TWI638972B - Multi-tube-type parallel vaper chamber - Google Patents

Abstract

The present invention provides a multi-tube parallel type soaking device, which mainly comprises: at least three pipes are arranged in parallel; a first connecting member is connected to the first end of each of the pipes, and one side of the first connecting member is provided a first insertion hole communicating with the first end of each of the conduits, and a first connecting passage having a first connecting passage communicating with each of the first insertion holes; a second connecting member connected to the second end of each of the conduits a second connecting hole is provided on one side of the second connecting member, and a second connecting hole is connected to each of the second ends of the second communicating end. The second connecting member has a second connecting passage communicating with each of the second connecting holes. The ducts are disposed inside the first and second communicating members in a vacuum state; the heat conducting seats are coupled to the ducts, and include a heat conducting surface and an abutting surface.

Description

Multi-tube parallel type soaking device

The invention relates to a soaking device; in particular to a multi-tube circulation-guided innovative soaking device structure type revealer.

According to the soaking device currently applied to the heat dissipation function of the product structure, the structure type is not limited to one type, for example, the extended duct body is matched with the internal capillary structure and the working fluid type, or the circulating flow channel space is adopted. The oscillating type of the higher proportion working fluid, or the structure type which adopts the plate shape and the inner circulation type or the radial flow path space to integrate the capillary structure of the capillary structure.

However, looking at the various conventional soaking devices described in the previous paragraph, there are still some problems and shortcomings in the practical application. Firstly, the type of the extended duct body with internal capillary structure and working fluid is taken as an example. Since the internal vaporized gas is opposite to the direction in which the cooling liquid flows, which causes the two to easily interfere with each other, the heat transfer efficiency is easily affected; and in the case of the oscillation type, because of the inside thereof The phase change movement of the working fluid is initiated in a circulating flow path space, and it is often prone to the problem that the heat pipe cannot be successfully operated when the working fluid is 40% low. In addition, other factors are also likely to cause difficulty in starting. In addition, in the form of the soaking plate structure described above, since this type is not easy to shape the appearance of the curved shape, the problem of its application is limited.

Therefore, in view of the problems existing in the above-mentioned conventional soaking device technology, how to develop an innovative structure that can be more ideal and practical, and it is necessary for the relevant industry to think again about the goals and directions of breakthrough; in view of this, the invention People have been engaged in the manufacturing development and design experience of related products for many years. After detailed design and careful evaluation of the above objectives, the invention has finally become practical.

The main object of the present invention is to provide a multi-tube parallel type soaking device, and the technical problem to be solved is to think about how to develop a new type of soaking device structure with more ideal practicability. breakthrough.

The technical feature of the present invention is mainly to provide that the multi-tube parallel type soaking device comprises: at least three pipes in a side-by-side configuration, each of which includes a first end and a second end; The first connecting member is disposed at a first end of each of the conduits, and the first connecting member is provided with a first insertion hole for each of the first ends of the conduits to be in alignment with each other, and the first connecting member has a first inside The first connecting member is connected to each of the first connecting holes; a second connecting member is connected to the second end of each of the conduits, and a second connecting member is provided with a second for each of the second ends of the conduits to communicate with each other a second connecting hole has a second connecting passage communicating with each of the second connecting holes; a working fluid is disposed in the free state in each of the conduits and the first connecting member and the second connecting member, and The conduits are in a vacuum state with the first communication member and the second communication member inner space; the heat conduction seat is coupled to at least one of the root conduits, and the heat conduction seat includes a heat conduction surface and an abutting surface of the corresponding conduit.

The main effects and advantages of the present invention are the multi-directional circulating space type formed by the multi-catheter communication structure, so that the working fluid of the heat equalizing device can be more easily started, and the practical progress of avoiding the start dead point problem can be effectively avoided. It also has the advantage of easily shaping the curved appearance to meet the needs of multiple installation environments.

Please refer to the first, second, third, and fourth drawings, which are preferred embodiments of the multi-tube parallel type heat equalizing device of the present invention, but the embodiments are for illustrative purposes only, and are not applicable to the patent application. Limit

The multi-tube parallel type heat equalizing device A comprises the following structure: at least three ducts 10 are arranged in a side-by-side configuration, each of the ducts 10 includes a first end 11 and a second end 12; The connecting member 20 is connected to the first end 11 of the at least three ducts 10, and at least three sides of the first connecting member 20 are provided for at least three of the at least three conduits 10 at the first end 11 The first connecting hole 21 has a first connecting passage 22 connected to each of the first connecting holes 21; a second connecting member 30 is connected to the at least three conduits 10 The second end 12 is provided with at least three second insertion holes 31 for aligning the at least three second ends 12 of the at least three conduits 10 on the side of the second communication member 30, and the second communication member 30 is inside. A second connecting passage 32 is connected to each of the second connecting holes 31; a working fluid 40 (such as pure water, ethanol, etc.) is accommodated in the free state in the at least three conduits 10 and the first connecting member 20 And the inside of the second communication member 30, and the at least three conduits 10 and the first communication member 20 and the second communication member 30 The space is in a vacuum state; at least one heat conducting seat 50 spans at least one of the at least three conduits 10 that are coupled to the side-by-side configuration, each of the heat conducting seats 50 including a heat conducting surface 51 and one of the corresponding conduits 10 Abuts face 52.

