TWI852403B - Heat dissipation net for a heat dissipation water tower - Google Patents

Abstract

A heat dissipation net for a heat dissipation water tower comprises a plurality of ribs arranged in a mesh shape. Each of the ribs at one end of the heat dissipation net has a plurality of side-connected male buckles. Each of the ribs at the other end of the heat dissipation net has a plurality of side female buckles. Each side is connected to a male buckle, and each side-connected female buckle is snap-fitted with each other.

Description

Cooling water tower cooling network

The present invention relates to a heat dissipation net for a heat dissipation water tower, or heat dissipation filler or heat dissipation sheet, which is filled in a heat dissipation water tower to effectively provide a heat dissipation effect.

The cooling water tower is one of the necessary equipment in the water cooling system. In the water cooling system, after the cooling water circulates into the equipment that needs to be cooled, it will take away the heat of the corresponding equipment, which will cause the cooling water temperature to rise. At this time, the heated cooling water enters the cooling water tower to reduce the cooling water temperature and then be sent back to the equipment for cooling.

In common cooling water towers, heat is generally dissipated through heat sinks, cooling fans and other equipment. The heat sink is usually installed below the water outlet, which can extend the stagnation time of water flow and increase the heat dissipation surface area, improve the heat exchange effect with the outside air, and make the water flow evenly to the water collection area below.

Although heat sinks are already a very common product, the heat sinks currently on the market have some problems. For example, in a cylindrical heat sink, a long heat sink is rolled into a cylindrical shape for use. However, the recycling rate of such heat sinks is extremely low. For example, if a larger heat sink is to be replaced, the original heat sink cannot be used. Or, if part of the heat sink is damaged, it can only be thrown away as a whole, which is quite wasteful.

In view of the above problems, it is necessary to improve the problems of known products such as difficult size adjustment and inconvenient maintenance.

The heat sink of the present invention is designed with a plurality of side male buckles and side female buckles on both sides, and each side male buckle and each side female buckle can be interlocked. By utilizing this structural characteristic, when using a plurality of heat sinks, the total length can be extended by only interlocking each side male buckle and each side female buckle of adjacent heat sinks, and the total length can be shortened by removing the connected heat sinks. That is to say, the user can reduce or increase the splicing of the heat sinks according to needs, and easily adapt to the internal space of each heat sink. In addition, during maintenance, only the damaged heat sink needs to be removed. The present invention has indeed improved the problems of the conventional products in that the size is difficult to adjust and the maintenance is inconvenient.

In order to achieve the above-mentioned purpose and effect, the present invention provides a heat dissipation network of a heat dissipation water tower, wherein: the heat dissipation network includes a plurality of ribs arranged in a mesh shape, each rib at one end of the heat dissipation network has a plurality of side male buckles, and each rib at the other end of the heat dissipation network has a plurality of side female buckles, and each side male buckle and each side female buckle can be interlocked.

Furthermore, each rib is arranged in a trapezoidal wave, so that the heat sink has a first peak side and a second peak side.

Furthermore, each side connecting male buckle and each side connecting female buckle are arranged on a rib located at the same peak side position of the first peak side and the second peak side.

Furthermore, the ribs are arranged in triangles and rectangles to form grids to form a network arrangement.

Furthermore, each of the ribs is in the shape of a semi-ellipse.

Furthermore, each rib on the non-sides of the heat sink is provided with a plurality of stacked female buckles and stacked male buckles, and each stacked male buckle and each stacked female buckle can be interlocked.

Furthermore, each stacked male buckle is arranged on a rib located at one of the first peak side and the second peak side, and each stacked female buckle is arranged on a rib located at the other of the first peak side and the second peak side.

Furthermore, the material used for the heat sink has anti-sticking and antibacterial properties.

Furthermore, each side male buckle includes an annular portion, the annular portion has a plurality of claw ribs extending toward the center, the ends of the claw ribs are connected to a buckle body, the ends of the buckle body are connected to a buckle head, the width of the buckle head is larger than the connected buckle body, and a plurality of grooves penetrate the connected buckle heads and buckle bodies, each claw rib portion is located in the corresponding groove, and each side female buckle presents a circular ring shape.

