TWI613954B - Cooling water cooling row structure - Google Patents

Abstract

The heat-dissipating water-cooling row structure comprises a first cover member, a second cover member and a plurality of heat-dissipating members stacked to form a heat-dissipating water-cooling row body, wherein the first cover member, the plurality of heat-dissipating members and the second cover member are sequentially Stacked and connected by a heat treatment method, one side of the first and second cover members are respectively connected to the upper side and the lower side of the heat-dissipating water-cooling discharge body, and are used for sealing the heat-dissipating water-cooled discharge body to form at least one of the plurality of internal disturbances The top side and the bottom side of the flow path of the flow area, a first joint portion may be disposed on the first cover member or one end of the heat dissipation water-cooling row body, and a second joint portion is selectively disposed on the first cover member or heat-dissipating The other end of the water-cooling row body, and the first and second joints communicate with the flow channel.

Description

Cooling water cooling row structure

The invention relates to a heat dissipating water cooling row structure, in particular to a heat dissipating water cooling row structure with good heat dissipating effect.

With the rapid development of high-tech industries such as computer information and the expansion of its application range, computer devices are processing data faster and faster. At present, the volume of electronic components inside computer equipment tends to be miniaturized, and the density of integrated circuits (ICs) is relatively increased, and the amount of heat generated per unit area is relatively increased. If the large amount of heat generated by the electronic components is not dissipated in time, the electronic components will be damaged and the computer device will not operate.

In order to reduce the operating temperature of the heat-generating electronic components, a water-cooled device is used in the market to connect a water pump (pump) and a water-cooling head through a water-cooled drain to drive a water-cooled liquid (or working fluid) through a pump. Dissipate heat on the water-cooled platoon and continuously circulate cooling to dissipate heat quickly. Referring to FIG. 1 , the conventional water-cooling row 1 is mainly composed of three independent components, that is, a plurality of fins 11 , a plurality of flat tubes 12 and two side water tanks 13 which are formed by bending, and the heat dissipation. The fins 11 are disposed between the flat tubes 12, and the heat dissipating fins 11 are bent and welded by soldering between the outer side of the bending point and the outer side of the corresponding flat tube 12 The two side water tanks 13 and the heat dissipating fins 11 and the two sides of the flat tubes 12 are also welded by soldering, so that the two side water tanks 13 and the heat dissipation are formed. The fins 11 and the flat tubes 12 are connected to form the water-cooled row 1 and on one side of the water tank 13 A water inlet 131 and a water outlet 132 are provided. The water inlet 131 and the water outlet 132 are respectively connected to the opposite water conduits (not shown).

Although it is known that the working liquid in the flat tubes 12 of the water-cooling row 4 is conducted to the heat-dissipating fins 11 for heat dissipation, another problem that extends is that the heat of the working liquid is conducted to the heat-dissipating fins. The heat transfer efficiency of the sheet 11 is not good. Since the heat dissipation fins 11 and the flat tubes 12 are soldered by two separate components, the heat dissipation fins 11 are not part of the flat tubes 12 themselves. Therefore, the flat tubes 12 conduct heat to the heat dissipating fins 11 to cause thermal resistance, so that the flat tubes 12 conduct heat absorbed into the water cooling liquid to the heat dissipating fins 11 on both sides. The heat transfer efficiency is poor, which in turn leads to a problem of a decrease in the heat release efficiency (or a decrease in heat exchange efficiency) of the entire water-cooled row 1. In addition, since the heat dissipating fins 11 are welded to the outside of the flat tubes 12 on both sides through the outer side of the bending point, the intermediate portion 111 of the heat dissipating fins 11 is relatively weak in structure and is easily damaged by external force collision ( The problem of deformation, and the heat conduction effect between the equal flat tubes 12 and the heat radiating fins 11 is also extremely unsatisfactory.

Furthermore, the conventional water-cooled row 1 is composed of three separate components, which makes the assembly process complicated and also takes a lot of time and labor, and is also prone to water leakage.

Accordingly, in order to effectively solve the above problems, it is an object of the present invention to provide a heat-dissipating water-cooling row structure with excellent heat-dissipating efficiency.

Another object of the present invention is to provide a heat-dissipating water-cooling row structure having improved heat transfer efficiency and increased fin structure strength.

