RU2794348C1 - Combined finned radiator and communication base station - Google Patents

Abstract

FIELD: heat-radiating technologies.

SUBSTANCE: invention is related in particular to a combined finned radiator and to a communication base station containing it. Combined finned radiator contains a main plate (1) containing an edge rib (4), the first heat-radiating unit located on the main plate (1) and containing a plurality of the first straight fins (21) and a plurality of the first air channels (22), each of which is formed between two adjacent first straight ribs (21). The second heat-radiating block is located on the main plate (1) and adjacent to the first heat-radiating block, and the second heat-radiating block contains two symmetrically located groups of inclined ribs and the second air channel (31) formed between two groups of inclined ribs. Each of the groups of inclined ribs contains a plurality of inclined ribs (32) and a plurality of third air channels (33), each of which is formed between two adjacent of the inclined ribs (32), and the third air channels (33) contain air outlets located at a distance from centre of symmetry of groups of inclined edges. Some of the first air channels (22) are in communication with the second air channel (31) and the rest of the first air channels (22) are respectively in communication with the adjacent third air channels (33). The fourth air channel (41) is formed between the edge rib (4) located on both sides of the second heat radiating unit and the air outlets of the third air channels (33), the fourth air channel (41) being located on both sides of the main plate (1), and the first air channels (22) and the fourth air channels (41) located on both sides of the first heat radiating block are in communication with each other.

EFFECT: increased reliability of long-term outdoor use of the base station by increasing the efficiency of thermal radiation as part of natural convection under the influence of external wind.

8 cl, 16 dwg

Description

Cross-reference to related application

This application is filed on the basis of PRC Patent Application No. 201921462483.1, filed on September 04, 2019, and claims priority of said PRC Patent Application, the entire content of which is hereby incorporated by reference.

TECHNICAL FIELD OF THE INVENTION

Embodiments of the present invention relate to the field of heat radiating technologies and, in particular, to a combined finned radiator and a communication base station.

State of the art of the present invention

Wireless communication has evolved from the 2G standard to the 3G and 4G standards, and now there is a 5G standard that will soon become mainstream. In the course of the development of communication technologies, an increase in transmission speed and an increase in output power has now led to an increase in the total heat consumption of the system from 300 W to 1500 W, to an increase in heat consumption per unit volume from 20 W / l to 30-40 W / l and to increasing the power consumption of microprocessors for an outdoor communication base station from 10-12 W to 20-45 W. The high reliability of a communication base station in outdoor applications is based on heat dissipation, which occurs in most cases by natural thermal radiation, since it is difficult to apply heat dissipation by other methods, such as air cooling and liquid cooling, which find application in the information technology industries and large data. Thus, the heat emitting capacity of the radiator is a decisive condition for an outdoor communication base station.

For a conventional heat sink used in a communication base station, most of the heat radiating fins contained in the heat sink have a single vertical straight fin structure with single air inlet and outlet passages, and thus the heat radiating capacity is not satisfactory. Alternatively, the heat radiating fins may be of a single V-shaped slanted fin design, and the sloping air exhaust mode is used. However, when there is wind in the environment, in the case of such a structure, the headwind easily affects the natural convection, i.e. the outflow of the generated hot air in the process of natural convection is hindered. Therefore, the temperature of the entire communication base station system rises, the heat radiation efficiency decreases, and the reliability of long-term outdoor use becomes unsatisfactory.

In order to solve the problem described above, the heat radiating effect can be improved by increasing the height of the heat radiating fins or increasing the overall volume of the heatsink. However, increasing the height of the heat radiating fins or increasing the overall volume of the heatsink can result in a corresponding increase in cost and weight. In addition, if limited to injection molding technology, there is a limitation on the maximum height of the fins, and thus the problem of heat radiation cannot be effectively solved.

Brief summary of the present invention

In view of the foregoing, according to embodiments of the present invention, a combined finned heatsink is provided. The combined finned radiator may include a base plate, a first heat radiating unit, and a second heat radiating unit. The first heat-radiating block is located on the main plate and contains a plurality of first straight ribs and a plurality of first air channels. Each of the first air channels is formed between two adjacent first straight ribs. The second heat radiating unit is located on the main plate and adjacent to the first heat radiating unit. The second heat-radiating block contains two symmetrically located groups of inclined fins, the second air channel is formed between two groups of inclined fins. Each of the two groups of inclined ribs contains a plurality of inclined ribs and a plurality of third air channels, each of which is formed between two adjacent of the inclined ribs. The third air channels contain air outlets located at a distance from the center of symmetry of the groups of inclined ribs. Some of the first air channels are in communication with the second air channel, and the rest of the first air channels are respectively in communication with adjacent third air channels.

