CN109951197B - An adjustable signal source receiver for D2D communication technology in 5G communication - Google Patents

Abstract

The invention relates to a receiver for D2D communication technology in 5G communication with an adjustable signal source, comprising a base, a heat dissipation mechanism, a moving mechanism and a beam line mechanism. For bonding, a panel is arranged on the front of the receiver body, and the panel and the receiver body are connected by bolts, the heat dissipation mechanism is embedded in the front of the panel, and the moving mechanism is connected to the lower end of the base. The beneficial effects of the present invention are: when the fan is activated to blow and dissipate heat inside the main body of the receiver, the shutter is pushed by the wind, and automatically rotates along the rotating shaft, so that the heat dissipation window is in an open state, and the heat inside the main body of the receiver can be released. When the heat dissipation is stopped, after the shutter is not subject to thrust, the manual self-gravity rotates in the reverse direction along the rotation axis, and the shutter and the shutter are connected to each other, so that the heat dissipation window is closed.

Description

An adjustable signal source receiver for D2D communication technology in 5G communication

technical field

The invention relates to the technical field of 5G communication, in particular to a receiver for D2D communication technology in 5G communication with an adjustable signal source.

Background technique

In the evolution of 5G-oriented wireless communication technology, as a key candidate technology for 5G, device-to-D2D communication technology has the potential to improve system performance, enhance user experience, and expand cellular communication applications. In the middle, a signal receiver is needed to receive the signal, and the quality of the receiver affects the quality of the signal.

The existing receivers are fixed and receive signals from a fixed place. When the signal is not good, the signal source can only be adjusted by adjusting the antenna, but the effect is not very satisfactory, and the receiver is equipped with heat dissipation. It is easy for external dust and impurities to enter the receiver from the heat sink, which will affect the internal components and affect the reception of the signal.

SUMMARY OF THE INVENTION

The purpose of the present invention is to provide a receiver for D2D communication technology in 5G communication with an adjustable signal source, so as to solve the problem that the existing receivers proposed in the above background technology are fixed and receive signals from a fixed place. When the signal is not good, you can only adjust the signal source by adjusting the antenna, but the effect is not very satisfactory, and the receiver is equipped with a heat sink, so the external dust and impurities can easily enter the receiver from the heat sink. If it affects, it will affect the acceptance of the signal.

In order to achieve the above purpose, the present invention provides the following technical solutions: a receiver for D2D communication technology in 5G communication with an adjustable signal source, comprising a base, a heat dissipation mechanism, a moving mechanism and a beamline mechanism, and the upper end of the base is provided with a receiver main body , and the main body of the receiver and the base are bonded, the front of the main body of the receiver is arranged with a panel, and the panel and the main body of the receiver are connected by bolts, the heat dissipation mechanism is inlaid on the front of the panel, and the moving mechanism Connected to the lower end of the base, the wire harnessing mechanism is installed on the front of the receiver body, and a wire clamping mechanism is fixed inside the wire harnessing mechanism, the upper end of the receiver body is provided with a fan top cover, and the inside of the fan top cover is A fan is installed, a joint is embedded in the inner wall of one side of the receiver body, and one side of the receiver main body is connected with a first rotating shaft, the first rotating shaft and the joint are fixed by welding, and the first rotating shaft An antenna is installed on the upper end of the shaft, and a display screen is fixed on the back of the receiver body.

Preferably, the interior of the heat dissipation mechanism includes a heat dissipation window, and the heat dissipation window and the panel are integrally connected by injection molding, the inner walls of both sides of the heat dissipation window are provided with rotating shafts, and the rotating shaft is close to the center line of the heat dissipation window One end is provided with a shutter.

Preferably, the shutters are arranged equidistantly inside the heat dissipation window, and the shutter and the heat dissipation window form a rotating structure through a rotating shaft.

Preferably, the inside of the moving mechanism includes a pulley frame, and the pulley frame and the base are welded and fixed, the lower end of the pulley frame is inlaid with a guide rail, and one end of the guide rail is connected with a post, and the post is connected to the guide rail. They are fixed by welding, and a hole is installed at the other end of the guide rail.

Preferably, the base forms a sliding structure through a pulley frame and a guide rail, and the guide rail is in a "T"-shaped structure.

Preferably, the shape of the plug is the same as that of the socket, and the plug and the guide rail are fixedly connected.