In order to achieve the above object, the present invention provides a heat-dissipating water-cooling row structure, comprising a first cover member, a second cover member and a plurality of heat-dissipating members, wherein the heat-dissipating members are stacked to form a heat-dissipating water-cooling row body, and each of the heat-dissipating members has At least one groove and a plurality of spoilers, the groove penetrating through each of the heat dissipating members, wherein the spoiler is disposed at the The trenches are stacked in the trenches, and the trenches are stacked to form at least a first-class track. The spoiler portions of the heat dissipating members are stacked to form a plurality of spoiler regions in the flow channel, and one side of the first and second cover members Connected to the upper side and the lower side of the corresponding heat-dissipating water-cooling row body, respectively, to close the top side and the bottom side of the flow channel, and a first joint portion is selectively disposed on the first cover member or one end of the heat-dissipating water-cooling row body, A second joint is selectively disposed on the first cover member or the other end of the heat-dissipating water-cooling row body; and the design of the structure of the present invention enables effective heat-dissipating effect to be achieved.

The present invention further provides a heat-dissipating water-cooling row structure, comprising a first cover member, a second cover member and a plurality of heat-dissipating members, wherein the heat-dissipating members are stacked to form a heat-dissipating water-cooling row body, each of the heat-dissipating members having a plurality of grooves, The plurality of spoilers and the at least one communication channel are connected to the trenches, and the trenches are formed in the heat dissipating members, and the spoiler portions are disposed in the trenches, and the trenches of the heat dissipating members The stacking of the slots forms a plurality of flow channels, and the plurality of spoiler sections are stacked to form a plurality of spoiler zones, wherein the plurality of spoiler zones are stacked to form a communicating waterway, and one side of the first and second cover members are respectively connected to each other. The upper side and the lower side of the water-cooling water discharge body should be disposed to close the flow channel and the top side and the bottom side of the communication water channel, and a first joint portion is selectively disposed on the first cover member or the heat-dissipating water-cooling row body is correspondingly connected One side of the water channel, the plurality of second joint portions are selectively disposed on the first cover member or the one end of the flow passages away from the communication water passage; and the design of the structure of the present invention makes it effective to achieve the effect of good heat release performance.

In one implementation, each of the heat dissipating members has a plurality of first fin portions, and the first fin portions are formed to protrude outward from sides of the heat dissipating members adjacent to the trenches, and the first The fin portions are formed with a bare space therebetween.

In one embodiment, the first and second joint portions are respectively disposed on the first cover member, and the first and second joint portions respectively have a first water guiding hole and a second water guiding hole, the first and second water guiding holes The first and second water guiding holes are respectively connected to one end and the other end of the flow path of the heat dissipating water cooling row body.

In one embodiment, the first and second joint portions are respectively formed at one end and the other end of the flow passage of the heat-dissipating water-cooling row body, and the first and second joint portions respectively communicate with one end and the other end of the flow channel.

In one implementation, the shape of each of the spoilers is a V-shape, a diagonal line, a curved shape or other geometric shape, and the spoiler of each heat sink is adjacent to the other heat sink. The spoilers are stacked in opposite directions to each other to form the aforementioned plurality of spoiler regions.

In one implementation, the spoilers are a convex body, and the spoiler stacks of each of the spoiler regions are annularly protruded from the peripheral wall in the flow channel.

In one implementation, the first cover member has at least one first flow channel cover portion and a plurality of second fin portions, and one side of the first flow channel cover portion is connected to an upper side corresponding to the heat dissipation water cooling discharge body to close the opposite a top side of the flow path, and the first and second joint portions are respectively disposed on the front end and the end of the first flow path cover portion, and the second fin portions are convex outward from the side of the first flow path cover portion Stretched.

In one implementation, the second cover member has at least one second flow path cover portion and a plurality of third fin portions, one side of the second flow path cover portion is connected to a lower side corresponding to the heat dissipation water-cooling discharge body, The bottom side of the flow passage is closed, and the third fin portions are formed to protrude outward from the side edges of the second flow passage cover portion.

In one embodiment, the first and second cover members are respectively formed by a metal material, the heat dissipation members are a metal material, and the second cover member and the heat dissipation member and the first cover are The components are sequentially connected from the bottom to the top by a heat treatment to form the heat dissipating water cooling row structure.

