Receiver for D2D communication technology in adjustable signal source 5G communication
Technical Field
The invention relates to the technical field of 5G communication, in particular to a receiver for a D2D communication technology in adjustable signal source 5G communication.
Background
In the evolution of 5G-oriented wireless communication technology, as a key candidate technology for 5G, the device-to-device D2D communication technology has potential prospects of improving system performance, improving user experience, and expanding cellular communication applications, and is receiving wide attention, whereas in 5G communication, a signal receiver is required to receive a signal, and the quality of the signal is affected by the quality of the receiver.
The existing receiver is fixed, receives signals from a fixed place, and can only adjust a signal source by adjusting an antenna when the signals are poor, but the effect is not ideal, and the receiver is provided with a heat dissipation device, external dust and impurities easily enter the receiver from the heat dissipation device, influence is caused on internal components, and the signal receiving is influenced.
Disclosure of Invention
The invention aims to provide a receiver for D2D communication technology in adjustable signal source 5G communication, which solves the problems that the existing receivers proposed in the background art are all fixed, receive signals from a fixed place, and can only adjust the signal source by adjusting an antenna when the signals are poor, but the effect is not ideal, and the receiver is provided with a heat dissipation device, so that external dust and impurities easily enter the receiver from the heat dissipation device, influence is caused on internal components, and the reception of the signals is influenced.
In order to achieve the purpose, the invention provides the following technical scheme: a receiver for D2D communication technology in adjustable signal source 5G communication comprises a base, a heat dissipation mechanism, a moving mechanism and a wire bundling mechanism, wherein a receiver main body is arranged at the upper end of the base, the receiver main body is bonded with the base, a panel is arranged on the front side of the receiver main body, the panel is connected with the receiver main body through a bolt, the heat dissipation mechanism is embedded in the front side of the panel, the moving mechanism is connected with the lower end of the base, the wire bundling mechanism is arranged on the front side of the receiver main body, a wire clamping mechanism is fixed in the wire bundling mechanism, a fan top cover is arranged at the upper end of the receiver main body, a fan is arranged in the fan top cover, a connector is embedded in the inner wall of one side of the receiver main body, a first rotating shaft is connected with one side of the receiver main body, and the first rotating shaft and the connector, and the antenna is installed to the upper end of first axis of rotation, the back of receiver main part is fixed with the display screen.
Preferably, the inside of the heat dissipation mechanism comprises a heat dissipation window, the heat dissipation window and the panel are integrally connected through injection molding, rotating shafts are arranged inside inner walls of two sides of the heat dissipation window, and a shielding plate is arranged at one end, close to the center line of the heat dissipation window, of each rotating shaft.
Preferably, the shutters are equidistantly arranged inside the heat dissipation window, and the shutters and the heat dissipation window form a rotating structure through a rotating shaft.
Preferably, the inside of moving mechanism is including the pulley yoke, and is welded fastening between pulley yoke and the base, the lower extreme of pulley yoke is inlayed and is had the guide rail, and the one end of guide rail is connected with and inserts the post, insert for welded fastening between post and the guide rail, and the jack is installed to the inside other end of guide rail.
Preferably, the base and the guide rail form a sliding structure through a pulley yoke, and the guide rail is in a T-shaped structure.
Preferably, the shape of the inserting column is the same as that of the inserting hole, and the inserting column is fixedly connected with the guide rail.
Preferably, the inside of the wire bundling mechanism comprises a wire bundling groove, the wire bundling groove and the receiver main body are integrally connected through injection molding, a second rotating shaft is fixed on one side of the inside of the wire bundling groove, a wire bundling rod is arranged on one side of the second rotating shaft, and a partition plate is arranged on the outer wall of the wire bundling rod.
Preferably, the separation plates are equidistantly arranged on the outer wall of the wire bundling rod, and the wire bundling rod and the wire bundling groove form a rotating structure through the second rotating shaft.
Preferably, the inside of thread clamping mechanism is including the threading groove, and constitutes the integration through moulding plastics between threading groove and the division board and be connected, the inside both sides in threading groove are inlayed and are had the spring, and the spring is connected with splint near the one end of threading groove central line.
