KR101708672B1 - Washing machine - Google Patents

Abstract

The present invention includes a vibration reduction member disposed between an upper bearing portion and a lower bearing portion. The vibration reduction member can form a bend. The vibration reduction member is disposed between the upper bearing portion and the lower bearing portion to reduce the vibration transmitted from the lower bearing portion. The vibration reduction member includes a plurality of upper bearing engagement portions fixedly coupled to the upper bearing portion and a plurality of lower bearing engagement portions arranged between the upper bearing engagement portions to connect the upper bearing engagement portions and to fix the lower bearing engagement portions, .

Description

[0001] Washing machine [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a laundry processing apparatus, and more particularly, to a laundry processing apparatus including an enamel reducing member disposed between an upper bearing portion and a lower bearing portion to absorb vibration.

The laundry processing equipment refers to a device that removes foreign substances from the laundry. The laundry processing apparatus includes a washing tub in which laundry is inserted. Further, the laundry processing apparatus rotates the washing tub to remove foreign matter. At this time, the laundry processing apparatus includes a driving device that generates a driving force to rotate the washing tub. The driving device includes a stator for generating an electromagnetic force and a rotor for rotating by an electromagnetic force. The rotor is fastened to a rotating shaft which is directly connected to the washing tub, and the rotating force is transmitted to the washing tub. At this time, when the rotor rotates, the washing tub and the water storage tank are vibrated by the vibration. Therefore, there is a case where external noise is generated by the vibration and the consumer is discomforted.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a laundry processing apparatus for reducing vibration transmitted from a lower bearing portion to an upper bearing portion.

The present invention provides a laundry processing apparatus comprising an upper bearing portion, a lower bearing portion engaged with the upper bearing portion, and a vibration reduction member disposed between the upper bearing portion and the lower bearing portion.

The present invention includes a vibration reduction member disposed between the upper bearing portion and the lower bearing portion to reduce the vibration transmitted from the lower bearing portion to the upper bearing portion. Therefore, noise generated during operation of the drive apparatus is reduced by the vibration reduction member.

1 is a perspective view showing an embodiment of a laundry processing apparatus 100 according to the present invention. 2 is a cross-sectional view taken along the line II-II in Fig.

1 and 2, the laundry processing apparatus 100 includes a cabinet 110, a water storage tank 115 disposed inside the cabinet 110 for storing wash water introduced from the outside, a water storage tank 115, (Not shown) for generating a driving force to rotate the washing tub 122 and supplying the washing water to the washing tub 115 and the washing tub 122 from the outside, (Not shown), a water storage tank 115, and a drain device (not shown) for discharging the wash water to the outside. The cabinet 110 includes a cabinet main body 111, a base (unrepresented) disposed under the cabinet main body 111 and fastened to the cabinet main body 111, And a control panel 126 disposed on one side of the cover 123 and fastened to the cabinet body 111. On the other hand, an input unit (not shown) for receiving an external signal from the user is formed on the control panel 126.

When the user inputs an external signal through the input unit, the laundry processing apparatus 100 operates. That is, the washing water supply device introduces the washing water from the outside into the washing tub 122 and the water storage tank 115. At this time, the detergent inserted by the user is dissolved while being supplied with the washing water, and is supplied to the washing tub 122 and the water storage tank 115. When the washing water is supplied, the driving device generates a driving force to rotate the washing tub 122. At this time, when the washing tub 122 rotates, a force is applied to the laundry by the flow of washing water in the washing tub 122. Accordingly, the foreign matter of the laundry is separated from the laundry. On the other hand, after the foreign substances in the laundry are removed, the washing water in the washing tub 122 and the water storage tank 115 is discharged to the outside. When the discharge of the washing water is completed, the washing water supply device causes the washing water not containing the detergent to flow from the outside, thereby dissolving the detergent adsorbed on the laundry with the washing water. Further, the driving device repeats the process of rotating the washing tub 122 to rinse laundry. When the rinsing process of the laundry is completed, the driving device rotates the washing tub 122 to discharge the washing water of the laundry to the outside. At this time, the drainage device operates to discharge the washing water from the washing tub 122 and the water storage tank 115 to the outside. The laundry processing apparatus 100 removes foreign matter from the laundry by repeating the above-described processes as necessary.

FIG. 3 is a perspective view showing an embodiment of the driving apparatus shown in FIG. 2. FIG. 4 is a cross-sectional view taken along the line IV-IV in FIG.

