JP2023124218A - Vibration suppression structure - Google Patents

Abstract

To provide a vibration suppression structure capable of suppressing vibration mainly in a thrust direction while attaining compactification.SOLUTION: A vibration suppression structure includes an installation part 14, a device side base 12 on which a device 100 or the like is disposed, a coil spring 13 which is provided between the installation part 14 and the device side base 12 so as to support a load on a side of the device 100 or the like, a spring seat 15 which is brought into contact with an end 13t1 on the side of the device 100 or the like of the coil spring 13, a shaft member 11 which extends from the installation part 14 side to the side of the device 100 or the like, an elastic body 22 which is brought into contact with an outer periphery of the shaft member 11 and the device side base 12 and has an attenuation function, and a base movement suppressing member 22c and a spring movement suppressing member 22d which suppress relative movement between the spring seat 15 and the device side base 12.SELECTED DRAWING: Figure 4

Description

The present technology relates to a vibration suppression structure that occurs in a device installed in a machine room or the like.

2. Description of the Related Art A device using a motor, such as a fan of an air conditioner, uses a vibration suppressing device such as a vibration absorber made of spring, rubber, or the like in order to prevent the vibration of the motor from being transmitted to the surrounding structure. This vibration suppressing device not only dampens vibrations in the vertical direction, but also needs to alleviate the thrust force generated by driving the motor when movement in the thrust direction occurs due to the driving of the motor.

For example, Japanese Patent Application Laid-Open No. 2009-092034 (Patent Document 1) describes a structure that alleviates the thrust force by distributing the thrust load by providing an airtight elastic layer between the fan chamber partition plate and the bell mouth. It is disclosed that In this structure, a vibration absorber provided under the vibration isolation mount is used for the purpose of vibration isolation in the vertical direction.

Vibration absorbers for the purpose of damping vibrations in the vertical direction have various structures in which rubber as a damping element and a coil spring as a spring element are combined. 2) relates to a vibration isolation support device for a compressor mounted on a refrigerator or an air conditioner. A structure is disclosed in which the compressor is fitted to the base plate. In this structure, not only is a sufficient anti-vibration effect obtained, but the surging frequency of the coil spring does not change due to changes in the weight of the compressor itself.

JP 2009-92034 A JP-A-5-99143

However, in recent years, there has been a demand for space-saving structures such as machine rooms. For example, in air handling units used in air conditioners, for example, ducts and fans are directly connected to make them more compact. . Therefore, with regard to the vibration suppressing structure such as the vibration absorber, there is a need to take countermeasures against the thrust force without adopting a separate stopper mechanism.

An object of the present technology is to provide a vibration suppression structure arranged between an installation portion and a device-side base that mainly suppresses vibrations in the thrust direction while making the structure compact. .

A vibration suppression structure according to the present technology includes an installation section, a device-side base on which a device is arranged, a coil spring provided between the installation section and the device-side base and supporting a load of the device, a spring seat connected to the device-side end of the coil spring; a shaft member extending from the installation portion side toward the device side; and a movement suppressing member that suppresses relative movement between the spring seat and the device-side base.

In another aspect, the movement suppressing member is arranged between the device-side base and the spring seat and between the spring seat and the end of the coil spring. and a spring movement restraining member, wherein the base movement restraining member and the spring movement restraining member are elastic members having a damping function.

In another aspect, the elastic body, the base movement restraining member, and the spring movement restraining member are the same elastic member, and are integrally molded with the spring seat.

According to the present technology, it is possible to provide a vibration suppression structure capable of mitigating thrust force and suppressing vibration including in the thrust direction while achieving compactness.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the whole apparatus structure by which the vibration suppression structure of embodiment is employ|adopted. 1 is a longitudinal sectional view showing a vibration suppression structure of an embodiment; FIG. FIG. 4 is a vertical cross-sectional view when the minimum distance between the upper surface of the installation portion and the lower surface of the device-side base is present; FIG. 3 is a partially enlarged view of a region surrounded by IV in FIG. 2; It is a longitudinal cross-sectional view showing a vibration suppression structure of another embodiment. FIG. 11 is a vertical cross-sectional view showing a vibration suppressing structure according to still another embodiment;

Each embodiment of the present technology will be described below. The same or corresponding parts are denoted by the same reference numerals, and the description thereof may not be repeated.

