CN218072287U - Multi-compatibility receiving terminal of Internet of things - Google Patents

Abstract

The utility model discloses a many compatibilities thing networking receiving terminal relates to receiving terminal technical field. The utility model discloses a: a circuit board; further comprising: the circuit board is arranged in the accommodating cavity; and the communicating pipe is arranged in the shell and is attached to the circuit board. The utility model discloses a design of communicating pipe and honeycomb duct to formed a closed loop cavity that runs through the casing inside and outside, thereby make the water flow along closed loop cavity, thereby realize inside and outside circulation heat exchange, in order to with the continuous direction outside of the heat of inside, and make for providing an inclosed operational environment for the circuit board with the cooperation of casing, compare with prior art, this design makes at whole radiating in-process, the circuit board is in an inclosed environment always, thereby the adhesion of dust on it has been reduced, in order to reduce the influence to whole receiving terminal's life.

Description

Multi-compatibility receiving terminal of Internet of things

Technical Field

The utility model relates to a receiving terminal equipment technical field, concretely relates to multi-compatibility thing networking receiving terminal.

Background

The internet of things is that any object or process needing monitoring, connection and interaction is collected in real time through various devices and technologies such as various information sensors, radio frequency identification technologies, global positioning systems, infrared sensors, laser scanners and the like, various required information such as sound, light, heat, electricity, mechanics, chemistry, biology, positions and the like is collected, ubiquitous connection of objects and objects, and ubiquitous connection of objects and people are realized through various possible network accesses, and intelligent sensing, identification and management of the objects and the processes are realized. The internet of things is an information carrier based on the internet, a traditional telecommunication network and the like, all common physical objects which can be independently addressed form an interconnected network, information terminal equipment refers to communication equipment used for receiving and sending information at two ends of a channel, and the receiving range of a receiving terminal is gradually enlarged along with the gradual increase of networking objects, so that the receiving terminal needs more compatibility, and the workload of the receiving terminal is continuously increased.

The receiving terminal is mainly constructed by a circuit board, which comprises a board body and corresponding ports mounted on the board body, and further comprises a shell, wherein the board body is mounted inside the shell, the ports are exposed outside the shell and are used for convenient insertion, at present, the quantity of information to be received by the receiving terminal is increased due to the increasing of networking objects, so that the quantity of the ports is increased due to the requirement of multiple compatibility, the burden of the whole circuit board in working is increased, and the requirement of heat dissipation is increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: for solving the problem in the above-mentioned background art, the utility model provides a multi-compatibility thing networking receiving terminal.

The utility model discloses a realize above-mentioned purpose and specifically adopt following technical scheme:

a multi-compatibility Internet of things receiving terminal comprises:

a circuit board;

further comprising:

the circuit board comprises a shell, a circuit board and a connecting piece, wherein a closed cavity is formed in the shell, and the circuit board is arranged in the cavity;

the communicating pipe is arranged in the shell and is attached to the circuit board;

the honeycomb duct is arranged outside the shell, and two ends of the honeycomb duct penetrate through the shell and are respectively communicated with two ends of the communicating pipe so as to form a closed-loop cavity by matching with the communicating pipe;

the water body is encapsulated in the closed-loop cavity;

the flow guide assembly is arranged in the flow guide pipe and is used for driving the water body to circularly flow in the closed-loop cavity along the ring diameter direction;

and the air cooling assembly is arranged on the outer side of the shell and is used for generating air flow flowing through the flow guide pipe.

Further, still including installing power component on the honeycomb duct, the honeycomb duct subassembly is including rotating the spiral leaf of installing in the honeycomb duct inside, power component is used for providing rotary power for the spiral leaf.

Further, still include the guide duct, the air-cooled subassembly is including rotating the wind wheel of installing at the guide duct first end, power component still is used for providing rotary power for the wind wheel, the guide duct second end is towards the honeycomb duct.

Furthermore, the communicating pipe is formed by sequentially communicating a plurality of sections of branch pipes, and the plurality of sections of branch pipes are vertically and horizontally arranged, so that the communicating pipe forms a multi-section bending structure.

Further, the branch pipe is of a plate type structure so as to form a joint surface for jointing the circuit board.

Furthermore, the guide pipe comprises a cooling section and guide sections communicated with two ends of the cooling section along the length direction of the guide pipe, the free ends of the two guide sections are respectively communicated with the two branch pipes, the second end of the guide pipe points to the cooling section, and the cooling section is composed of a plurality of cooling pipes which are parallel.