3 and 4, the driving apparatus includes a driving unit 170 for generating driving force, a rotating shaft 190 coupled to the driving unit 170 to transmit the driving force to the washing tank 122, (Not shown). The bearing portion 175 includes an upper bearing portion 174 into which the rotary shaft 190 is inserted and fastened to the water storage tank 115 and a lower bearing portion 173 into which the rotary shaft 190 is inserted and fastened to the driving portion 170 . Meanwhile, the vibration reducing member 180 is inserted between the upper bearing portion 174 and the lower bearing portion 173. In the upper bearing portion 174 and the lower bearing portion 173, a clock (unrepresented) for changing the rotating method in the washing process and the dewatering process of the laundry is disposed. The driving unit 170 may be formed in various ways. That is, the driving unit 170 may include a motor 170 or the like. Hereinafter, the motor 170 will be mainly described for convenience of explanation.

The motor 170 includes a stator 172 that generates an electromagnetic force and a rotor 171 that rotates by an electromagnetic force generated by the stator 172. The stator 172 includes a body portion (unrepresented) and a coil (unrepresented) that is repeatedly wound on one side of the body portion to generate an electromagnetic force. The rotor 171 includes a rotor body portion 171a and a blade 171b formed on one side of the rotor body portion 171a to discharge heat generated from the rotor body portion 171a to the outside, And a magnetic body 171c fastened to one side of the magnetic body 171a to receive a force by an electromagnetic force. Meanwhile, the rotor body portion 171a includes a connector (not illustrated) formed to fasten the rotary shaft 190 and the rotor body portion 171a. The rotary shaft 190 is fastened to the rotor 171 by the connector and the rotary shaft 190 is rotated by the rotation of the rotor 171.

Referring to the operation of the motor 170, a user inputs an external signal through an input unit (not shown) to operate the laundry processing apparatus 100. At this time, when an external signal is inputted, a current is applied to the motor 170. When a current is applied, a current is applied to the coil, and the coil generates an electromagnetic force. When an electromagnetic force is generated, the magnetic body 171c is subjected to a force by the electromagnetic force. At this time, since the magnetic body 171c is fastened to the rotor body portion 171a as described above, the rotor 171 rotates. When the rotor 171 rotates, the rotary shaft 190 connected to the connector also rotates. Since the rotary shaft 190 is directly connected to the washing tub 122, the washing tub 122 rotates according to the rotation of the rotary shaft 190. On the other hand, when the washing tub 122 rotates, the clench changes the rotating method according to the operating state of the laundry processing apparatus 100. [ That is, when the laundry processing apparatus 100 performs the washing process, the clamps are operated to rotate the washing tub 122 and the pulsator 140. On the other hand, when the laundry processing apparatus 100 performs the dewatering process, the clutch is operated so that the washing tub 122 rotates at a high speed. Accordingly, the laundry processing apparatus 100 can accurately transmit the rotation of the motor 170 to the washing tub 122.

5 is a perspective view showing an embodiment of the vibration reducing member 180 shown in FIG.

5, the vibration reduction member 180 includes a plurality of upper bearing coupling portions 181 that are coupled to the upper bearing portion 174 to fix the upper bearing portion 174, and a plurality of upper bearing coupling portions And a plurality of lower bearing coupling portions 184 which are disposed between the upper bearing coupling portions 181 and the lower bearing coupling portions 181 to connect the plurality of upper bearing coupling portions 181 and fix the lower bearing portion 173. The plurality of upper bearing coupling portions 181 may be integrally formed with the plurality of lower bearing coupling portions 184 and the upper bearing coupling portions 181 and the lower bearing coupling portions 184 may be integrally formed with one To form a ring. Each lower bearing coupling portion 184 includes a lower bearing coupling portion 183 coupled to the lower bearing portion 173 and a lower bearing coupling portion 183 extending in both directions from the lower bearing coupling portion 183, And connection portions 182 connected to the connection portion 181. The connection portions 182 extend from the lower bearing coupling portion 183 in a bent manner and are coupled to be bent from the upper bearing coupling portions 181. That is, the connection portions 182 are formed by bending from the lower bearing coupling portion 183. At this time, the lower bearing coupling portion 183 and the coupling portions 182 may be formed to be bent at a predetermined angle. The connection portions 182 may be formed by bending at a predetermined angle from the upper bearing coupling portions 181. On the other hand, the upper bearing coupling portions 181 can be coupled to be bent from the lower bearing coupling portions 184.

