CN211289580U - Heat dissipation support for ultra-capacity helium series storage equipment - Google Patents

Abstract

The utility model discloses a serial storage device heat dissipation support of supercapacity helium, comprising a base plate, bottom plate bottom both sides central authorities position cup joints through the sleeve pipe and is connected with the loop bar, and loop bar bottom fixedly connected with shock attenuation board, shock attenuation board upper end is close to a set of shock attenuation pole of middle part both sides middle section fixedly connected with, and the shock attenuation pole extends into inside the oil pocket that the bottom plate bottom is close to the middle part setting of the casing middle part both sides, a set of riser of bottom plate upper end both sides fixedly connected with, end threaded connection has a set of horizontal pole around the inboard upper portion of riser, and the inboard middle part equidistance of horizontal pole is connected with the extension board. The utility model discloses a set up shock attenuation board, shock attenuation pole, oil pocket, thermovent, spacing groove, louvre and heat dissipation cavity structure, have and be convenient for carry out structure fixing and heat dissipation to helium storage jar, promote the advantage of helium storage jar shock attenuation nature in the transportation.

Description

Heat dissipation support for ultra-capacity helium series storage equipment

Technical Field

The utility model relates to a helium storage specifically is a super capacity helium series storage device heat dissipation support with relevant equipment technical field.

Background

Helium, the symbol is He, is colorless and tasteless, can not burn gas, the content of air is about 5.2 ppm, chemical property is inactive, usually state is not combined with other elements or compounds, 1908 year 7 month 10 day, dutch physicist angniss has liquefied helium for the first time, helium is colorless and tasteless gas under room temperature and atmospheric pressure, helium volume content in air is 5.24 x 10-6, is the substance that the human finds the lowest critical temperature, shows dark yellow when low pressure discharge is carried out, generally stores helium through the storage tank, at present, in the process of storing and transporting cold gas by the storage tank, the structure of the storage tank is fixed inconveniently, and is not favorable for its own heat dissipation, meanwhile, the storage tank is easy to damage and has great limitation due to insufficient shock absorption measures in transportation, therefore, improvement is necessary, to solve the above problems.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a super capacity helium series storage device heat dissipation support to solve the problem that proposes in the above-mentioned background art.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a super capacity helium series storage device heat dissipation support, includes the bottom plate, bottom plate bottom both sides central authorities position cup joints through the sleeve pipe and is connected with the loop bar, and loop bar bottom fixedly connected with shock attenuation board, shock attenuation board upper end is close to a set of shock attenuation pole of middle part both sides middle section fixedly connected with, and the shock attenuation pole extends into inside the oil pocket that the bottom plate bottom is close to the middle part both sides setting and the middle part sets up in the casing, a set of riser of bottom plate upper end both sides fixedly connected with, and the inboard lower part threaded connection of riser has the diaphragm, the thermovent has been seted up to diaphragm bottom equidistance, end threaded connection has a set of horizontal pole around the inboard upper portion of riser, and the inboard middle part equidistance of horizontal pole is connected with the extension board.

Preferably, the cross rod and the transverse plate are connected with the vertical plate through second fastening bolts arranged at the upper end part and the lower end part of the two sides of the vertical plate, and the vertical plate is connected with the bottom plate through first fastening bolts arranged at the central positions of the two sides of the bottom end of the bottom plate.

Preferably, the central position of the upper parts of the two sides of the vertical plate is fixedly connected with a group of hinged shafts through screws, and the front ends of the hinged shafts are movably connected with a group of hanging rings.

Preferably, a helium tank is arranged in the limiting groove, the bottom end of the helium tank is in contact connection with grooves formed in the upper end of the transverse plate at equal intervals, and the grooves and the heat dissipation ports are arranged in a penetrating mode and are larger than the transverse diameter of the heat dissipation ports.