The cooling air duct comprises a casing, a plurality of support plates and a plurality of cooling pipes, wherein the support plates are connected in an initial position, the support plates are all constructed on the casing, the support plates are constructed into an annular shape, sealing plates are covered at annular openings to form a closed enclosure cavity, the cooling pipes are all located in the closed enclosure cavity, the second end of the air guide pipe penetrates through one support plate and is located inside the closed enclosure cavity, and the cooling air duct further comprises a vent hole constructed on the other support plate.

Furthermore, the quantity in ventilation hole is a plurality of, and is a plurality of the ventilation hole is evenly distributed on the face of the branch.

The beneficial effects of the utility model are as follows:

1. the utility model discloses a design of communicating pipe and honeycomb duct, thereby formed one and run through the inside and outside closed loop cavity of casing, thereby make the water flow along closed loop cavity, thereby realize inside and outside circulation heat exchange, so that the continuous direction outside of the heat with inside, and make for providing an inclosed operational environment for the circuit board with the cooperation of casing, compare with prior art, this design makes at whole radiating in-process, the circuit board is in an inclosed environment always, thereby the adherence of dust above that has been reduced, in order to reduce the influence to whole receiving terminal's life.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a partially-structured three-dimensional sectional view of the present invention;

FIG. 3 is a perspective view of the present invention;

FIG. 4 is a sectional view between the partial structures and a three-dimensional sectional view of the partial structures of the present invention;

FIG. 5 is a perspective sectional view of another partial structure of the present invention;

reference numerals: 1. a circuit board; 2. a housing; 3. a cavity; 4. a communicating pipe; 401. a branch pipe; 5. a flow guide pipe; 501. a cooling section; 5011. a cooling tube; 502. a flow guide section; 6. a flow guide assembly; 7. an air-cooled assembly; 8. a power assembly; 9. an air guide pipe; 10. a vent hole; 11. a support plate; 12. and (7) closing the plate.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the drawings in the embodiments of the present invention are combined below to clearly and completely describe the technical solutions in the embodiments of the present invention.

As shown in fig. 1-5, an embodiment of the utility model provides a multi-compatibility thing networking receiving terminal, include:

the circuit board comprises a circuit board 1 and a port arranged on the side edge of the board body, wherein the circuit board 1 is of an existing structure, the circuit board 1 is a core structure of a receiving terminal and is used for receiving information, and in the prior art, the circuit board 1 is also provided with a shell used for protecting the circuit board 1, so that the problem that dust is easily carried into the shell during heat dissipation in the prior art is solved by adopting the following components;

the method specifically comprises the following steps:

the circuit board comprises a shell 2, wherein a closed containing cavity 3 is formed in the shell 2, a circuit board 1 is arranged in the containing cavity 3, so that physical protection is provided for the circuit board 1, a port on the circuit board 1 still leaks out of the shell 2, but a metal shell of the port is tightly attached to a penetrating part of the shell 2, and dust is difficult to enter the shell 2;

the communication pipe 4 is made of metal, so that the communication pipe has good thermal conductivity, is specifically installed in the shell 2 and is attached to the circuit board 1, so that heat generated by the circuit board 1 during working can be transferred to the communication pipe 4, and the communication pipe 4 can generate heat;

the draft tube 5 is arranged outside the shell 2, two ends of the draft tube 5 penetrate through the shell 2 and are respectively communicated with two ends of the communicating tube 4, the penetrating position is closed, no gap is generated, so that dust cannot enter the interior from the penetrating position, and through the design, the draft tube 5 can be matched with the communicating tube 4 to form a closed-loop cavity, so that half of the closed-loop cavity is arranged inside the shell 2, and half of the closed-loop cavity is arranged outside the shell 2;

the water body is encapsulated in the closed-loop cavity, and the water has good temperature conduction effect due to the characteristic of large specific heat capacity coefficient;

the flow guide assembly 6 is arranged in the flow guide pipe 5 and is used for driving the water body to circularly flow in the closed-loop cavity along the ring diameter direction, so that the water body can circularly flow along the cavity diameter direction all the time, and the heat on the circuit board 1 is transferred to the water body when being transferred to the communicating pipe 4, and the heat can be taken to the outside due to the circular flow of the water body, namely the outside of the shell 2, so that the heat can be transferred to the flow guide pipe 5;