Wherein, the outer diameter of the at least three conduits 10 is between 3 mm and 10 mm, and the length is between 100 mm and 1000 mm. According to the tube size ratio defined in this example, the multi-tube parallel type soaking device A disclosed in the present invention can achieve a scale of installation with a long extension length, and this part of the non-conventional heat pipe structure can be achieved (Note: The heat pipe extension length is usually below 400 mm).

As shown in FIG. 2, in this example, the abutting surface 52 of the heat conducting base 50 is further provided with at least three recessed grooves 53 for inserting one side of the at least three ducts 10, and as shown in FIG. 5, each The two sides of the opening of a recessed groove 53 are further deformed by means of rolling means (shown by hollow arrows in the figure) to respectively form a riveted flange 54, which is used to correspondingly The catheter 10 is placed against the limit.

As shown in Fig. 6, in this example, one or more curved portions 14 are formed at opposite positions of the at least three catheters 10.

As shown in Fig. 7, the catheter 10B disclosed in this example is further provided with a groove-like capillary structure 15.

As shown in FIG. 8, in this example, the at least three conduits 10 include a heated evaporation section 16 and a heat dissipation cooling section 17 such that the thermally conductive seat 50 is coupled to the heated evaporation section 16 or At least one of the heat-dissipating cooling sections 17; in this example, the heat-dissipating section 16 and the heat-dissipating cooling section 17 are both provided with an embodiment of the heat conducting block 50, wherein the heated evaporation section The heat conducting surface 51 of the heat conducting base 50 is provided with a heat source 60 (in this case, an LED light board), and the heat conducting surface 51B of the heat conducting seat 50B of the heat radiating cooling section 17 is provided with a heat radiating member 70. (In this example, a fin holder) is abutted; thus, the heat conduction function of the heat conduction seats 50, 50B may be heat or heat.

The ratio of the working fluid 40 to the internal space volume of the at least three conduits 10 and the first connecting member 20 and the second connecting member 30 is between 10% and 80%.

As shown in FIGS. 1 to 4, in this example, the first communication member 20 and the second communication member 30 are in the form of a rectangular hollow casing; as shown in FIG. 9, the disclosure in this example The two-connecting member 30B (the first connecting member is also applicable) is a type formed by closing the two ends of the pipe body (for example, a press-fit type); the pipe body disclosed in this example may be exposed in the figure. The flat tube shape can also be a round tube shape, and this part is not limited.

According to the above-mentioned structural composition type and technical features, the structure of the multi-tube parallel type heat equalizing device A disclosed in the present invention is designed as shown in FIG. 3, and the first through the parallel arrangement of at least three conduits 10 The connecting member 20 and the second connecting member 30 are configured to create a multi-cavity communication structure similar to the Roman numeral "III", and the inside thereof is relatively formed into a multi-directional circulating space type, that is, any two conduits 10 can pass through The first connecting member 20 and the second connecting member 30 form a circulation passage, so that the circulation of the working fluid 40 inside the heat equalizing device after being vaporized by thermal evaporation can be triggered by a plurality of circulating passage paths. Circulating conduction state, thereby achieving easier starting operation, and effectively solving the problem of starting dead point in the conventional single circulation channel; on the other hand, the catheter structure of the multi-tube parallel type homogenizing device A of the present invention is applied It also has the advantage of easily forming a curved appearance (as shown in Figures 6 and 8), and is more suitable for a diverse installation environment.

Further, as shown in FIG. 10, the outer side of the first connecting member 20B (the second connecting member is also applicable) of the present embodiment is further provided with a planar heat conducting portion 23; in the present embodiment, the planar heat conducting portion 23 is thermally conductive. The function may be heated or heat-dissipating. Therefore, the heat source or the heat-dissipating member may be abutted and combined in a specific application to meet the user's multiple use requirements. The addition of the planar heat conduction portion 23 in this example is relative to the heat conduction seat. 50 can be an auxiliary gain relationship, or a mutual relationship, depending on the user's decision.