In each embodiment described below, when referring to the number, amount, dimension, etc., the scope of the present technology is not necessarily limited to the number, amount, dimension, etc., unless otherwise specified. In the following embodiments, each component is not necessarily essential for the present technology unless otherwise specified. The same reference numbers are given to the same parts and equivalent parts, and redundant description may not be repeated. It is planned from the beginning to use the configurations in the embodiments in combination as appropriate.

As used herein, references to "comprise," "include," and "have" are open-ended. That is, when a certain configuration is included, other configurations may or may not be included. In addition, the present technology is not necessarily limited to one that exhibits all of the effects referred to in the present embodiment.

In the drawings used below, the direction of the arrow indicated by X indicates the vertical direction, and the direction of the arrow indicated by Y indicates the horizontal direction.

(Vibration suppression structure 1)
A vibration suppression structure 1 according to the present embodiment will be described with reference to FIGS. 1 and 2. FIG. FIG. 1 is a schematic diagram showing the overall configuration of a device employing a vibration suppression structure 1 of the embodiment, and FIG. 2 is a longitudinal sectional view showing the vibration suppression structure 1. As shown in FIG. In the following description, an air handling device for an air conditioner installed in a machine room or the like is used as an example of a location to which the vibration suppression structure 1 is applied. However, it is intended to be applied to a device in which a force is generated in the thrust direction and a similar action and effect for suppressing vibration is required.

Referring to FIG. 1 , the air handling device for air conditioners includes a housing 800 housing a base 100 , an auxiliary base 200 , a motor 300 , a fan 400 and a canvas 500 .

A motor 300 is placed on the base 100 and the auxiliary base 200 . A fan 400 is fixed to the rotating shaft of the motor 300 . A fan 400 is rotated by driving the motor 300 . Air is sent out through the canvas 500 by the rotation of the fan 400 . The air sent out from the canvas 500 is sent to the external air conditioner 700 via the short duct 600 .

As the fan 400 is rotated by the motor 300, vibrations are generated in various directions. In the air handling device, force in the thrust (horizontal) direction is generated due to the vibration of the motor 300 and the suction or discharge due to the rotation of the fan 400 . In the conventional vibration absorber, which is a countermeasure against vibration, this force in the thrust direction causes the fan 400 to sink or move forward or backward in the axial direction. was likely to occur. The vibration suppressing structure 1 of the present embodiment can suppress or alleviate this force in the thrust direction, so it is possible to effectively suppress vibration.

Vibration suppression structure 1 of the present embodiment is provided between base 100 and housing 800 . A plurality of vibration suppression structures 1 are provided at two locations in a side view, but are arranged at four or more locations in a plan view, depending on the required vibration suppression. The number of vibration suppressing structures 1 is appropriately selected.

The lower side of the vibration suppression structure 1 is to be fixed to the installation portion of the installation target position of the device serving as the vibration generation source for the purpose of suppressing vibration, and is fixed to the housing 800 and the installation surface B that is the foundation. or to both the housing 800 and the installation surface B. In the following description, it will be referred to as fixing to the installation portion.

A detailed structure of the vibration suppressing structure 1 of the present embodiment will be described with reference to FIG. The vibration suppressing structure 1 is provided between the installation portion 14 and the device-side base 12 . The device-side base 12 is connected to a device to be vibration-isolated, and devices such as a base 100, an auxiliary base 200, and a motor 300 are arranged on the device-side base 12. FIG. In this embodiment, the device-side base 12 is provided on the base 100 .

A shaft member 11 extending from the installation portion 14 side to the device side is provided between the installation portion 14 and the device side base 12 . The shaft member 11 is a bolt member provided with a male screw (S1) on its surface. In this embodiment, M12 (SS400) is used for the shaft member 11, but a shaft member that can support the load when the device moves in the thrust direction can be used. The installation portion 14 is provided with a through hole 14h. The device-side base 12 is provided with a through hole 12h. The shaft member 11 passes through the through holes 14h and 12h.