Preferably, the inside of the wire harnessing mechanism includes a wire harness groove, and the wire harness groove and the receiver body are integrally connected by injection molding, and a second rotating shaft is fixed on an inner side of the wire harness groove, and One side of the second rotating shaft is provided with a wire harness rod, and a partition plate is arranged on the outer wall of the wire harness rod.

Preferably, the dividing plates are arranged at an equal distance on the outer wall of the wire harnessing rod, and the wire harnessing rod forms a rotating structure through the second rotating shaft and the wire harnessing groove.

Preferably, the inside of the thread clamping mechanism includes a threading groove, and the threading groove and the partition plate are integrally connected by injection molding. Springs are embedded on both sides of the interior of the threading groove, and the springs are close to the center line of the threading groove. One end is connected with a splint.

Preferably, the splint forms an elastic expansion and contraction structure through a spring and the threading slot, and the splint is axially symmetrical about the center line of the threading slot.

Compared with the prior art, the beneficial effects of the present invention are:

1. When the receiver for D2D communication technology in the adjustable signal source 5G communication uses the fan to start blowing and dissipating heat inside the receiver body, the shutter is pushed by the wind and automatically rotates along the rotation axis, so that the heat dissipation window is open. , the heat inside the main body of the receiver can be dissipated. When the heat dissipation is stopped, after the shutter is not subject to thrust, the manual self-gravity rotates in the reverse direction along the rotation axis, and the shutter and the shutter are connected to each other, so that the heat dissipation window is In the closed state, it can prevent external dust from entering the receiver body from the heat dissipation window, effectively solving the problem that the external dust and impurities are easy to enter the receiver from the heat dissipation device in the past, which will affect the internal components. The problem of signal reception.

2. The receiver for D2D communication technology in the adjustable signal source 5G communication can slide on the upper end of the guide rail through the base, and the receiver body can move, instead of the fixed receiver in the past, so that when the signal is unstable When the receiver body can adjust the signal source in a large range by moving, the receiver body can receive the signal stably, effectively solving the problem that the receiver received the signal from a fixed place in the past. When the signal is not good, it can only pass the signal. Adjust the antenna to adjust the signal source, but the effect is not very satisfactory.

3. The receiver for D2D communication technology in the adjustable signal source 5G communication can be inserted into the jack through the post, so that the splicing between the guide rail and the guide rail can be realized, so that the moving distance of the receiver body can be changed by splicing the guide rail. and moving range, which can help the receiver body to better adjust the signal source and enhance the stability of the signal.

4. The receiver for D2D communication technology in the adjustable signal source 5G communication can wrap the connecting wire on the main body of the receiver through the wire harness rod, and the dividing plate can clamp each coil of the connecting wire and wrap it. Separated, so that the connecting wire is wound on the wire harness rod in an orderly manner, and the wire harness rod can rotate in the wire harness groove along the second rotation axis, so that the wound connection wire can be hidden in the wire harness groove, so that It is possible to avoid stray outside of the connecting wires on the receiver body.

5. The receiver for D2D communication technology in the adjustable signal source 5G communication has a wire slot on the dividing plate, which can make the connecting wire run through the dividing plate when the connecting wire is wound on the beam rod, and When the two opposite clamping plates are approached by the elastic force of the spring, the connecting wire can be clamped in the threading groove to prevent the connecting wire from falling off the wire harness rod and the dividing plate.

Description of drawings

1 is a schematic structural diagram of a receiver for D2D communication technology in an adjustable signal source 5G communication according to the present invention;

FIG. 2 is a schematic diagram of the right side view structure of a receiver body of a receiver for D2D communication technology in an adjustable signal source 5G communication according to the present invention;

3 is a left side view and enlarged structural schematic diagram of a receiver for D2D communication technology in an adjustable signal source 5G communication according to the present invention;

FIG. 4 is a schematic diagram of the enlarged structure of the receiver for D2D communication technology in 5G communication with an adjustable signal source according to the present invention in FIG. 2;

FIG. 5 is a schematic diagram of a rear view structure of a receiver body of a receiver for D2D communication technology in 5G communication with an adjustable signal source according to the present invention.