The plurality of upper bearing coupling portions 181 and the plurality of lower bearing coupling portions 184 may be formed in different planes from each other. That is, each upper bearing coupling portion 181 and each lower bearing coupling portion 184 are fastened to be bent. The upper bearing engagement portion 181 is formed in a plane different from that of the lower bearing engagement portion 184 because the upper bearing engagement portion 181 is bent to be bent. The upper bearing coupling portion 181 may be formed higher than the lower bearing coupling portion 184. Further, the upper bearing coupling portion 181 may be formed lower than the lower bearing coupling portion 184. On the other hand, the upper bearing coupling portion 181 may be formed on the same plane. Hereinafter, for convenience of explanation, the case where the upper bearing coupling portion 181 is higher than the lower bearing coupling portion 184 will be mainly described. The upper bearing portion 174 is fastened to the upper bearing coupling portions 181. Further, the lower bearing portion 173 is fastened to the lower bearing coupling portions 184. When the upper bearing portion 174 is fastened to the upper bearing coupling portions 181 and the lower bearing portion 173 is fastened to the lower bearing coupling portions 184, the upper bearing portion 174 and the lower bearing portion 173 mutually And is separately fastened to the vibration reduction member 180.

A coupling hole may be formed in each of the upper bearing coupling portion 181 and each lower bearing coupling portion 184 so that the coupling member is inserted. At this time, the fastening holes of the upper bearing coupling portions 181 may be arranged along the first circumferential direction. Further, the fastening holes of the lower bearing engagement portions 184 may be arranged along the second circumferential direction. At this time, the first circumferential direction and the second circumferential direction may be substantially the same. The plurality of upper bearing coupling portions 181 and the plurality of lower bearing coupling portions 184 may be spaced apart from each other at regular intervals. That is, each upper bearing coupling portion 181 may be disposed between each lower bearing coupling portion 184. The upper bearing coupling portion 181 is bent and fastened to one side of the lower bearing coupling portion 184. The other side of the lower bearing coupling portion 184 is bent and fastened to the upper bearing coupling portion 181. Thus, the upper bearing engagement portion 181 is disposed between the lower bearing engagement portions 184.

The assembling person tightens the stator 172 and the rotor 171 according to the order of engaging the driving devices. The assembler tightens the stator 172 to the lower bearing portion 173. At this time, the stator 172 and the lower bearing portion 173 are fastened using a fastening member (not shown). On the other hand, when the stator 172 is fastened to the lower bearing portion 173, the assembler tightens the lower bearing portion 173 to the vibration reduction member 180. That is, the assembler inserts the lower bearing portion 173 into the fastening hole of the lower bearing coupling portion 184 and inserts the fastening member. Further, the assembler tightens the upper bearing portion 174 to the vibration reduction member 180. [ That is, the assembler inserts the fastening member into the fastening hole formed in the upper bearing coupling portion 181 and fastens it. Accordingly, the upper bearing portion 174 and the lower bearing portion 173 are connected by the vibration reducing member 180.

6 is a conceptual diagram showing an embodiment of the vibration of the vibration reduction member 180 shown in Fig. 7 is a conceptual diagram showing another embodiment of the vibration of the vibration reduction member 180 shown in Fig.

6 and 7, the vibration reduction member 180 is fastened to the upper bearing portion 174 and the lower bearing portion 173 as described above. At this time, when the user inputs an external signal to operate the driving unit, a current is applied to the driving unit 170 and the rotor 171 rotates. When the rotor 171 rotates, the rotor 171 vibrates. Further, the rotation shaft 190 is vibrated by the rotation of the rotor 171, and the stator 172 is also vibrated. In particular, when the stator 172 vibrates, the vibration is transmitted to the upper bearing portion 174 through the lower bearing portion 173. At this time, the vibration reduction member formed between the upper bearing portion 174 and the lower bearing portion 173 absorbs or reduces vibration to a certain extent. That is, when the motor 170 is operated, the lower bearing portion 173 vibrates. When the lower bearing portion 173 vibrates, the vibration is transmitted to the vibration reduction member 180. The transmitted vibration is moved through the lower bearing coupling part 183. At this time, vibration occurs in the direction of C '. Thus, the vibration advances in the direction of C 'in the vibration reduction member 180. As described above, the lower bearing coupling portion 183 formed on the other side of the vibration reduction member 180 has the vibration transmitted to the upper bearing coupling portion 181. That is, vibration is also generated in the direction C 'on the other side of the vibration reduction member 180. At this time, in the lower bearing coupling portion 183 formed on the other side of the vibration reduction member 180, reflected waves are formed in the C direction opposite to the direction of C '. Therefore, the vibration in the C 'direction and the vibration in the C direction cancel each other to reduce the vibration.