A coil spring 13 that supports the load of the device is provided between the installation portion 14 and the device-side base 12 . The coil spring 13 is provided with a lower end portion 13t2 and an upper end portion 13t1 on both sides, and supports the load from the device side to the installation portion side via the lower spring seat 20 and the upper spring seat 15, respectively. For the coil spring 13, a wire rod can be appropriately selected depending on the load on the device side, and a coil spring manufactured by spirally cold-forming a round wire rod can be used.

A hollow portion is formed inside the coil spring 13 to extend between a lower end portion 13t2 and an upper end portion 13t1, and the shaft member 11 passes through the inside of the coil spring 13. As shown in FIG. The inner diameter of the hollow portion of the coil spring 13 may be larger than the outer diameter of the shaft member 11 and may be large enough to accommodate the long fixing nut 19 and the elastic body 22 inside the coil spring 13 . and the coil spring 13 may be in contact with each other. The opening diameter (φD1) of the through hole 14h provided in the installation portion 14 is set to be substantially the same as the shaft outer diameter of the shaft member 11 . Since the opening diameter (φD1) is substantially the same as the shaft outer diameter of the shaft member 11, relative movement of the shaft member 11 with respect to the installation portion 14 is suppressed. The opening diameter (φD2) of the through hole 12h is set larger than the shaft outer diameter of the shaft member 11 . Since the opening diameter (φD2) is larger than the shaft outer diameter of the shaft member 11, when a device to be vibration-isolated is installed on the device-side base 12, the device-side base 12 can withstand a load such as the weight of the device itself. relative movement of the device-side base 12 with respect to the shaft member 11 caused by

A circular lower spring seat 20 is provided between the lower end portion 13 t 2 of the coil spring 13 and the upper surface 14 a of the installation portion 14 . The lower spring seat 20 includes a circular flat plate portion 20a and an annular wall portion 20b that rises upward on the outer peripheral portion of the flat plate portion 20a. The lower spring seat 20 evenly distributes the downward force received from the coil spring 13 to the installation portion 14 . The wall portion 20b abuts on the lower end portion 13t2 of the coil spring 13 to suppress lateral movement of the lower end portion 13t2. By providing the lower spring seat 20, the lower end portion 13t2 of the coil spring 13 is installed when the apparatus-side base 12 moves relative to the shaft member 11 due to a load such as the weight of the apparatus to be vibration-isolated. Displacement from a predetermined position with respect to the portion 14 is suppressed.

A circular upper spring seat 15 is provided between the upper end portion 13 t 1 of the coil spring 13 and the lower surface 12 a of the device-side base 12 . A detailed structure of the upper spring seat 15 will be described later. The upper spring seat 15 includes a circular flat plate portion 15a and an annular wall portion 15b extending downward from the outer peripheral portion of the flat plate portion 15a.

The upper spring seat 15 evenly distributes the upward force received from the coil spring 13 to the device-side base 12 . By providing the upper spring seat 15, it is possible to prevent the surface of the device-side base 12 on the installation portion 14 side from being damaged by vibration or the like. The wall portion 15b abuts on the upper end portion 13t1 of the coil spring 13 and suppresses lateral movement of the upper end portion 13t1. The upper spring seat 15 is provided with an opening through which the shaft member 11 penetrates in the center. The upper spring seat 15 is connected to the elastic body 22 at its central portion. The elastic body 22 is provided with a through hole 22h through which the shaft member 11 is passed. The opening provided in the central portion of the upper spring seat 15 can be substantially coaxial with the through hole 22h of the elastic body 22 .

A rubber bush 18 with a washer is provided above the upper spring seat 15 with the device-side base 12 interposed therebetween. The washer-equipped rubber bushing 18 includes a circular washer 18a, a body portion 18b having substantially the same outer diameter as the washer 18a, and an extension portion 18c extending downward from the body portion 18b and having a smaller diameter than the body portion 18b. A through-hole 18h through which the shaft member 11 passes is provided in the central portion of the washer-equipped rubber bush 18 . The washer 18a and the rubber bushing portion having the main body portion 18b and the extension portion 18c may be separated from each other, and the rubber bushing portion may support the device-side base 12 elastically.