Preferably, the loop bar extends into the intraduct by the opening that sets up in the middle part of the sleeve pipe bottom, and the loop bar is connected with the expanding spring bottom that sets up in the middle part of the intraductal top of cover.

Preferably, oil is uniformly filled in the oil cavity, and oil holes are formed in the two sides of the oil cavity and in the center of the bottom end at equal intervals.

(III) advantageous effects

The utility model provides a super capacity helium series storage device heat dissipation support possesses following beneficial effect:

(1) the utility model discloses a through setting up spacing groove, thermovent, louvre and heat dissipation chamber, when being convenient for carry out the structure fixed to the helium storage jar, promote the effect of thermal diffusivity between the helium storage jar, solved the inconvenient structure fixed to the storage jar, and be unfavorable for its self heat dissipation problem, be connected with horizontal pole and diaphragm respectively at the upper and lower part of the riser inboard, be provided with the spacing groove in the middle part of the extension board upper end that the horizontal pole inboard equidistance set up, carry out the bearing of structure to the helium tank by the spacing groove that sets up, and utilize the recess of equidistance setting up in the diaphragm upper end to carry out the structure bearing to the helium tank bottom, realize carrying out the structure fixed to the helium tank, and the diaphragm bottom is provided with the thermovent, and run through with the recess and be connected, set up the heat dissipation chamber between the spacing groove, simultaneously, be provided with the louvre at, further improving the heat dissipation of the helium tank.

(2) The utility model has the advantages of improving the shock absorption of the helium storage tank in transportation by arranging the sharp shock absorption plate, the shock absorption rod, the shell and the oil cavity, the effect of real-time protection on the helium storage tank in transportation solves the problem that the storage tank is easy to damage due to insufficient shock absorption measures for the storage tank in transportation, the lower end of the sleeve at the bottom end of the bottom plate is connected with a damping plate through a sleeve rod, the middle part of the upper end of the damping plate extends into the shell arranged at the bottom end of the bottom plate through the damping rod, when the damping plate is stressed, the sleeve rod extends into the sleeve so that the damping rod pressurizes oil in an oil cavity in the shell, and the oil is pressurized by the internal molecular force between the oil and the friction force between the oil and the oil hole, buffering the shock attenuation operation to the atress, help promoting the damping nature of bottom plate, and then carry out the shock attenuation operation to the helium tank that the bottom plate upper end is connected, effectually protect the operation to the helium tank.

Drawings

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

FIG. 2 is an enlarged schematic view of the present invention at A in FIG. 1;

FIG. 3 is a schematic top view of the inner side of the cross bar of the present invention;

fig. 4 is an enlarged schematic view of the point B in fig. 1 according to the present invention.