Preferably, the clamping plate and the threading groove form an elastic telescopic structure through a spring, and the clamping plate is symmetrical about a central line of the threading groove.
Compared with the prior art, the invention has the beneficial effects that:
1. D2D for communication technology receiver passes through the fan start-up and when the heat dissipation of blowing to receiver main part inside in this adjustable signal source 5G communication, the sunshade receives the promotion of wind-force, it rotates along the rotation axis automatically, make the heat dissipation window be open state, then the inside heat of receiver main part can distribute out, when stopping the heat dissipation, the sunshade does not receive thrust back, manual self gravity rotates along rotation axis antiport, interconnect between sunshade and the sunshade, it is closed state to make the heat dissipation window, just so can prevent that external dust from entering into the inside of receiver main part from the heat dissipation window, effectual solution was inside external dust impurity entered into the receiver easily from heat abstractor in the past, cause the influence to the subassembly of inside, then can influence the problem of the acceptance to the signal.
2. The receiver for the D2D communication technology in the adjustable signal source 5G communication can slide at the upper end of the guide rail through the base, and then the receiver main body can move to replace the fixed form of the receiver in the past.
3. D2D communication technology can insert the jack in through inserting the post with the receiver in this adjustable signal source 5G communication, then can realize the concatenation between guide rail and the guide rail, can change the migration distance and the migration range of receiver main part through the concatenation guide rail like this, can help the better adjustment signal source of receiver main part like this, the stability of reinforcing signal.
4. D2D communication technology can be collected the connecting wire winding in the receiver main part through the pencil pole with the receiver in this adjustable signal source 5G communication, and the division board can press from both sides tightly every circle of connecting wire of winding and separate, makes the orderly winding of connecting wire on the pencil pole, and the pencil pole can rotate the pencil inslot along the second axis of rotation, can hide the pencil inslot with the connecting wire that twines like this, just so can avoid the scattered outside of connecting wire in the receiver main part.
5. There is the threading groove on this D2D receiver for communication technology in adjustable signal source 5G communication through the division board, can make the connecting wire run through in the division board when twining the connecting wire to bunch pole on, and two relative splint receive the elastic force of spring and be close to each other, then can press from both sides the connecting wire tightly in the threading groove, prevent that the connecting wire from taking off from bunch pole and division board and getting off.
Drawings
Fig. 1 is a schematic structural diagram of a receiver for D2D communication technology in adjustable signal source 5G communication according to the present invention;
FIG. 2 is a schematic diagram of a right-view structure of a receiver body of a receiver for D2D communication technology in adjustable signal source 5G communication according to the present invention;
fig. 3 is a schematic diagram of a left side view and an enlarged structure of a separation plate of a receiver for D2D communication technology in adjustable signal source 5G communication according to the present invention;
FIG. 4 is an enlarged schematic diagram of a receiver at A in FIG. 2 for D2D communication technology in communication with an adjustable signal source 5G according to the present invention;
fig. 5 is a schematic rear view of a receiver body of a receiver for D2D communication technology in adjustable signal source 5G communication according to the present invention.
In the figure: 1. a base; 2. a receiver body; 3. a panel; 4. a fan top cover; 5. a fan; 6. a joint; 7. a first rotating shaft; 8. an antenna; 9. a heat dissipation mechanism; 901. a heat dissipation window; 902. a rotating shaft; 903. a shutter; 10. a moving mechanism; 1001. a pulley yoke; 1002. a guide rail; 1003. inserting a column; 1004. a jack; 11. a wire bundling mechanism; 1101. a wiring trough; 1102. a second rotating shaft; 1103. a wire bundling rod; 1104. a partition plate; 12. a wire clamping mechanism; 1201. a threading slot; 1202. a spring; 1203. a splint; 13. a display screen.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.
In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.
