KR102374374B1 - 3-axis vibration isolation mount using ball and spring for seismic isolation - Google Patents

Abstract

The present invention is a bottom member installed on the ground; a seismic isolation ball seated on the bottom member in plurality to enable return by rolling; a connection member seated on the seismic isolation ball and installed on the bottom member; a fixing member that is installed slidably up and down on the upper side of the connection member and is fixed to support the lower side of the table on which the vibration-proof object or the vibration-proof object is installed; a wave spring installed so as to be wrapped between the connecting member and the fixing member and stacked in a plurality of upper and lower parts to elastically support the fixing member from the connecting member; and a connecting bolt connecting the fixing member, the connecting member, and the bottom member to each other.
According to the present invention, due to the two-dimensional arrangement of the balls for seismic isolation, it is possible to increase the seismic isolation efficiency in the horizontal axis direction, and to increase the seismic isolation efficiency in the vertical axis direction due to the stacked structure of the wave spring, while making it relatively high in small size It can support the weight and has the effect of improving the additional damping efficiency by the damping member made of a material such as silicon.

Description

3-axis vibration isolation mount using ball and spring for seismic isolation}

The present invention relates to a three-axis anti-vibration mount using a ball and a spring for seismic isolation, and more particularly, due to the two-dimensional arrangement of the ball for seismic isolation, increased seismic isolation efficiency in the horizontal axis direction, and the stacked structure of the wave spring , a 3-axis type using a ball and spring for seismic isolation that increases the seismic isolation efficiency in the vertical axis direction, supports a relatively high load even in a small size, and further increases the additional damping efficiency by a damping member made of a material such as silicon It's about the anti-vibration mount.

In general, vibration-sensitive equipment, for example, not only a woofer speaker or an optical microscope, but also various cutting processing equipment or various optical measuring equipment, prevents performance degradation due to vibration generated from itself or vibration applied from the outside during use measures are required to

As such, vibration-sensitive equipment does not operate properly due to vibrations generated from itself or vibrations applied from the outside, or provides data such as incorrect measurement values to the user, thereby reducing the operational reliability of the equipment. .

In order to solve this problem, vibration-sensitive equipment is installed using a vibration-proof mount. As a prior art related to the vibration-proof mount, Korean Patent Registration No. 10-1514146, "Collision prevention device between the vibration-proof hole of the shelf and the tailstock" has been suggested. This includes a ball holder fixedly installed on the tailstock, a ball mounted so as not to be separated from the inside of the ball holder, and a first spring providing an elastic force for pushing the ball; A spring cap coupled to the ball holder with a first spring interposed therebetween, and a bracket fixedly installed at a position facing the ball on the tool rest and provided with a seating groove for engaging the ball. A dog installed in the seating groove of the bracket, a second spring providing an elastic force for pushing the dog, and a limit installed around the dog and detecting the vertical movement of the dog including a switch.

However, such a prior art makes it difficult to support a high load in a small size due to a single ball structure in the center along with the adoption of a coil spring, and has a limit on the increase in damping damping force, so high efficiency dust protection cannot be expected. had a problem

In order to solve the problems of the prior art as described above, the present invention increases the seismic isolation efficiency in the horizontal axis direction due to the two-dimensional arrangement of the balls for seismic isolation, and due to the stacked structure of the wave spring, the vertical axis direction seismic isolation An object of the present invention is to increase the efficiency, to support a relatively high load even in a small size, and to improve additional damping efficiency by a damping member made of a material such as silicon.

Other objects of the present invention will be easily understood through the description of the following embodiments.

In order to achieve the above object, according to an aspect of the present invention, a bottom member installed on the ground; a seismic isolation ball seated on the bottom member in plurality to enable return by rolling; a connection member seated on the seismic isolation ball and installed on the bottom member; a fixing member that is installed slidably up and down on the upper side of the connection member and is fixed to support the lower side of the table on which the vibration-proof object or the vibration-proof object is installed; a wave spring installed so as to be wrapped between the connecting member and the fixing member and stacked in a plurality of upper and lower parts to elastically support the fixing member from the connecting member; and a connecting bolt connecting the fixing member, the connecting member, and the bottom member to each other.

The bottom member is provided with a plurality of first accommodating support grooves having a concave curvature surface facing upward to accommodate the lower portion of the seismic isolation ball around the central portion, and the connection member is provided in correspondence with each of the first accommodating grooves. , by providing a plurality of second accommodating support grooves having a concave curvature surface to face downward, the upper portions of each of the seismic isolation balls can be accommodated in each of the second accommodating support grooves.

The connecting member and the fixing member are slidable in a state in which the edges are overlapped with each other, and the connecting member is provided such that a first seating groove is opened upwardly around a central portion, and the fixing member is the first A second seating groove is provided to open downward to correspond to the seating groove, and the wave spring is formed in a ring shape, and is seated so as to be stacked vertically between the first seating groove and the second seating groove, each A washer may be interposed between the

The connection bolt is inserted downward so that the head is caught in the locking hole formed in the center of the fixing member and penetrates through the through hole formed in the center of the wave spring and the connection member, respectively, the fastening provided in the bottom member It can be fixed by screwing to the part.