The washer 18a, the body portion 18b and the extension portion 18c are integrally formed. The body portion 18b and the extension portion 18c are made of the same rubber member (elastomer). The extension portion 18c is fitted into the through hole 12h of the device-side base 12. As shown in FIG. A lower end 18e of the extended portion 18c contacts the upper surface 22u of the elastic body 22 of the upper spring seat 15 (see FIG. 4).

A fixing long nut 19 is mounted below the shaft member 11 inside the coil spring 13 . The length (H11) of the fixing long nut 19 along the axial direction of the shaft member 11 is a desired length that can exhibit the strength required to fix the shaft member 11 to the installation portion 14 and the stopper function described later. should be

A plain washer 25 and a spring washer 24 are fitted to the lower side 11b of the shaft member 11, and are tightened upward with a hexagonal nut (one kind) 23. As shown in FIG. With the lower end 19b of the fixing long nut 19 and the hexagonal nut (one type) 23, the installation portion 14 and the lower spring seat 20 are tightened and fixed. The flat washer 25 , the spring washer 24 and the hexagonal nut (one type) 23 function as a lower end side fixing portion for the installation portion 14 of the shaft member 11 to prevent the shaft member 11 from being detached from the installation portion 14 .

The above-mentioned rubber bush 18 with a washer is fitted in the upper portion 11u of the shaft member 11, and is directed downward by a hexagonal nut (type 3) 17 and a hexagonal nut (type 1) 16 against the biasing force of the coil spring 13. and tightened.

The distance (H1) between the upper surface 14a of the installation portion 14 and the lower surface 12a of the device-side base 12 is determined according to the supporting force of the coil springs 13 required for the vibration suppression structure 1. FIG. Specifically, the compression length of the coil spring 13 is determined by the fixed position of the washer-equipped rubber bushing 18 by the hexagonal nut (three types) 17 and the hexagonal nut (one type) 16 .

Referring to FIG. 3, a vertical cross section when the minimum distance (H2) between the upper surface 14a of the installation portion 14 and the lower surface 12a of the device-side base 12 is present. In the axial direction of the shaft member 11, when the maximum load is generated from the device side toward the installation portion, the distance between the upper surface 14a of the installation portion 14 and the lower surface 12a of the device-side base 12 is the minimum distance (H2). Become. In the state of the minimum distance (H2), the lower end 22e of the elastic body 22 is set to be in contact with the upper end 19a of the long fixing nut 19. As shown in FIG. When the device is loaded on the installation portion 14 and a further load is applied from the device side toward the installation portion due to vibration or thrust force generation, the lower end 22e of the elastic body 22 may and suppresses further relative movement of the installation portion 14 . A lower end 22e of the elastic body 22 functions as a stopper. Even in the state of this minimum distance H2, the coil spring 13 can be further compressed and functions as the vibration suppressing structure 1 .

Next, with reference to FIG. 4, the detailed structure of the area surrounded by IV in FIG. 2 will be described. FIG. 4 is a partially enlarged view of the area surrounded by IV in FIG.

The elastic body 22 includes a columnar body upper portion 22a located on the side of the device-side base 12, and a columnar body lower portion 22b extending downward from the body upper portion 22a and having a smaller diameter than the body upper portion 22a. The outer surfaces of the upper body portion 22a and the lower body portion 22b are continuously connected by a curved surface portion 22r having a predetermined radius of curvature to avoid stress concentration.

The main body upper portion 22a has an annular shape with a space in the center in FIG. The outer peripheral surface of the main body upper portion 22a is in contact with the inner periphery of the coil spring 13, but does not have to contact the inner periphery of the coil spring 13 as long as the vibration of the shaft member 11 can be damped. The lower main body portion 22b of the elastic body 22 extends in the axial direction of the shaft member 11 and has a space extending through it in the axial direction to communicate with the space portion of the upper main body portion 22a. 22 h of through-holes of the elastic body 22 contain the space part of the main body lower part 22b, and the space part of the main body upper part 22a. The inner peripheral surface of the lower body portion 22b contacts the outer peripheral surface of the shaft member 11 and elastically supports the upper body portion 22a in the axial direction of the shaft member 11 . A lower end 22e that functions as a stopper is provided on the lower surface of the main body lower portion 22b.