Meanwhile, when the lower bearing portion 173 and the upper bearing portion 174 are vibrated as described above, the displacement of the vibration reducing member 180 is varied. That is, the upper bearing coupling portion 181 and the lower bearing coupling portion 184 of the vibration reduction member 180 are formed to include the curvature. Therefore, when the lower bearing portion 173 and the upper bearing portion 174 are vibrated by the bending, the same function as the leaf spring is achieved. That is, as described above, when the lower bearing portion 173 is vibrated, the bent portion moves in the vibration direction. Further, even when the upper bearing portion 174 vibrates, the bent portion moves in the vibration direction. Therefore, when the upper bearing portion 174 and the lower bearing portion 173 are vibrated, the vibration is not transmitted to the lower bearing portion 173 and the upper bearing portion 174, respectively. On the other hand, one side of the vibration reducing member 180 may be formed to be open. When one side of the vibration reducing member 180 is opened, it is possible to prevent the vibration reducing member 180 from being deformed by the vibration when the upper bearing portion 174 and the lower bearing portion 173 are vibrated.

On the other hand, the vibration reduction member 180 is formed so that the displacement varies according to the vibrations of the lower bearing portion 173 and the upper bearing portion 174. That is, as described above, when the lower bearing portion 173 and the upper bearing portion 174 are vibrated, they vibrate in the vibration direction. The vibration reduction member 180 may be formed of a different material from the upper bearing portion 174 and the lower bearing portion 173. When the vibration reduction member 180 includes the same material as the upper bearing portion 174 and the lower bearing portion 173, the vibration reduction member 180 is in contact with the upper bearing portion 174 and the lower bearing portion 173, The intensity of the vibration can be counted. Therefore, the vibration reducing member 180 can reduce the vibration transmitted from the lower bearing portion 173 to the upper bearing portion 174 by using a material different from the upper bearing portion 174 and the lower bearing portion 173. In addition, by reducing the vibration, it is possible to reduce the noise generated when the drive device operates.

8 is a conceptual view showing an embodiment of the combination of the upper bearing engagement portion 181 and the lower bearing engagement portion 184 shown in FIG. 9 is a conceptual diagram showing another embodiment of the combination of the upper bearing coupling portion 181 and the lower bearing coupling portion 184 shown in FIG. 10 is a conceptual diagram showing another embodiment of the combination of the upper bearing coupling portion 181 and the lower bearing coupling portion 184 shown in FIG.

Referring to FIGS. 8 to 10, the upper bearing coupling portion 181 is bent and engaged from the lower bearing coupling portion 184. At this time, the upper bearing coupling portion 181 can be engaged with the lower bearing coupling portion 184 at a predetermined angle. That is, the lower bearing coupling part 183 and the coupling part 182 can be fastened at a predetermined angle. Also, the connection portion 182 and the upper bearing coupling portion 181 can be fastened at a predetermined angle. Hereinafter, the upper bearing coupling portion 181 and the lower bearing coupling portion 184 are fastened at a predetermined angle for convenience of explanation.

The upper bearing coupling portion 181 and the lower bearing coupling portion 184 can be fastened at a predetermined angle. That is, the upper bearing coupling portion 181 may be fastened with the lower bearing coupling portion 184 to form an acute angle? ₃ . Further, the upper bearing coupling portion 181 may be fastened to form an obtuse angle &thetas; ₂ with the lower bearing coupling portion 184. The upper bearing coupling portion 181 may be coupled with the lower bearing coupling portion 184 at a substantially right angle (? ₁ ). When fastening the upper bearing engaging portion 181 and a lower bearing engaging portion 184 so as to form an acute angle (θ _3), the upper bearing engaging portion 181 and connecting portion 182 fastened also to form an acute angle (θ ₃₎ . Further, the lower bearing coupling portion 184 and the connecting portion 182 can be fastened to form an acute angle? ₃ . When the upper bearing coupling portion 181 and the lower bearing coupling portion 184 are coupled to form an obtuse angle θ ₂ , the upper bearing coupling portion 181 and the coupling portion 182 form an obtuse angle θ ₂ Respectively. Further, the lower bearing coupling portion 184 and the coupling portion 182 can be fastened to form an obtuse angle? ₂ . The upper bearing coupling portion 181 and the lower bearing coupling portion 184 form a substantially right angle &thetas; ₁ . Therefore, the vibration reducing member 180 includes bending to form a predetermined angle, so that the vibration can be effectively absorbed.