Advantages of the Invention: The "multi-tube parallel type heat equalizing device" disclosed in the present invention mainly comprises an innovative unique structure composed of the at least three pipes, the first connecting member, the second connecting member, the working fluid and the heat conducting seat. The type and technical features enable the present invention to be more easily activated by the multi-directional circulating space type formed by the multi-catheter communication structure in comparison with the conventional structure proposed in [Prior Art]. It is practical and progressive to avoid the problem of starting dead point, and its duct structure has the advantage of easily shaping the curved appearance to meet the needs of multiple installation environments.

A‧‧‧Multi-tube parallel type soaking device

10, 10B‧‧‧ catheter

11‧‧‧ first end

12‧‧‧ second end

14‧‧‧Bending parts

15‧‧‧Troughed capillary structure

16‧‧‧heated evaporation section

17‧‧‧Heat cooling section

20, 20B‧‧‧ first connected components

21‧‧‧First plug hole

22‧‧‧First Link

23‧‧‧planar heat conduction

30, 30B‧‧‧Second connected components

31‧‧‧Second plug hole

32‧‧‧Second link

40‧‧‧ working fluid

50, 50B‧‧‧heat conduction seat

51, 51B‧‧‧ heat conduction surface

52‧‧‧Abutment

53‧‧‧ embedded groove

54‧‧‧Ringed flange

60‧‧‧heat source

70‧‧‧heating components

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view of a combination of preferred embodiments of the present invention. Figure 2 is an exploded perspective view of a preferred embodiment of the present invention. Figure 3 is a partial cross-sectional view of a preferred embodiment of the present invention. Figure 4 is a partial cross-sectional view of a preferred embodiment of the present invention. Figure 5 is a partial cross-sectional view of a preferred embodiment of the present invention. Fig. 6 is a view showing an embodiment in which a catheter of the present invention is formed with a curved portion. Fig. 7 is a view showing an embodiment in which a groove-like capillary structure is provided in the catheter of the present invention. Figure 8 is a diagram showing an embodiment of an application state of the present invention. Fig. 9 is a view showing an embodiment in which the second communicating member of the present invention is closed by the two ends of the pipe body. Fig. 10 is a view showing an example in which a planar heat conducting portion is provided outside the first communicating member of the present invention.

Claims (10)

A multi-tube parallel type soaking device comprising: at least three pipes in a side-by-side configuration, each of which includes a first end and a second end; a first connecting member connected to the at least a first end of the three conduits, at one side of the first connecting member, at least three first insertion holes for respectively communicating the first ends of the at least three conduits, and the first connecting member has a inside a first connecting passage is connected to each of the first insertion holes; a second connecting member is connected to the second end of the at least three conduits, and the second connecting member is provided with the second end of the at least three conduits At least three second insertion holes that are respectively connected to the alignment plug, and a second connection channel inside the second communication member is connected to each of the second insertion holes; a working fluid is accommodated in the free state At least three conduits and the first communication member and the second communication member are internal, and the at least three conduits and the first communication member and the second communication member are in a vacuum state; and at least one heat conduction seat is straddle Abutting in parallel configuration The state of the at least one conduit at least three, each of the thermally conductive base comprises a thermally conductive surface and a corresponding one of the conduit abutment surface. The multi-tube parallel type heat equalizing device according to claim 1, wherein the outer diameter of the at least three conduits is between 3 mm and 10 mm, and the length is between 100 mm and 1000 mm. The multi-tube parallel type heat equalizing device according to claim 2, wherein the outer side of at least one of the first communicating member or the second communicating member is further provided with a planar heat conducting portion. The multi-tube parallel type heat equalizing device according to claim 3, wherein the abutment surface of the heat conducting seat is further provided with at least three recessed grooves for embedding one side of the at least three tubes, and each recessed surface The two sides of the opening of the groove are further deformed by a rolling means to respectively form a riveted flange for resisting the corresponding conduit. The multi-tube parallel type heat equalizing device of claim 4, wherein the at least three ducts comprise a heated evaporating section and a heat dissipating cooling section, so that the thermally conductive seat is coupled to the heated evaporation. At least one of the segment or the cooling cooling section. The multi-tube parallel type heat equalizing device according to claim 5, wherein the at least three ducts further form one or more curved portions corresponding to the tube segments outside the heat conducting seat. The multi-tube parallel type heat equalizing device according to claim 6, wherein each of the ducts is further provided with a groove-like capillary structure. The multi-tube parallel type heat equalizing device according to claim 7, wherein the ratio of the working liquid phase to the internal space volume of the at least three conduits and the first connecting member and the second connecting member is Between 10% and 80%. The multi-tube parallel type heat equalizing device according to claim 1, 2, 3, 4, 5, 6, 7, or 8, wherein the first connecting member and the second connecting member are rectangular hollow shells Type. The multi-tube parallel type heat equalizing device as described in claim 1, 2, 3, 4, 5, 6, 7, or 8, wherein the first connecting member and the second connecting member are by the tube body The type formed by closing the end.