The main body upper portion 22a is connected to the mounting side surface of the flat plate portion 15a of the upper spring seat 15 so as to dampen the vibrations input from the upper spring seat 15. As shown in FIG. The elastic body 22 has a cylindrical protrusion extending from the center of the upper surface of the main body upper portion 22 a toward the device-side base 12 . Further, a base movement suppressing member 22c, which will be described later, is connected to the apparatus-side base 12 side of the protrusion.

Here, attention is focused on the flat plate portion 15a of the upper spring seat 15. As shown in FIG. A base movement suppressing member 22c is provided between the lower surface 12a of the device-side base 12 and the flat plate portion 15a. A spring movement suppressing member 22d is provided between the flat plate portion 15a and the upper end portion 13t1 of the coil spring 13. As shown in FIG. Both the base movement restraining member 22c and the spring movement restraining member 22d are provided integrally with the main body upper part 22a so as to extend radially outward from the main body upper part 22a. In the embodiment shown in FIG. 4, the main body upper portion 22a and the base movement restraining member 22c are integrated, but they can be provided separately.

A main body upper portion 22 a , a main body lower portion 22 b , a base movement restraining member 22 c and a spring movement restraining member 22 d , which constitute the elastic body 22 , are the same elastic member, and are formed integrally with the upper spring seat 15 . Synthetic rubber is used for the elastic member of the elastic body 22 . The base movement suppressing member 22c only needs to suppress the relative movement between the device-side base 12 and the upper spring seat 15. In the present embodiment, a rubber member is used. It may be present or may be integrated with the upper spring seat. In addition, the spring movement suppressing member 22d only needs to suppress the relative movement between the upper spring seat 15 and the coil spring 13. In this embodiment, a rubber member is used, but it may be a friction surface. It may be integrated with the upper spring seat.

Here, when a large thrust force (in the arrow X direction in the figure) having a predetermined vibration frequency (for example, 60 Hz) is applied from a device installed on the device-side base 12, the lower surface 12a of the device-side base 12 and the flat plate A large thrust force (in the direction of the arrow X in the figure) is applied between the flat plate portion 15a and the upper end portion 13t1 of the coil spring 13 as well.

If the base movement restraining member 22c and the spring movement restraining member 22d are not provided, lateral displacement occurs between the lower surface 12a of the device-side base 12 and the flat plate portion 15a. As a result, after the end of the vibration, the device-side base 12 remains shifted in the lateral direction without restoring to its original position.

Furthermore, the shaft member 11 continues to abut against the extended portion 18c of the washer-equipped rubber bushing 18 located in the through hole 12h provided in the device-side base 12, causing damage to the extended portion 18c and further damage to the shaft member 11 through the through hole. 12h, and the shaft member 11 may be damaged (decrease in anti-vibration performance). In addition, when there is a thrust direction deviation between the flat plate portion 15a and the upper end portion 13t1 of the coil spring 13, friction is generated between the coil spring 13 and the flat plate portion 15a, which may cause noise. be.

On the other hand, in the configuration of the present embodiment, the outer peripheral surface of the shaft member 11 and the through hole 22h of the elastic body 22 are connected, and the lower surface 12a of the device-side base 12 and the upper surface 22u of the elastic body 22 are connected. ing. In this embodiment, the elastic body 22 is in contact with the outer peripheral surface of the shaft member 11 at the inner peripheral surface of the through hole 22h. When the shaft member 11 relatively moves in the horizontal direction, the outer peripheral surface of the elastic body 22 presses the inner peripheral surface of the through hole 22h of the elastic body 22, and the horizontal load of the shaft member 11 attenuates the elastic body 22. mitigated by function. Accordingly, since the elastic body 22 has a damping function, it exerts a function of alleviating the thrust force. Synthetic rubber, for example, can be used for the elastic body 22 .

Further, between the lower surface 12a of the apparatus-side base 12 and the flat plate portion 15a, a base movement suppressing member 22c, which is a movement suppressing member that suppresses relative movement between the upper spring seat 15 and the apparatus-side base 12, is provided. there is A spring movement suppressing member 22d is provided between the flat plate portion 15a and the upper end portion 13t1 of the coil spring 13. As shown in FIG. By adopting this configuration, the base movement suppressing member 22c and the spring movement suppressing member 22d exhibit the effect of preventing slippage, and the gaps between the lower surface 12a of the device-side base 12 and the flat plate portion 15a, and between the flat plate portion 15a and the coil. Lateral displacement between the upper end portion 13t1 of the spring 13 and the upper end portion 13t1 is suppressed. After the end of the vibration, the device-side base 12 can be restored to its initial position.

