CN216743624U - Anti-seismic base - Google Patents

Abstract

An anti-seismic base relates to the technical field of building construction. The utility model solves the problems that the traditional data center cabinet supporting base has poor damping effect, single structure and function and can not realize height adjustment. The top ends of four right-angle connecting positions of the anti-seismic base body are uniformly provided with four spring assemblies, the tops of the spring assemblies are detachably connected with the lower end face of a data center cabinet to be supported, the bottoms of the spring assemblies are detachably connected with the anti-seismic base body, four spiral assemblies are vertically and uniformly distributed at the bottom ends of the four right-angle connecting positions of the anti-seismic base body, an upper mounting seat, a lower mounting seat and a base are sequentially arranged from top to bottom, a lower connecting plate is fixedly connected with the anti-seismic base body, a lower connecting plate is detachably connected at the top end of the upper mounting seat, an optical axis at the top end of a screw rod is inserted into a shaft hole of the upper mounting seat, and the bottom end of the screw rod is spirally arranged in a mounting seat threaded hole in the center of the upper end face of the lower mounting seat. The utility model is used for supporting the data center cabinet.

Description

Anti-seismic base

Technical Field

The utility model relates to the technical field of building construction, in particular to an anti-seismic base.

Background

The existing data center cabinet supporting base generally adopts a rigid structure formed by welding, and the rigid structure base has better bearing performance. For some areas on the seismic zone, the requirement on the seismic resistance of a base used by the data center is high, and the base with the rigid structure does not have the damping function and damages a cabinet of the data center when vibration occurs. When the cabinet body is vibrated or collided, the internal devices are easily damaged. In addition, the structure and the function of the existing data center cabinet supporting base are single, and the height adjusting function is not achieved. When ground is level inadequately, lead to data center rack to support the unable level that keeps of base up end, in addition when the data center rack in case will use many years by confirming after the installation, the sunken condition in ground appears probably in the use period, because data center rack quality is great, the transport of being not convenient for, when the data center rack was arranged in and is supported the base, the rack slope phenomenon can appear, causes the destruction to the data center rack when taking place the vibration.

To sum up, current data center rack supports that there is the shock attenuation effect poor in the base, and structure and function are comparatively single, can't realize altitude mixture control's problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems that an existing data center cabinet supporting base is poor in damping effect, single in structure and function and incapable of achieving height adjustment, and further provides an anti-seismic base.

The technical scheme of the utility model is as follows:

an anti-seismic base comprises an anti-seismic base body 1, the anti-seismic base further comprises four spring assemblies 2 and four spiral assemblies 3, the anti-seismic base body 1 is a rectangular frame, the four spring assemblies 2 are uniformly arranged at the top ends of four right-angle connecting positions of the anti-seismic base body 1, the spring assemblies 2 are vertically arranged, the tops of the spring assemblies 2 are detachably connected with the lower end face of a data center cabinet to be supported through connecting pieces, the bottoms of the spring assemblies 2 are detachably connected with the anti-seismic base body 1 through connecting pieces, the four spiral assemblies 3 are vertically and uniformly distributed at the bottom ends of the four right-angle connecting positions of the anti-seismic base body 1, each spiral assembly 3 comprises an upper mounting seat 31, a lower mounting seat 32, a base 33, a screw 34 and a lower connecting plate 35, the upper mounting seat 31, the lower mounting seat 32 and the base 33 are sequentially arranged from top to bottom, and the lower connecting plate 35 is fixedly connected with the upper end face of the anti-seismic base body 1, go up mount pad 31 top and can dismantle with connecting plate 35 down through the connecting piece and be connected, go up mount pad 31 down terminal surface center processing have a shaft hole, screw rod 34 vertical setting is between last mount pad 31 and lower mount pad 32, and screw rod 34 top processing has the optical axis, the optical axis is inserted and is established in the shaft hole of last mount pad 31, and optical axis and last mount pad 31 rotatable fit, and lower mount pad 32 up end center processing has the mount pad screw hole, and screw rod 34 bottom spiral is installed in the mount pad screw hole, and mount pad 32 bottom can be dismantled with base 33 through the connecting piece and be connected down.