In the figure: 1. Base; 2. Receiver body; 3. Panel; 4. Fan top cover; 5. Fan; 6. Joint; 7. First rotating shaft; 8. Antenna; Window; 902, rotating shaft; 903, shutter; 10, moving mechanism; 1001, pulley frame; 1002, guide rail; 1003, post; 1004, jack; 11, harness mechanism; 1101, harness slot; 1102, The second rotating shaft; 1103, the wire beam rod; 1104, the dividing plate; 12, the wire clamping mechanism; 1201, the threading groove; 1202, the spring; 1203, the splint; 13, the display screen.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, rather than all the embodiments.

In the description of the present invention, unless otherwise stated, "plurality" means two or more; the terms "upper", "lower", "left", "right", "inner", "outer" The orientation or positional relationship indicated by , "front end", "rear end", "head", "tail", etc. are based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing the present invention and simplifying the description, not An indication or implication that the referred device or element must have a particular orientation, be constructed and operate in a particular orientation, is not to be construed as a limitation of the invention. Furthermore, the terms "first," "second," "third," etc. are used for descriptive purposes only and should not be construed to indicate or imply relative importance.

1-5, the present invention provides a technical solution: a receiver for D2D communication technology in 5G communication with an adjustable signal source, comprising a base 1, a receiver body 2, a panel 3, a fan top cover 4, and a fan 5 , joint 6, first rotating shaft 7, antenna 8, heat dissipation mechanism 9, heat dissipation window 901, rotating shaft 902, shutter 903, moving mechanism 10, pulley frame 1001, guide rail 1002, post 1003, jack 1004, wire harness Mechanism 11, wire harness groove 1101, second rotating shaft 1102, wire harness rod 1103, partition plate 1104, wire clamping mechanism 12, threading groove 1201, spring 1202, splint 1203 and display screen 13, the upper end of base 1 is provided with a receiving The main body 2 of the receiver is connected to the main body 2 of the receiver, and the main body 2 of the receiver and the base 1 are bonded together. The front surface of the main body of the receiver 2 is arranged with a panel 3, and the panel 3 and the main body of the receiver 2 are connected by bolts. The heat dissipation mechanism 9 is embedded in the panel 3. The inside of the heat dissipation mechanism 9 includes a heat dissipation window 901, and the heat dissipation window 901 and the panel 3 are integrally connected by injection molding. The inner walls of both sides of the heat dissipation window 901 are provided with rotating shafts 902, and the rotating shafts 902 are close to the heat dissipation. One end of the center line of the window 901 is provided with a shutter 903, and the shutters 903 are arranged at equal distances inside the heat dissipation window 901, and the shutter 903 forms a rotating structure with the heat dissipation window 901 through the rotating shaft 902. When blowing and dissipating heat, the shutter 903 is pushed by the wind, and automatically rotates along the rotating shaft 902, so that the heat dissipation window 901 is in an open state, and the heat inside the receiver body 2 can be dissipated. When the heat dissipation is stopped, the shutter 903 After no thrust, the manual self-gravity rotates in the reverse direction along the rotating shaft 902, and the shutter 903 and the shutter 903 are connected to each other, so that the heat dissipation window 901 is in a closed state, which can prevent external dust from entering from the heat dissipation window 901. To the inside of the receiver body 2, it can effectively solve the problem that the dust and impurities from the outside easily enter the receiver from the heat sink in the past, which will affect the internal components and affect the reception of the signal;

The moving mechanism 10 is connected to the lower end of the base 1, the interior of the moving mechanism 10 includes a pulley frame 1001, and the pulley frame 1001 and the base 1 are welded and fixed, the lower end of the pulley frame 1001 is embedded with a guide rail 1002, and one end of the guide rail 1002 is connected There is a pin 1003, the pin 1003 and the guide rail 1002 are fixed by welding, and the other end of the guide rail 1002 is installed with a socket 1004, the base 1 forms a sliding structure through the pulley frame 1001 and the guide rail 1002, and the guide rail 1002 is "T" type structure, the base 1 can slide on the upper end of the guide rail 1002, then the receiver body 2 can move, instead of the fixed receiver in the past, so when the signal is unstable, the receiver body 2 can be moved to enlarge By adjusting the signal source in the range, the receiver body 2 can receive the signal stably, which effectively solves the problem that the receiver received the signal from a fixed place in the past. When the signal is not good, the signal source can only be adjusted by adjusting the antenna 8, but The effect is not very ideal. The shape of the post 1003 is the same as the shape of the socket 1004, and the post 1003 and the guide rail 1002 are fixedly connected. The post 1003 can be inserted into the socket 1004, and the rail can be realized. The splicing between 1002 and the guide rail 1002, so that the moving distance and moving range of the receiver body 2 can be changed by splicing the guide rail 1002, which can help the receiver body 2 to better adjust the signal source and enhance the stability of the signal;