Referring to fig. 1-5, the present invention provides a technical solution: a receiver for D2D communication technology in adjustable signal source 5G communication comprises a base 1, a receiver main body 2, a panel 3, a fan top cover 4, a fan 5, a joint 6, a first rotating shaft 7, an antenna 8, a heat dissipation mechanism 9, a heat dissipation window 901, a rotating shaft 902, a shielding plate 903, a moving mechanism 10, a pulley frame 1001, a guide rail 1002, an insertion column 1003, an insertion hole 1004, a wire bundling mechanism 11, a wire bundling groove 1101, a second rotating shaft 1102, a wire bundling rod 1103, a separation plate 1104, a wire clamping mechanism 12, a wire threading groove 1201, a spring 1202, a clamping plate 1203 and a display screen 13, wherein the receiver main body 2 is arranged at the upper end of the base 1, the receiver main body 2 and the base 1 are bonded, the panel 3 is arranged on the front surface of the receiver main body 2, the panel 3 is connected with the receiver main body 2 through bolts, the heat dissipation mechanism 9 is embedded in the front surface of the panel 3, the heat dissipation window 901 is integrally connected with the panel 3 by injection molding, a rotating shaft 902 is arranged inside the inner walls of the two sides of the heat dissipation window 901, a cover plate 903 is arranged at one end of the rotating shaft 902 close to the center line of the heat dissipation window 901, the cover plates 903 are arranged inside the heat dissipation window 901 at equal intervals, the cover plates 903 and the heat dissipation window 901 form a rotating structure through the rotating shaft 902, when the fan 5 starts to blow and dissipate heat inside the receiver main body 2, the cover plates 903 are pushed by wind power to automatically rotate along the rotating shaft 902, so that the heat dissipation window 901 is in an open state, heat inside the receiver main body 2 can be dissipated, when heat dissipation is stopped, the cover plates 903 do not receive thrust force, manual self gravity reversely rotates along the rotating shaft 902, the cover plates 903 and the cover plates 903 are mutually connected, so that the heat dissipation window 901 is in a closed state, thereby preventing external dust from entering the inside, the problem that in the past, external dust and impurities easily enter the receiver from the heat dissipation device to affect internal components and affect signal reception is effectively solved;
the moving mechanism 10 is connected to the lower end of the base 1, the inside of the moving mechanism 10 comprises a pulley frame 1001, the pulley frame 1001 and the base 1 are welded and fixed, the lower end of the pulley frame 1001 is inlaid with a guide rail 1002, one end of the guide rail 1002 is connected with an inserting column 1003, the inserting column 1003 and the guide rail 1002 are welded and fixed, the other end inside the guide rail 1002 is provided with an inserting hole 1004, the base 1 and the guide rail 1002 form a sliding structure through the pulley frame 1001, the guide rail 1002 is in a T-shaped structure, the base 1 can slide on the upper end of the guide rail 1002, the receiver main body 2 can move, the fixing mode of the receiver in the past is replaced, when the signal is unstable, the receiver main body 2 can adjust the signal source in a large range through moving, the receiver main body 2 can stably receive the signal, the problem that the receiver in the past receives the signal from a, when the signal is not good, the signal source can be adjusted only by adjusting the antenna 8, but the effect is not ideal, the shape of the inserting column 1003 is the same as that of the inserting hole 1004, the inserting column 1003 is fixedly connected with the guide rail 1002, and the inserting column 1003 can be inserted into the inserting hole 1004, so that the guide rail 1002 and the guide rail 1002 can be spliced, the moving distance and the moving range of the receiver main body 2 can be changed by splicing the guide rail 1002, and the signal source can be adjusted better by the receiver main body 2, and the stability of the signal is enhanced;