In addition, according to another embodiment of the present invention, there is provided a communication base station comprising a combined finned heatsink as described above.

Brief description of the figures

In FIG. 1 is a schematic diagram of a combined finned heat sink according to Embodiment I of the present invention;

in fig. 2 is a front view of a combined finned radiator according to Embodiment I of the present invention;

in fig. 3 is a schematic diagram of a combined finned heat sink according to Embodiment II of the present invention;

in fig. 4 is a sectional view of a combined finned heat sink according to Embodiment II of the present invention;

in fig. 5 is a schematic diagram illustrating derivative ribs fastened together by a frame according to Embodiment II of the present invention;

in fig. 6 is a schematic diagram of a combined finned heat sink according to Embodiment III of the present invention;

in fig. 7 is a front view of a combined finned radiator according to Embodiment III of the present invention;

in fig. 8 is a schematic diagram of a combined finned heat sink according to Embodiment IV of the present invention;

in fig. 9 is a schematic diagram of a combined finned heat sink according to Embodiment V of the present invention;

in fig. 10 is a front view of a combined finned heat sink according to Embodiment V of the present invention;

in fig. 11 is a schematic diagram of a combined finned heat sink according to Embodiment VI of the present invention;

in fig. 12 is a front view of a combined finned heat sink according to Embodiment VI of the present invention;

in fig. 13 is a schematic diagram of a combined finned heat sink according to Embodiment VII of the present invention;

in fig. 14 is a front view of a combined finned heat sink according to Embodiment VIII of the present invention;

in fig. 15 is a front view of a combined finned heatsink according to an embodiment of the GC of the present invention; And

in fig. 16 is a schematic diagram of a communication base station according to Embodiment X of the present invention.

Legend:

1 - main plate; 21 - the first straight edge; 22 - the first air channel; 31 - second air channel; 32 - inclined rib; 33 - third air channel; 4 - edge rib; 41 - fourth air channel; 5 - derived edge; 6 - cover plate; 71 - second straight edge; 72 - fifth air channel; 8 - the first derivative edge; 9 - the first cover plate; 10 - second cover plate; 20 - third cover plate; and 30 - the fourth cover plate.

Detailed disclosure of the present invention

Hereinafter, the present invention will be described in detail with reference to the accompanying figures and embodiments. It should be understood that the specific embodiments that are described herein are presented only to explain the present invention, but are not intended to limit the present invention. In addition, it should be further noted that for ease of description, the accompanying figures show only parts, but not all, of the structures that are relevant to the present invention.

In the description of the present invention, unless expressly provided otherwise condition or limitation, should be understood in a broad sense, such terms as "connected", "connection" and "attached". For example, a "connection" may be a fixed connection, a releasable connection, or an integral connection; may be a mechanical connection or an electrical connection; may be a direct connection or an indirect connection through an intermediate link; or may represent a connection within two elements or an interaction relationship between two elements. One of ordinary skill in the art may understand the specific meanings of the above terms in the present invention, depending on the specific circumstances.

According to the present invention, unless expressly provided otherwise condition or limitation, the statement that the first object is "higher" or "lower" than the second object may mean that the first object is in direct contact with the second object, or may mean that the first object is in contact with the second object through an additional object located between the first object and the second object, and not directly in contact with the second object. In addition, the statement that the first object is "above", "above" and "on" the second object means that the first object is directly above or obliquely higher than the second object, or simply means that the first object is horizontally higher than the second object. The statement that the first object is "below", "below" and "below" the second object means that the first object is directly below or obliquely lower than the second object, or simply means that the first object is horizontally below, than the second object.

In the descriptions of embodiments, terms meaning orientation or location relationships such as "top", "bottom", and "right" are orientation or location relationships given based on the accompanying figures and are used solely for ease of description and simplification operation, but do not indicate and do not imply that a device or element must have a particular orientation, or be manufactured and operated in a particular orientation. Thus, this should not be understood as a limitation of the present invention. In addition, terms such as "first" and "second" are used solely to distinguish between terms in the description and have no special meanings.

Embodiment I

According to this embodiment, a combined finned heat sink is provided that can be used in a communication device such as a communication base station to effect natural heat radiation in a communication device such as a communication base station. According to this embodiment, a communication base station is used as an example. As illustrated in FIG. 1 and FIG. 2, the combination finned radiator according to this embodiment includes a base plate 1, a first heat radiating unit, and a second heat radiating unit.