The reference numbers in the figures are: 1. a base plate; 2. a tension spring; 3. a sleeve; 4. a transverse plate; 5. a damper plate; 6. a loop bar; 7. a port; 8. a first fastening bolt; 9. a groove; 10. a heat dissipation port; 11. a cross bar; 12. a helium tank; 13. a vertical plate; 14. a second fastening bolt; 15. a screw; 16. hinging a shaft; 17. a hoisting ring; 18. heat dissipation holes; 19. a support plate; 20. a limiting groove; 21. a heat dissipation cavity; 22. an oil hole; 23. oil liquid; 24. an oil chamber; 25. a housing; 26. shock-absorbing rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-4, the utility model provides a technical solution: a heat dissipation support for an ultra-capacity helium series storage device comprises a bottom plate 1, sleeve rods 6 are connected to the central positions of two sides of the bottom end of the bottom plate 1 in a sleeved mode through sleeve pipes 3, shock absorption plates 5 are fixedly connected to the bottom ends of the sleeve rods 6, the sleeve rods 6 are connected in a structural mode through the sleeve pipes 3, the shock absorption plates 5 are fixedly installed and fixed in a structural mode through the sleeve rods 6, connection between the shock absorption plates 5 and the bottom plate 1 is achieved, shock absorption operation is conducted on the bottom plate 1, a group of shock absorption rods 26 are fixedly connected to the upper end of the shock absorption plates 5, close to the middle portion of the bottom plate 1, the shock, the inner molecular force between oil liquid 23 and the friction force between the oil liquid 23 and the oil hole 22 are used for damping and buffering the bottom plate 1 when being stressed, so as to realize the safety protection of a helium tank 12, a group of vertical plates 13 are fixedly connected to two sides of the upper end of the bottom plate 1, a transverse plate 4 is in threaded connection with the lower part of the inner side of each vertical plate 13, the vertical plates 13 are in structural connection with the bottom plate 1, the transverse plate 4 is structurally installed and fixed through the arranged vertical plates 13, heat dissipation ports 10 are formed in the bottom ends of the transverse plates 4 at equal intervals, the bottom end of the helium tank 12 is subjected to heat dissipation treatment through the arranged heat dissipation ports 10, a group of transverse rods 11 are in threaded connection with the front end and the rear end of the upper part of the inner side of each vertical plate 13, support plates 19 are connected in the middle parts of the transverse rods 11 at equal intervals, the transverse rods 11 are structurally connected, the support, and run through between the spacing groove 20 and be provided with heat dissipation chamber 21 to louvre 18 has been seted up at the external surface equidistance, and the spacing groove 20 that is set up carries out the installation of structure fixedly to helium gas pitcher 12, and by heat dissipation chamber 21 and the louvre 18 that set up, carries out the further promotion of heat dispersion to helium gas pitcher 12 that is the interval and sets up the certain heat dispersion.

Further, the horizontal pole 11, the diaphragm 4 is connected with riser 13 through the second fastening bolt 14 that riser 13 both sides upper and lower extreme tip set up, and riser 13 is connected with bottom plate 1 through the first fastening bolt 8 that 1 bottom both sides central point of bottom plate put the setting, carry out the structure of both sides on bottom plate 1 to riser 13 by the first fastening bolt 8 that sets up and fix, carry out the structural connection of lower extreme on riser 13 inboard by the second fastening bolt 14 that sets up to horizontal pole 11, diaphragm 4, and be convenient for to horizontal pole 11, diaphragm 4, bottom plate 1 go on with the structure between riser 13 dismantle.

Further, a set of articulated shaft 16 of screw rod 15 fixedly connected with is passed through to riser 13 both sides upper portion central point, and articulated shaft 16 front end swing joint has a set of rings 17, carries out the structural connection on its both sides upper portion to screw rod 15 by the riser 13 that sets up to carry out structural swing joint to rings 17 by articulated shaft 16 through screw rod 15, realize lifting by crane the operation to bottom plate 1, realize carrying out the removal of position, convenient transportation to bottom plate 1 that is connected with helium tank 12.

Further, limiting groove 20 is inside to be provided with helium tank 12, and the bottom of helium tank 12 is connected with the recess 9 contact that diaphragm 4 upper end equidistance set up, run through the setting between recess 9 and the thermovent 10, and be greater than the setting of thermovent 10 horizontal diameter, carry out the structure fixed by the limiting groove 20 who sets up to helium tank 12, and carry out accepting of bottom structure by the recess 9 who sets up to helium tank 12 in the structure fixed, help promoting the stability of helium tank 12 structure, and simultaneously, carry out through connection with recess 9 and thermovent 10, be convenient for carry out the heat dissipation operation in helium tank 12 bottom.

Further, the opening 7 that the loop bar 6 set up by sleeve pipe 3 bottom middle part extends into inside the sleeve pipe 3, and loop bar 6 and the 2 bottoms of the expanding spring that set up in the middle part of the intraductal top of sleeve pipe 3, extend into inside the sleeve pipe 3 with loop bar 6 by the opening 7 that sets up, and through the expanding spring 2 that sets up go on the loop bar 6 and the structural connection between sleeve pipe 3, be convenient for under the effect of 2 self elastic forces of expanding spring, make the damping plate 5 extend into inside the oil chamber 24, carry out the shock attenuation operation to bottom plate 1.