the wire bunching mechanism 11 is installed on the front face of the receiver main body 2, the wire clamping mechanism 12 is fixed inside the wire bunching mechanism 11, the wire bunching mechanism 11 comprises a wire bunching groove 1101, the wire bunching groove 1101 and the receiver main body 2 are integrally connected through injection molding, a second rotating shaft 1102 is fixed on one side of the inside of the wire bunching groove 1101, a wire bunching rod 1103 is arranged on one side of the second rotating shaft 1102, a partition plate 1104 is arranged on the outer wall of the wire bunching rod 1103, the partition plates 1104 are equidistantly arranged on the outer wall of the wire bunching rod 1103, the wire bunching rod 1103 and the wire bunching groove 1101 form a rotating structure through the second rotating shaft 1102, the wire bunching rod 1103 can bunch connection wires on the receiver main body 2, the partition plate 1104 can clamp and separate every circle of wound connection wires, the connection wires are orderly wound on the wire bunching rod 1103, and the wire bunching rod 1103, this allows the wound connecting wires to be hidden in the harness slot 1101, which prevents the connecting wires on the receiver body 2 from being scattered outside;
the interior of the wire clamping mechanism 12 comprises a threading slot 1201, the threading slot 1201 and the partition plate 1104 are integrally connected through injection molding, springs 1202 are inlaid on two sides of the interior of the threading slot 1201, one end, close to the central line of the threading slot 1201, of each spring 1202 is connected with a clamp plate 1203, each clamp plate 1203 forms an elastic telescopic structure with the threading slot 1201 through the corresponding spring 1202, the clamp plates 1203 are axisymmetric with respect to the central line of the threading slot 1201, the threading slot 1201 is formed in the partition plate 1104, when a connecting wire is wound on the bunching rod 1103, the connecting wire can penetrate through the partition plate 1104, two opposite clamp plates 1203 approach to each other under the elastic force of the springs 1202, the connecting wire can be clamped in the threading slot 1201, the connecting wire is prevented from falling off from the bunching rod 1103 and the partition plate 1104, a blower top cover 4 is arranged at the upper end of the receiver body 2, a blower 5 is arranged in the blower top cover 4, a joint 6 is, and one side of the receiver main body 2 is connected with a first rotating shaft 7, the first rotating shaft 7 and the joint 6 are welded and fixed, an antenna 8 is installed at the upper end of the first rotating shaft 7, and a display screen 13 is fixed on the back of the receiver main body 2.
The working principle of the embodiment is as follows: the receiver for the D2D communication technology in the adjustable signal source 5G communication is characterized in that firstly, guide rails 1002 are spliced according to needs, inserting columns 1003 on a first section of guide rails 1002 are inserted into inserting holes 1004 in the guide rails 1002 at the other end, the guide rails 1002 are spliced in sequence, after splicing is completed, pulley frames 1001 at the lower end of a base 1 are correspondingly arranged on the guide rails 1002, pulleys at two sides in the pulley frames 1001 are in contact with the guide rails 1002, when the signal source needs to be adjusted, a speed reducing motor at the lower end of the base 1 is turned on, output ends of a high speed reducing motor drive transmission shafts in the pulley frames 1001 to rotate through a transmission belt, the transmission shafts drive the pulleys at two ends to rotate, then the pulley frames 1001 drive the base 1 and a receiver main body 2 at the upper end to move along the guide rails 1002, the form that the receiver is fixed in the past is replaced, and, the receiver main body 2 can stably receive signals, when the inside of the receiver main body 2 needs to dissipate heat, the fan 5 in the fan top cover 4 is started, the fan 5 blows air to dissipate heat of the internal components, the cover 903 is pushed by wind power to automatically rotate along the rotating shaft 902, the heat dissipation window 901 is in an open state, heat inside the receiver main body 2 can be dissipated, when heat dissipation is stopped, after the cover 903 is not pushed, the cover 903 is manually rotated along the rotating shaft 902 in the reverse direction by gravity, the cover 903 and the cover 903 are connected with each other, the heat dissipation window 901 is in a closed state, so that external dust can be prevented from entering the inside of the receiver main body 2 from the heat dissipation window 901, when the connecting wires need to be collected, the connecting wires 1104 are sequentially wound on the bunching rods 1103 and then pass through the threading grooves 1201 on the partition plate, the connecting wire is orderly wound on the bunching rod 1103, two opposite clamping plates 1203 in the threading groove 1201 are respectively subjected to elastic force of the springs 1202, the connecting wire is clamped in the threading groove 1201, and after the connecting wire is completely bunched, the bunching rod 1103 is rotated in the bunching groove 1101 along the second rotating shaft 1102.
Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.