The main plate 1 is configured to accommodate the entire combined finned heatsink in the communication base station, and the main plate 1 is generally vertically disposed in the communication base station.

The first heat radiating block is located on the front surface of the base plate 1, and in some examples the first heat radiating block is located on the bottom of the base plate 1 in the height direction. The first heat-radiating block contains a plurality of first straight ribs 21 spaced at regular intervals. The first straight fins 21 are arranged in the height direction of the main plate 1, and each of the plurality of first air passages 22 is formed between two adjacent first straight ribs 21, whereby cold air can flow into the first air passages 22 from below the main plate 1 to cool the source component. heat base station communication, located in the area of the first air channel 22.

According to this embodiment, a thermal obstruction area is formed depending on the position of the heat source component of the communication base station. When the first straight ribs 21 are present, the first straight ribs 21 extend upward from the bottom of the base plate 1 to a region above the thermal obstruction region, this region being at least 100 mm above the thermal obstruction region. Thus, the first heat radiating unit has an improved heat radiating effect in the thermal obstruction area.

The second heat radiating block is also located on the front surface of the main plate 1 and adjacent to the first heat radiating block, and in some cases the second heat radiating block is located on the top of the main plate 1 in the height direction. The second heat radiating block comprises two symmetrically arranged groups of inclined fins, and the second air channel 31 is formed between the two groups of inclined fins. The second air passage 31 extends upward from the first straight ribs 21 to the top of the base plate 1, and the second air passage 31 may be in communication with one or more intermediate first air passages 22 (there may be one first air passage 22, or there may be several intermediate and adjacent first air channels 22). According to this embodiment, the width of the second air passage 31 is exactly the same as the total width of some intermediate first air passages 22.

Each of the groups of inclined ribs comprises a plurality of inclined ribs 32, and the inclined ribs 32 are arranged vertically at regular intervals and are parallel in the height direction of the base plate 1. There are a plurality of third air channels 33, each of the third air channels 33 being formed between two adjacent inclined ribs 32 and has an air outlet located at a distance from the center of symmetry of the groups of inclined ribs. In other words, the air outlets of the third air passages 33 are located on the left side and on the right side of the main plate 1.

Some of the third air channels 33 are in communication with the rest of the first air channels 22 that are not in communication with the second air channel 31. In particular, the third air channels 33 located on the bottom are in communication with the first air channel 22. In In this case, it can be understood that the distance between two adjacent inclined ribs 32 and the distance between two adjacent first straight ribs 21 are the same, whereby the width of the third air passages 33 corresponds to the width of the first air passages 22. Thus, when the second heat radiating unit is adjacent to the first radiant unit, the third air passages 33 located on the lower part may be adjacent to the first air passages 22 so as to effect moderate air transfer between the first air passages 22 and the third air passages 33.

According to this embodiment, through the second air passage 31 and the third air passages 33, the air in the first air passages 22 can enter the second air passage 31 and the third air passages 33 to cool the heat source component of the base station while flowing in the second air passage 31 and third air ducts 33. In addition, the hot air resulting from heat transfer flows out from the air outlets of the third air ducts 33. hot air flows out through the top of the radiator through the second air passage 31. Thus, heating of the lower hot air at the top of the radiator can be facilitated, in other words, the heat radiating effect at the top of the radiator is improved.

In some examples, the inclined rib 32 has a certain internal angle with the height direction of the main plate 1, and the value of this internal angle can be from 30° to 45°, resulting in a moderate air flow velocity in the formed second air channel 31, sufficient heat transfer, and an excessively low airflow rate can be prevented.

One-piece molding by injection molding is adopted to manufacture the base plate 1, the first heat radiating unit, and the second heat radiating unit in the combined finned heat sink according to this embodiment. In addition, the first air passages 22 formed between the first straight ribs 21 of the first heat radiating unit are in communication with the third air passages 33 formed between the inclined ribs 32 of the second heat radiating unit, whereby the air inlet and air outlet of the conventional heat sink are adjusted using natural convection heat radiation, the convection heat transfer of cold air on the first straight fins 21 and the inclined fins 32 is enhanced, and the heat accumulation of the heat source components located on the top and bottom of the heatsink is reduced. In addition, the temperature of the component located on the top of the heat sink or coupler can be reduced by 5-8 degrees, and the temperature of the component located on the bottom of the heat sink or coupler can be reduced by 4 degrees without increasing the overall volume and height of the heat radiating fin. , and as a result, the efficiency of thermal radiation is improved by 20-30%.