A damping member made of a material capable of damping and made of a hollow member to be interposed between the boss protruding to surround the fastening part and the inner surface of the through hole may be further included.

According to the three-axis anti-vibration mount using the ball and spring for seismic isolation according to the present invention, it is possible to increase the seismic isolation efficiency in the horizontal axis direction due to the two-dimensional arrangement of the balls for seismic isolation, and due to the stacked structure of the wave spring, the vertical axis direction It is possible to support a relatively high load even in a small size while increasing the seismic isolation efficiency of the device, and has the effect of improving additional damping efficiency by a damping member made of a material such as silicon.

1 is a perspective view illustrating a three-axis type vibration-proof mount using a ball and a spring for vibration isolation according to an embodiment of the present invention.
2 is an exploded perspective view illustrating a three-axis type anti-vibration mount using a seismic isolation ball and a spring according to an embodiment of the present invention.
3 is a bottom perspective view showing an exploded three-axis type vibration-proof mount using a vibration-isolation ball and a spring according to an embodiment of the present invention.
4 is a front cross-sectional view showing a 3-axis type vibration-proof mount using a vibration-isolation ball and a spring according to an embodiment of the present invention.
5 is a perspective view showing the lamination of an elastic member and a washer of a triaxial vibration-proof mount using a vibration-isolation ball and a spring according to an embodiment of the present invention.
6 is a perspective view illustrating a use state of a three-axis type vibration-proof mount using a ball and a spring for vibration isolation according to an embodiment of the present invention.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and it should be understood as including all changes, equivalents and substitutes included in the spirit and scope of the present invention, and may be modified in various other forms. and the scope of the present invention is not limited to the following examples.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings, and the same reference numbers are assigned to the same or corresponding components regardless of reference numerals, and redundant description thereof will be omitted.

1 is a perspective view showing a three-axis vibration-proof mount using a ball and spring for vibration isolation according to an embodiment of the present invention, and FIG. 3 is an exploded perspective view showing a disassembled three-axis anti-vibration mount using a vibration isolation ball and a spring according to an embodiment of the present invention, and FIG. 4 is a bottom perspective view showing an exploded view of the present invention. It is a front sectional view showing a 3-axis type vibration-proof mount using a vibration-isolating ball and spring.

1 to 4, the three-axis type anti-vibration mount 100 using a seismic isolation ball and a spring according to an embodiment of the present invention includes a bottom member 110, a seismic isolation ball 120, a connection member 130, It may include a fixing member 150 , a wave spring 170 and a connection bolt 160 .

The bottom member 110 is installed on the ground, and the first receiving support groove 111 made of a concave curvature surface for accommodating the lower part of the seismic isolation ball 120 around the center so that the seismic isolation ball 120 can be returned by rolling. ) may be provided in plurality to face upward. Here, the first accommodating support groove 111 is formed to have a greater curvature than that of the seismic isolation ball 120 , so that the seismic isolation ball 120 can be rolled from the inside by vibration of the upper connecting member 130 .

A plurality of seismic isolation balls 120 are seated on the bottom member 110 so as to be able to return by rolling. In this embodiment, although it is shown that there are three, it is not necessarily limited thereto.

The connecting member 130 is seated on the seismic isolation ball 120 and installed on the bottom member 110 . The connection member 130 corresponds to each of the first accommodating grooves 111, and a plurality of second accommodating support grooves 131 having a concave curvature surface are provided to face downward, so that each of the second accommodating support grooves 131 is provided. The upper part of each of the seismic isolation balls 120 may be accommodated in the . Also, the second accommodating support groove 131 may be formed to have a greater curvature than the curvature of the seismic isolation ball 120 like the first accommodating support groove 111 .

The connecting member 130 may be provided such that the first seating groove 133 is opened upwardly around the central portion, and thus the wave spring 170 may be seated so as to be stacked upward.

The fixing member 150 is installed to be slidable up and down on the upper side of the connection member 130 , and may be fixed to support the vibration-proof object or the lower side of the table on which the vibration-proof object is installed.

The connecting member 130 and the fixing member 150 enable sliding with the edges overlapping each other, thereby preventing the inner wave spring 170 from being exposed to the outside. In this embodiment, the connecting member 130 may be slidably coupled so that the edge of the fixing member 150 is opposite to the outside of the sliding coupling groove 134 by the sliding coupling groove 134 is formed on the outer circumferential surface.

The fixing member 150 may be provided such that the second seating groove 151 is opened downward to correspond to the first seating groove 133 , and the wave spring 170 is vertically stacked in the second seating groove 151 . The upper part can be seated.

The wave spring 170 is installed to be wrapped between the connection member 130 and the fixing member 150 , and is stacked in a plurality of top and bottom to elastically support the fixing member 150 from the connection member 130 .