To understand the implementation of the present invention in more detail, please refer to the drawings. As shown in the first to sixth figures, the present invention is a heat dissipation network 1 of a heat dissipation water tower, wherein: the heat dissipation network 1 includes a plurality of ribs 11 arranged in a mesh shape, each rib 11 at one end of the heat dissipation network 1 has a plurality of side male buckles 12, and each rib 11 at the other end of the heat dissipation network 1 has a plurality of side female buckles 13, and each side male buckle 12 and each side female buckle 13 can be interlocked.

The implementation method of the present invention is further described in detail following the above contents. The heat sink 1 of the present invention is designed with a plurality of side male buckles 12 and side female buckles 13 on both sides, and each side male buckle 12 and each side female buckle 13 can be interlocked. By utilizing this structural characteristic, when using a plurality of heat sinks 1, it is only necessary to connect each side male buckle 12 and each side female buckle 13 of the adjacent heat sink 1 as shown in FIG. The total length can be extended by interlocking the female buckles 13, and the total length can be shortened by removing the connected heat sink 1. That is to say, the user can reduce or increase the splicing of the heat sink 1 according to the needs, and it can easily adapt to the internal space of various heat sinks. During maintenance, only the damaged heat sink 1 needs to be removed. The present invention has indeed improved the problems of the conventional products, such as the difficulty in adjusting the size and the inconvenience in maintenance.

As shown in the third and fourth figures, the ribs are arranged in a trapezoidal wave, so that the heat sink 1 has a first peak side 14 and a second peak side 15. The ribs 11 are arranged in a trapezoidal wave, which can effectively increase the heat dissipation effect and is less prone to scale.

As shown in the third and fourth figures, each side male buckle 12 and each side female buckle 13 are arranged on the rib 11 located at the same peak side position of the first peak side 14 and the second peak side 15. For example, in this embodiment, each side male buckle 12 and each side female buckle 13 are all arranged on the first peak side 14. Only when each side male buckle 12 and each side female buckle 13 are all located on the same peak side can they be smoothly spliced as shown in the sixth figure.

As shown in the second figure, it can be clearly seen from the figure that the ribs 11 are arranged in a triangular shape and a rectangular shape to form grids to form a network arrangement, which can effectively increase the heat dissipation effect and is less likely to cause scale.

As shown in FIG. 11 , each rib 11 is in a semi-elliptical (or approximate) shape, which can effectively increase the heat dissipation effect and is less likely to cause scale.

As shown in the first, seventh and eighth figures, each rib 11 of the heat sink 1 is provided with a plurality of stacked female buckles 16 and stacked male buckles 17. Each stacked male buckle 17 and each stacked female buckle 16 can be interlocked with each other and can be stacked upwards in the direction of the arrow in the figure. Since not all heat sinks are cylindrical, it is necessary to provide a stacked connection structure so that the present invention can be applied to heat sinks of different shapes.

Each stacking male buckle 17 is arranged on the rib 11 located at one of the first peak side 14 and the second peak side 15, and each stacking female buckle 16 is arranged on the rib 11 located at the other of the first peak side 14 and the second peak side 15. For example, in this embodiment, each stacking male buckle 17 is located at the first peak side 14, and each stacking female buckle 16 is located at the second peak side 15. Such a design enables each stacking male buckle 17 and each stacking female buckle 16 to be located at different peak sides. In this way, when stacking, only one of the heat dissipation nets 1 needs to be horizontally rotated 180 degrees to stack smoothly, and each space 2 is formed as shown in FIG. 8, thereby effectively producing The stacking height is increased. In combination with the above contents, the ribs 11 of the present invention are arranged in a triangle, a rectangle (or a similar arrangement) to form grids and present a trapezoidal wave arrangement. The spaces 2 generated when multiple heat sinks 1 are stacked make the ribs 11 construct a variety of corner structures. In this way, when water flows through the heat sinks 1 in actual use, it flows back through the aforementioned corners to increase the water retention time. The aforementioned structure can also produce a good ventilation effect at multiple angles. When the fan of the heat sink water tower draws air, it can flow through each space well, greatly increasing the contact opportunity between air and water, thereby achieving a better heat dissipation effect.

Furthermore, the material used for the heat sink 1 has anti-sticking and antibacterial functions.

Furthermore, each side male buckle 12 includes an annular portion 121, and the annular portion 121 has a plurality of claw ribs 122 extending toward the center. The ends of the claw ribs 122 are connected to a buckle body 123, and the ends of the buckle body 123 are connected to a buckle head 124. The width of the buckle head 124 is larger than the connected buckle body 123. There are also a plurality of grooves 125 penetrating each connected buckle head 124 and buckle body 123. Part of each claw rib 122 is located in the corresponding groove 125. Each side female buckle 13 presents a circular ring shape. This structure enables the side male buckle 12 and the side female buckle 13 to be stably engaged and connected, and the design of the claw rib 122 abutting against the groove 125 makes it difficult for the buckle body 123 to be skewed due to force.

