JP4740721B2 - Viscous fluid filled damper - Google Patents

Description

  The present invention relates to discs such as CDs, CD-ROMs, DVDs, DVD-ROMs, DVD-RAMs, and magneto-optical disks used for audio equipment, video equipment, information equipment, various precision equipments including in-vehicle use and consumer use. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vibration damping device provided in a disk device that reproduces a disk-shaped recording medium (hereinafter referred to as a disk). The present invention relates to a viscous fluid-filled damper that attenuates vibration.

  In the disk device, when vibration is applied to the mechanical chassis, an error may occur in reading recorded data from the disk. For this reason, a viscous fluid-filled damper having a vibration damping action is interposed between the mechanical chassis (supported body) and the housing (support body) containing the mechanical chassis.

In such a conventional viscous fluid-filled damper 1, for example, as shown in FIG. 20, a stirring cylinder portion 4 is formed in a flexible portion 3 made of a rubber-like elastic body constituting a sealed container 2. The mounting shaft 6 of the mechanical chassis 5 is inserted into and fixed to. Further, the lid portion 7 constituting the sealed container 2 is fixed to the housing 8 by a mounting screw N penetrating into the hole 7 a of the lid portion 7. Thus, the viscous fluid-filled damper 1 is attached to the mechanical chassis 5 and the housing 8. And vibration is attenuated when the stirring cylinder part 4 stirs the viscous fluid 9 enclosed with the airtight container 2. FIG. Further, the other end of a suspension spring 10 having one end attached to the housing 8 is attached to the mechanical chassis 5 and is supported in a floating state inside the housing 8 (Patent Documents 1 and 2).
Japanese Patent Laid-Open No. 2000-220681 (FIG. 3) Japanese Patent Laying-Open No. 2001-271867 (FIG. 9)

  Incidentally, the disk device 11 is required to be further reduced in size and thickness in order to reduce the mounting space. As one of the methods, it has been studied to set the gap between the mechanical chassis 5 and the housing 8 to be smaller. For this reason, it is desired that the viscous fluid-filled damper can cope with it. However, the conventional viscous fluid-filled damper 1 has a structure in which the mounting shaft 6 is inserted into the stirring cylinder portion 4 from the top of the flexible portion 3, and as long as this basic structure is followed, the viscous fluid is sealed while maintaining the vibration damping performance. There is a limit to reducing the height of the damper itself so that it can be installed even if the gap is narrow. That is, if the viscous fluid-filled damper 1 is lowered as it is, the stirring cylinder portion 4 may collide with the inner wall surface of the sealed container 2 to generate an impact. If the stirring cylinder portion 4 is shortened to avoid a collision, the viscous fluid 9 is not sufficiently stirred and the vibration damping performance cannot be maintained.

  The present invention has been made against the background of the prior art as described above, and an object of the present invention is to provide a viscous fluid-filled damper that can contribute to downsizing of the disk device.

  And this invention which achieves the said objective is comprised as follows.

  That is, the present invention includes a hermetic container and a viscous fluid sealed in the hermetic container, and the viscous fluid-sealed damper that damps vibration of the supported body by attaching the hermetic container to the support body and the supported body. The mounting container is fixed to either the support body or the supported body and the outer surface of the mounting shaft is fixed to the sealed container, and either the support body or the supported body is fixed. And an elastic bulging portion made of a rubber-like elastic body that elastically supports the mounting portion in a floating state, and the elastic bulging portion is either the support body or the supported body. When the airtight container is fixed, the viscous fluid-filled damper is provided, which is crushed and bulged and deformed outward in the axial direction of the mounting shaft to form a bellows-like bent portion.

  In the present invention, the sealed container is provided with an attachment shaft that is fixed to either the support or the supported body, and an attachment portion that fixes either of the other. That is, when the supported body moves relative to the support body, the mounting shaft or the mounting portion is interlocked, and the viscous fluid enclosed in the inside of the sealed container is agitated along with this interlocking. For this reason, even if there is no stirring cylinder part which protrudes inside the airtight container like a prior art example, the vibration damping effect by stirring of a viscous fluid can be exhibited. Therefore, even if there is no stirring cylinder part, the outstanding vibration damping effect is exhibited and the sealed container can be made smaller than the conventional example.

  Moreover, in this invention, it has the said bellows-like bending part. In other words, when subjected to vibration or impact, the bellows-shaped bent portion with a high degree of freedom of deformation that elastically supports the mounting portion in a floating state is deformed, and the viscous fluid filled inside the sealed container attenuates the vibration and impact due to this deformation. Produces viscous resistance. For this reason, even if there is no stirring cylinder part, the vibration damping effect and shock absorption effect which were excellent in the bellows-like bending part can be exhibited.

  By the way, the viscous fluid is enclosed in the inside of the airtight container of the viscous fluid enclosure damper of this invention. If the bellows-like bent portion is formed in the closed container in advance when the viscous fluid is sealed, air may remain in the bent portion, thereby reducing the damping effect due to the stirring of the viscous fluid. Therefore, in the present invention, the bellows-like bent portion is formed after the viscous fluid is sealed. In other words, in the present invention, the elastic bulging portion is crushed by fixing the sealed container to either the support or the supported body, and the bellows-like bent portion is formed by bulging and deforming outward in the axial direction of the mounting shaft. To do. Therefore, according to the present invention, it is possible to suppress the reduction of the vibration damping effect due to the remaining air in the sealed container while having the bellows-like bent portion.

  In the viscous fluid-filled damper according to the present invention, the sealed container has a hollow donut shape, has an attachment shaft on the inner periphery thereof, and has an attachment portion and an elastic bulge portion outside the attachment shaft. That is, it has a mounting shaft integral with the sealed container. For this reason, when fixing an airtight container to a support body or a to-be-supported body, the separate member for fixing which replaces an attachment axis is unnecessary, and can reduce a number of parts.

  The viscous fluid-filled damper according to the present invention is a hollow donut shape in which the sealed container has a center hole, and has a mounting shaft that is a separate member from the sealed container inside the center hole, and a mounting portion outside the mounting shaft. And an elastic bulge. For this reason, there exists an advantage which can comprise an airtight container and an attachment axis | shaft with a different raw material. For example, in a combination of a sealed container made of a rubber-like elastic body and a mounting shaft made of a hard resin, the entire sealed container is flexibly deformed to increase the viscous resistance of the viscous fluid enclosed therein, and the support or It can be securely fixed to the supported body.

  In the viscous fluid-filled damper, the present invention has elastic bulge portions on both sides of the mounting portion in the axial direction of the mounting shaft. In other words, when the viscous fluid-filled damper is attached, the attachment part of the support body or the supported body is supported in a floating state between the bellows-like bent parts. When subjected to vibration or impact, the bellows-shaped bent portions on both sides are deformed, and viscous resistance of the viscous fluid filled in the sealed container is generated. For this reason, synergistic vibration damping and shock absorption by the bellows-like bent portions on both sides can be exhibited.

  In order to achieve the above object, the present invention provides the following viscous fluid-filled damper.

  In the first aspect of the present invention, the viscous fluid-filled damper further includes a pin-shaped fixing member, the mounting shaft has an insertion hole for the pin-shaped fixing member, and the mounting portion faces in the axial direction of the mounting shaft. It is a ring shape having a pair of annular surface portions, and the elastic bulge portion is provided continuously with one of the annular surface portions adjacent to either the support or the supported body in the mounting portion, On the other hand, when the pin-shaped fixing member is fixed, the pin-shaped fixing member is crushed by any one of the above to form a bellows-like bent portion. That is, a bellows-like bent portion is formed between either the support or the supported body and the attachment portion.

  According to a second aspect of the present invention, the viscous fluid-filled damper further includes a pin-shaped fixing member and a pressing plate provided in contact with the elastic bulge, and the mounting shaft has an insertion hole for the pin-shaped fixing member. The mounting portion is a ring shape having a pair of annular surface portions facing each other in the axial direction of the mounting shaft, and the elastic bulge portion is not adjacent to either the support or the supported body in the mounting portion. When the pin-shaped fixing member is fixed to either one of the annular surface portions, it is crushed by the pressing plate to form a bellows-like bent portion. That is, a bellows-like bent part is formed between the pressing plate and the attaching part.

  According to a third aspect of the present invention, the viscous fluid-filled damper includes a pressing plate provided with an attachment shaft in contact with the elastic bulge portion, the attachment portion being a ring shape having a pair of annular surface portions, and the elastic bulge. The portion is provided continuously with one annular surface portion that is not adjacent to either the support or the support at the attachment portion, and when the attachment shaft is fixed to one of the above, it is crushed by the pressure plate and bellows A bent portion is formed. That is, a bellows-like bent portion is formed between the mounting shaft and the pressing plate integral with the pin-shaped fixing member and the mounting portion.