2‧‧‧Heat cooling water cooling structure

21‧‧‧First cover

211‧‧‧First runner cover

212‧‧‧second fin section

213‧‧‧First Waterway Cover

22‧‧‧Second cover

221‧‧‧Second runner cover

222‧‧‧ Third Fin Section

223‧‧‧Second Waterway Cover

24‧‧‧heating water cooling body

24a‧‧‧heat sink

241a‧‧‧First Fin section

242a‧‧‧ trench

243a‧‧‧Connecting slot

244a‧‧‧Surveying Department

245a‧‧‧ spoiler area

246a‧‧‧ runner

247a‧‧‧Connected waterways

248a‧‧‧ naked room

25‧‧‧ First Joint Department

251‧‧‧First water guiding hole

26‧‧‧Second junction

261‧‧‧Second water guiding hole

Figure 1 is a schematic perspective view of a conventional water-cooled row combination.

Fig. 2 is an exploded perspective view showing the first embodiment of the present invention.

Fig. 2A is a partially enlarged schematic view of Fig. 2 of the present invention.

Fig. 2B is a partially enlarged schematic view of Fig. 2 of the present invention.

Fig. 3A is a perspective view showing the combination of the first embodiment of the present invention.

Fig. 3B is a top plan view showing a partial cross section of the first embodiment of the present invention.

Fig. 4 is a perspective view showing another combination of the first embodiment of the present invention.

Fig. 5 is an exploded perspective view showing a second embodiment of the present invention.

Fig. 6A is a perspective view showing the combination of the second embodiment of the present invention.

Figure 6B is a top plan view showing a partial cross section of a second embodiment of the present invention.

Figure 7 is a perspective view showing another combination of the second embodiment of the present invention.

The above object of the present invention, as well as its structural and functional features, will be described in accordance with the preferred embodiments of the drawings.

The present invention provides a heat dissipating water cooling row structure, please refer to FIGS. 2 and 3A, which is a schematic exploded view of the first embodiment of the present invention, and is supplemented with reference to the 2A, 2B, and 3B drawings; The structure 2 includes a first cover member 21, a second cover member 22, a first joint portion 25, a second joint portion 26, and a plurality of heat sink members 24a. The heat sink members 24a are stacked to form a heat-dissipating water-cooling row body 24. The heat dissipating members 24a are represented in the embodiment as a sheet made of a metal material (such as copper, aluminum, stainless steel, magnesium aluminum alloy, titanium or other ductile, thermally conductive material or other composite material, etc.). Each of the heat dissipating members 24a has at least one groove 242a, a plurality of first fin portions 241a and a plurality of spoiler portions 244a, and the first fin portions 241a are from two of the heat dissipating members 24a adjacent to the groove 242a. The side edges are outwardly convexly configured to dissipate the absorbed heat outwardly, and the first fin portions 241a are formed with a bare space 248a therebetween for allowing the outside air to pass through. , the outer air fluid is quickly exchanged with the corresponding first fin portion 241a heat. And the groove 242a in the embodiment shows that the heat sink 24a has a curved groove thereon. 242a, the trench 242a is formed on each of the heat dissipating members 24a, and both ends (ie, the front end and the end) of the trench 242a are respectively disposed on the same side of each of the heat dissipating members 24a, and the trenches 242a are stacked to form at least The flow path 246a is shown as a curved flow path 246a in this embodiment. In a specific implementation, the groove 242a may be designed in advance according to heat dissipation and space requirements, such as two or more adjustment grooves 242a, and the shape of the groove 242a may also be selected as an arc shape, a W shape, such as V shape or other shape.

The spoiler 244a is integrally connected to the groove 242a of each of the heat dissipating members 24a. The spoiler portions 244a of the heat dissipating members 24a are stacked to form a plurality of spoiler regions 245a located in the flow channel 246a. The shape of each of the spoilers 244a is shown as a diagonal line in the embodiment. The spoiler 244a of each of the heat sinks 24a is in the shape of a left oblique line and adjacent to each of the other heat sinks 24a. The equal turbulence portion 244a has a direction opposite to the right oblique line, and sequentially forms the aforementioned turbulence region 245a from the bottom to the top in a reverse-staggered stack (as shown in FIG. 3B). In one embodiment, the shape of each of the spoilers 244a may also be designed as a V-shape, a curved shape or other geometric shapes. For example, the spoiler 244a of each heat sink 24a is in a positive V shape and adjacent to each other. The spoiler portion 244a of each of the heat dissipating members 24a has an inverted V-shaped opposite direction, and sequentially forms the aforementioned spoiler region 245a from the bottom to the top. In another embodiment, each of the spoiler portions 244a is a convex body, and the spoiler portions 244a of each of the spoiler regions 245a are stacked in a ring shape on the peripheral wall of the flow channel 246a. Therefore, when a working liquid (such as pure water or other water-cooled liquid) flows through the flow passage 246a through the spoiler 245a, the working fluid will flow and hit the spoiler 244a to generate eddy current, thereby slowing down the work. The flow rate of the liquid and increased flow time.

