole in the center to allow insertion;
a rotating shaft rotatably inserted into the plurality of perforated fixing members;
an elastic member wound around the center of the rotating shaft;
a stopper body that is perforated so that one end is fastened to the rotating shaft, has a plurality of stopper protrusions protruding downward at regular intervals on the inner surface, and has a coupling protrusion protruding upward on one end of the outer surface;
a housing engaged with the engaging protrusion of the stopper body to protect the stopper body;
Including,
The movement module is,
In order for the stopper body to stop and fix the moving module, the stopper protrusion is inserted into the breaking groove of the wheel to prevent the wheel from rotating, so that the moving module is fixed,
A compressor vibration isolator comprising the feature that the stopper body rotates and rotates along the rotation axis so that the stopper protrusion is detached from the braking groove and the wheel rotates. delete delete