In addition, according to this embodiment, the first heat radiating unit is on the bottom. Compared with the structure in which all the heat-radiating fins of the radiator are inclined fins, according to this embodiment, it is possible to improve the natural convection effect and the heating ability of the bottom of the radiator, and also improve the reliability of the radiator used outdoors for a long time. In addition, the second heat radiating unit is on the top, whereby the problem that the temperature of the top of the heatsink is excessively high and the heat radiation temperatures are unbalanced, the problem being caused by hot air flowing out from the top of the heatsink can be prevented. when all heat sink fins are straight fins. Thus, the heat-radiating capacity of the radiator is improved.

Embodiment II

As illustrated in FIG. 3 and 4, the combination finned heat sink proposed according to this embodiment includes a base plate 1, a first heat radiating unit, a second heat radiating unit, a plurality of derived fins 5, and a cover plate 6. The structures of the base plate 1, the first heat radiating unit, and the second heat radiating unit are as follows the same as the structures according to Embodiment I, and the relevant details will not be described again. According to this embodiment, only the structures of the derived ribs 5 and the cover plate 6 are described.

According to this embodiment, the plurality of derived ribs 5 are spaced, and the derived ribs 5 extend from one side to the other side in the width direction of the base plate 1. In some examples, the plurality of derived ribs 5 are evenly spaced. In addition, some of the derived ribs 5 alternate with the first straight ribs 21 of the first heat radiating unit to form air inlets, and the rest of the derived ribs 5 alternate with the inclined ribs 32 of the second heat radiant unit to form air inlets. Outside air can be directed to the first air passages 22 and the second air passages 31 through the air inlets to allow air intake from a variety of orientations, not just from the bottom of the radiator.

In some examples, derived ribs 5 may be on the end surfaces of the first straight ribs 21 and sloping ribs 32 and attached to the end surfaces of the first straight ribs 21 and sloping ribs 32 in a manner such as welding, screwing, or soldering. Alternatively, slots may be present at the top of the first straight ribs 21 and oblique ribs 32, and derived ribs 5 may be embedded into the slots of the first straight ribs 21 and oblique ribs 32 using a fixed fit (see the design illustrated in FIG. 4). In addition, the derived ribs 5 can be installed separately, or a plurality of derived ribs 5 can be processed and molded as a whole, and the derived ribs 5 can be installed on the first straight ribs 21 and oblique ribs 32. As illustrated in FIG. 5, a plurality of derived ribs 5 are integrally formed by stamping from a metal sheet. Thereafter, the integral derived ribs 5 are attached to the upper portions of the first straight ribs 21 and the inclined ribs 32, and the plurality of derived ribs 5 are attached to the first straight ribs 21 and the inclined ribs 32 using the attachment method described above.

According to this embodiment, the width and thickness of the derived ribs 5 and the shape of the air inlets can be set according to requirements. Through the derived ribs 5, cold air can flow not only from below the radiator, but also from the front porous structure of the radiator, so as to adjust the position at which cold air enters and the position at which hot air leaves the radiator, and also regulate the distribution of the internal temperature.

In addition, according to this embodiment, a cover plate 6 may additionally be present. The cover plate 6 is located on the air outlets of the third air channels 33. In other words, the cover plate 6 extends at least from the air outlet of the third air channel 33 below to the air outlet of the third air channel 33 at the top. The end portions of the derived ribs 5 on the inclined ribs 32 bear against one side of the cover plate 6. By means of the cover plate 6, the hot air flowing out of the third air passages 33 can quickly flow out along the cover plate 6, in other words, the cold air entering through the air inlet , can quickly flow into the third air passages 33. In addition, according to this embodiment, the cover plate 6 cooperates with the derived fins 5 to enhance the stack effect, whereby more cold air enters through the air hole which the derived fins 5 form, and this increases the speed and volume of cold air that enters the third air channels 33. In some examples, the thickness of the cover plate 6 is approximately 1 mm, and its width is 1/3 of the length of the inclined rib 32.

According to this embodiment, the cover plate 6 and derived ribs 5 may be machined and molded separately, or they may be machined and molded as a single unit and then installed together on the end surfaces of the first straight ribs 21 and inclined ribs 32.