The first and second cover members 21, 22 and the heat dissipating members 24a are stacked to form the heat dissipating water cooling row structure 2, in other words, the second cover member 22 and the heat dissipating members 24a and the first cover member 21 The heat-dissipating water-cooling row structure 2 is integrally formed by bottom-up stacking by a heat treatment method (such as an atmosphere furnace or a vacuum furnace or other suitable heat treatment method according to materials), and the first and second cover members 21, One side of the 22 is respectively connected to the upper side and the lower side of the corresponding heat-dissipating water-cooling body 24 to close the top side and the bottom side of the flow path 246a. in Alternative embodiments may also be designed as two or more of the aforementioned flow passages 246a, and the number of the flow passages 246a is defined following the number of grooves 242a on each heat sink 24a, such as each heat sink 24a. There are 2 (or 2) grooves 242a on the stack, and 2 (or 2) flow channels 246a are stacked, and so on.

The first cover member 21 is a piece made of a metal material (such as copper, aluminum, stainless steel, magnesium aluminum alloy, titanium or other ductile, thermally conductive material or other composite material, etc.) in this embodiment. The first cover member 21 has at least one first flow channel cover portion 211 and a plurality of second fin portions 212. The second fin portions 212 protrude outward from the side edges of the first flow channel cover portion 211. And corresponding to the first fin portion 241a, the first flow channel cover portion 211 corresponds to the flow channel 246a, and one side of the first flow channel cover portion 211 is connected to the upper side corresponding to the heat dissipation water-cooling discharge body 24, The top side of the flow passage 246a is closed. The second cover member 22 is shown in the embodiment as a sheet made of a metal material (such as copper, aluminum, stainless steel, magnesium aluminum alloy, titanium, etc.), and the second cover member 22 has at least one second flow passage cover. a portion 221 and a plurality of third fin portions 222, the third fin portions 222 projecting outwardly from the side edges of the second flow channel cover portion 221, and opposite to the first fin portions 241a, and One side of the second flow path cover portion 221 is connected to the lower side of the heat dissipation water-cooling discharge body 24 to close the bottom side of the flow path 246a. The second and third fin portions 212 and 222 are configured to dissipate the absorbed heat outward.

In addition, the first joint portion 25 is disposed on the first cover member 21 or one end of the heat dissipation water-cooling row body 24, and the first joint portion 25 of the present embodiment is provided with a flow formed on the heat-dissipating water-cooling row body 24. One end of the channel 246a, and the second joint portion 26 is disposed on the first cover member 21 or the other end of the heat-dissipating water-cooling row body 24. The second joint portion 26 of the present embodiment is disposed on the heat-dissipating water-cooling row. The other end of the flow path 246a of the body 24. And the first bonding portion 25 is configured to guide a working liquid (such as pure water or other water-cooled liquid) to flow into the corresponding flow channel 246a, and then discharged by the second bonding portion 26, and the first and second joint portions 25 and 26 are respectively connected to one end and the other end of the flow passage 246a, and the first joint portion 25 communicates with the second joint portion 26 through the flow passage 246a. In an embodiment, as shown in FIG. 4, with reference to FIGS. 2 and 3B, the first and second joint portions 25 and 26 are respectively designed and disposed on the first cover member 21, that is, the first and second joints. Department 25, And a first water guiding hole 251 and a second water guiding hole 261 are respectively formed on the front end and the end of the first flow path cover portion 211 of the first cover member 21, respectively. The first and second water guiding holes 251 and 261 are respectively formed on the first and second joint portions 25 and 26, and the first and second water guiding holes 251 and 261 respectively communicate with the flow path of the heat dissipating water cooling main body 24. One end of the 246a and the other end.