The wire harnessing mechanism 11 is installed on the front of the receiver body 2 , and the wire harnessing mechanism 11 is fixed with a wire clamping mechanism 12 . An integrated connection is formed by injection molding, a second rotating shaft 1102 is fixed on the inner side of the wire harness groove 1101, and a wire harness rod 1103 is arranged on one side of the second rotating shaft 1102, and the outer wall of the wire harness rod 1103 is arranged with a dividing The partition plate 1104, the partition plate 1104 is arranged on the outer wall of the wire harness rod 1103 at equal distances, and the wire harness rod 1103 forms a rotating structure through the second rotating shaft 1102 and the wire harness groove 1101, and the wire harness rod 1103 can attach the receiver body 2 to the The connecting wire is wound and bundled, and the separating plate 1104 can clamp and separate each winding of the connecting wire, so that the connecting wire is wound on the wire harness rod 1103 in an orderly manner, and the wire harness rod 1103 can be along the Rotate the wire harness groove 1101 along the second rotating shaft 1102, so that the wound connecting wire can be hidden in the wire harness groove 1101, so as to avoid the scattered outer side of the connecting wire on the receiver body 2;

The inside of the threading mechanism 12 includes a threading groove 1201, and the threading groove 1201 and the partition plate 1104 are integrally connected by injection molding. Springs 1202 are embedded on both sides of the interior of the threading groove 1201, and the springs 1202 are close to the center of the threading groove 1201. One end of the line is connected with a splint 1203, the splint 1203 forms an elastic expansion and contraction structure through the spring 1202 and the threading groove 1201, and the splint 1203 is axisymmetric about the center line of the threading groove 1201. When reaching the wire harness rod 1103, the connecting wire is made to pass through the dividing plate 1104, and the two opposite splints 1203 are close to each other by the elastic force of the spring 1202, so that the connecting wire can be clamped in the wire threading groove 1201 to prevent The connecting wire is detached from the wire harness rod 1103 and the partition plate 1104, the upper end of the receiver main body 2 is provided with a fan top cover 4, and the fan top cover 4 is arranged with a fan 5 inside, and one side inner wall of the receiver main body 2 is provided. A joint 6 is embedded inside, and a first rotating shaft 7 is connected to one side of the receiver body 2. The first rotating shaft 7 and the joint 6 are fixed by welding, and an antenna 8 is installed on the upper end of the first rotating shaft 7 to receive A display screen 13 is fixed on the back of the device main body 2 .

The working principle of this embodiment: the receiver for D2D communication technology in the adjustable signal source 5G communication firstly splices the guide rails 1002 as needed, and inserts the posts 1003 on the first guide rail 1002 into the guide rail 1002 at the other end The guide rails 1002 are spliced in sequence in the socket 1004 of the base 1. After the splicing is completed, the pulley frame 1001 at the lower end of the base 1 corresponds to the guide rail 1002, so that the pulleys on both sides of the pulley frame 1001 are in contact with the guide rail 1002. When the signal source needs to be adjusted When the gear motor at the lower end of the base 1 is turned on, the output end of the high gear motor drives the drive shaft in the pulley frame 1001 to rotate through the transmission belt, and the drive shaft drives the pulleys at both ends to rotate, then the pulley frame 1001 drives the base 1 and the receiver at the upper end. The main body 2 moves along the guide rail 1002, instead of the fixed receiver in the past, so that when the signal is unstable, the receiver main body 2 can adjust the signal source in a large range by moving, so that the receiver main body 2 can be stable. When receiving the signal, when the receiver body 2 needs to dissipate heat, the fan 5 in the fan top cover 4 is started, and the fan 5 blows and dissipates the internal components, and the shutter 903 is driven by the wind and automatically rotates along the rotation axis 902. , so that the heat dissipation window 901 is in an open state, the heat inside the receiver body 2 can be dissipated. When the heat dissipation is stopped, after the shutter 903 is not thrust, the manual self-gravity rotates in the reverse direction along the rotating shaft 902, and the shutter 903 and the The shutters 903 are connected to each other, so that the heat dissipation window 901 is in a closed state, so as to prevent external dust from entering the receiver body 2 from the heat dissipation window 901. It is wound on the wire harness rod 1103 in turn, and then passes through the wire threading groove 1201 on the dividing plate 1104, so that the connecting wire is wound on the wire harness rod 1103 in an orderly manner, and the two opposite splints in the wire threading groove 1201. 1203 are respectively subjected to the elastic force of the spring 1202, and the connecting wire is clamped in the threading groove 1201. After the connecting wire is bundled, the wire harnessing rod 1103 is rotated along the second rotating shaft 1102 into the wire harnessing groove 1101.