The wave spring 170 may be formed in a ring shape as in the present embodiment (refer to FIG. 5), and may be seated so as to be stacked vertically between the first seating groove 133 and the second seating groove 151, and stable. In order to increase the reliability of the buffer action in the vertical direction while maintaining the stacked state, a washer 171 may be interposed therebetween.

The connecting bolt 160 connects the fixing member 150 , the connecting member 130 and the bottom member 110 to each other. The connection bolt 160 is inserted downward so that the head is caught in the locking hole 152 formed in the central portion of the fixing member 150, for example, as in this embodiment, and is inserted into the center of the wave spring 170 and the connection member 130. Through each of the formed through-holes 132 , they may be screwed to and fixed to the fastening parts 112 provided in the bottom member 110 .

A damping member 140 may be installed between the bottom member 110 and the connecting member 130 . The damping member 140 may be formed of a hollow member to be interposed between the boss 113 protruding to surround the fastening portion 112 of the bottom member 110 and the inner surface of the through hole 132 of the connecting member 130 . and may be made of a material capable of damping, for example, an elastic material such as silicone or rubber. That is, the damping member 140 is made of a hollow member and fitted to the outside of the boss 113 , so that it can be interposed between the boss 113 and the inner surface of the through hole 132 .

The fixing member 150 is a vibration-proof object in the present invention, but is fixed to support the lower side of the table on which the vibration-proof object is installed. B. In addition to optical microscopes, various types of cutting processing equipment or various optical measuring equipment may be used, as well as equipment requiring various vibration protection.

As shown in Figure 6, the table 10 supported by the fixing member 150 is sensitive to vibration or for installing equipment that is unfavorable to vibration, the fixing part 153 of the fixing member 150 at each corner. ) indicates that it is installed to be spaced apart from the ground by screwing. On the other hand, in the fixing member 150, the fixing part 153 may be made of a male screw part for screwing to the bottom surface of the equipment sensitive to vibration or unfavorable to operation as well as the table 10, and for their support A support protrusion 154 (refer to FIG. 1 ) may be provided around the lower end of the fixing part 153 .

According to the three-axis anti-vibration mount using the ball and spring for seismic isolation according to the present invention, the seismic isolation efficiency in the horizontal axis direction can be increased due to the two-dimensional arrangement of the ball for seismic isolation, and due to the stacked structure of the wave spring, While increasing the seismic isolation efficiency in the vertical axis direction, it can support a relatively high load even in a small size.

In addition, according to the present invention, there is an effect of improving the additional damping efficiency by the damping member made of a material such as silicon.

As described above, the present invention has been described with reference to the accompanying drawings, but it goes without saying that various modifications and variations can be made within the scope without departing from the technical spirit of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims described below as well as those claims and equivalents.

110: bottom member 111: first receiving support groove
112: fastening part 113: boss
120: seismic isolation ball 130: connecting member
131: second receiving support groove 132: through hole
133: first seating groove 134: sliding coupling groove
140: damping member 150: fixing member
151: second seating groove 152: locking hole
153: fixed part 154: support end
160: connection bolt 170: wave spring
171: washer

Claims (5)

a bottom member installed on the ground;
a seismic isolation ball seated on the bottom member in plurality to enable return by rolling;
a connection member seated on the seismic isolation ball and installed on the bottom member;
a fixing member that is installed slidably up and down on the upper side of the connection member and is fixed to support the lower side of the table on which the vibration-proof object or the vibration-proof object is installed;
a wave spring installed so as to be wrapped between the connecting member and the fixing member and stacked in a plurality of upper and lower parts to elastically support the fixing member from the connecting member; and
a connecting bolt connecting the fixing member, the connecting member, and the bottom member to each other;
including,
The bottom member is
A plurality of first accommodating support grooves made of a concave curvature surface to accommodate the lower portion of the seismic isolation ball around the center are provided to face upward,
The connecting member is
Corresponding to each of the first accommodating grooves, a plurality of second accommodating support grooves having a concave curvature surface are provided to face downward, so that an upper portion of each of the seismic isolation balls is accommodated in each of the second accommodating support grooves,
The connecting member and the fixing member,
Make it possible to slide with the edges overlapping each other,
The connecting member is
A first seating groove is provided around the center to open upward,
The fixing member is
A second seating groove is provided to open downward to correspond to the first seating groove,
The wave spring is
It is made in a ring shape and is seated so as to be stacked vertically between the first and second seating grooves, and a washer is interposed between them. mount. delete delete The method according to claim 1,
The connecting bolt is
It is inserted downward so that the head is caught in the locking hole formed in the center of the fixing member and penetrates through the through holes formed in the center of the wave spring and the connecting member, respectively, and is screwed into the fastening part provided in the bottom member. Fixed, 3-axis anti-vibration mount using an isolating ball and spring. 5. The method according to claim 4,
A three-axis anti-vibration mount using a ball and spring for vibration isolation, further comprising a damping member made of a hollow member and made of a damping material to be interposed between the boss protruding so as to surround the fastening part and the inner surface of the through hole.

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