Embodiment III

As illustrated in FIG. 6 and 7, the combination finned heat sink proposed according to this embodiment comprises a base plate 1, a first heat radiating unit, a second heat radiating unit, and edge fins 4 located on the base plate 1. The structures of the base plate 1, the first heat radiating unit, and the second heat radiating unit are the same as those of Embodiment I. The edge ribs 4 of this Embodiment may be a plate structure vertically extending along the front surface of the base plate 1 and located on two sides of the second heat radiating unit. A fourth air passage 41 may be formed between each edge rib 4 and the air outlets of adjacent third air passages 33. The fourth air passage 41 extends from at least the air outlet of the third air passage 33 below to the air outlet of the third air passage 33 at the top. Through the fourth air passage 41, the hot air after heat transfer can uniformly flow into the fourth air passage 41 through the third air passages 33 (excluding the hot air which flows into the second air passage 31) and finally flow out from the top of the fourth air passage 41, and as a result this creates a chimney effect, and prevents the effect of a headwind on the inclined ribs 32 when an external wind is present. Thus, the problem that the hot air in the third air passage 33 formed by natural convection between the inclined fins 32 cannot flow out, which causes deterioration in heat radiation, is prevented.

In some examples according to this embodiment, the first air channels 22 may additionally be present on both side edges of the base plate 1, whereby the first air channels 22 are in communication with the bottom openings of the fourth air channels 41. In this case, the air that flows in through the first air channels channels 22 can directly enter the fourth air channels 41 through the bottom holes of the fourth air channels 41 and flow out through the top of the fourth air channels 41.

According to this embodiment, through the fourth air passages 41, hot air can evenly flow out from the air outlets of the fourth air passages 41 and the second air passage 31, that is, flow out through the top of the radiator. This can reduce the effect of hot air heat accumulation in the first air passages 22 and third air passages 33 on the component located on top of the communication base station in accordance with the heatsink. In addition, since the external wind can generally exist in all directions around the communication base station, the hot air that flows out through the top of the heatsink prevents the external wind from blocking the hot air flowing from the third air passages 33 and thus heat radiation does not deteriorate under the influence of wind. This solves the problem that the reliability of the conventional inclined finned heat sink system is not satisfactory when an external wind is present.

Embodiment IV

According to this embodiment, a combined finned heatsink is provided. Based on Embodiment II, an additional combined finned heatsink is present in the construction according to Embodiment III. In particular, as illustrated in FIG. 8, the combined finned heatsink according to this embodiment comprises a base plate 1, a first heat radiating unit, a second heat radiating unit, derived fins 5, a cover plate 6, and edge fins 4. The structures and configurations of the components described above are the same as those of Embodiment II and Embodiment III. According to this embodiment, basically, the cover plate 6 comes into contact with the edge ribs 4, assuming that the fourth air passages are closed passages. By using the combination finned heat sink according to the embodiment, the quick exhaust of hot air can be enhanced, and outside air can quickly flow in through the air inlets and from the bottom of the heat sink. In addition, the chimney effect that the fourth air passages create can be further improved, so as to prevent the sloping ribs 32 from being subjected to a headwind when an external wind is present. Thus, the problem that hot air in the third air passage 33 formed between the inclined fins 32 cannot flow out due to natural convection can be prevented. Embodiment V

According to this embodiment, a combined finned heatsink is provided. As illustrated in FIG. 9 and 10, the combined finned radiator includes a base plate 1, a first heat radiating unit, a second heat radiating unit, and a third heat radiating unit. The structures of the base plate 1, the first heat radiating unit, and the second heat radiating unit are the same as those of Embodiment I, and the respective details will not be described again. According to this embodiment, only the structure of the third heat radiating unit will be described.

According to this embodiment, the third heat radiating unit is on top of the base plate 1 and adjacent to the second heat radiating unit. In some examples, the third heat radiating block includes a plurality of second straight ribs 71 spaced at regular intervals. The second straight ribs 71 are arranged in parallel, and the distance between two adjacent of the second straight ribs 71 is the same as the distance between two adjacent inclined ribs 32. Each of the plurality of fifth air channels 72 is formed between two adjacent of the second straight ribs 71, and some of fifth air passages 72 are in communication with the second air passage 31. The third heat radiating unit is above the second heat radiating unit, causing an empty space to be formed between the two sets of inclined fins of the second heat radiating unit. Thus, the length of the second straight ribs 71, which form some of the fifth air channels 72 in communication with the second air channel 31, increases depending on the size of this empty space, with the result that some of the fifth air channels 72 may be in communication with second air channel 31. The rest of the fifth air channels 72, which are not in communication with the second air channel 31, respectively, are in communication with the adjacent third air channels 33.