  In the first to third aspects of the present invention, since the elastic bulge provided on at least one annular surface portion of the attachment portion forms a bellows-like bent portion, the attachment portion floats when subjected to vibration or impact. The bellows-like bent portion elastically supported by the deforms deforms to produce a viscous resistance of the viscous fluid filled in the sealed container. For this reason, effective vibration attenuation and shock absorption can be performed at the bellows-like bent portion. In the third invention, since the pin-shaped fixing member, the mounting shaft, and the pressing plate are integrated, the number of parts is small, and the viscous fluid-filled damper can be easily mounted without taking time and effort.

  In the present invention, the mounting shaft of the viscous fluid-filled damper is a hard material. For this reason, the mounting shaft is rigid, and the sealed container can be securely mounted on either the support or the supported body.

  According to the present invention, the viscous fluid-filled damper has a recessed portion that accommodates a proximal-side head portion of a pin-like fixing member having a distal end fixed to either the support body or the support body in the sealed container. For this reason, the proximal end side head of the pin-shaped fixing member does not protrude to the outside of the hermetic container, and the mounting space for the viscous fluid-sealed damper can be reduced.

  According to the present invention, the viscous fluid-filled damper has an elastic support film that elastically supports the attachment portion in a floating state on the other annular surface that is the opposite surface of the one annular surface that forms the elastic bulge portion of the attachment portion. That is, the mounting portion fixed to either the support body or the supported body is supported in a floating state between the elastic bulge portion and the elastic support film. The elastic support film is deformed when subjected to vibration or shock, and generates a viscous resistance of the viscous fluid filled in the sealed container, so that synergistic vibration damping and shock absorption can be exhibited together with the elastic bulge. .

  In the present invention, the elastic support membrane of the viscous fluid-filled damper is bent in a bellows cross section. For this reason, when subjected to vibration or impact in the direction perpendicular to the axis of the mounting shaft, the vibration is attenuated and absorbed by the bending deformation and the viscous resistance of the viscous fluid filled inside. can do.

  In the viscous fluid-filled damper according to the present invention, the attachment portion is a hard material, an attachment groove is formed on the outer peripheral surface of the attachment portion, and at least one of the elastic bulge portion and the elastic support film is an annular surface portion of the attachment portion. And a covering portion that covers the outer peripheral surface of the mounting portion excluding the groove surface of the mounting groove.

  In the present invention, the mounting portion in which the mounting groove is formed on the outer peripheral surface is a hard material. For this reason, even when either the support member or the supported member engaged with the mounting groove rubs or collides, the mounting groove can be prevented from being worn or broken, and the durability of the mounting groove can be improved. . In many cases, the support body or the supported body engaged with the mounting groove is formed of a rigid material such as metal or hard resin. Since the mounting groove is continuously rubbed and collided, wear of the mounting groove progresses and breaks, and the viscous fluid may leak from the sealed container. Therefore, the present invention solves this problem by assuming that the mounting groove is made of a hard material.

  In the present invention, at least one of the elastic bulge and the elastic support film is provided with a covering portion that covers the annular surface portion of the mounting portion made of a hard material and the outer peripheral surface of the mounting portion excluding the groove surface of the mounting groove. Is. That is, at least one of the elastic bulge and the elastic support film covers the annular surface portion of the attachment portion and the outer peripheral surface of the attachment portion excluding the groove surface of the attachment groove. For this reason, at the time of vibration of the supported body, it is possible to prevent the elastic bulging portion and the elastic supporting film from colliding with or rubbing against the mounting portion made of a hard material. Therefore, breakage of the elastic bulge can be prevented and durability can be improved.

  The present invention relates to the viscous fluid-filled damper, in an airtight container, an annular lid frame made of a hard resin provided at an end portion of the elastic support film, and a hard resin that closes between the end portion of the mounting shaft and the annular lid frame. And a lid. For this reason, the fixing between the annular lid frame and the lid becomes hard resins, and a stronger and more stable fixing strength is obtained as compared with the fixing between the hard resin and the rubber-like elastic body.

  In the present invention, the lid body is rigid because it is formed of a hard resin, and if the pin-like member is inserted from the lid body side and fixed so as to press the sealed container against the support body or the supported body, the lid body However, since the elastic bulge is crushed by pressing the closed container, the number of parts can be reduced without preparing a separate pressing plate for crushing the elastic bulge.

  Further, since the lid body is rigid, the mounting portion for fixing either the support body or the supported body is supported in a floating state between the other body and the lid body. For this reason, the displacement amount of the supported body along the axial direction of the mounting shaft of the hermetic container due to vibration or impact can be suppressed between the other one and the lid. Therefore, the amount of displacement of the support within the support can be reduced.

  In the viscous fluid-filled damper according to the present invention, the mounting shaft, the mounting portion, and the annular lid frame are made of a hard resin material, and the elastic bulging portion and the elastic support film are made of a thermoplastic elastomer, which are formed as an integral molded body. ing. For this reason, a sealed container can be manufactured in a short time by two-color molding or insert molding.

  In the viscous fluid-filled damper according to the present invention, the lid, the annular lid frame, and the mounting shaft have a fixing surface obtained by ultrasonic welding. For this reason, fixation with a lid, an annular lid frame, and an attachment axis becomes firm compared with fixation with an adhesive agent, and a highly durable airtight container can be obtained.

  According to the present invention, the viscous fluid-filled damper is provided with a coil spring that elastically supports a supported body attached to the attachment portion by contact with an annular surface portion of the attachment portion inside the sealed container. That is, the coil spring supports the load of the supported body. For this reason, it is possible to prevent the elastic bulging portion and the elastic support film from being crushed in the axial direction of the mounting shaft by the load of the supported body, and stirring of the viscous fluid becomes insufficient, making it difficult for viscous resistance to occur.

  According to the viscous fluid-filled damper of the present invention, when the supported body relatively moves with respect to the support body, at least one of the mounting shaft or the mounting portion is interlocked, and along with this interlock, the inside of the sealed container is The enclosed viscous fluid is agitated. For this reason, even if there is no stirring cylinder part which protrudes inside the airtight container like a prior art example, the vibration damping effect by stirring of a viscous fluid can be exhibited. Therefore, the sealed container can be made smaller than the conventional example, and the gap between the support and the supported body can be reduced.

  Further, according to the present invention, when subjected to vibration or impact, the bellows-like bent portion that elastically supports the mounting portion in a floating state is deformed, and the viscous resistance of the viscous fluid filled in the sealed container is generated. For this reason, the vibration-damping effect and the impact absorbing effect can be exhibited at the bellows-like bent portion, and the sealed container can be made smaller than the conventional example. Therefore, in combination with the above, the disk device can be made smaller than the conventional example by saving space.

  According to the present invention, the bellows-shaped bent portion is formed after the viscous fluid is sealed. In other words, the elastic bulge is crushed by fixing the sealed container to either the support or the supported body, and the bellows-like bent portion is formed by bulging and deforming outward in the axial direction of the mounting shaft. For this reason, it is possible to suppress the reduction of the vibration damping effect due to the remaining air in the sealed container while having the bellows-like bent portion.

  Hereinafter, examples of embodiments of the present invention will be described with reference to the drawings. In addition, about the structure which is common in each embodiment, the same code | symbol is attached | subjected and duplication description is abbreviate | omitted.

First Embodiment [FIGS. 1 to 3]
The viscous fluid-filled damper 12 of this embodiment has a configuration in which a viscous fluid 9 is sealed in a sealed container 13. The sealed container 13 has a hollow donut shape, and is formed by adhering a container body 14 and a lid body 15 formed separately to each other by ultrasonic fusion.

  The container main body 14 has a hollow donut shape with one end opened, and includes a mounting shaft 16, an outer peripheral portion 17, and a bottom portion 18 on the inner periphery. Among these, the mounting shaft 16 is formed in a cylindrical shape made of hard resin, and a circular insertion hole 16a through which the mounting screw N is passed is provided through the shaft center. The outer peripheral portion 17 has a substantially cylindrical shape made of a rubber-like elastic body, and an annular lid frame 17a made of hard resin is fixed to the open end. An annular attachment groove 19 as an “attachment portion” for fixing the attachment piece 5 a of the mechanical chassis 5 is formed in the outer peripheral portion 17, and an annular elastic support film 20 is formed between the attachment groove 19 and the lid frame 17 a. Is provided. The bottom portion 18 is made of a rubber-like elastic body, and closes the other end sides of the attachment shaft 16 and the outer peripheral portion 17 and is formed in a curved shape from the lower end of the attachment shaft 16 downward in the axial direction. And the part of the outer peripheral part 17 connected from the bottom part 18 and the bottom part 18 to the attachment groove | channel 19 comprises the "elastic swelling part."

