CN203279451U - A heat-dissipating tube structure - Google Patents

Abstract

The utility model relates to a heat-dissipating tube structure. The heat-dissipating tube structure mainly comprises a body. At least one heat-dissipating channel is disposed in the body and passes through the body along the axial direction of the body. The heat-dissipating channels are separated by separator plates. On a first heat-dissipating surface disposed on the outer surface of the body, multiple first heat-dissipating fins are formed by cutting and bending the body. The first heat-dissipating fins arranged in parallel and at equal intervals. The heat-dissipating fins are bent by simply planning the heat-dissipating tube body. A heat-dissipating member produced by a complex manufacture procedure can be replaced. The heat-dissipating tube structure is capable of effectively reducing the manufacturing cost of heat-dissipating tubes and the assembling cost of heat-dissipating modules.

Description

Radiation tube structure with heat

Technical field

The radiation tube structure with heat of the relevant a kind of radiating module of the utility model, especially relevant a kind of liquid gas pressure radiation tube structure with heat.

Background technology

as shown in Figure 1, a kind of radiating module that its fluid heat radiation that is used for toolroom machine is used, mainly comprise a radiator 70, a plurality of embedded components 731 and a plurality of heat sink 76, this radiator includes one first pipe fitting 71, one second pipe fitting 72 and a plurality of tube connector 73 that is connected in this first pipe fitting 71 and this second pipe fitting 72, and form the heat-dissipating space 74 of strip between each tube connector 73, these a plurality of embedded component 731 correspondences are placed in the inside of each tube connector 73, each heat sink 76 removably corresponding intrument in each heat-dissipating space 74, and these a plurality of embedded components 731 are the dictyosome of heat radiation material, after it forms strip in the screw winding mode, the corresponding filling filled in each interface channel of each tube connector 73 respectively, these a plurality of heat sinks 76 are high score handset material such as nylon, staple fibre or chemical fibre are interwoven, but and in skin with the made concrete dynamic modulus rectangle block of the even coating heat-conducting metal of chemical deposition mode, each heat sink 76 is corresponding respectively to be filled in and is embedded in each heat-dissipating space 74 of radiator 70.Two openings 711,721 of this radiator 70 are connected to deep fat oil circuit to be cooled, and introduce deep fat by the opening 711 of this first pipe fitting 71, and make stream of hot oil through the communication channel of each tube connector 73, derived by the opening 721 of the second pipe fitting 72 again, via the effect of each embedded component 731 and each heat sink 76, to reach cooling effect.

Use the dictyosome of heat radiation material due to the embedded component of the tube connector 73 of existing radiating module, after must first forming strip in the screw winding mode, the corresponding filling filled in each interface channel of each tube connector 73 respectively again, but heat sink 76 uses high score handset material to be interwoven and is made with the even coating heat-conducting metal of chemical deposition mode in skin, its fabrication schedule is relatively loaded down with trivial details and cost is higher, and therefore necessity of its improvement arranged.

The utility model content

Must fill in embedded component in order to solve its tube connector of existing radiating module, and be to promote radiating effect, a plurality of heat sinks must be embedded in each heat-dissipating space of radiator again, and cause the problem that the process technique difficulty increases and manufacturing cost is higher, main purpose of the present utility model is to provide a kind of durable, processing procedure the simple and lower radiation tube structure with heat of manufacturing cost, comprising:

One body, this body interior are provided with at least one passage of heat along this body shaft to perforation, and on set one first radiating surface of the outer surface of this body, are cut and rolled over and routed up a plurality of the first radiating fins by this body.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein said the first radiating fin parallels arrangement.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein said the first radiating fin is equidistant arrangement.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein this first radiating fin is vertical with this first radiating surface.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein this first radiating surface is the plane.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein this passage of heat comprises one first passage of heat and one second passage of heat, this first passage of heat and this second passage of heat are with one first dividing plate separately.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein this passage of heat further comprises one the 3rd passage of heat, this second passage of heat and the 3rd passage of heat are with a second partition separately.

Aforesaid radiation tube structure with heat wherein on the outer surface of this body, is formed with second radiating surface that is the plane in non-this the first radiating surface place.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat wherein on this second radiating surface, is cut and is rolled over and routed up a plurality of the second radiating fins by this body.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein said the second radiating fin parallels arrangement.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein said the second radiating fin is equidistant arrangement.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein respectively this second radiating fin is vertical with this second radiating surface.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein this second radiating surface further forms a radiating segment and a conduction contact-segment, and the width of this conduction contact-segment is greater than the width of this radiating segment.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein further stick on this radiating segment surface a heat conduction film.