Furthermore, each screw assembly 3 further comprises a handle 36, an assembly circular hole is radially processed on the outer cylindrical surface of the upper part of the screw rod 34, the handle 36 is of a circular cylindrical structure, and one end of the handle 36 is inserted into the assembly circular hole.

Further, each screw assembly 3 further comprises a support bearing, the support bearing is sleeved on the optical axis at the top end of the screw rod 34, the support bearing is embedded in the shaft hole of the upper mounting seat 31, and the screw rod 34 is rotatably connected with the upper mounting seat 31 through the support bearing.

Furthermore, each spring assembly 2 comprises a foot seat 21, an upper positioning seat 22, a supporting spring 23, a lower positioning seat 24 and an upper connecting plate 25, the foot seat 21, the upper positioning seat 22, the lower positioning seat 24 and the upper connecting plate 25 are sequentially arranged from top to bottom, the foot seat 21 is of a rectangular block-shaped structure, the upper positioning seat 22 is of a circular columnar structure, a spring positioning counter bore is processed in the center of the lower end face of the upper positioning seat 22, the supporting spring 23 is vertically arranged between the upper positioning seat 22 and the lower positioning seat 24, the top end of the supporting spring 23 is inserted into the spring positioning counter bore of the upper positioning seat 22, the upper end face of the supporting spring 23 abuts against the bottom face of the spring positioning counter bore of the upper positioning seat 22, the lower positioning seat 24 is of a circular columnar structure, the bottom end of the lower positioning seat 24 is fixedly connected with the upper connecting plate 25 through a connecting piece, the upper connecting plate 25 is fixedly connected with the upper end face of the anti-seismic base body 1 in a welding manner, a spring positioning column is processed at the top end of the lower positioning seat 24, the bottom end of the supporting spring 23 is sleeved on the spring positioning column, the lower end face of the supporting spring 23 abuts against the upper end face of the lower positioning seat 24, and the top end of the supporting spring 23 and the upper positioning seat 22, and the bottom end of the supporting spring 23 and the lower positioning seat 24 are fixedly connected in a welding mode.

Further, each spring assembly 2 further comprises an angle steel plate 26 and a locking bolt 27, the angle steel plate 26 is vertically arranged at the top end of the foot base 21, two steel plates of the angle steel plate 26 are arranged in parallel with two end faces close to the outer side in four side faces of the foot base 21 respectively, a threaded hole a is machined in the angle steel plate 26, a threaded hole b matched with the threaded hole a is machined in the data center cabinet to be supported, and the locking bolt 27 is sequentially installed in the threaded hole a and the threaded hole b from outside to inside in a spiral mode.

Further, each spring assembly 2 further comprises a rubber gasket 28, and the rubber gasket 28 is adhered to the upper end surface of the foot seat 21.

Further, the anti-seismic base body 1 is a steel-structure rectangular frame.

Further, antidetonation base body 1 includes four stands 11, four long crossbeams 12 and four short crossbeams 13, and four vertical equipartitions of stand 11 are under treating to support the data center rack, and two adjacent stand 11 upper and lower both ends are connected through two long crossbeams 12 respectively on 1 long edge of antidetonation base body, and two adjacent stand 11 upper and lower both ends are connected through two short crossbeams 13 respectively on 1 short edge of antidetonation base body.

Further, the anti-seismic base body 1 further comprises two short rib plates 14 and four long rib plates 15, one short rib plate 14 is arranged between two vertically adjacent short cross beams 13, the end parts of the short rib plates 14 are detachably connected with the corresponding short cross beams 13 through connecting pieces, two long rib plates 15 which are obliquely arranged are arranged between two vertically adjacent long cross beams 12, and the end parts of the long rib plates 15 are detachably connected with the corresponding long cross beams 12 through connecting pieces.

Compared with the prior art, the utility model has the following effects:

1. the anti-seismic base is used for supporting the data center cabinet and can achieve the effect of shock absorption. The whole steel structure rectangular frame that is of antidetonation base body 1, antidetonation base body 1 can carry out stable supporting role to the data center rack effectively as the main bearing structure of whole equipment. In addition, the four spring assemblies 2 are uniformly arranged at the top ends of the four right-angle connecting positions of the anti-seismic base body 1, so that a good shock absorption effect can be achieved, and damage to a data center cabinet when vibration occurs is avoided.