  The lid body 15 is formed in an annular shape made of a hard resin, and an insertion hole 15a that is aligned with the insertion hole 16a of the mounting shaft 16 is formed through the center thereof. The inner edge of the lid 15 is fixed to the opening end of the mounting shaft 16 by ultrasonic fusion, and the outer edge is fixed to the lid frame 17 a of the outer peripheral portion 17 by ultrasonic fusion.

  Next, a disk device 21 to which the viscous fluid-filled damper 12 of this embodiment is attached and a method for attaching the viscous fluid-filled damper 12 will be described.

  As shown in FIG. 1, the disk device 21 includes a mechanical chassis 5, a housing 8 incorporating the mechanical chassis 5, and a viscous fluid-filled damper 12 interposed between the mechanical chassis 5 and the housing 8. Yes. The viscous fluid-filled damper 12 is fixed to the mechanical chassis 5, fixed to the housing 8, and attached to the disk device 21.

  The mechanical chassis 5 is provided with an attachment piece 5a protruding from the side surface. As shown in FIG. 2A, the attachment piece 5a has a circumferential shape of the attachment groove 19 of the damper 12 filled with viscous fluid. A relatively shaped engagement inner edge 5b is formed. This engagement inner edge 5b is inserted into the mounting groove 19 from the side of the viscous fluid-filled damper 12 with the lid 15 facing upward. In this way, the viscous fluid-filled damper 12 is attached to the mechanical chassis 5. The mechanical chassis 5 is provided with such attachment pieces 5a at a plurality of locations (for example, four corners of the mechanical chassis 5), each of which is inserted into the attachment groove 19 of the viscous fluid-filled damper 12 as described above. Engage.

  A hole 8 a is formed through the housing 8. As shown in FIG. 2B, the bottom 18 of the viscous fluid-filled damper 12 is opposed to the bottom surface 8b of the housing 8, and the mounting screw N is inserted into the insertion holes 15a and 16a from the lid 15 side. And screwed into a hole 8a formed in the bottom surface 8b. At this time, the mounting screw N is screwed until the lower end of the mounting shaft 16 comes into contact with the bottom surface 8 b of the housing 8. As a result, the bottom portion 18 of the viscous fluid-filled damper 12 is attached so as to be crushed by the bottom surface 8 b of the housing 8. As a result, the bottom 18 and the portion of the outer peripheral portion 17 connected from the bottom 18 to the mounting groove 19 bulge and deform outward in a direction orthogonal to the axis of the mounting shaft 16, and the bellows-shaped bent portion 22 is mounted on the mounting groove 19. And the housing 8. In this way, as shown in FIG. 1, the mechanical chassis 5 is supported in a vibration-proof manner inside the housing 8 by the viscous fluid-filled damper 12.

  Here, the material of each member constituting the viscous fluid-filled damper 12 will be described. In addition, the following description is common also to each below-mentioned embodiment.

  The material of the “rubber-like elastic body” is preferably a synthetic rubber or a thermoplastic elastomer that is flexibly deformed, has bending resistance, and has a damping effect. For example, synthetic rubber includes butyl rubber, styrene butadiene rubber, chloroprene rubber, nitrile rubber, urethane rubber, silicone rubber, fluorine rubber, acrylic rubber, and the like. , Urethane thermoplastic elastomers, vinyl chloride thermoplastic elastomers, and the like.

  The material of the “hard resin” is preferably a thermoplastic resin due to required performance such as mechanical strength, heat resistance, durability, dimensional accuracy, reliability, and weight reduction and workability. For example, polyethylene resin, polypropylene resin, polyvinyl chloride resin, polystyrene resin, acrylonitrile / styrene / acrylate resin, acrylonitrile / butadiene / styrene resin, polyamide resin, polyacetal resin, polycarbonate resin, polyethylene terephthalate resin, polybutylene terephthalate resin, polyphenylene oxide Examples thereof include thermoplastic resins such as resins, polyphenylene ether resins, polyphenylene sulfide resins, polyurethane resins, and liquid crystal polymers, or composite resins thereof. By adding a filler such as powdered or fibrous metal, glass, filler, etc. to the thermoplastic resin, the dimensional accuracy and heat resistance can be further improved.

  The container body 14 and the lid 15 as described above are concrete from the viewpoint of a mutual fixing method preferable for obtaining liquid tightness required as a “sealed container” and a manufacturing method for realizing the fixing method. The material is selected. For example, from the viewpoint of realizing integral molding with the mounting shaft 16, the outer peripheral portion 17, the lid frame 17a, and the bottom portion 18 by using a mold, a thermoplastic elastomer is used as the rubber-like elastic body, and the mounting shaft 16 and the lid frame 17a are used. Using this thermoplastic elastomer and a thermoplastic resin (for example, polypropylene resin, acrylonitrile butadiene styrene resin) that is fixed by mold forming, the lid 15 is ultrasonically fused to the mounting shaft 16 and the lid frame 17a. The cover 15 can be made of a thermoplastic resin (for example, polypropylene resin, acrylonitrile butadiene styrene resin) that can be ultrasonically fused with the thermoplastic resin of the mounting shaft 16 and the lid frame 17a. And according to this, it is possible to firmly fix the mounting shaft 16, the outer peripheral portion 17, the lid frame 17 a, and the bottom portion 18 by die integral molding such as insert molding or two-color molding. By fixing the lid 15 by sonic fusion, the lid 15 can be instantly and firmly integrated with the mounting shaft 16 and the lid frame 17a, and has excellent liquid tightness and high production. Can be realized.

  The material of the viscous fluid 9 is preferably a liquid or a liquid to which solid particles that do not react and dissolve in the liquid are added. Examples thereof include liquids such as silicone oils, paraffinic oils, ester oils, and liquid rubbers, or those obtained by adding solid particles that do not react and dissolve in these liquids. Of these, silicone-based oils are preferred as liquids due to required performance such as temperature dependency, heat resistance, and reliability. Specifically, dimethyl silicone oil, methyl phenyl silicone oil, methyl hydrogen silicone oil, fluorine-modified silicone are preferred. Examples of solid particles that react and do not dissolve in these silicone oils include silicone resin powder, polymethylsilsesquioxane powder, wet silica, dry silica, glass beads, glass balloons, etc., or surface treatment thereof. These are used alone or in combination.

  Next, functions and effects of this embodiment will be described.

  According to the viscous fluid-filled damper 12, the mounting shaft 16 is fixed to the housing 8, and the mounting groove 19 is fixed to the mechanical chassis 5. That is, when the mechanical chassis 5 moves relative to the housing 8, the mounting groove 19 is interlocked, and the viscous fluid 9 enclosed in the sealed container 13 is agitated along with this interlocking. For this reason, even if there is no stirring cylinder part 4 which protrudes into the inside of the airtight container 2 like the prior art example of FIG. 21, a vibration damping effect can be exhibited. Therefore, even if there is no stirring cylinder part 4, the vibration damping effect is exhibited, the sealed container 13 can be made smaller than the conventional example, and the gap between the housing 8 and the mechanical chassis 5 can be reduced.

  The bellows-like bent portion 22 is deformed when subjected to vibration or impact, and generates a viscous resistance of the viscous fluid 9 filled in the sealed container 13. For this reason, even if there is no stirring cylinder part 4, the vibration-damping effect and the impact absorption effect which were excellent in the bellows-like bending part 22 can be exhibited. Therefore, the sealed container 13 can be made smaller than the conventional example.

  The bellows-like bent portion 22 is formed by fixing the viscous fluid-filled damper 12 to the housing 8 after the viscous fluid 9 is sealed. For this reason, there is no air accumulation in the inside of the bellows-like bent portion 22, and the viscous fluid 9 is sufficiently stirred. Therefore, an excellent vibration damping effect and shock absorbing effect can be exhibited.

  The elastic support film 20 holds the mounting groove 19 between the bellows-shaped bent portion 22 and supports the mounting groove 19 in a floating state. The elastic support film 20 is deformed when subjected to vibration or impact, and generates a viscous resistance of the viscous fluid 9 filled in the sealed container 13. Absorption can be demonstrated.