the air cooling assembly 7 is installed on the outer side of the shell 2, the air cooling assembly 7 is used for generating air flow flowing through the flow guide pipe 5, so that the flow guide pipe 5 is cooled, when water body flowing out of the interior and carrying heat flows through the cooled flow guide pipe 5, the heat in the water body can be transferred to the flow guide pipe 5 due to the heat conduction principle, the temperature of the water body is reduced, the water body after being cooled flows into the interior again, the heat in the water body is taken out continuously, meanwhile, the flow guide pipe 5 after being heated is subjected to air cooling, and the circulation is carried out, so that the heat in the water body is continuously dissipated;

in whole process, because inside is a inclosed state always, it is mainly continuous outside with the heat direction of inside through the flow of water, thereby carry out the contact cooling to inside circuit board 1, so whole compare with current mode of directly blowing through the fan, the dust is difficult to enter into inside, thereby can prolong inside circuit board 1's life to a certain extent, thereby improved receiving terminal's life on the whole, along with networking more and more of article, only improved receiving terminal's durability, just can adapt to present many compatible demands.

As shown in fig. 2-5, in some embodiments, the device further comprises a power assembly 8 mounted on the draft tube 5, the draft assembly 6 comprises a spiral blade rotatably mounted inside the draft tube 5 so as to stir the water inside the draft tube to flow when the spiral blade rotates, the power assembly 8 is used for providing rotary power for the spiral blade, wherein the power assembly 8 is a small motor, an output shaft of which penetrates through the wall of the draft tube 5 and is coaxially connected with the rotating shaft of the spiral blade, and the motor is also mounted on the wall shell.

As shown in fig. 1-5, in some embodiments, the air cooling assembly 7 further comprises a wind wheel rotatably mounted at a first end of the wind guiding tube 9, so that when the wind wheel rotates, air at a second end of the wind guiding tube 9 is drawn to the first end, and the power assembly 8 is further configured to provide rotational power to the wind wheel, i.e., a small motor is also drivingly connected to the wind wheel, wherein the motor is a two-shaft motor, and two ends of the motor are coaxially connected to the helical blade and the wind wheel, respectively, so that another output shaft passes through a wall of the wind guiding tube 9, and the second end of the wind guiding tube 9 faces the wind guiding tube 5, so that air around the wind guiding tube 5 is drawn elsewhere, so that a flow of air is formed at the wind guiding tube 5 to cool the wind guiding tube.

As shown in fig. 2 to 4, in some embodiments, the communication pipe 4 is formed by sequentially connecting a plurality of sections of branch pipes 401, and the plurality of sections of branch pipes 401 are arranged vertically and horizontally, i.e., vertically distributed, so that the communication pipe 4 forms a multi-section bent structure, and this design increases the length of the whole communication pipe 4 inside, thereby increasing the contact area with the circuit board 1 and increasing the heat conduction effect.

As shown in fig. 2 to 4, in some embodiments, the manifold 401 has a plate-type configuration, and the pipe diameter is located inside the plate-type configuration, so that the exterior of the manifold 401 is formed with a joint surface for jointing the circuit board 1, so that the joint area with the circuit board 1 can be further increased to further increase the heat conduction effect.

As shown in fig. 2-4, in some embodiments, the draft tube 5 includes a cooling section 501 and flow guiding sections 502 connected to two ends of the cooling section 501 along its length, the free ends of the two flow guiding sections 502 are respectively connected to the two branch tubes 401, so that the entire draft tube 5 passes through the housing 2 through the flow guiding sections 502 located at two ends to be connected to the internal communication tube 4, the second end of the air guiding tube 9 is directed to the cooling section 501, so that the cooling process is mainly completed at the same position of the cooling section 501, the cooling section 501 is composed of a plurality of cooling tubes 5011 arranged side by side, in order to match the design, two square tubes are connected to two ends of the plurality of cooling tubes 5011 in an aligned manner, and then the two square tubes are connected to the two flow guiding sections 502, and the design of the plurality of cooling tubes 5011 increases the contact area of the section with air, that is, the contact area with the air flow is increased, so as to increase the air cooling effect.