2. The anti-seismic base is used for supporting the data center cabinet and can achieve the effect of height adjustment. According to the utility model, the four spiral assemblies 3 are uniformly arranged at the bottom ends of the four right-angle connecting positions of the anti-seismic base body 1, so that the height of the whole equipment can be adjusted, when the height of the data center cabinet to be supported needs to be adjusted, the height of the anti-seismic base body 1 can be adjusted by adjusting the spiral assemblies 3 at the same time, and further the height of the data center cabinet to be supported is adjusted. In addition, when the ground is not level enough, can realize the fine setting of height through independent spiral component 3 of independent regulation, and then guarantee 1 up end of antidetonation base body and keep in a horizontal plane, treat to support the data center rack and play stable support, treat when avoiding taking place the vibration and support the data center rack and cause the destruction.

Drawings

FIG. 1 is a front view of the shock resistant base of the present invention;

FIG. 2 is a side view of the shock base of the present invention;

FIG. 3 is a top view of the shock base of the present invention;

FIG. 4 is a front view of the screw assembly 3 of the present invention;

FIG. 5 is a front view of the upper mount 31 of the present invention;

FIG. 6 is a front view of the lower mount 32 and base 33 of the present invention assembled;

FIG. 7 is a front view of the screw 34 and handle 35 of the present invention assembled;

FIG. 8 is a front view of the spring assembly 2 of the present invention;

fig. 9 is a front view of the assembled foot seat 21 and upper positioning seat 22 of the present invention;

fig. 10 is a front view of the support spring 23 and the lower positioning seat 24 of the present invention after assembly.

In the figure:

an anti-seismic base body 1; a spring assembly 2; a screw member 3;

a column 11; four long beams 12; four short beams 13; short rib plates 14; four long ribs 15;

a foot seat 21; an upper positioning seat 22; a support spring 23; a lower positioning seat 24; an upper connecting plate 25; angle plates 26; a lock bolt 27; a rubber gasket 28;

an upper mount 31; a lower mount 32; a base 33; a screw 34; a lower connecting plate 35; a handle 36.

Detailed Description

The first embodiment is as follows: the present embodiment is described with reference to fig. 1 to 10, and the anti-seismic base of the present embodiment includes an anti-seismic base body 1, the anti-seismic base further includes four spring assemblies 2 and four spiral assemblies 3, the anti-seismic base body 1 is a rectangular frame, the four spring assemblies 2 are uniformly arranged on the top ends of the four right-angle connecting positions of the anti-seismic base body 1, the spring assemblies 2 are vertically arranged, the tops of the spring assemblies 2 are detachably connected with the lower end surface of a data center cabinet to be supported through connecting pieces, the bottoms of the spring assemblies 2 are detachably connected with the anti-seismic base body 1 through connecting pieces, the four spiral assemblies 3 are vertically and uniformly arranged at the bottom ends of the four right-angle connecting positions of the anti-seismic base body 1, each spiral assembly 3 includes an upper mounting seat 31, a lower mounting seat 32, a base 33, a screw 34 and a lower connecting plate 35, the upper mounting seat 31, the lower mounting seat 32 and the base 33 are sequentially arranged from top to bottom, connecting plate 35 and 1 up end fixed connection of antidetonation base body down, go up 31 tops of mount pad and can dismantle with connecting plate 35 down through the connecting piece and be connected, it has the shaft hole to go up terminal surface center processing under the mount pad 31, and 34 vertical settings of screw rod have an optical axis at the processing between last mount pad 31 and lower mount pad 32, 34 tops of screw rod are processed, the optical axis is inserted and is established in the shaft hole at last mount pad 31, and optical axis and last mount pad 31 rotatable fit, and lower mount pad 32 up end center processing has the mount pad screw hole, and 34 bottom screws of screw rod are installed in the mount pad screw hole, and mount pad 32 bottom can be dismantled with base 33 through the connecting piece and be connected down.