  Since the lid 15 is formed of a hard resin, it has rigidity and does not deform, and the mounting groove 19 for fixing the mechanical chassis 5 can be supported in a floating state between the housing 8 and the lid 15. For this reason, the maximum amount of displacement of the mechanical chassis 5 along the axial direction of the mounting shaft 16 of the sealed container 13 due to vibration or impact can be suppressed between the housing 8 and the lid 15. Therefore, the maximum displacement amount of the mechanical chassis 5 in the housing 8 can be fixed, and the mechanical chassis 5 is not displaced beyond the maximum displacement amount. In other words, since the displacement amount of the mechanical chassis 5 is not restricted in the conventional viscous fluid-filled damper 1, it is necessary to set a wide gap between the housing 8 and the mechanical chassis 5 that exceeds the expected displacement amount of the mechanical chassis 5. is there. However, with the viscous fluid-filled damper 12 of the present embodiment, the maximum displacement amount of the mechanical chassis 5 can be fixed as described above, so there is no need to set a larger gap than necessary with the housing 8. The arrangement of the mechanical chassis 5 without waste in space can be realized. Therefore, the disk device 21 can be made smaller than the conventional example.

  Since the mounting shaft 16 is formed of a hard resin, the mounting shaft 16 is rigid, and no separate fixing member is required, and the number of parts can be reduced. The sealed container 13 can be easily and securely fixed to the housing 8 with the mounting screw N.

  Since the lid 15 is rigid, if the mounting screw N is inserted into the insertion holes 15a and 16a from the lid 15 side and fixed so as to press the sealed container 13 against the housing 8, the lid 15 is sealed. 13 is pressed and the bottom portion 18 and the like are crushed, so that the number of parts can be reduced without preparing a separate member for crushing the bottom portion 18 and the like.

  The mounting shaft 16 and the lid frame 17a are made of a hard resin material, the mounting groove 19, the elastic support film 20 and the bellows-shaped bent portion 22 are made of a thermoplastic elastomer, and these are formed as an integral molded body. The sealed container 13 can be manufactured in a short time.

  Since the lid 15, the mounting shaft 16 and the lid frame 17 a are formed of hard resin, the lid 15, the mounting shaft 16 and the lid frame 17 a can be fixed by ultrasonic fusion. For this reason, it can be firmly and stably fixed as compared with the adhesive, and the liquid tightness of the sealed container 13 can be improved.

Second Embodiment [FIG. 4]
The viscous fluid-filled damper 23 of the second embodiment is different from the viscous fluid-filled damper 12 of the first embodiment in the configuration of the ring 24 as an “attachment portion”. The remaining configuration is the same as in the first embodiment.

  The ring 24 is made of a hard resin, and an attachment groove 19 is formed on the outer peripheral surface, and is fixed integrally with the outer peripheral portion 17. Specifically, of the pair of annular surface portions 24a facing each other in the axial direction of the mounting shaft 16 in the ring 24, a portion of the outer peripheral portion 17 connected to the bottom portion 18 on the inner edge of one annular surface portion 24a adjacent to the bottom portion 18. Is fixed. The elastic support film 20 is fixed to the outer peripheral surface of the other annular surface portion 24a.

  The method of attaching the viscous fluid-filled damper 23 is the same as that of the viscous fluid-filled damper 12 of the first embodiment.

  The viscous fluid-filled damper 23 of the second embodiment can reduce the size of the disk device 21 as compared with the conventional viscous fluid-filled damper 12 of the first embodiment and can be easily and securely fixed to the disk device 21. Demonstrates the following effects. That is, since the mounting groove 19 is made of a hard resin, the viscous fluid-filled damper 23 can prevent the mounting groove 19 from being worn or broken even when the mounting piece 5a of the mechanical chassis 5 is rubbed or collided. A highly sealed container 13 can be realized.

Third Embodiment (FIG. 5)
The viscous fluid-filled damper 25 of the third embodiment is different from the viscous fluid-filled damper 23 of the second embodiment in a configuration in which a recess 26 is provided on the lid 15 side of the hermetic container 13. The remaining configuration is the same as in the second embodiment.

  A concave portion 15b having a diameter larger than the diameter of the insertion hole 15a is formed at the center of the lid body 15, and a concave portion 16b having a diameter larger than the diameter of the insertion hole 16a is formed at the upper end of the mounting shaft 16. And the recessed part 26 which accommodates the base end side head of the attachment screw N by the recessed part 15b of the cover body 15 fitting in the recessed part 16b of the attachment shaft 16 is comprised. Also in this embodiment, the lid 15 is ultrasonically fused to both the lid frame 17a and the mounting shaft 16.

  Next, a method for attaching the viscous fluid-filled damper 25 will be described. The mechanical chassis 5 is fixed in the same manner as the viscous fluid-filled damper 23. For the housing 8, similarly to the viscous fluid-filled damper 23, the mounting screw N is inserted into the insertion holes 15 a and 16 a from the lid 15 side, and the hole 8 a formed in the bottom surface 8 b of the housing 8. Although the screw is engaged, the proximal end side head of the mounting screw N is accommodated inside the recess 26.

  The viscous fluid-filled damper 25 of the third embodiment can reduce the size of the disk device 21 as compared with the conventional viscous fluid-filled damper 23 of the second embodiment, can be easily and securely fixed to the disk device 21, and is highly durable. The airtight container 13 can be realized, and further, the following actions and effects are exhibited. That is, the viscous fluid-filled damper 25 is provided with the concave portion 26 that accommodates the proximal-side head of the mounting screw N, so that the proximal-side head of the mounting screw N does not protrude to the outside of the hermetic container 13, and the viscous fluid The mounting space for the enclosed damper 25 can be reduced.

Fourth Embodiment [FIG. 6]
The viscous fluid-filled damper 27 of the fourth embodiment is different from the viscous fluid-filled damper 25 of the third embodiment in that the covering portion 28 is provided on the annular surface portion 24 a of the ring 24 adjacent to the bottom portion 18. The remaining configuration is the same as in the third embodiment.

  A rubber-like elastic body constituting the outer peripheral portion 17 connected from the bottom portion 18 to the ring 24 forms a covering portion 28 that covers the annular surface portion 24a excluding the mounting groove 19 of the ring 24 adjacent to the bottom portion 18 in the ring 24. .

  The method of attaching the viscous fluid-filled damper 27 is the same as that of the viscous fluid-filled damper 25 of the third embodiment.

  The viscous fluid-filled damper 27 according to the fourth embodiment can reduce the size of the disk device 21 as compared with the conventional viscous fluid-filled damper 25, and can be easily and securely fixed to the disk device 21 with high durability. The airtight container 13 can be realized, and further, the following actions and effects are exhibited. That is, since the viscous fluid-filled damper 27 covers the bellows-like bent portion 22 side of the ring 24 made of hard resin with the covering portion 28 made of a rubber-like elastic body, the soft bellows-like bent portion is vibrated when the mechanical chassis 5 vibrates. It is possible to prevent 22 from directly colliding with or rubbing against the hard ring 24. Therefore, breakage of the bellows-like bent portion 22 can be prevented, and the durability of the sealed container 13 can be improved.

Fifth embodiment (FIG. 7)
The viscous fluid-filled damper 29 of the fifth embodiment is different from the viscous fluid-filled damper 27 of the fourth embodiment in that the elastic support film 20 and the annular surface portion 24a adjacent to the lid 15 in the ring 24 are covered with the covering portion. 28 is provided. The remaining configuration is the same as in the fourth embodiment.

  The elastic support film 20 is formed in a bent shape having an annular shape and a bellows-shaped cross section, and forms a covering portion 28 that covers the annular surface portion 24a excluding the mounting groove 19 on the side adjacent to the lid body 15 in the ring 24. .

  The method of attaching the viscous fluid-filled damper 29 is the same as that of the viscous fluid-filled damper 27 of the fourth embodiment.

  As with the viscous fluid-filled damper 27 of the fourth embodiment, the viscous fluid-filled damper 29 of the fifth embodiment can make the disk device 21 smaller than the conventional one, and can be easily and securely fixed to the disk device 21 and has high durability. The airtight container 13 can be realized, and further, the following actions and effects are exhibited.

  In the viscous fluid-filled damper 29, the elastic support film 20 has a bent shape with a bellows cross section. Therefore, when subjected to vibration or impact in the direction perpendicular to the axis of the mounting shaft 16, the bending deformation is caused. The viscous resistance of the viscous fluid 9 filled therein can attenuate the vibration and absorb the impact.

  In the viscous fluid-filled damper 29, the annular surface portion 24 a adjacent to the elastic support film 20 of the ring 24 made of hard resin is covered with the covering portion 28 made of a rubber-like elastic body, so that it is soft when the mechanical chassis 5 vibrates. It is possible to prevent the elastic support film 20 from directly colliding with or rubbing against the hard ring 24. Therefore, the elastic support film 20 can be prevented from being broken, and the durability of the sealed container 13 can be improved.

Sixth Embodiment [FIG. 8]
The viscous fluid-filled damper 30 of the sixth embodiment is different from the viscous fluid-filled damper 29 of the fifth embodiment in the configuration of the upper end of the lid 15 and the mounting shaft 16. The remaining configuration is the same as that of the fifth embodiment.