11 is a perspective view showing another embodiment of the vibration reducing member 180 shown in FIG. Hereinafter, the same reference numerals as those in the above-described embodiments denote the same members.

11, the vibration reducing member 280 includes a plurality of upper bearing coupling portions 281 that are coupled to the upper bearing portion 174 to fix the upper bearing portion 174, And a plurality of lower bearing coupling portions 284 which are disposed between the lower bearing coupling portions 281 and connect the plurality of upper bearing coupling portions 281 and fix the lower bearing portion 173. In addition, as described above, the vibration reduction member 280 is formed in a different plane from the upper bearing coupling portion 281 and the lower bearing coupling portion 284. At this time, the vibration reduction member 280 is formed in the same or similar manner as described above. Meanwhile, the lower bearing coupling portions 284 may be formed with bosses 286 into which bolts are inserted. At this time, the bosses 286 are formed to extend from the lower bearing engagement portions 284 to the plane where the upper bearing engagement portions 281 are formed.

The vibration reduction member 280 is disposed between the upper bearing portion 174 and the lower bearing portion 173 as described above. At this time, the upper bearing portion 174 is fastened to the upper bearing coupling portion 281. Further, the lower bearing portion 173 is fastened to the lower bearing engagement portion 284. Accordingly, the upper bearing portion 174 and the lower bearing portion 173 are disposed in different planes from each other. At this time, the bolts are fastened to the bosses 286 formed in the lower bearing coupling portion 284 to secure the coupling between the lower bearing portion 173 and the vibration reduction member 280. On the other hand, the bosses 286 are not limited to the above but may be formed in the upper bearing coupling portion 281. Accordingly, the vibration reduction member 280 can securely fasten the upper bearing portion 174 and the lower bearing portion 173. Further, when the lower bearing portion 173 vibrates, the vibration reducing member 280 can change the displacement and absorb the vibration.

12 is a view showing still another embodiment of the vibration reducing member 180 shown in Fig. Hereinafter, the same reference numerals as those in the above-described embodiments denote the same members.

12, the vibration reducing member 380 includes a plurality of upper bearing engaging portions 381 engaged with the upper bearing portion 174 to fix the upper bearing portion 174, and a plurality of upper bearing engaging portions And a plurality of lower bearing coupling portions 384 disposed between the upper bearing coupling portions 381 and the lower bearing coupling portions 381 to connect the plurality of upper bearing coupling portions 381 and fix the lower bearing portion 173. In addition, as described above, the vibration reducing member 380 is formed in a plane different from that of the lower bearing coupling portion 384 and the upper bearing coupling portion 381. At this time, the vibration reduction member 380 is formed in the same or similar manner as described above. Meanwhile, bosses (not shown) into which the bolts are inserted may be formed in each lower bearing coupling portion 384. At this time, the bosses are formed to extend from the lower bearing engagement portions 384 to the plane where the upper bearing engagement portions 381 are formed.

The vibration reducing member 380 may also include at least one recess 382 or protrusion 382 formed in the lower bearing engagement portion 384. That is, at least one inlet 382 or protrusion 382 from the upper bearing engagement portion 381 is bent and tightened. In addition, the upper bearing coupling portion 381 and the at least one lead-in portion 382 or the projection portion 382 can be engaged with each other at a predetermined angle. Meanwhile, the lower bearing coupling portion 384 may have at least one lead-in portion 382 or a projection portion 382 formed in the same or similar manner as described above. The lower bearing engagement portion 384 includes at least one inlet 382 or projection 382 and a lower bearing engagement portion 383 formed to extend from the at least one inlet 382 or projection 382. [ . ≪ / RTI > Therefore, as described above, it is possible to prevent the vibration generated from the lower bearing portion 173 from being transmitted to the upper bearing portion 174. Further, when the lower bearing portion 173 vibrates, the vibration reducing member 380 absorbs the vibration by changing the displacement, thereby effectively reducing the noise during operation of the drive device.

1 is a perspective view showing an embodiment of a laundry processing apparatus according to the present invention.