In the actual implementation of the present invention, the first and second joint portions 25 and 26 are respectively connected and connected to the outlet and the inlet of a corresponding water-cooling head (not shown) through two water conduits (not shown). One side of the water-cooling head contacts the heat of a heat-generating component (such as a central processing unit or a graphic display wafer), and the working liquid in the water-cooling head absorbs the heat and passes through a pump in the water-cooling head. The pump (or the pumping of the water-cooling head) drives the hot working liquid to flow through the first joint portion 25 into the flow passage 246a of the heat-dissipating water-cooling body 24, and along the curved flow path 246a flows toward the other end of the flow path 246a, and the heat absorbed by the working liquid is conducted to the first, second, and third fin portions 241a, 212, and 222, and the first The second and third fin portions 241a, 212, and 222 are dissipated, and then the cooled working liquid is discharged from the second joint portion 26 into the water-cooling head to circulate continuously to achieve the effect of water cooling.

In another embodiment, the heat-dissipating water-cooling structure 2 is connected to a fan (not shown). The fan is docked above the heat-dissipating water-cooling structure 2, and the fan is forced to dissipate the heat-dissipating water-cooling structure 2 by the fan. .

Therefore, the groove 242a and the first fin portions 241a are formed on each of the heat dissipation members 24a of the present invention, and the second and third portions are formed on the first and second cover members 21 and 22 themselves. The fin portions 212, 222 are designed such that the heat of the working liquid can be directly conducted from each of the heat dissipating members 24a to the first fin portions 241a thereon, and directly conducted by the first and second cover members 21, 22. The second and third fin portions 212 and 222 on the upper portion thereof are effective to greatly improve the overall heat transfer efficiency, thereby improving the heat dissipation efficiency. In addition, through the integrated design of the first and second cover members 21 and 22 and the heat dissipating members 24a of the present invention, the structural strength and heat dissipation effect of the entire heat dissipating water-cooling row structure 1 are effectively increased. Furthermore, by means of the curved flow path 246a, the time during which the working fluid flows in the flow channel 246a can be increased, and further in the flow path 246a. The turbulence zone 245a therein can slow down the flow rate of the working liquid and prolong the flow time, thereby effectively achieving a better heat dissipation effect. In addition, the first and second cover members 21 and 22 and the heat dissipating members 24a may be the same or different metal materials.

Please refer to FIG. 5 and FIG. 6A, which are schematic diagrams of the decomposition and combination of the second embodiment of the present invention, and supplemented with reference to FIG. 6B; the structure and the connection relationship of the embodiment and the functions thereof are substantially the same as the foregoing The same is true for an embodiment, so it will not be described again here. In this embodiment, the structure of the heat dissipating members 24a of the first embodiment is modified to have at least one communication groove 243a and a plurality of grooves 242a. That is, the heat sinks 24a have the plurality of spoiler portions 244a, the plurality of trenches 242a, the plurality of first fin portions 241a, and the at least one communication groove 243a communicating with the trenches 242a, and the trenches 242a are connected thereto. A groove 243a is formed in each of the heat dissipating members 24a, and the spoiler portions 244a are disposed in each of the grooves 242a. The grooves 242a of the heat dissipating members 24a are stacked to form a plurality of flow channels 246a. The heat dissipating members 24a are formed. The plurality of spoiler portions 244a are stacked to form a plurality of spoiler regions 245a located in each of the flow channels 246a. The communication channels 243a are stacked to form a communication channel 247a. The communication channel 247a is shown in the embodiment as the channel 246a. Arranged vertically to each other. One side of the first and second cover members 21, 22 is respectively connected to the upper side and the lower side of the corresponding heat-dissipating water-cooling discharge body 24 to close the top side and the bottom side of the flow passage 246a and the communication water passage 247a.