  The upper end of the lid 15 and the mounting shaft 16 is formed flat, and the viscous fluid-filled damper 30 is recessed on the side adjacent to the lid 15 of the hermetic container 13 in the same manner as the lid 15 side of the viscous fluid-filled damper 23. 26 is not provided.

  The viscous fluid sealing damper 30 is attached to the mechanical chassis 5 with the bottom 18 facing upward and the inner edge 5b of the attachment piece 5a inserted into the attachment groove 19 from the side. For the housing 8, the mounting screw N is attached to the bottom portion 18 through a pressing plate 31 made of a hard resin with the lid body 15 facing the bottom surface 8 b of the housing 8 and penetrating the insertion hole 31 a prepared separately. It penetrates into the insertion holes 31a, 15a, 16a from the side, and is screwed into the hole 8a in the bottom surface 8b of the housing 8. At this time, the mounting screw N is screwed until the mounting shaft 16 and the pressing plate 31 come into contact with each other. Thus, the viscous fluid-filled damper 30 is attached such that the bottom 18 is crushed by the pressing plate 31. As a result, the bottom portion 18 and the portion of the outer peripheral portion 17 connected from the bottom portion 18 to the ring 24 bulge and deform outwardly perpendicular to the mounting shaft 16, and the bellows-like bent portion 22 is between the ring 24 and the pressing plate 31. Will be formed. The pressing plate 31 has a circular shape made of hard resin, and has an outer diameter that is larger than the outer diameter of the bulging portion 22. In this way, the mechanical chassis 5 is supported in a vibration-proof manner inside the housing 8 by the viscous fluid-filled damper 30.

  As with the viscous fluid-filled damper 29 of the fifth embodiment, the viscous fluid-filled damper 30 of the sixth embodiment can make the disk device 21 smaller than the conventional one, and can be easily and securely fixed to the disk device 21 and has high durability. The airtight container 13 can be realized, and further, the following actions and effects are exhibited. That is, in the viscous fluid-filled damper 30, the lid 15 is in contact with the bottom surface 8b of the housing 8, but since the pressing plate 31 is formed of a hard resin, it is rigid and does not deform, and fixes the mechanical chassis 5. The ring 24 can be supported in a floating state between the housing 8 and the pressing plate 31. For this reason, the maximum displacement amount of the mechanical chassis 5 along the axial direction of the mounting shaft 16 of the sealed container 13 due to vibration or impact can be suppressed between the housing 8 and the pressing plate 31. Therefore, the maximum displacement amount of the mechanical chassis 5 in the housing 8 can be fixed. Therefore, the disk device 21 can be made smaller than the conventional example.

Seventh Embodiment [FIG. 9]
The viscous fluid-filled damper 32 of the seventh embodiment has a configuration in which the viscous fluid 9 is sealed in a sealed container 33. The sealed container 33 is formed in a hollow donut shape made of a rubber-like elastic body.

  The sealed container 33 includes an inner peripheral portion 34, an outer peripheral portion 35, and bottom portions 36 a and 36 b that close these end portions. Of these, the inner peripheral portion 34 is formed in a cylindrical shape, and an inner wall 34b that protrudes toward the axial center projects from the center hole 34a. A hole 34c is formed through the inner wall 34b and engages with a mounting shaft 37 which is a separate member from the sealed container 33 penetrating into the center hole 34a. The outer peripheral portion 35 is formed in a cylindrical shape, and a ring 24 made of hard resin as an “attachment portion” for fixing the attachment piece 5 a of the mechanical chassis 5 is integrally fixed thereto. A mounting groove 19 is formed on the outer peripheral surface of the ring 24, and an outer peripheral portion 35 is formed on the outer peripheral surface of the ring 24 excluding the mounting groove 19, that is, on the pair of annular surface portions 24 a opposed in the axial direction of the mounting shaft 37. The covering portion 28 is formed by a rubber-like elastic body constituting the structure. The bottom portions 36a and 36b close the end portions of the inner peripheral portion 34 and the outer peripheral portion 35, and both ends of the inner peripheral portion 34 and the outer peripheral portion 35 and the bottom portions 36a and 36b constitute an “elastic bulge portion”.

  Next, a method for attaching the viscous fluid-filled damper 32 of the seventh embodiment will be described.

  The viscous fluid-filled damper 32 is fixed to the housing 8 after being fixed to the mechanical chassis 5 in the same manner as the viscous fluid-filled damper of each of the above-described embodiments. First, the inner edge 5b of the attachment piece 5a is inserted into the attachment groove 19 from the side and attached to the mechanical chassis 5.

  Next, as shown in FIG. 9A, the housing 8 is attached to the housing 8 with mounting screws N using a separate mounting shaft 37 and a pressing plate 31. Of these, the mounting shaft 37 is formed in a cylindrical shape made of hard resin. A circular insertion hole 37a through which the mounting screw N penetrates is formed through the shaft, and a stepped portion having a relative shape to the hole 34c of the inner wall 34b is provided at an end portion engaged with the inner wall 34b of the inner peripheral portion 34. ing. A recess 26 having a diameter larger than the diameter of the insertion hole 31 a is formed in the center of the pressing plate 31 and accommodates the proximal end side head of the mounting screw N. An attachment shaft 37 is inserted into the center hole 34 a of the inner peripheral portion 34, an attachment screw N is inserted into the insertion holes 31 a and 37 a through the pressing plate 31, and screwed into the hole 8 a formed in the bottom surface 8 b of the housing 8. Combine. The proximal end side head of the mounting screw N is accommodated inside the recess 26. At this time, the attachment screw N is screwed until the lower end of the attachment shaft 37 comes into contact with the bottom surface 8 b of the housing 8. Accordingly, the bottom portions 36 a and 36 b of the viscous fluid-filled damper 32 are attached so as to be crushed by the bottom surface 8 b of the housing 8 and the pressing plate 31. As a result, both ends of the bottom portions 36 a and 36 b and the inner peripheral portion 34 and the outer peripheral portion 35 bulge and deform outward outward perpendicular to the axis of the mounting shaft 37, and the bellows-shaped bent portion 22 is in the axial direction of the mounting shaft 37. It will be formed on both sides of the ring 24. Thus, the mechanical chassis 5 is supported by the viscous fluid-filled damper 32 in a vibration-proof manner inside the housing 8.

  As with the viscous fluid-filled damper 30 of the sixth embodiment, the viscous fluid-filled damper 32 of the seventh embodiment can make the disk device 21 smaller than the conventional one, and can be easily and securely fixed to the disk device 21 and has high durability. The airtight container 33 can be realized, and further, the following actions and effects are exhibited.

  In the viscous fluid-filled damper 32, the sealed container 33 and the mounting shaft 37 are made of different materials. For this reason, the combination of the sealed container 33 made of a rubber-like elastic body and the mounting shaft 37 made of a hard resin can be realized, the entire sealed container 33 is deformed flexibly, and the viscous resistance of the viscous fluid 9 enclosed inside is increased, and the hard The mounting shaft 37 can be securely fixed to the housing 8.

  In the viscous fluid-filled damper 32, the ring 24 is supported in a floating state between the bellows-shaped bent portions 22 on both sides. For this reason, when subjected to vibration or impact, the bellows-like bent portions 22 on both sides are deformed, and the viscous resistance of the viscous fluid 9 filled in the sealed container 33 is generated. Excellent vibration damping and shock absorption.

  In the viscous fluid-filled damper 32, since the pressing plate 31 is made of hard resin, it is rigid and does not deform, and the ring 24 that fixes the mechanical chassis 5 is supported in a floating state between the housing 8 and the pressing plate 31. it can. For this reason, the maximum displacement amount of the mechanical chassis 5 along the axial direction of the mounting shaft 37 of the sealed container 33 due to vibration or impact can be suppressed between the housing 8 and the pressing plate 31. Therefore, the maximum displacement amount of the mechanical chassis 5 in the housing 8 can be fixed. Therefore, the disk device 21 can be made smaller than the conventional example.

Eighth Embodiment [FIG. 10]
The viscous fluid-filled damper 38 of the eighth embodiment differs from the viscous fluid-filled damper 32 of the seventh embodiment in the configuration of the mounting shaft 39. The remaining configuration is the same as in the seventh embodiment.