According to this embodiment, in the structures described above, after the cold air flowing in through the first air passages 22 flows into the second air passage 31 and the third air passages 33, respectively, the cold air flows into the respective fifth air passages 72 and finally flows out of the fifth air passages 72. Thus, the heat sink can further improve the heat radiating capacity, the effect of heat accumulation on the components occupying different positions of the communication base station can be reduced, and most of the hot air flows out of the heat sink through the top of the heat sink, thereby easing the problem in that the hot air of the inclined fins 32 does not flow out, and therefore, heat radiation is degraded due to the effect of a headwind on the inclined fins 32 when an outside wind is present.

Embodiment VI

Based on Embodiment V, according to this embodiment, additional edge ribs 4 are present. As illustrated in FIG. 11 and FIG. 12, the combined finned radiator comprises a main plate 1, a first heat radiating unit, a second heat radiating unit, a third heat radiating unit, and edge ribs 4. The structures of the main plate 1, the first heat radiating unit, the second heat radiating unit, and the third heat radiating unit are the same as those of Embodiment Embodiment V. The edge ribs 4 according to this embodiment may have a plate structure, a vertical orientation on the front surface of the base plate 1, and positioned on both sides of the first heat radiating unit, the second heat radiating unit, and the third heat radiating unit. The fourth air duct 41 may be formed between the edge rib 4 and the adjacent first straight rib 21, the air outlet of the third air duct 33 and the second straight rib 71. Through the fourth air duct 41, hot air flows evenly through the top of the fourth air duct 41, creating a chimney effect. , so as to prevent the effect of a headwind on the inclined fins 32 when an external wind is present. Thus, the problem that hot air in the third air passages 33 formed between the inclined fins 32 cannot flow out due to natural convection is solved.

According to this embodiment, through the fourth air passages 41, hot air can evenly flow out through the air outlets of the fourth air passages 41 and the air outlets of the fifth air passages 72 which are in communication with the second air passage 31, i.e., flow out of the radiator through the top. This can reduce the impact of hot air heat accumulation in the first air ducts 22 and third air ducts 33 on the component located on top of the communication base station, which corresponds to the fifth air duct 72. In addition, since external wind generally exists in all directions around the base communication station, the hot air which flows out from the top of the heatsink is allowed not to be blocked by the external wind of the hot air flowing out from the third air passage 33, and thus the thermal radiation is not degraded by the wind. This solves the problem that the reliability of the traditional oblique finned heat sink system becomes unsatisfactory when an outside wind is present.

Embodiment VII

Based on Embodiment VI, according to this embodiment, derivative ribs 5, cover plate 6, first derivative ribs 8, first cover plate 9, and second cover plate 10 are additionally present. Specifically, as illustrated in FIG. 13, the combined finned radiator comprises a base plate 1, a first heat radiating unit, a second heat radiating unit, a third heat radiating unit, edge ribs 4, derivative ribs 5, a cover plate 6, first derivative fins 8, a first cover plate 9, and a second cover plate 10. Structures the base plate 1, the first heat radiating unit, the second heat radiating unit, the third heat radiating unit, and the edge ribs 4 are the same as the structures of Embodiment VI. The structures and configurations of the derived ribs 5 and the cover plate 6 are the same as those of Embodiment P. The above components will not be described again. Here, only the structures of the first derivative ribs 8, the first cover plate 9, and the second cover plate 10 according to this embodiment will be described.

According to this embodiment, the plurality of first derivative ribs 8 are spaced, and the first derivative ribs 8 extend from one side to the other side in the width direction of the base plate 1. In some examples, the plurality of first derivative ribs 8 are equally spaced. In addition, the first derived ribs 8 alternate with the second straight ribs 71 of the third heat radiating unit to form air inlets. Outside air can flow into the first air passage 22 and the second air passage 31 through the air inlets which form the derivative ribs 5, the first straight ribs 21 and the inclined ribs 32, and may also flow into the fifth air passages 72 through the air inlets formed by the first derived ribs 8 and second straight ribs 71, allowing air to flow in from a variety of orientations.

In some examples, the first derived ribs 8 may be located on the end surfaces of the second straight ribs 71 and attached to the end surfaces of the second straight ribs 71 in a manner such as welding, screwing, or soldering. Alternatively, slots may be present at the top of the second straight ribs 71 and the first derived ribs 8 are embedded into the second straight ribs 71 by a firm fit. In addition, the first derivative ribs 8 may be installed separately, or a plurality of first derivative ribs 8 may be processed and molded as a whole, and the first derivative ribs 8 may be installed on the second straight ribs 71.