Thus, the base movement restraining member 22c and the spring movement restraining member 22d function as movement restraining members that restrain the relative movement between the upper spring seat 15 and the device-side base 12. As shown in FIG.

According to the vibration suppressing structure 1 , it is possible to suppress relative movement between the upper spring seat 15 and the device-side base 12 only by employing the movement suppressing member provided inside the upper spring seat 15 . As a result, it is possible to reduce the size of the movement suppressing member without using a separate stopper mechanism, and to effectively suppress vibration mainly in the thrust direction.

A vibration suppression structure according to another embodiment will be described with reference to FIG. FIG. 5 is a vertical cross-sectional view showing a vibration suppressing structure according to another embodiment. In the above-described embodiment, the base movement suppressing member 22c and the spring movement suppressing member 22d are integrally provided with the main body upper portion 22a of the elastic body 22. However, as shown in FIG. The member 22c and the spring movement suppressing member 22d may be separate members from the main body upper portion 22a.

A vibration suppression structure according to still another embodiment will be described with reference to FIG. FIG. 6 is a longitudinal sectional view showing a vibration suppression structure of another embodiment. In the above-described embodiment, the structure in which the vibration suppressing member is provided inside the upper spring seat 15 has been described, but the lower spring seat 20 can similarly adopt the vibration suppressing structure.

As shown in FIG. 6, a base movement suppressing member 22c is provided between the upper surface 14a of the installation portion 14 and the flat plate portion 20a, and a spring movement suppressing member 22c is provided between the flat plate portion 20a and the lower end portion 13t2 of the coil spring 13. As shown in FIG. By providing 22d, a movement suppressing member that suppresses relative movement between the lower spring seat 20 and the installation portion 14 can be configured.

It should be noted that the above-described vibration suppression structure can be expected not only to suppress vibration generated from a device that moves in the thrust direction when driven, but also to be applied to countermeasures against vibration generated by an earthquake or the like.

The embodiments of the present technology have been described above, but the embodiments disclosed this time should be considered as examples in all respects and not restrictive. The scope of the present technology is indicated by the scope of claims, and is intended to include all modifications within the meaning and scope of equivalence to the scope of the claims.

Reference Signs List 1 vibration suppression structure 11 shaft member 11b lower side 11u upper side 12 device side base 12a lower surface 12h, 14h, 18h, 22h through hole 13 coil spring 13t1 upper end 13t2 lower end 14 installation portion , 14a, 22u upper surface, 15 upper spring seat, 15a, 20a flat plate portion, 15b, 20b wall portion, 18 rubber bush with washer, 18a washer, 18b body portion, 18c extension portion, 18e, 19b, 22e lower end, 19 for fixing long nut 19a upper end 20 lower spring seat 22 elastic body 22a main body upper part 22b main body lower part 22c base movement suppressing member 22d spring movement suppressing member 22r curved surface portion 24 spring washer 25 plain washer 100 base, 200 auxiliary base, 300 motor, 400 fan, 500 canvas, 600 short duct, 700 air conditioner, 800 housing, B installation surface.

Claims (3)

an installation section;
a device-side base on which the device is arranged;
a coil spring provided between the installation portion and the device-side base for supporting the load of the device;
a spring seat connected to the device-side end of the coil spring;
a shaft member extending from the installation portion side to the device side;
an elastic body connected to the outer periphery of the shaft member and the device-side base and having a damping function;
a movement suppressing member that suppresses relative movement between the spring seat and the device-side base;
Vibration suppression structure. The movement suppressing member is
a base movement suppressing member arranged between the device-side base and the spring seat;
a spring movement suppressing member disposed between the spring seat and the end of the coil spring;
The base movement suppressing member and the spring movement suppressing member are elastic members having a damping function,
The vibration suppressing structure according to claim 1. the elastic body, the base movement suppressing member, and the spring movement suppressing member are the same elastic member;
3. The vibration suppressing structure according to claim 2, wherein said spring seat is integrally molded.

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