  The mounting shaft 39 is formed of a hard resin, and the mounting shaft 37 and the pressing plate 31 are integrated. The mounting shaft 39 includes a mounting shaft portion 39a and a pressing plate portion 39b. A circular insertion hole 39c through which the mounting screw N penetrates is formed through the shaft center of the mounting shaft portion 39a, and one end portion that engages with the inner wall 34b of the inner peripheral portion 34 has a shape relative to the hole 34c of the inner wall 34b. A step portion is provided. At the other end, an annular pressing plate portion 39b protruding in a direction perpendicular to the axis is formed, and the outer diameter of the pressing plate portion 39b is formed larger than the outer diameter of the bellows-like bent portion 22. A concave portion 26 having a diameter larger than the diameter of the insertion hole 39a is formed in the center of the pressing plate portion 39b, and the proximal end side head portion of the mounting screw N is accommodated.

  Next, a method for attaching the viscous fluid-filled damper 38 will be described. The mechanical chassis 5 is fixed in the same manner as the viscous fluid-filled damper 32. As shown in FIG. 10 (A), the mounting shaft 39 is inserted into the center hole 34a of the inner peripheral portion 34, and the mounting screw 39 is inserted into the housing 8 from the pressing plate portion 39b side. It penetrates into the hole 39 c and is screwed into the hole 8 a formed in the bottom surface 8 b of the housing 8. The proximal end side head of the mounting screw N is accommodated inside the recess 26. As a result, like the viscous fluid-filled damper 32, the bellows-like bent portions 22 are formed on both sides of the ring 24, and the mechanical chassis 5 is supported by the viscous fluid-filled damper 38 on the inside of the housing 8 for vibration isolation. .

  As with the viscous fluid-filled damper 32 of the seventh embodiment, the viscous fluid-filled damper 38 of the eighth embodiment can make the disk device 21 smaller than the conventional one, and can be easily and securely fixed to the disk device 21 and is highly durable. In addition to the airtight container 33 being realized, the following actions and effects are further exhibited. That is, the viscous fluid-filled damper 38 has a small number of parts because the mounting shaft 39 is composed of the mounting shaft portion 39a and the pressing plate portion 39b, and the viscous fluid-filled damper 38 can be easily mounted without taking time and effort.

Ninth Embodiment [FIG. 11]
The viscous fluid-filled damper 40 of the ninth embodiment is different from the viscous fluid-filled damper 32 of the seventh embodiment in the configuration of the pressing plate 41. The remaining configuration is the same as in the seventh embodiment.

  The pressing plate 41 is formed of a hard resin, and the pressing plate 31 and the mounting screw N are integrated. The pressing plate 41 includes the pressing plate portion 41a and the mounting screw portion 41b. The outer diameter of the pressing plate portion 41a is formed larger than the outer diameter of the bellows-like bent portion 22, and an attachment screw portion 41b is formed in the center of the pressing plate portion 41a so as to penetrate the pressing plate portion 41a.

  Next, a method for attaching the viscous fluid-filled damper 40 will be described. The mechanical chassis 5 is fixed in the same manner as the viscous fluid-filled damper 32. 11A, the mounting shaft 37 is inserted into the center hole 34a of the inner peripheral portion 34, and the mounting screw portion 41b of the pressing plate 41 is inserted from the upper end side of the mounting shaft 37. It penetrates into the hole 37 a and is screwed into the hole 8 a formed in the bottom surface 8 b of the housing 8. As a result, like the viscous fluid-filled damper 32, the bellows-like bent portions 22 are formed on both sides of the ring 24, and the mechanical chassis 5 is supported by the viscous fluid-filled damper 40 on the inside of the housing 8 in a vibration-proof manner. .

  As in the viscous fluid-filled damper 32 of the seventh embodiment, the viscous fluid-filled damper 40 of the ninth embodiment can make the disk device 21 smaller than the conventional one, and can be easily and securely fixed to the disk device 21 and has high durability. The airtight container 33 can be realized, and further, the following actions and effects are exhibited. That is, in the viscous fluid-filled damper 40, since the pressing plate 41 includes the pressing plate portion 41a and the mounting screw portion 41b, the number of components is small, and the viscous fluid-filled damper 40 can be easily attached without taking time and effort.

Tenth Embodiment [FIG. 12]
The viscous fluid-filled damper 42 of the tenth embodiment differs from the viscous fluid-filled damper 32 of the seventh embodiment in the configuration of the mounting shaft 43. The remaining configuration is the same as in the seventh embodiment.

  The mounting shaft 43 is made of a hard resin, and is formed by integrating the mounting shaft 37, the pressing plate 31, and the mounting screw N, and includes the mounting shaft portion 43a, the pressing plate portion 43b, and the mounting screw portion 43c. The Of the mounting shaft portion 43a, one end portion engaged with the inner wall 34b of the inner peripheral portion 34 is provided with a stepped portion having a shape relative to the hole 34c of the inner wall 34b, and the outer diameter of the bellows-like bent portion 22 at the other end portion. A pressing plate portion 43b having a larger diameter is provided, and a screw portion 43c is formed in the shaft center so as to penetrate the mounting shaft portion 43a.

  Next, a method for attaching the viscous fluid-filled damper 40 will be described. The mechanical chassis 5 is fixed in the same manner as the viscous fluid-filled damper 32. For the housing 8, as shown in FIG. 12A, the mounting shaft 43 is inserted into the center hole 34 a of the inner peripheral portion 34 with the mounting screw portion 43 c as the tip, and the mounting screw portion 43 c is inserted into the housing 8. It is screwed into the hole 8a formed in the bottom surface 8b. As a result, like the viscous fluid-filled damper 32, the bellows-like bent portions 22 are formed on both sides of the ring 24, and the mechanical chassis 5 is supported by the viscous fluid-filled damper 42 on the inside of the housing 8 in a vibration-proof manner. .

  As with the viscous fluid-filled damper 32 of the seventh embodiment, the viscous fluid-filled damper 42 of the tenth embodiment can make the disk device 21 smaller than the conventional one, and can be easily and securely fixed to the disk device 21 and has high durability. The airtight container 33 can be realized, and further, the following actions and effects are exhibited. That is, the viscous fluid sealing damper 43 has a small number of parts because the mounting shaft 43 is composed of the mounting shaft portion 43a, the pressing plate portion 43b, and the mounting screw portion 43c. it can.

  Next, a modified example of the disk device 21 will be described. The viscous fluid-filled damper will be described with the viscous fluid-filled damper 12 of the first embodiment described above as a representative example, but it is of course possible to install a viscous fluid-filled damper other than the first embodiment. is there.

Modified examples of the disk device 21 to which the viscous fluid-filled damper 12 of the first embodiment is attached [FIGS. 13 and 14]
The disk device 44 of the modified example has a hole 5 c threadedly engaged with the mounting screw N in the mechanical chassis 5 and a mounting piece 8 c formed in the housing 8.

  As shown in FIG. 14A, a through hole 8d through which the viscous fluid-filled damper 12 can penetrate is formed in the bottom surface 8b of the housing 8, and the through hole 8d projects inward from the side surface of the through hole 8d. A mounting piece 8c is formed. The mounting piece 8c is inserted into the mounting groove 19 of the viscous fluid-filled damper 12 in the same manner as the mounting piece 5a of the mechanical chassis 5 described above. The housing 8 has such mounting pieces 8d formed at a plurality of locations (locations facing the mounting portion 5d of the mechanical chassis 5), each of which is as described above with respect to the mounting groove 19 of the viscous fluid-filled damper 12. To be engaged.

  A hole 5 c is formed through the attachment portion 5 d of the mechanical chassis 5. As shown in FIG. 14 (B), the bottom 18 of the viscous fluid-filled damper 12 is opposed to the mounting portion 5d of the mechanical chassis 5, and the mounting screw N is inserted into the insertion holes 15a and 16a from the lid body 15 side. Screwed into the hole 5c of the portion 5d. At this time, the attachment screw N is screwed in until the end of the attachment shaft 16 adjacent to the bottom 18 contacts the attachment portion 5d of the mechanical chassis 5. As a result, the bottom 18 of the viscous fluid-filled damper 12 is attached so as to be crushed by the attachment 5d of the mechanical chassis 5. As a result, the bottom portion 18 and the portion of the outer peripheral portion 17 connected from the bottom portion 18 to the mounting groove 19 bulge outwardly perpendicular to the axis of the mounting shaft 16, and the bellows-shaped bent portion 22 is mechanically coupled to the ring 24. It is formed between the chassis 5. Thus, as shown in FIG. 13, the mechanical chassis 5 is supported in a vibration-proof manner inside the housing 8 by the viscous fluid-filled damper 12.

  According to the disk device 44, as with the disk device 21, it can be made smaller than before, and can be easily and securely fixed to the disk device 44, and a highly durable sealed container 13 can be realized.

  Next, a viscous fluid-filled damper including the compression coil spring 45 will be described. The viscous fluid-filled damper will be described with reference to typical examples from the above-described embodiments, but it is of course possible to attach a viscous fluid-filled damper other than that embodiment.