The second embodiment is as follows: referring to fig. 4 and 7, the present embodiment is described, each screw module 3 of the present embodiment further includes a handle 36, an assembly circular hole is radially formed on an outer cylindrical surface of an upper portion of the screw rod 34, the handle 36 is a circular cylindrical structure, and one end of the handle 36 is inserted into the assembly circular hole. So set up, can drive screw 34 rotatory through revolving to twist handle 36, and then realize the adjustment of antidetonation base overall height, labour saving and time saving, the operation of being convenient for. Other components and connections are the same as in the first embodiment.

The third concrete implementation mode: referring to fig. 4 and 5, each screw assembly 3 of the present embodiment further includes a support bearing, the support bearing is disposed on the optical axis of the top end of the screw rod 34, the support bearing is embedded in the shaft hole of the upper mounting seat 31, and the screw rod 34 is rotatably connected to the upper mounting seat 31 through the support bearing. With the arrangement, the optical axis of the screw 34 is connected with the upper mounting seat 31 through the bearing, so that the optical axis can be rotationally matched with the upper mounting seat 31. Other compositions and connections are the same as in the first or second embodiments.

The fourth concrete implementation mode: the present embodiment is described with reference to fig. 8 to 10, each spring assembly 2 of the present embodiment includes a foot base 21, an upper positioning base 22, a supporting spring 23, a lower positioning base 24 and an upper connecting plate 25, the foot base 21, the upper positioning base 22, the lower positioning base 24 and the upper connecting plate 25 are sequentially arranged from top to bottom, the foot base 21 is a rectangular block structure, the upper positioning base 22 is a circular column structure, a spring positioning counter bore is processed in the center of the lower end surface of the upper positioning base 22, the supporting spring 23 is vertically arranged between the upper positioning base 22 and the lower positioning base 24, the top end of the supporting spring 23 is inserted into the spring positioning counter bore of the upper positioning base 22, the upper end surface of the supporting spring 23 abuts against the bottom surface of the spring positioning counter bore of the upper positioning base 22, the lower positioning base 24 is a circular column structure, the bottom end of the lower positioning base 24 is fixedly connected to the upper connecting plate 25 through a connecting member, the upper connecting plate 25 is fixedly connected to the upper end surface of the anti-seismic base body 1 through a welding method, a spring positioning column is processed at the top end of the lower positioning seat 24, the bottom end of the supporting spring 23 is sleeved on the spring positioning column, the lower end face of the supporting spring 23 abuts against the upper end face of the lower positioning seat 24, and the top end of the supporting spring 23 and the upper positioning seat 22, and the bottom end of the supporting spring 23 and the lower positioning seat 24 are fixedly connected in a welding mode. So set up, spring assembly 2 can play absorbing effect, avoids causing destruction to data center rack when taking place the vibration. Other compositions and connection relationships are the same as in the first, second or third embodiment.

The fifth concrete implementation mode: the embodiment is described with reference to fig. 8 and 9, each spring assembly 2 of the embodiment further includes an angle steel plate 26 and a locking bolt 27, the angle steel plate 26 is vertically disposed at the top end of the foot base 21, two steel plates of the angle steel plate 26 are respectively arranged in parallel with two end faces near the outer side of the four side faces of the foot base 21, a threaded hole a is processed on the angle steel plate 26, a threaded hole b matched with the threaded hole a is processed on the data center cabinet to be supported, and the locking bolt 27 is sequentially installed in the threaded hole a and the threaded hole b from the outside to the inside. So set up, treat that the four corners department of supporting the data center rack places angle steel plate 26 inboard in, connect through locking bolt 27 between data center rack and the angle steel plate 26. Other compositions and connection relationships are the same as those in the first, second, third or fourth embodiment.

The sixth specific implementation mode: the present embodiment is described with reference to fig. 8 and 9, and each spring assembly 2 of the present embodiment further includes a rubber gasket 28, and the rubber gasket 28 is adhered to the upper end surface of the foot seat 21. So set up, rubber gasket 28 treats the cabinet body that supports the data center rack and plays the effect of protection, can also increase the cabinet body and the frictional force at support position simultaneously. Other compositions and connection relationships are the same as in the first, second, third, fourth or fifth embodiment.