According to this embodiment, the width and thickness of the first derived fin 8 and the shape of the air inlets can be set according to requirements. Through the first derivative ribs 8, cold air can flow in not only from below the heatsink but also in front of the porous structure of the heatsink, so as to adjust the position at which cold air enters and the position at which hot air flows out of the heatsink, and therefore adjust internal temperature distribution.

In addition, according to this embodiment, the first cover plate 9 may be present. The first cover plate 9 covers the non-air outlet areas of the fifth air passages 72, which are located on both sides, in the width direction of the base plate 1, and the first cover plate 9 is adjacent to one end. cover plate 6.

The first cover plate 9 comes into contact with the edge ribs 4 and promotes contact between the cover plate 6 and the edge ribs 4, which allows the fourth air passages 41 and the edges of the fifth air passages 72 to jointly form closed passages. As a result of the first cover plate 9 and the first derivative ribs 8, the hot air that flows out of the fourth air passages 41 can rapidly flow out of the fifth air passages 72 along the first cover plate 9, whereby the cold air which flows in through the air inlets can quickly flow into the fifth air channels 72. In addition, according to this embodiment, the first cover plate 9 and the cover plate 6 cooperate with the derived ribs 5, which increases the speed and volume of cold air flowing into the third air channel 33. In some examples, the thickness of the first of the cover plate 9 is approximately 1 mm and its width is 1/3 of the length of the inclined rib 32.

In addition, according to this embodiment, there is a second cover plate 10, the second cover plate 10 extending from one side to the other side in the width direction of the base plate 1 and covering the air inlet areas of all fifth air passages 72. The first cover plate 9 and the edge ribs 4 are separately attached to the second cover plate 10. By using the second cover plate 10, the hot air in the fifth air passage 72 can rapidly flow out through the top. In addition, according to this embodiment, the second cover plate 10 cooperates with the first derived ribs 8 to increase the speed and volume of cold air that flows into the fifth air passage 72.

According to this embodiment, the first cover plate 9, the second cover plate 10, and the first derived ribs 8 may be processed and formed separately, or they may be processed and formed as a whole.

Embodiment VIII

According to this embodiment, a combined finned heatsink is provided. As illustrated in FIG. 14, the combination finned heat sink according to this embodiment includes a base plate 1, a first heat radiating unit, and a second heat radiating unit. The structures of the base plate 1, the first heat radiating unit and the second heat radiating unit are the same as those of Embodiment I.

According to this embodiment, the second heat radiating unit is located lower than the first heat radiating unit. In other words, according to this embodiment, the first air passages 22 formed by the first straight ribs 21 are located on the top of the base plate 1, and the second air passage 31 formed by two sets of inclined ribs and the third air passages 33 formed by the inclined ribs 32 are located on the bottom of the main plate 1.

Embodiment IX

According to this embodiment, a combined finned heatsink is provided. As illustrated in FIG. 15, the combination finned radiator according to this embodiment comprises edge fins 4, derivative fins 4, a third cover plate 20, and a fourth cover plate 30, which are additionally present based on Embodiment VIII. The structures of the edge ribs 4 and the derivative ribs 5 are the same as those of Embodiment IV, and the structures of the third cover plate 20 and fourth cover plate 30 are the same as those of the first cover plate 9 and the second cover plate 10 of Embodiment VII. Thus, constructions corresponding to the constructions presented above are again described here.

In addition, according to this embodiment, the third cover plate 20 is located on the air outlets of the third air passages 33 and in the non-air discharge areas of the first air passages 22 located on both sides, in the width direction, of the base plate 1. In other words, according to this embodiment, the third cover plate 20 extends from the bottom of the main plate 1 to the top of the main plate 1, reaching the air outlet areas of the first air passages 22. on top of the first heat-radiating block. Specifically, the fourth cover plate 30 extends from one side to the other in the width direction of the base plate 1 and covers the air outlet areas of all the first air passages 22. In addition, the edge ribs 4 are attached to the third cover plate 20 and the fourth cover plate 30 to form closed fourth air channels.

Embodiment X

According to this embodiment, there is provided a communication base station comprising one of the combined finned heat sinks according to embodiments I to IX, whereby the temperature of the component located on the top of the communication device can be reduced by 5 to 8 degrees, and the temperature of the component located on the lower part of the communication device can be lowered by 4 degrees, and as a result, the heat-radiating effect of the components of the communication base station is improved. As illustrated in FIG. 16, the communication base station 61 according to this embodiment includes a combined finned heatsink 161.

According to an embodiment of the present invention, a combined finned heat sink is provided that can provide improved heat radiation efficiency at least to some extent without increasing the overall volume and height of the heat radiating fin.