As shown in fig. 1, in some embodiments, the air-cooling device further includes a plurality of support plates 11 configured on the outer side of the housing 2 and connected to each other at an initial position, the plurality of support plates 11 are configured in a ring shape, and a sealing plate 12 is covered at the ring opening, so that a closed enclosure is formed, the enclosure is formed by two square pipes, as can be seen from the figure, so that the two square pipes can also be regarded as two support plates 11 to participate in the formation of the enclosure, the plurality of cooling pipes 5011 are all located in the closed enclosure, the second end of the air guiding pipe 9 penetrates through one of the support plates 11 and is located inside the closed enclosure, and further includes a vent hole 10 configured on the other support plate 11, so that when an air flow is formed, the air flows into the cavity from the vent hole 10 and then enters into the air guiding pipe 9 and is sucked away by the wind wheel, so that the air flow completely flows through the enclosure, and the air flow can be completely "enclosed" covered "by the design of forming the enclosure, so that the air flow can be blown through each cooling pipe 5011 as possible to further increase the air-cooling effect.

As shown in fig. 1, in some embodiments, the number of the ventilation holes 10 is multiple, and the multiple ventilation holes 10 are uniformly distributed on the surface of the support plate 11, so that the air flow in the enclosure is more uniform, and the cooling effect of each cooling tube 5011 can be kept as uniform as possible.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. A multi-compatibility Internet of things receiving terminal comprises:

a circuit board (1);

it is characterized by also comprising:

the circuit board comprises a shell (2), wherein a closed cavity (3) is formed in the shell, and the circuit board (1) is installed in the cavity (3);

a communication pipe (4) mounted in the housing (2) and attached to the circuit board (1);

the honeycomb duct (5) is installed outside the shell (2), and two ends of the honeycomb duct (5) penetrate through the shell (2) and are respectively communicated with two ends of the communicating pipe (4) so as to be matched with the communicating pipe (4) to form a closed-loop cavity;

the water body is encapsulated in the closed-loop cavity;

the flow guide assembly (6) is arranged in the flow guide pipe (5) and is used for driving the water body to circularly flow in the closed-loop cavity along the ring diameter direction;

the air cooling assembly (7) is installed on the outer side of the shell (2), and the air cooling assembly (7) is used for generating air flow flowing through the flow guide pipe (5).

2. The receiving terminal of the multi-compatibility internet of things of claim 1, further comprising a power assembly (8) installed on the flow guide pipe (5), wherein the flow guide assembly (6) comprises a spiral blade rotatably installed inside the flow guide pipe (5), and the power assembly (8) is used for providing rotary power for the spiral blade.

3. The receiving terminal of the multi-compatibility internet of things of claim 2, further comprising an air guide pipe (9), wherein the air cooling assembly (7) comprises a wind wheel rotatably mounted at a first end of the air guide pipe (9), the power assembly (8) is further configured to provide rotating power for the wind wheel, and a second end of the air guide pipe (9) faces the flow guide pipe (5).

4. The receiving terminal of the multi-compatibility internet of things as claimed in claim 3, wherein the communicating pipe (4) is formed by sequentially communicating a plurality of sections of branch pipes (401), and the plurality of sections of branch pipes (401) are arranged vertically and horizontally, so that the communicating pipe (4) forms a multi-section bending structure.

5. The receiving terminal of the IOT of claim 4, wherein the manifold (401) is of a plate type configuration to form a mating face for mating with the circuit board (1).

6. The receiving terminal of the multi-compatibility internet of things of claim 4, wherein the flow guide pipe (5) comprises a cooling section (501) and flow guide sections (502) communicated with two ends of the cooling section (501) along the length direction of the flow guide pipe, the free ends of the two flow guide sections (502) are respectively communicated with the two branch pipes (401), the second end of the air guide pipe (9) points to the cooling section (501), and the cooling section (501) is composed of a plurality of cooling pipes (5011) which are parallel to each other.

7. The receiving terminal of the internet of things of claim 6, further comprising a plurality of support plates (11) connected in an initial position, wherein the plurality of support plates (11) are all configured on the shell (2), the plurality of support plates (11) are configured to be annular, a sealing plate (12) covers an annular opening to form a closed enclosure, the plurality of cooling pipes (5011) are all located in the closed enclosure, the second end of the air guide pipe (9) penetrates through one of the support plates (11) and is located inside the closed enclosure, and further comprising a vent hole (10) configured on the other support plate (11).

8. The receiving terminal of the internet of things of multi-compatibility according to claim 7, wherein the number of the ventilation holes (10) is multiple, and the ventilation holes (10) are uniformly distributed on the surface of the support plate (11).

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