The seventh embodiment: the present embodiment will be described with reference to fig. 1 to 3, and the seismic base body 1 of the present embodiment is a steel-structured rectangular frame. So set up, antidetonation base body 1 can carry out stable supporting role to the data center rack effectively as the main bearing structure of whole equipment. Other compositions and connection relationships are the same as in the first, second, third, fourth, fifth or sixth embodiment.

The specific implementation mode is eight: the embodiment is described with reference to fig. 1 to 3, the anti-seismic base body 1 of the embodiment includes four columns 11, four long beams 12 and four short beams 13, the four columns 11 are vertically and uniformly distributed under the cabinet of the data center to be supported, the upper and lower ends of two adjacent columns 11 on the long side of the anti-seismic base body 1 are respectively connected through the two long beams 12, and the upper and lower ends of two adjacent columns 11 on the short side of the anti-seismic base body 1 are respectively connected through the two short beams 13. Other compositions and connection relationships are the same as those of embodiment one, two, three, four, five, six or seven.

The specific implementation method nine: the embodiment is described with reference to fig. 1 and fig. 2, the anti-seismic base body 1 of the embodiment further includes two short rib plates 14 and four long rib plates 15, one short rib plate 14 is disposed between two adjacent short beams 13, an end of each short rib plate 14 is detachably connected to the corresponding short beam 13 through a connecting member, two long rib plates 15 arranged in an inclined manner are disposed between two adjacent long beams 12, and an end of each long rib plate 15 is detachably connected to the corresponding long beam 12 through a connecting member. Other compositions and connection relationships are the same as those in the first, second, third, fourth, fifth, sixth, seventh or eighth embodiment.

Principle of operation

The working principle of the anti-seismic base of the utility model is explained with reference to fig. 1 to 10: firstly, the anti-seismic base is arranged on the ground, and an assembly worker can simultaneously adjust the heights of the four spiral components 3 according to the installation height requirement of the data center cabinet, so that the overall height of the anti-seismic base is adjusted. The specific operation process is that an assembling worker holds the handle 36 to screw the screw 34, and when the upper end face of the anti-vibration base reaches a given height, the assembling worker stops screwing the screw 34. Then when the ground is not level enough, the assembly worker can realize the fine adjustment of height through independently adjusting independent spiral component 3, and finally after the up end of antidetonation base body 1 keeps in a horizontal plane, will wait to support the data center rack and place in the footstands 21 of four spring assembly 2 of antidetonation base, adopt locking bolt 27 will wait to support the data center rack and angle steel plate 26 fixed connection.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (9)

1. The utility model provides an antidetonation base, antidetonation base includes antidetonation base body (1), its characterized in that: the anti-seismic base further comprises four spring assemblies (2) and four spiral assemblies (3), the anti-seismic base body (1) is a rectangular frame, the four spring assemblies (2) are uniformly arranged at the top ends of four right-angle connecting positions of the anti-seismic base body (1), the spring assemblies (2) are vertically arranged, the top parts of the spring assemblies (2) are detachably connected with the lower end face of a data center cabinet to be supported through connecting pieces, the bottom parts of the spring assemblies (2) are detachably connected with the anti-seismic base body (1) through connecting pieces, the four spiral assemblies (3) are vertically and uniformly distributed at the bottom ends of the four right-angle connecting positions of the anti-seismic base body (1), each spiral assembly (3) comprises an upper mounting seat (31), a lower mounting seat (32), a base (33), a screw rod (34) and a lower connecting plate (35), the upper mounting seat (31), the lower mounting seat (32) and the base (33) are sequentially arranged from top to bottom, connecting plate (35) and antidetonation base body (1) up end fixed connection down, go up mount pad (31) top and can dismantle with connecting plate (35) down through the connecting piece and be connected, go up mount pad (31) down terminal surface center processing have a shaft hole, screw rod (34) vertical setting is between last mount pad (31) and lower mount pad (32), and screw rod (34) top processing has the optical axis, the optical axis is inserted and is established in the shaft hole of last mount pad (31), and optical axis and last mount pad (31) rotatable fit, and mount pad (32) up end center processing has the mount pad screw hole down, and screw rod (34) bottom spiral is installed in the mount pad screw hole, and mount pad (32) bottom can be dismantled through connecting piece and base (33) and be connected down.