2 is a cross-sectional view taken along the line II-II in Fig.

FIG. 3 is a perspective view showing an embodiment of the driving apparatus shown in FIG. 2. FIG.

4 is a cross-sectional view taken along the line IV-IV in FIG.

5 is a perspective view showing an embodiment of the vibration reduction member shown in FIG.

6 is a conceptual view showing an embodiment of the vibration of the vibration reduction member shown in Fig.

7 is a conceptual diagram showing another embodiment of the vibration of the vibration reduction member shown in Fig.

8 is a conceptual view showing an embodiment of the combination of the upper bearing engagement portion and the lower bearing engagement portion shown in FIG.

9 is a conceptual view showing another embodiment of the combination of the upper bearing engagement portion and the lower bearing engagement portion shown in FIG.

10 is a conceptual view showing another embodiment of the engagement of the upper bearing engagement portion and the lower bearing engagement portion shown in FIG.

11 is a perspective view showing another embodiment of the vibration reducing member shown in Fig.

12 is a perspective view showing still another embodiment of the vibration reducing member shown in Fig.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

100: laundry processing device 171: rotor

110: cabinet 171a: rotor body part

111: cabinet main body 171b: blade

115: Water tank 171c:

122: washing tub 180: vibration reducing member

140: pulsator 190: rotating shaft

170: motor

Claims (21)

An upper bearing portion, A lower bearing portion which is engaged with the upper bearing portion at a lower side of the upper bearing portion, And a vibration reduction member disposed between the upper bearing portion and the lower bearing portion, The vibration- A plurality of upper bearing engaging portions for engaging and fixing the upper bearing portions, A plurality of lower bearing coupling portions disposed between the plurality of upper bearing coupling portions and disposed on a plane different from the plurality of upper bearing coupling portions to fix the lower bearing portion, And upper and lower bearing engaging portions that are connected to the adjacent upper bearing engaging portions, The upper bearing engagement portions and the lower bearing engagement portions are connected to form one ring having one side opened, The plurality of upper bearing engagement portions and the plurality of lower bearing engagement portions are integrally formed, Wherein the connection portions extend from the lower bearing coupling portion so as to bend and to be bent from the upper bearing coupling portions. delete delete delete delete delete The method according to claim 1, Wherein each of the upper bearing coupling portions forms a predetermined angle with the respective lower bearing coupling portions. The method of claim 7, Wherein each of the upper bearing coupling portions forms a substantially right angle with the respective lower bearing coupling portions. The method according to claim 1, Wherein the fastening holes of the plurality of upper bearing engaging portions are arranged along a first circumferential direction, Wherein the fastening holes of the plurality of lower bearing engaging portions are arranged between the upper bearing engaging portions along a second circumferential direction. The method of claim 9, Wherein the first circumferential direction and the second circumferential direction are substantially the same. The method according to claim 1, Wherein the plurality of lower bearing engagement portions and the plurality of upper bearing engagement portions are spaced apart from each other by a predetermined distance. The method according to claim 1, Wherein the plurality of lower bearing coupling portions comprise: And bosses formed to extend from the lower bearing coupling portions to the same plane as the upper bearing coupling portions and to receive bolts for coupling with the lower bearing portion. The method according to claim 1, Wherein each of the lower bearing coupling portions includes: A lower bearing coupling portion coupled to the lower bearing portion, And at least one inlet or protrusion formed on one side of the lower bearing coupling part. The method according to claim 1, Wherein at least one boss is formed in the plurality of lower bearing engaging portions. The method according to claim 1, The plurality of lower bearing engagement portions A plurality of upper bearing engaging parts formed integrally with the upper bearing engaging parts, Wherein the lower bearing portion is bolted to the lower bearing portion. The method according to claim 1, Wherein the vibration reduction member is formed of a material different from that of the upper bearing portion and the lower bearing portion. The method according to claim 1, Wherein the vibration reduction member is coupled to the upper bearing portion and the lower bearing portion, respectively, to reduce vibrations transmitted from the lower bearing portion to the upper bearing portion. delete The method according to claim 1, Wherein the vibration reduction member varies in displacement when the lower bearing portion vibrates. The method according to claim 1, Wherein the vibration reducing member is fastened to the upper bearing part and the lower bearing part, respectively, to separate the upper bearing part and the lower bearing part from each other by a predetermined distance. The method according to claim 1, Wherein the vibration reduction member reduces noise due to vibration of the upper bearing portion and the lower bearing portion.

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