Although the present invention has been described in detail with reference to the foregoing embodiments, for those skilled in the art, it is still possible to modify the technical solutions described in the foregoing embodiments, or to perform equivalent replacements for some of the technical features. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention shall be included within the protection scope of the present invention.

Claims (1)

1. A receiver for D2D communication technology in an adjustable signal source 5G communication, comprising a base (1), a heat dissipation mechanism (9), a moving mechanism (10) and a beamline mechanism (11), characterized in that: the base ( 1) The upper end of the receiver body (2) is provided with a receiver body (2), and the receiver body (2) and the base (1) are bonded, and a panel (3) is arranged on the front of the receiver body (2), and the panel (3) is connected with the receiver main body (2) by bolts, the heat dissipation mechanism (9) is inlaid on the front of the panel (3), the moving mechanism (10) is connected to the lower end of the base (1), the The wire harnessing mechanism (11) is installed on the front surface of the receiver main body (2), the wire clamping mechanism (12) is fixed inside the wire harnessing mechanism (11), and the upper end of the receiver main body (2) is provided with a fan top cover (4), and the fan (5) is arranged inside the fan top cover (4), the inner wall of one side of the receiver body (2) is inlaid with a joint (6), and one side of the receiver body (2) A first rotating shaft (7) is connected, the first rotating shaft (7) and the joint (6) are fixed by welding, and an antenna (8) is installed on the upper end of the first rotating shaft (7), and the receiving A display screen (13) is fixed on the back of the main body (2), the heat dissipation mechanism (9) includes a heat dissipation window (901), and the heat dissipation window (901) and the panel (3) are integrated by injection molding connection, a rotating shaft (902) is provided inside the inner walls of both sides of the heat dissipation window (901), and a shutter (903) is arranged at one end of the rotating shaft (902) close to the centerline of the heat dissipation window (901), and the shutter (903) are equidistantly arranged inside the heat dissipation window (901), and the shutter (903) forms a rotating structure through the rotating shaft (902) and the heat dissipation window (901), and the interior of the moving mechanism (10) includes a pulley frame (1001), and the pulley frame (1001) and the base (1) are fixed by welding, the lower end of the pulley frame (1001) is inlaid with a guide rail (1002), and one end of the guide rail (1002) is connected with a post (1003) ), the post (1003) and the guide rail (1002) are welded and fixed, and the inner other end of the guide rail (1002) is provided with a socket (1004), and the base (1) is connected to the base (1) through the pulley frame (1001). The guide rail (1002) constitutes a sliding structure, and the guide rail (1002) has a "T"-shaped structure, the shape of the post (1003) is the same as that of the socket (1004), and the post (1003) and the guide rail (1002) There is a fixed connection therebetween, the wire harness mechanism (11) includes a wire harness groove (1101) inside, and the wire harness groove (1101) and the receiver body (2) are integrally connected by injection molding. A second rotating shaft (1102) is fixed on the inner side of the wire harness groove (1101), and a wire harness rod (1103) is arranged on one side of the second rotating shaft (1102), and the outer wall of the wire harness rod (1103) is A divider plate (1104) is placed, The dividing plates (1104) are equidistantly arranged on the outer wall of the wire harnessing rod (1103), and the wire harnessing rod (1103) forms a rotating structure through the second rotating shaft (1102) and the wire harnessing groove (1101). The interior of the threading mechanism (12) includes a threading groove (1201), and the threading groove (1201) and the partition plate (1104) are integrally connected by injection molding, and both sides of the interior of the threading groove (1201) are inlaid with A spring (1202), and one end of the spring (1202) close to the center line of the threading groove (1201) is connected with a splint (1203), and the splint (1203) forms an elastic expansion and contraction structure through the spring (1202) and the threading groove (1201), and The clamping plate (1203) is axisymmetric about the center line of the threading groove (1201).

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