According to another embodiment of the present invention, a communication base station is provided in which, by means of a combined finned heat sink, the heat energy of the entire system can be effectively reduced at least to some extent, resulting in improved application reliability.

According to embodiments of the present invention, the first air passages formed by the first straight fins of the first heat radiating unit are in communication with the third air passages formed by the oblique fins of the second heat radiating unit, such that the air inlet and outlet passages of a conventional heat sink are optimized using natural convection thermal heat. radiation, the convection heat transfer of cold air to the first straight fins and the inclined fins is enhanced, and the heat accumulation for the heat source components located on the top and bottom of the heatsink is reduced. In addition, the temperature of the component located on the top of the heatsink or communication device can be reduced by 5-8 degrees, and the temperature of the component located on the bottom of the heatsink or communication device can be reduced by 4 degrees without increasing the overall volume and height. heat-radiating fin, and as a result of this, there is an increase in the efficiency of thermal radiation by 20-30%.

According to embodiments of the present invention, edge ribs are present to allow vertical fourth air channels to be formed at the edges of the first heat radiating unit and the second heat radiating unit. The hot air evenly flows out through the top of the fourth air passage to create a smokestack effect, so as to prevent the sloping fins from being affected by a headwind when an outside wind is present. Thus, the problem that hot air in the third air passages formed by the inclined fins cannot flow out due to natural convection is prevented.

Obviously, the above embodiments of the present invention are merely examples, which are intended to explain the present invention, but not to limit the embodiments of the present invention. Various obvious changes, modifications and substitutions can be made by one of ordinary skill in the art without departing from the scope of the present invention. An exhaustive listing of all embodiments herein is neither mandatory nor possible. Any modifications, equivalent substitutions and improvements made in accordance with the ideas and principles of the present invention are within the scope of the legal protection of the claims of the present invention.

Claims (15)

1. Combined finned radiator, containing: the main plate (1) containing the edge rib (4), the first heat-radiating block located on the main plate (1) and containing a plurality of first straight ribs (21) and a plurality of first air channels (22), each of which is formed between two adjacent first straight ribs (21), and the second heat radiating block located on the main plate (1) and adjacent to the first heat radiating block, the second heat radiating block comprising two symmetrically arranged groups of inclined ribs and a second air channel (31) formed between the two groups of inclined ribs, wherein each of the groups of inclined ribs contains a plurality of inclined ribs (32) and a plurality of third air channels (33), each of which is formed between two adjacent of the inclined ribs (32), and the third air channels (33) contain air outlets located on distance from the center of symmetry of groups of inclined ribs, while some of the first air channels (22) are in communication with the second air channel (31) and the rest of the first air channels (22) are respectively in communication with the adjacent third air channels (33), and the fourth air channel (41) is formed between the edge rib (4) located on both sides of the second heat radiating block and the air outlets of the third air channels (33), the fourth air channel (41) being located on both sides of the main plate (1), And the first air channels (22) and the fourth air channels (41) located on both sides of the first heat-radiating block are in communication with each other. 2. Combined ribbed radiator according to claim 1, additionally containing a plurality of derivative ribs (5) located at intervals, and the derivative ribs (5) extend from one side to the other side in the width direction of the main plate (1), some of the derivative ribs ( 5) alternate with the first straight ribs (21), and the rest of the derived ribs (5) alternate with inclined ribs (32), respectively, to form air inlets. 3. Combined finned radiator according to claim 2, additionally containing a cover plate (6) located at the air outlets of the third air channels (33). 4. Combined ribbed radiator according to claim 3, in which the end parts of the derived ribs (5) are adjacent to one side of the cover plate (6). 5. Combined ribbed radiator according to any one of paragraphs. 1-4, in which the first heat radiating unit is located below the second heat radiating unit in the height direction of the base plate (1). 6. Combined ribbed radiator according to any one of paragraphs. 1-4, further comprising a third heat radiating block, wherein the third heat radiating block comprises a plurality of second straight fins (71) and a plurality of fifth air channels (72), each of which is formed between two adjacent of the second straight ribs (71), with some of fifth air channels (72) are in communication with the second air channel (31), and the rest of the fifth air channels (72) are respectively in communication with the adjacent third air channels (33). 7. Combined ribbed radiator according to claim 6, further comprising a plurality of first derivative ribs (8), wherein the first derivative ribs (8) extend from one side to the other side in the width direction of the main plate (1), and the first derivative ribs (8) alternate with second straight ribs (71) to form air inlets. 8. The base station, containing a combined finned radiator according to any one of paragraphs. 1-7.

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