In an embodiment of the present utility model, aforesaid radiation tube structure with heat, wherein further sticking on this second radiating surface has a heat conduction film.

Therefore, its radiating fin of radiation tube structure with heat of the present utility model only needs namely to can be made into by general planing operation, needn't fill in embedded component and heat sink is filled between radiating tube in radiating tube, can fully reach radiating effect, therefore its processing procedure is simple and easy, can reduce the manufacturing cost of assembling radiating module.

Description of drawings

Fig. 1 is radiating module schematic diagram of the prior art.

Fig. 2 is the schematic perspective view of the utility model the first embodiment.

Fig. 3 is the schematic perspective view of the utility model the second embodiment.

Fig. 4 is the schematic perspective view of the utility model the 3rd embodiment.

Wherein, description of reference numerals is as follows:

Embodiment

Below by particular specific embodiment explanation execution mode of the present utility model, those of ordinary skill in the art can understand other advantage of the present utility model and effect easily by content disclosed in the present specification.The utility model also can be implemented or be used by other different specific embodiment, and the every details in this specification also can based on different viewpoints and application, be carried out various modifications and change under not departing from spirit of the present utility model.

Please refer to Fig. 2, it is the first execution mode of the present utility model.The utility model is a kind of radiation tube structure with heat, it comprises a body 10, this body interior 12 connects along this body shaft to 13 and is provided with at least one passage of heat 20, for example this passage of heat can comprise one first passage of heat 21 and one second passage of heat 22, this first passage of heat 21 and this second passage of heat 22 are with one first dividing plate 24 separately, this passage of heat 20 can further comprise one the 3rd passage of heat 23, and this second passage of heat 22 and the 3rd passage of heat 23 are with a second partition 25 separately.On set one first radiating surface 11 of the outer surface of this body 10, cut and roll over and routed up a plurality of the first radiating fins 30 by this body 10, described the first radiating fin 30 parallels arrangement, described the first radiating fin 30 can be equidistant arrangement to each other, and vertical with this first radiating surface 11 or be a specific angle with this first radiating surface 11 and arrange, wherein this first radiating surface 11 is the plane, and this passage of heat is not limited to two or three passages of heat, also can make according to actual needs variation.

In above-described embodiment, can be applicable to for example that but the two ends of a plurality of radiation tube structure with heats of the present utility model are (not shown in the figures with the first pipe fitting and second pipe fitting of air feed, liquid flow respectively, please refer to Fig. 1) engage, when coming into operation, gas to be cooled, liquid can pour into via the arrival end of the first pipe fitting, make this gas to be cooled, liquid enter the passage of heat 20 of described a plurality of radiation tube structure with heat one end, flow into the second pipe fitting by the other end, and discharge cooling gas, liquid from the port of export of the second pipe fitting.Described radiating fin reaches the effect of heat radiation by this.

please refer to Fig. 3, it is the second execution mode of the present utility model, as shown in the figure, on its outer surface based on the body 10 of above-mentioned radiator structure of the present utility model, be formed with second radiating surface 40 that is the plane in non-this the first radiating surface 11 places, on this second radiating surface 40, cut and roll over and routed up a plurality of the second radiating fins 50 by this body, described the second radiating fin 50 parallels arrangement, described the second radiating fin 50 can be equidistant arrangement to each other, and vertical with this second radiating surface 40 or be a special angle with this second radiating surface 40 and arrange, wherein this second radiating surface 40 is the plane.Thus, radiator structure of the present utility model has further had the second radiating fin 50 in its opposite face except having the first original radiating fin 30, therefore can reach the effect of radiator structure two-side radiation of the present utility model.

In above-mentioned execution mode, this second radiating surface 40 also can not cut because coordinating the radiating module demand, and further stick, a heat conduction film 60 is arranged on this second radiating surface 40 of body 10, to promote its radiating effect.