2. An earthquake-resistant base as defined in claim 1, wherein: each spiral component (3) further comprises a handle (36), an assembly circular hole is machined in the outer cylindrical surface of the upper portion of the screw rod (34) along the radial direction, the handle (36) is of a circular cylindrical structure, and one end of the handle (36) is inserted into the assembly circular hole.

3. An earthquake-resistant base as claimed in claim 2, wherein: each spiral component (3) further comprises a supporting bearing, the supporting bearing is sleeved on an optical axis at the top end of the screw rod (34), the supporting bearing is embedded in a shaft hole of the upper mounting seat (31), and the screw rod (34) is rotatably connected with the upper mounting seat (31) through the supporting bearing.

4. A seismic base according to claim 1, 2 or 3, wherein: each spring assembly (2) comprises a foot seat (21), an upper positioning seat (22), a supporting spring (23), a lower positioning seat (24) and an upper connecting plate (25), the foot seat (21), the upper positioning seat (22), the lower positioning seat (24) and the upper connecting plate (25) are sequentially arranged from top to bottom, the foot seat (21) is of a rectangular block structure, the upper positioning seat (22) is of a circular columnar structure, a spring positioning counter bore is processed in the center of the lower end face of the upper positioning seat (22), the supporting spring (23) is vertically arranged between the upper positioning seat (22) and the lower positioning seat (24), the top end of the supporting spring (23) is inserted into the spring positioning counter bore of the upper positioning seat (22), the upper end face of the supporting spring (23) is abutted against the bottom face of the spring positioning counter bore of the upper positioning seat (22), the lower positioning seat (24) is of a circular columnar structure, the bottom end of the lower positioning seat (24) is fixedly connected with the upper connecting plate (25) through a connecting piece, the anti-seismic base is characterized in that the upper connecting plate (25) is fixedly connected with the upper end face of the anti-seismic base body (1) in a welding mode, a spring positioning column is processed at the top end of the lower positioning seat (24), the bottom end of the supporting spring (23) is sleeved on the spring positioning column, the lower end face of the supporting spring (23) abuts against the upper end face of the lower positioning seat (24), and the top end of the supporting spring (23) is fixedly connected with the upper positioning seat (22) and the bottom end of the supporting spring (23) is fixedly connected with the lower positioning seat (24) in a welding mode.

5. An earthquake-resistant base as claimed in claim 4, wherein: every spring unit (2) still includes angle steel plate (26) and locking bolt (27), angle steel plate (26) are vertical to be set up on foot rest (21) top, two terminal surface parallel arrangement that are close to the outside in two steel sheets of angle steel plate (26) respectively with four sides of foot rest (21), processing threaded hole an on angle steel plate (26), it has the screw hole b with screw hole a assorted to wait to support processing on the data center rack, locking bolt (27) are in proper order spiral installation in screw hole a and screw hole b from the outside in.

6. An earthquake-resistant base as claimed in claim 5, wherein: each spring component (2) also comprises a rubber gasket (28), and the rubber gasket (28) is stuck on the upper end surface of the foot seat (21).

7. A seismic base according to claim 1, 2, 3, 5 or 6, wherein: the anti-seismic base body (1) is a steel structure rectangular frame.

8. An earthquake-resistant base as claimed in claim 7, wherein: antidetonation base body (1) includes four stands (11), four long crossbeam (12) and four short beam (13), and four vertical equipartitions of stand (11) are under treating to support the data center rack, and both ends are connected through two long crossbeam (12) respectively about two adjacent stands (11) on antidetonation base body (1) long edge, and both ends are connected through two short beam (13) respectively about two adjacent stands (11) on antidetonation base body (1) short edge.

9. An earthquake-resistant base as defined in claim 8, wherein: antidetonation base body (1) still includes two short floor (14) and four long floor (15), is equipped with a short floor (14) between two upper and lower adjacent short crossbeam (13), short floor (14) tip passes through the connecting piece and can dismantle with corresponding short crossbeam (13) and be connected, is equipped with long floor (15) that two slopes were arranged between two upper and lower adjacent long crossbeam (12), long floor (15) tip passes through the connecting piece and can dismantle with corresponding long crossbeam (12) and be connected.

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