The first cover member 21 of the first embodiment is mainly designed to change the structure of the first cover member 21 of the first embodiment to have a waterway cover portion and a plurality of first flow path cover portions 211, that is, the first cover member 21 The cover member 21 has the plurality of second fin portions 212, the plurality of first flow passage cover portions 211, and a first waterway cover portion 213, and the first flow passage cover portions 211 correspond to the equal flow passages 246a, and the same The first side cover portion 211 and one side of the first water channel cover portion 213 are respectively connected to the upper side corresponding to the heat dissipation water-cooling discharge body 24 to close the top side of the flow path 246a and the top side of the communication water passage 247a. The second cover member 22 of the first embodiment is mainly configured to change the structure of the second cover member 22 of the first embodiment to a waterway cover portion and a plurality of second flow path cover portions 221, that is, the second cover member. The member 22 has the plurality of third fin portions 222, the plurality of second flow passage cover portions 221, and a second water passage cover portion 223, and the second flow passage cover portions 221 correspond to the equal flow passages 246a, and the second portions Runner The cover portion 221 and one side of the second waterway cover portion 223 are respectively connected to the lower side of the heat-dissipating water-cooling discharge body 24 to close the bottom side of the flow passage 246a and the bottom side of the communication water passage 247a.

In addition, a first joint portion 25 is disposed on the first cover member 21 or a side of the heat-dissipating water-cooling row body 24 corresponding to the water passage 247a. The first joint portion 25 of the embodiment is formed in the heat-dissipating water-cooling. The discharge body 24 corresponds to a side that communicates with the water passage 247a, and the first joint portion 25 communicates with the communication water passage 247a, and the plurality of second joint portions 26 are selectively disposed on the first cover member 21 or the flow passages 246a. The second joint portion 26 of the present embodiment is formed at one end of the flow passage 246a away from the communication water passage 247a, and each of the second joint portions 26 communicates with the respective flow passages 246a. The other end of the flow passage 246a is connected to the communication passage 247a and communicates with the first joint portion 25, and the first joint portion 25 communicates with the second joint portion 26 through the communication passage 247a and the flow passage 246a. In an embodiment, as shown in FIG. 7, the first joint portion 25 and the second joint portion 26 are selectively disposed on the first cover member 21, that is, the first joint portion 25 is disposed at the first The second joint portion 26 of the cover member 21 is disposed on an end of the first cover member 211 of the first cover member 21 away from the first waterway cover portion 213, and The first joint portion 25 has a first water guiding hole 251, and each of the second joint portions 26 has a second water guiding hole 261, and the first water guiding hole 251 and the second water guiding hole 261 are respectively formed through the corresponding portion. a joint portion 25 and each of the second joint portions 26, and the first water guiding hole 251 and each of the second water guiding holes 261 are respectively communicated with the communication water passage 247a and one end of each of the flow passages 246a, and the communication water passage 247a is connected. Relative to the flow channels 246a.

In the actual implementation of the present invention, the first joint portion 25 and the second joint portion 26 are respectively connected to the outlet and the inlet of a corresponding water-cooling head (not shown) through a plurality of water conduits (not shown). And communicating, such that one side of the water-cooling head contacts the heat of the heat-absorbing element (such as a central processing unit or a graphic display chip), and the working liquid in the water-cooling head absorbs the heat and passes through the water-cooled head. a pump (or a pumping of the peripheral water in the water-cooling head) drives the working liquid with heat to pass through the first joint portion 25 and then through the communicating water passage 247a of the heat-dissipating water-cooling body 24 and the flow passages 246a. And along the flow passages 246a toward the other end of the flow passage 246a, the heat absorbed by the working liquid is transmitted. Leading to the first, second, and third fin portions 241a, 212, 222, and ejecting through the first, second, and third fin portions 241a, 212, 222, and then cooling the working liquid The second joint portion 26 discharges the backflow into the water-cooling head and continuously circulates to achieve the effect of water cooling.

Therefore, through the integrated design of the first and second cover members 21 and 22 and the heat dissipating members 24a of the present invention, the multi-functional design and the effect of effectively increasing the structural strength of the entire heat-dissipating water-cooling row structure 2 are effective. Improve heat transfer efficiency.