Eleventh Embodiment (FIG. 15)
The viscous fluid-filled damper 46 of the eleventh embodiment is configured to include a compression coil spring 45 inside the hermetic container 13 in the viscous fluid-filled damper 30 of the sixth embodiment.

  The compression coil spring 45 is concentric with the mounting shaft 16, and is provided between the lid 15 of the ring 24 adjacent to the annular surface portion 24 a and the lid 15. That is, the ring 24 is elastically supported together with the elastic support film 20 in a floating state. Even when the ring 24 moves horizontally together with the mechanical chassis 5 at the time of mounting, since the annular elastic support film 20 surrounds the compression coil spring 45 from the periphery, the compression coil spring 45 is formed in the annular surface portion of the ring 24. It does not fall out of 24a.

  The method of attaching the viscous fluid-filled damper 46 is the same as that of the viscous fluid-filled damper 30 of the sixth embodiment.

  As with the viscous fluid-filled damper 30 of the sixth embodiment, the viscous fluid-filled damper 46 of the eleventh embodiment can make the disk device 21 smaller than the conventional one, and can be easily and securely fixed to the disk device 21 and has high durability. The airtight container 13 can be realized, and further, the following actions and effects are exhibited.

  According to the viscous fluid sealing damper 46, the compression coil spring 45 elastically supports the ring 24 together with the elastic support film 20 in a floating state, so that the elastic support film 20 is crushed in the axial direction of the mounting shaft 16 by the load of the mechanical chassis 5. It is possible to prevent the viscous fluid 9 from being insufficiently agitated and viscous resistance from becoming difficult to occur.

  Since the compression coil spring 45 is installed inside the sealed container 13, it is not necessary to assemble the compression coil spring 45 separately. Therefore, assembly to the disk device 21 is easy, and the number of parts can be reduced.

A disk device 47 with a modified example of the viscous fluid-filled damper 46 of the eleventh embodiment (FIG. 16)
The disk device 47 is configured to include a modification of the viscous fluid-filled damper 46, and the modification of the viscous fluid-filled damper 46 is configured to include a compression coil spring 45 on the outer periphery of the viscous fluid-filled damper 30.

  The compression coil spring 45 is concentric with the mounting shaft 16, and is installed between the surface of the mounting piece 5 a of the mechanical chassis 5 that faces the bottom surface 8 b of the housing 8 and the bottom surface 8 b of the housing 8. . That is, as shown in FIG. 16, the mechanical chassis 5 is elastically supported in a floating state.

  In the modified example of the viscous fluid-filled damper 46, the disk device 47 can be made smaller than the conventional one in the same manner as the viscous fluid-filled damper 30 of the sixth embodiment, and can be easily and securely fixed to the disk device 47. 13 can be realized, and further, the following actions and effects are exhibited.

  According to the modification, since the compression coil spring 45 elastically supports the mechanical chassis 5 in a floating state, the elastic support film 20 is crushed in the axial direction of the mounting shaft 16 by the load of the mechanical chassis 5 and the viscous fluid 9 is stirred. It can prevent that it becomes inadequate and it becomes difficult to produce viscous resistance.

  Further, since the compression coil spring 45 is not installed inside the viscous fluid-filled damper, the amount of the viscous fluid 9 enclosed can be larger than that of the viscous fluid-filled damper 46, and the vibration damping effect and the impact absorbing effect are increased.

Twelfth embodiment (FIG. 17)
The viscous fluid-filled damper 48 of the twelfth embodiment is configured to include a compression coil spring 45 on the outer periphery of the hermetic container 33 in the viscous fluid-filled damper 38 of the eighth embodiment.

  The compression coil spring 45 is concentric with the mounting shaft 39, and is laid between the surface of the mounting piece 5 a of the mechanical chassis 5 that faces the bottom surface 8 b of the housing 8 and the bottom surface 8 b of the housing 8. . That is, the mechanical chassis 5 is elastically supported in a floating state.

  Next, a method for attaching the viscous fluid-filled damper 48 will be described. The mechanical chassis 5 is fixed in the same manner as the viscous fluid-filled damper 38. For the housing 8, the mounting screw N is inserted into the insertion hole 39c of the mounting shaft 39 from the pressing plate portion 39b side, and the compression coil spring 45 is sandwiched between the mounting piece 5a and the bottom surface 8b. The mounting screw N is screwed into a hole 8 a formed in the bottom surface 8 b of the housing 8. The proximal end side head of the mounting screw N is accommodated inside the recess 26. As a result, like the viscous fluid-filled damper 38, the bellows-like bent portions 22 are formed on both sides of the ring 24. As shown in FIG. 17, the mechanical chassis 5 includes the viscous fluid-filled damper 38 and the compression coil spring 45. Therefore, the anti-vibration is supported inside the housing 8.

  In the viscous fluid-filled damper 48 of the twelfth embodiment, similarly to the viscous fluid-filled damper 38 of the eighth embodiment, the disk device 47 can be made smaller than before, and can be easily and securely fixed to the disk device 47, and has high durability. The airtight container 33 can be realized, and further, the following actions and effects are exhibited. That is, in the viscous fluid-filled damper 48, since the compression coil spring 45 elastically supports the mechanical chassis 5 in a floating state, the bellows-like bent portion 22 formed between the ring 24 and the bottom surface 8b of the housing 8 has the mechanical chassis 5 It is possible to prevent the viscous fluid 9 from being crushed in the axial direction of the mounting shaft 39 due to this load, and the viscous fluid 9 from being insufficiently agitated, making it difficult for viscous resistance to occur.

13th Embodiment (FIGS. 18 and 19)
A viscous fluid-filled damper 49 according to the thirteenth embodiment is configured to include a compression coil spring 45 inside the hermetic container 13 in the viscous fluid-filled damper 29 according to the fifth embodiment.

  The compression coil spring 45 is concentric with the mounting shaft 16, and is provided between the lid 15 of the ring 24 adjacent to the annular surface portion 24 a and the lid 15. That is, the ring 24 is elastically supported together with the elastic support film 20 in a floating state.

  Next, a disk device 50 to which the viscous fluid-filled damper 49 of this embodiment is attached and a method for attaching the viscous fluid-filled damper 49 will be described.

  As shown in FIG. 18, the disk device 50 includes a mechanical chassis 5, a housing 8 incorporating the mechanical chassis 5, and a viscous fluid-filled damper 49 interposed between the mechanical chassis 5 and the housing 8. . The viscous fluid-filled damper 49 is fixed to the mechanical chassis 5 and then fixed to the housing 8.

  The inner edge 5b of the attachment piece 5a is inserted into the attachment groove 19 from the side and attached to the mechanical chassis 5 with the bottom 18 facing upward. For the housing 8, the bottom portion 18 is opposed to the upper surface 8 e of the housing 8, and the mounting screw N is inserted into the insertion holes 15 a and 16 a from the lid 15 side, with respect to the hole 8 a on the upper surface 8 e of the housing 8. Screw together. The proximal end side head of the mounting screw N is accommodated inside the recess 26. At this time, the attachment screw N is screwed until the attachment shaft 16 and the upper surface 8e of the housing 8 come into contact with each other. Thus, the viscous fluid-filled damper 49 is attached such that the bottom 18 is crushed by the upper surface 8e. As a result, the bottom 18 and the portion of the outer peripheral portion 17 connecting from the bottom 18 to the ring 24 bulge and deform outward outward perpendicular to the axis of the mounting shaft 16, and the bellows-like bent portion 22 forms the ring 24 and the housing. 8 is formed between the upper surface 8e and the upper surface 8e. Thus, as shown in FIG. 18, the mechanical chassis 5 is supported in a vibration-proof manner inside the housing 8 by the viscous fluid-filled damper 49.

  In the viscous fluid-filled damper 49 of the thirteenth embodiment, the disk device 50 can be made smaller than the conventional one, similarly to the viscous fluid-filled damper 29 of the fifth embodiment, and can be easily and securely fixed to the disk device 50 and is highly durable. The airtight container 13 can be realized, and further, the following actions and effects are exhibited.

  According to the viscous fluid sealing damper 49, the compression coil spring 45 elastically supports the ring 24 together with the elastic support film 20 in a floating state, so that the elastic support film 20 is crushed in the axial direction of the mounting shaft 16 by the load of the mechanical chassis 5. It is possible to prevent the viscous fluid 9 from being insufficiently agitated and viscous resistance from becoming difficult to occur.

  Since the compression coil spring 45 is installed inside the sealed container 13, it is not necessary to assemble the compression coil spring 45 separately. Therefore, assembly to the disk device 50 is easy, and the number of parts can be reduced.