In the second execution mode, the body 10 of radiator structure of the present utility model can cut except two side planes at original body 10 based on above-mentioned execution mode and roll over the first radiating fin 30 and the second radiating fin 50 of routing up, and can cut in all the other two side planes of this body 10 again and roll over the 3rd radiating fin (not being shown in figure) routed up and the hot fin (not being shown in figure) that scatters.

Please refer to Fig. 4, it is the 3rd execution mode of the present utility model, as shown in the figure, radiator structure of the present utility model is based on the first execution mode, further form a radiating segment 101 and a conduction contact-segment 102 in this second radiating surface 40, and width that should conduction contact-segment 102 is greater than the width of this radiating segment 101, and wherein a heat conduction film 60 can be further sticked on this conduction contact-segment 101 surfaces, to promote its radiating effect.The side fit dimension that for example will stick the conduction contact-segment 101 of this heat conduction film 60 is arranged on a pyrotoxin, and the heat conduction film that the thermal radiation that pyrotoxin gives out just can be by tight attaching dispels the heat away via the fin of radiator structure of the present utility model.

In above-mentioned execution mode, the arrangement mode of its described the first radiating fin and described the second radiating fin is only a kind of execution mode of the present utility model, and other arrangement mode or variation also belong in category of the present utility model.

Radiation tube structure with heat of the present utility model, the outer surface of its body is through cutting and rolling over that to rout up a plurality of radiating fins be to plane by machining to form, do not need to get final product integrally formed producing via the processing procedure of complexity, therefore low production cost is quick, it is when the assembling radiating module, more do not need the outer heat sink of amount of production to plant between radiating tube, only need to reach sufficient radiating effect by the radiating fin of radiation tube structure with heat of the present utility model, produce and assembly cost therefore can effectively reduce.

In sum, it is only preferred embodiment of the present utility model, be not to any pro forma restriction of the utility model, the technical staff who has common knowledge in technical field under any, if in the scope that does not break away from technical characterictic that the utility model is carried, utilize technology contents that the utility model discloses to make the local equivalent embodiment that changes or modify, all still belong in the scope of the utility model technical characterictic.

Claims (15)

1. a radiation tube structure with heat, is characterized in that, comprising:

One body, this body interior are provided with at least one passage of heat along this body shaft to perforation, and on set one first radiating surface of the outer surface of this body, are cut and rolled over and routed up a plurality of the first radiating fins by this body.

2. radiation tube structure with heat as claimed in claim 1, is characterized in that, described the first radiating fin parallels arrangement.

3. radiation tube structure with heat as claimed in claim 1 or 2, is characterized in that, described the first radiating fin is equidistant arrangement.

4. radiation tube structure with heat as claimed in claim 1 or 2, is characterized in that, respectively this first radiating fin is vertical with this first radiating surface.

5. radiation tube structure with heat as claimed in claim 1, is characterized in that, this first radiating surface is the plane.

6. radiation tube structure with heat as claimed in claim 1, is characterized in that, this passage of heat comprises one first passage of heat and one second passage of heat, and this first passage of heat and this second passage of heat are with one first dividing plate separately.

7. radiation tube structure with heat as claimed in claim 2, is characterized in that, this passage of heat further comprises one the 3rd passage of heat, and this second passage of heat and the 3rd passage of heat are with a second partition separately.

8. radiation tube structure with heat as claimed in claim 1, is characterized in that, on the outer surface of this body, is formed with second radiating surface that is the plane in non-this the first radiating surface place.

9. radiation tube structure with heat as claimed in claim 8, is characterized in that, on this second radiating surface, cut and rolled over and routed up a plurality of the second radiating fins by this body.

10. radiation tube structure with heat as claimed in claim 9, is characterized in that, described the second radiating fin parallels arrangement.

11. radiation tube structure with heat as described in claim 9 or 10 is characterized in that, described the second radiating fin is equidistant arrangement.

12. radiation tube structure with heat as described in claim 9 or 10 is characterized in that, respectively this second radiating fin is vertical with this second radiating surface.

13. radiation tube structure with heat as claimed in claim 8 is characterized in that, this second radiating surface further forms a radiating segment and a conduction contact-segment, and the width of this conduction contact-segment is greater than the width of this radiating segment.

14. radiation tube structure with heat as claimed in claim 13 is characterized in that, further stick on this conduction contact-segment surface a heat conduction film.

15. radiation tube structure with heat as claimed in claim 8 is characterized in that, further sticking on this second radiating surface has a heat conduction film.

Images