2‧‧‧Heat cooling water cooling structure

21‧‧‧First cover

211‧‧‧First runner cover

212‧‧‧second fin section

22‧‧‧Second cover

221‧‧‧Second runner cover

222‧‧‧ Third Fin Section

24‧‧‧heating water cooling body

24a‧‧‧heat sink

241a‧‧‧First Fin section

242a‧‧‧ trench

244a‧‧‧Surveying Department

248a‧‧‧ naked room

Claims (21)

A heat dissipating water cooling row structure comprises a first cover member, a second cover member and a plurality of heat dissipating members, wherein the heat dissipating members are stacked to form a heat dissipating water cooling row body, wherein each heat dissipating member has at least one groove and a plurality of spoilers a trench is formed in each of the heat dissipating members, the spoiler is disposed in the trench, and the trenches are stacked to form at least a first-class track, and the spoiler portions of the heat dissipating members are stacked to form a complex The flow area is located in the flow channel, and one side of the first and second cover members are respectively connected to the upper side and the lower side of the corresponding heat-dissipating water-cooling discharge body to close the top side and the bottom side of the flow path, and a first combination The portion is disposed on the first cover member or one end of the heat-dissipating water-cooling row body, and a second joint portion is selectively disposed on the first cover member or the other end of the heat-dissipating water-cooling row body. The heat-dissipating water-cooling row structure according to claim 1, wherein each of the heat dissipating members has a plurality of first fin portions, and the first fin portions are from sides of the heat dissipating members adjacent to the grooves The side is convex outward, and the first fin portions are formed with a bare space therebetween. The heat-dissipating water-cooling row structure according to claim 2, wherein the first and second joint portions are respectively disposed on the first cover member, and the first and second joint portions respectively have a first water guiding hole and a first a second water guiding hole, wherein the first and second water guiding holes are respectively formed on the first and second joint portions, and the first and second water guiding holes respectively communicate with one end and the other end of the flow channel of the heat radiating water cooling row body . The heat-dissipating water-cooling row structure according to claim 2, wherein the first and second joint portions are respectively formed at one end and the other end of the flow path of the heat-dissipating water-cooling row body, and the first and second joint portions are Do not connect one end to the other end of the flow channel. The heat-dissipating water-cooling row structure according to claim 4, wherein each of the spoiler portions has a shape of a V-shape, a diagonal line, a curved shape or the like, and the interference of each of the heat dissipating members The flow portions and the spoiler portions adjacent to the other heat sink are stacked in opposite directions to each other to constitute the plurality of spoiler regions. The heat-dissipating water-cooling row structure of claim 4, wherein the spoiler is a convex body, and the stack of the spoiler portions of each of the spoiler regions is annularly protruded in the flow channel. On the wall of the week. The heat-dissipating water-cooling row structure of claim 3, wherein the first cover member has at least one first flow channel cover portion and a plurality of second fin portions, and the second fin portions are from the first flow channel cover The side of the portion is outwardly convexly formed, and one side of the first flow passage cover portion is connected to an upper side corresponding to the heat-dissipating water-cooling discharge body to close the top side opposite to the flow passage, and the first and second joint portions It is not disposed on the front end and the end of the first flow path cover. The heat-dissipating water-cooling row structure according to claim 7, wherein the second cover member has at least one second flow path cover portion and a plurality of third fin portions, one side and a pair of the second flow path cover portion The lower side of the heat-dissipating water-cooling row body is connected to close the bottom side of the flow path, and the third fin portions are formed to protrude outward from the side edges of the second flow-path cover portion. The heat-dissipating water-cooling row structure of claim 4, wherein the first cover member has at least one first flow path cover portion and a plurality of second fin portions, and one side of the first flow path cover portion and the corresponding heat dissipation portion The upper sides of the water-cooled row bodies are connected to close the top side of the flow channels. The heat-dissipating water-cooling row structure according to claim 9, wherein the second cover member has at least one second flow channel cover portion and a plurality of third fin portions, one side of the second flow channel cover portion The lower side of the heat-dissipating water-cooling row body is connected to close the bottom side of the flow channel, and the third fin portions are formed to protrude outward from the side edges of the second flow-path cover portion. The heat-dissipating water-cooling row structure according to claim 1, wherein the first and second cover members are respectively formed by a metal material, the heat dissipation members are a metal material, and the second The cover member and the heat dissipating member and the first cover member are sequentially connected from the bottom to the top by a heat treatment to form the heat dissipating water cooling row structure. A heat-dissipating water-cooling row structure comprises a first cover member, a second cover member and a plurality of heat-dissipating members, wherein the heat-dissipating members are stacked to form a heat-dissipating water-cooling row body, wherein each heat-dissipating member has a plurality of grooves and a plurality of spoilers