Furthermore, oil 23 is uniformly filled in the oil cavity 24, the oil holes 22 are formed in the two sides of the oil cavity 24 and in the middle of the bottom end of the oil cavity 24 at equal intervals, the damping rod 26 is used for pressurizing the oil 23 arranged in the oil cavity 24, and the stress is damped and buffered through the internal molecular force of the oil 23 and the friction force between the oil 23 and the oil holes 22, so that the safety protection operation of the helium tank 12 is realized.

The working principle is as follows: when in use, the vertical plate 13 is structurally connected with the two sides of the upper end of the bottom plate 1 by the arranged first fastening bolts 8, the cross rod 11 and the transverse plate 4 are structurally connected with the upper end and the lower end of the inner side of the vertical plate 13 by the arranged second fastening bolts 14, clockwise force is applied to the screw rod 15 which is connected with the hanging ring 17 by the articulated shaft 16, the screw rod 15 is structurally connected with the middle sections of the upper parts of the two sides of the vertical plate 13, the cross rod 11 is connected with the front end and the rear end of the inner side of the vertical plate 13, at the moment, the helium tank 12 is placed in the limiting groove 20 which is equidistantly arranged in the middle part of the upper end of the support plate 19 in the cross rod 11, and the bottom end structure of the helium tank 12 is supported by the grooves 9 which are equidistantly arranged in the upper end of the transverse plate 4, at the moment, the bottom plate 1 connected with the helium, the specified position is moved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a super capacity helium series storage device support that dispels heat, includes bottom plate (1), its characterized in that: the middle positions of two sides of the bottom end of the bottom plate (1) are connected with a loop bar (6) in a sleeved mode through a sleeve (3), the bottom end of the loop bar (6) is fixedly connected with a damping plate (5), the upper end of the damping plate (5) is close to the middle of the damping plate (5) of the middle of the damping plate (26) of the middle of the, and heat dissipation cavities (21) are arranged between the limiting grooves (20) in a penetrating manner, and heat dissipation holes (18) are formed in the outer surface at equal intervals.

2. The heat sink stand of claim 1, wherein said heat sink stand comprises: the transverse rod (11) and the transverse plate (4) are connected with the vertical plate (13) through second fastening bolts (14) arranged at the upper end and the lower end of the two sides of the vertical plate (13), and the vertical plate (13) is connected with the bottom plate (1) through first fastening bolts (8) arranged at the central positions of the two sides of the bottom end of the bottom plate (1).

3. The heat sink stand of claim 1, wherein said heat sink stand comprises: the middle positions of the upper parts of the two sides of the vertical plate (13) are fixedly connected with a group of hinged shafts (16) through screws (15), and the front ends of the hinged shafts (16) are movably connected with a group of lifting rings (17).

4. The heat sink stand of claim 1, wherein said heat sink stand comprises: the limiting groove (20) is internally provided with a helium tank (12), the bottom end of the helium tank (12) is in contact connection with grooves (9) formed in the upper end of the transverse plate (4) at equal intervals, and the grooves (9) and the heat dissipation port (10) are arranged in a penetrating mode and are larger than the transverse diameter of the heat dissipation port (10).

5. The heat sink stand of claim 1, wherein said heat sink stand comprises: the loop bar (6) is extended into the interior of the sleeve (3) through the through hole (7) formed in the middle of the bottom end of the sleeve (3), and the loop bar (6) is connected with the bottom end of the telescopic spring (2) arranged in the middle of the top end of the sleeve (3).

6. The heat sink stand of claim 1, wherein said heat sink stand comprises: oil (23) is uniformly filled in the oil cavity (24), and oil holes (22) are formed in the two sides of the oil cavity (24) and in the middle of the bottom end at equal intervals.

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