The structure of the stacked female buckle 16 is the same as that of the side female buckle 13 , and the structure of the stacked male buckle 17 is the same as that of the side male buckle 12 .

The above is only used to explain the preferred embodiments of the present invention, and is not intended to limit the present invention in any form. Therefore, any modifications or changes made to the present invention under the same spirit of the invention, which are other forms that can be implemented and have the same effect, should still be included in the scope of protection intended by the present invention.

In summary, the "heat dissipation water tower heat dissipation network" of the present invention is indeed fully in line with the needs of industrial development in terms of practicality and cost-effectiveness, and the disclosed structural invention is also an unprecedented innovative structure, so there is no doubt that it is "novel". In addition, the present invention can improve the effectiveness of the commonly used structure, so it is also "progressive". It fully complies with the provisions of the application requirements for invention patents in the Patent Law of our country. Therefore, a patent application is filed in accordance with the law, and we sincerely request the Jun Bureau to review it as soon as possible and give affirmation.

1: Heat sink 11: Ribs 12: Side male buckle 121: Ring 122: Claw ribs 123: Buckle body 124: Buckle head 125: Groove 13: Side female buckle 14: First peak side 15: Second peak side 16: Stacking female buckle 17: Stacking male buckle 2: Space

The first figure is a three-dimensional diagram of the present invention. The second figure is a plan view of the present invention. The third figure is a plan view of the present invention with a male buckle at one end. The fourth figure is a plan view of the present invention with a female buckle at one end. The fifth figure is a schematic diagram of two heat sinks connected. The sixth figure is a schematic diagram of the section of line segment VI-VI in the fifth figure. The seventh figure is a schematic diagram of multiple heat sinks stacked and connected. The eighth figure is a schematic diagram of the section of line segment VIII-VIII in the seventh figure. The ninth figure is a partial enlarged schematic diagram of part A of the first figure. The tenth figure is a partial enlarged schematic diagram of part B of the second figure. The eleventh figure is a schematic diagram of the section of line segment XII-XII in the second figure.

1: Heat dissipation network

11: Ribs

12: Side male buckle

13: Side female buckle

16: Stacking female buckle

17: Stacking male buttons

Claims (8)

A heat dissipation network of a heat dissipation water tower, wherein: the heat dissipation network includes a plurality of ribs arranged in a mesh shape, each rib at one end of the heat dissipation network has a plurality of side male buckles, and each rib at the other end of the heat dissipation network has a plurality of side female buckles, each side male buckle and each side female buckle can be interlocked, wherein each rib also presents a trapezoidal wave arrangement, so that the heat dissipation network has a first peak side and a second peak side. As described in claim 1, the heat sink water tower heat sink network, wherein each side male buckle and each side female buckle are arranged on the rib located at the same peak side position of the first peak side and the second peak side. As described in claim 1, the heat dissipation network of the heat dissipation water tower, wherein the ribs are arranged in triangles and rectangles to form grids to form a network arrangement. As described in claim 1, the heat sink network of the heat sink water tower, each rib of which is in the shape of a semi-ellipse. As described in claim 1, the heat sink of the heat sink has multiple stacked female buckles and stacked male buckles distributed on the ribs on the sides of the heat sink, and each stacked male buckle and each stacked female buckle can be interlocked. As described in claim 1, the heat sink water tower heat sink network, wherein each stacked male buckle is arranged on a rib located at one of the first peak side and the second peak side, and each stacked female buckle is arranged on a rib located at the other of the first peak side and the second peak side. As described in claim 1, the heat sink of the heat sink, wherein the material used in the heat sink has anti-stick and antibacterial functions. As described in claim 1, the heat sink water tower heat sink net, wherein each side male buckle includes an annular portion, the annular portion has a plurality of claw ribs extending toward the center, the ends of each claw rib are connected to a buckle body, the ends of the buckle body are connected to a buckle head, the width of the buckle head is larger than the connected buckle body, and there are a plurality of grooves through each connected buckle head and buckle body, each claw rib portion is located in the corresponding groove, and each side female buckle presents a circular ring shape.