Explanatory drawing of the disc apparatus which attached the viscous fluid enclosure damper of 1st Embodiment. FIGS. 2A and 2B are attachment methods of the viscous fluid-filled damper of FIG. 1, and FIG. 1A is an explanatory view of the attachment method to the mechanical chassis, and FIG. 2B is an explanatory view of the attachment method to the housing. It is a viscous fluid enclosure damper of a 1st embodiment, a division figure (A) is the sectional view, and a division figure (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of a 2nd embodiment, a division figure (A) is the sectional view, and a division figure (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of a 3rd embodiment, a division figure (A) is the sectional view, and a division figure (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of a 4th embodiment, a division figure (A) is the sectional view, and a division figure (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of a 5th embodiment, a division figure (A) is the sectional view, and a division figure (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of a 6th embodiment, a division figure (A) is the sectional view, and a division figure (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of 7th Embodiment, and a part (A) is explanatory drawing of the attachment method with respect to a housing | casing, and a part (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of 8th Embodiment, A part (A) is explanatory drawing of the attachment method with respect to a housing | casing, A part (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of 9th Embodiment, a part (A) is explanatory drawing of the attachment method with respect to a housing | casing, and a part (B) is attachment explanatory drawing. It is a viscous fluid enclosure damper of 10th Embodiment, A part (A) is explanatory drawing of the attachment method with respect to a housing | casing, A part (B) is attachment explanatory drawing. Explanatory drawing of the modification of the disc apparatus which attached the viscous fluid enclosure damper of 1st Embodiment. FIG. 1 is a modification of the method of attaching the viscous fluid-filled damper of FIG. 1, and FIG. (A) is an explanatory view of the attachment method to the housing, and (B) is an explanatory view of the attachment method to the mechanical chassis. It is a viscous fluid enclosure damper of 11th Embodiment, a part figure (A) is the sectional drawing, and a part figure (B) is attachment explanatory drawing. The principal part expansion explanatory drawing of the disc apparatus which attached the modification of the viscous fluid enclosure damper of 11th Embodiment. The principal part expansion explanatory drawing of the disc apparatus which attached the viscous fluid enclosure damper of 12th Embodiment. Explanatory drawing of the disc apparatus which attached the viscous fluid enclosure damper of 13th Embodiment. It is a viscous fluid enclosure damper of 13th Embodiment, a division figure (A) is the sectional drawing, and a division figure (B) is attachment explanatory drawing. Explanatory drawing of the disc apparatus which attached the viscous fluid enclosure damper by one prior art example. The attachment explanatory drawing of the viscous fluid enclosure damper by one prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 5 Mechanical chassis 5a Attachment piece 5b Inner edge 5c Hole 5d Attachment part 8 Housing | casing 8a Hole 8b Bottom face 8c Attachment piece 8d Through-hole 8e Upper surface 9 Viscous fluid 12 Viscous fluid enclosure damper (1st Embodiment)
DESCRIPTION OF SYMBOLS 13 Sealed container 14 Container main body 15 Cover body 15a Insertion hole 15b Recessed part 16 Mounting shaft 16a Insertion hole 16b Recessed part 17 Outer peripheral part 17a Lid frame 18 Bottom part 19 Mounting groove 20 Elastic support film 21 Disk apparatus 22 Bellows-shaped bending part 23 Viscous fluid enclosure damper (Second Embodiment)
24 ring 24a annular surface portion 25 viscous fluid-filled damper (third embodiment)
26 Concave portion 27 Damper containing viscous fluid (fourth embodiment)
28 Covering portion 29 Damper containing viscous fluid (fifth embodiment)
30 viscous fluid-filled damper (sixth embodiment)
31 pressure plate 31a insertion hole 32 viscous fluid-filled damper (seventh embodiment)
33 Sealed Container 34 Inner Perimeter 34a Center Hole 34b Inner Wall 34c Hole 35 Outer Perimeter 36a Bottom 36b Bottom 37 Mounting Shaft 37a Insertion Hole 38 Viscous Fluid Enclosed Damper (Eighth Embodiment)
39 mounting shaft 39a mounting shaft portion 39b pressing plate portion 39c insertion hole 40 viscous fluid-filled damper (9th embodiment)
41 pressure plate 41a pressure plate portion 41b mounting screw portion 42 viscous fluid-filled damper (10th embodiment)
43 mounting shaft 43a mounting shaft portion 43b pressing plate portion 43c mounting screw portion 44 disk device 45 compression coil spring 46 viscous fluid-filled damper (11th embodiment)
47 disk device 48 viscous fluid-filled damper (12th embodiment)
49 Damper filled with viscous fluid (13th embodiment)
50 Disk unit N Mounting screw

Claims (15)

In a viscous fluid-filled damper that damps vibration of a supported body by attaching a sealed container that encloses the viscous fluid to the support and the supported body,
Securing a mounting shaft for fixing one of the support or the supported body has an insertion hole, the other of the outside provided et been pre Symbol support of the outer peripheral surface of the mounting shaft or the supported body a mounting portion provided with a resilient bulging portion formed of a rubber-like elastic body for elastically supporting the floating state the mounting portion,
The direction perpendicular to the axis outward of the mounting shaft mounting shaft elastic bulging portion deforms the support or being crushed in a fixed state of the closed container to either one of the supported body that bulges in the axial direction of the viscous fluid-sealed damper and forming a bellows-shaped bent portion which issued Rise. The viscous fluid-filled damper according to claim 1, wherein the elastic bulging portion bulges from the bottom surface of the mounting shaft in the axial direction of the mounting shaft. The viscous fluid-filled damper according to claim 1, wherein the mounting shaft is a hard material. It claims 1 to 3 any one viscous fluid-sealed damper according with the resilient bulging portion on both sides of the mounting portion in the axial direction of the mounting shaft. It further comprises a pin-shaped fixing member,
Forming a pair of annular surface portion facing in the axial direction of the mounting shaft before Symbol mounting portion,
When fixing the shaft with said mounting with respect to one of the pin-like fixing member in the supporting body or the supported body to be inserted into the insertion hole of the mounting shaft, and one of the support or the supported body, the support claims 1 to 4 any one of the body or the elastic bulging portion crushed in at a location between said annular surface portion of either one close to the side of the support to form the bellows shaped bent portion The viscous fluid-filled damper as described. Wherein a pin-like fixing member further includes a pressing provided in contact with the elastic bulging portion plate,
A pair of annular surface portions facing the mounting portion in the axial direction of the mounting shaft ;
The airtight container is sandwiched between one of the support body or the support body and the pressing plate, and is inserted into the insertion hole of the mounting shaft to either the support body or the support body. When fixing the shaft with said mounting against, the pressing plate Toko supports or the elastic bulging portion crushed by the bellows-like bend between a position of said annular surface portion of either one farther the supported body The viscous fluid-filled damper according to any one of claims 1 to 4, wherein the damper is formed. Claim 5 or viscous fluid-sealed damper according to claim 6, wherein a recess for accommodating the base end side head before Symbol pin-like fixing member. Viscous fluid-sealed damper according to claim 5 or claim 6 wherein comprises a resilient support film for elastically supporting the mounting portion on a side opposite to the side where the formation of the elastic bulging portion across the mounting portion in a floating state. The viscous fluid-filled damper according to claim 8 , wherein the elastic support film has a bent shape having a bellows cross section. The mounting groove is formed of a hard material to the mounting portion, according to claim 5 or claim 6 provided with a cover portion covering an annular surface portion of the groove surface of the mounting groove and the outer circumferential surface excluding the elastic bulging portion The viscous fluid-filled damper as described. The mounting groove is formed of a hard material to the mounting portion, the viscous fluid-sealed of the grooves surface of the mounting groove and the outer circumferential surface excluding the elastic support film side according to claim 8, wherein providing a coating portion covering the annular surface portion Damper. In the sealed container,
An annular lid frame made of a hard resin provided at an end of the elastic support membrane;
The viscous fluid-filled damper according to claim 8 , further comprising a lid made of a hard resin that closes a gap between an end of the mounting shaft and the annular lid frame. 13. The viscous fluid-filled damper according to claim 12 , wherein the mounting shaft, the mounting portion, and the annular lid frame are made of a hard resin material, and the elastic bulge portion and the elastic support film are made of a thermoplastic elastomer, and these are an integral molded body. 14. The viscous fluid-filled damper according to claim 13, comprising a fixing surface obtained by ultrasonically fusing the lid, the annular lid frame, and the mounting shaft. The above attachment part and the contact with the hermetic container, according to claim 1 to claim 14 any one of claims with any coil spring and the other elastically supports the support or the supported body mounted to the mounting portion Viscous fluid filled damper.

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