And the at least one communication channel is connected to the trenches, the trenches and the communication trenches are formed in the heat dissipating members, and the spoiler portions are disposed in the trenches, and the trenches of the heat dissipating members The stacking of the plurality of channels forms a plurality of flow channels, and the plurality of spoiler portions of the heat dissipating members are stacked to form a plurality of spoiler regions, wherein the plurality of spoiler cells are stacked to form a communicating water channel, and the first and second cover members are The sides are respectively connected to the upper side and the lower side of the corresponding heat-dissipating water-cooling row body to close the flow channels and the top side and the bottom side of the connecting water channel, and a first joint portion is selectively disposed on the first cover member or the heat dissipation The water-cooling row body corresponds to a side that communicates with the water channel, and the plurality of second joint portions are selectively disposed on the first cover member or the one end of the flow channel away from the connecting water channel. The heat-dissipating water-cooling row structure according to claim 12, wherein each of the heat dissipating members has a plurality of first fin portions, and the first fin portions are from sides of the heat dissipating members adjacent to the grooves The side is convex outward, and the first fin portions are formed with a bare space therebetween. The heat-dissipating water-cooling row structure of claim 13 , wherein the first joint portion and the second joint portion are respectively disposed on the first cover member, and the first joint portion has a first water guide hole Each of the second joint portions has a second water guiding hole, and the first water guiding hole and each of the second water guiding holes are respectively formed on the corresponding first joint portion and each of the second joint portions, and the first The water guiding hole and each of the second water guiding holes respectively communicate with the communication water channel and one end of each of the flow channels, and the communication water channel communicates with the flow channels. The heat-dissipating water-cooling row structure according to claim 13 , wherein the first joint portion and the second joint portion are respectively formed on a side of the heat-dissipating water-cooling row body corresponding to the water channel and away from the flow channel One end of the water channel is connected, and the first joint portion and each of the second joint portions communicate with the communication water passage and one end of each of the flow passages, and the other ends of the flow passages are connected to and communicate with the communication water passage. The heat-dissipating water-cooling row structure according to claim 13, wherein each of the spoiler portions has a shape of a V-shape, a diagonal line, a curved shape or the like, and the interference of each of the heat dissipating members The flow portions and the spoiler portions adjacent to the other heat sink are stacked in opposite directions to each other to constitute the plurality of spoiler regions. The heat-dissipating water-cooling row structure according to claim 13 , wherein the spoiler is a convex body, and the stack of the spoiler portions of each of the spoiler regions is annularly protruded in each of the flow channels. On the perimeter wall. The heat-dissipating water-cooling row structure according to claim 14, wherein the first cover member has a plurality of first flow channel cover portions, a first water channel cover portion and a plurality of second fin portions, and the first flow channel cover portions And a side of the first waterway cover portion is respectively connected to an upper side corresponding to the heat-dissipating water-cooling discharge body to close a top side of the flow channel and a top side of the communication water channel, And the first joint portion is disposed on the first waterway cover portion, and the second joint portion is disposed on an end of the first flow passage cover portion away from the first waterway cover portion. The heat-dissipating water-cooling row structure according to claim 18, wherein the second cover member has a plurality of second flow channel cover portions, a second water channel cover portion and a plurality of third fin portions, and the second flow paths The cover portion and one side of the second waterway cover portion are respectively connected to the lower side of the corresponding heat-dissipating water-cooling discharge body to close the bottom side of the flow channel and the bottom side of the communication water channel, and the third fins The portion is formed to protrude outward from the side of each of the second flow path cover portions. The heat-dissipating water-cooling row structure according to claim 15, wherein the first cover member has a plurality of first flow channel cover portions, a first water channel cover portion and a plurality of second fin portions, and the first flow channel cover portions One side of the first waterway cover portion and the upper side corresponding to the heat-dissipating water-cooling discharge body are respectively connected to close the top side of the flow channel and the top side of the communication water channel. The heat-dissipating water-cooling row structure according to claim 20, wherein the second cover member has a plurality of second flow channel cover portions, a second water channel cover portion and a plurality of third fin portions, and the second flow paths The cover portion and one side of the second waterway cover portion are respectively connected to the lower side of the corresponding heat-dissipating water-cooling discharge body to close the bottom side of the flow channel and the bottom side of the communication water channel, and the third fins The portion is formed to protrude outward from the side of each of the second flow path cover portions.