CN216563534U - Integrative radium carving of many antennas combination plates structure antenna - Google Patents
Integrative radium carving of many antennas combination plates structure antenna Download PDFInfo
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- CN216563534U CN216563534U CN202123226471.9U CN202123226471U CN216563534U CN 216563534 U CN216563534 U CN 216563534U CN 202123226471 U CN202123226471 U CN 202123226471U CN 216563534 U CN216563534 U CN 216563534U
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- 229910052705 radium Inorganic materials 0.000 title claims abstract description 15
- HCWPIIXVSYCSAN-UHFFFAOYSA-N radium atom Chemical compound [Ra] HCWPIIXVSYCSAN-UHFFFAOYSA-N 0.000 title claims abstract description 15
- 230000005855 radiation Effects 0.000 claims abstract description 190
- 238000010329 laser etching Methods 0.000 claims abstract description 26
- 238000007747 plating Methods 0.000 claims abstract description 7
- 230000008878 coupling Effects 0.000 claims description 10
- 238000010168 coupling process Methods 0.000 claims description 10
- 238000005859 coupling reaction Methods 0.000 claims description 10
- 238000004891 communication Methods 0.000 claims description 4
- 238000004519 manufacturing process Methods 0.000 abstract description 7
- 238000003466 welding Methods 0.000 abstract description 7
- ATJFFYVFTNAWJD-UHFFFAOYSA-N Tin Chemical compound [Sn] ATJFFYVFTNAWJD-UHFFFAOYSA-N 0.000 abstract description 5
- 238000000034 method Methods 0.000 abstract description 5
- 238000005516 engineering process Methods 0.000 abstract description 4
- 238000010586 diagram Methods 0.000 description 7
- 238000013461 design Methods 0.000 description 5
- 230000008569 process Effects 0.000 description 4
- 238000012360 testing method Methods 0.000 description 3
- 239000004606 Fillers/Extenders Substances 0.000 description 2
- 239000003623 enhancer Substances 0.000 description 2
- 239000000463 material Substances 0.000 description 2
- 239000000243 solution Substances 0.000 description 2
- 238000005452 bending Methods 0.000 description 1
- 230000008859 change Effects 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000002347 injection Methods 0.000 description 1
- 239000007924 injection Substances 0.000 description 1
- 238000001746 injection moulding Methods 0.000 description 1
- 238000003780 insertion Methods 0.000 description 1
- 230000037431 insertion Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000004080 punching Methods 0.000 description 1
- 230000008054 signal transmission Effects 0.000 description 1
- 238000005476 soldering Methods 0.000 description 1
- 239000000126 substance Substances 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
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Abstract
The application relates to the field of WIFI routers and signal intensifiers, and provides an integrated laser etching plating structure antenna with a multi-antenna combination. The method comprises the following steps: support and WIFI antenna, the WIFI antenna is plated through radium carving the support surface, the WIFI antenna includes: the antenna comprises a first antenna radiation unit, a second antenna radiation unit, a third antenna radiation unit, a fourth antenna radiation unit, a fifth antenna radiation unit, a sixth antenna radiation unit, a seventh antenna radiation unit and an eighth antenna radiation unit, wherein the eight antenna radiation units are sequentially connected end to form a closed ring. The application provides a pair of integrative radium carving of many antenna combinations plates structure antenna has increased a plurality of passageways and signal strength for the router, has saved the required wire rod needs in the technology of production dial the line, beat the terminal, bend, the tin sticky to and with required welding between the antenna body.
Description
Technical Field
The application relates to the field of WIFI routers and signal intensifiers, in particular to an integrated laser etching plating structure antenna with a multi-antenna combination.
Background
With the rapid development of wireless communication technology, wireless communication is realized in public places, hotels, homes and the like, but the requirement on the use of public Wi-Fi is higher and higher, people are required to enter office buildings, Wi-Fi signals can be connected in all corners when people enter the office buildings, the shopping malls and the homes, the signal strength is not changed, the network speed and the experience are not affected, and the need of re-networking is avoided due to the change of network routers. The implementation of such wireless communication is achieved by a wireless router terminal. However, the range of the terminal of the wireless router is limited, many dead corners cannot be covered, such as underground parking lots, toilets and sundries cannot be covered, and the farther the distance from the terminal of the wireless router is, the weaker the signal received by the mobile device (such as a mobile phone, a computer, etc.) is, the slower the speed of the user accessing the internet is, and the poorer the user experience effect is.
In order to cover all model blank areas and dead corners, the WIFI extender is developed, the coverage range of wireless signals of the wireless router terminal can be enlarged through the WIFI extender, meanwhile, the wireless signals can be enhanced, and the internet access speed of the mobile terminal is higher.
In practical production, in order to add more signal channels and improve the structural design of the antenna, and according to the speed and channel requirements of signals, a certain number of antennas are integrated into a router or an enhancer.
Among the prior art, when integrating a certain amount of antennas in a router or the intensifier, the antenna design is based on single antenna independent design and walks the line overall arrangement, and need carry out the welding of wire rod or SMT's mode according to the product structure and weld, then communicate the PCB board end of being connected to the product with a certain amount of antennas, but the antenna is when assembling the complete machine structure, the lock that needs a plurality of terminals with walk the line, and the wire rod and the welding process that need match when antenna itself is producing, the high management and control of soldering tin of welding back product can not be accurate management and control well.
SUMMERY OF THE UTILITY MODEL
To above-mentioned problem, the application provides an integrative radium carving of many antenna combinations plates structure antenna, includes: support and WIFI antenna.
The WIFI antenna is plated on the surface of the support through laser etching.
The WIFI antenna includes: the antenna comprises a first antenna radiation unit, a second antenna radiation unit, a third antenna radiation unit, a fourth antenna radiation unit, a fifth antenna radiation unit, a sixth antenna radiation unit, a seventh antenna radiation unit and an eighth antenna radiation unit, wherein the eight antenna radiation units are sequentially connected end to form a closed ring.
The first antenna radiating element and the second antenna radiating element are higher than the third antenna radiating element, the fourth antenna radiating element, the fifth antenna radiating element, the sixth antenna radiating element, the seventh antenna radiating element and the eighth antenna radiating element.
Optionally, the first antenna radiating element comprises: the antenna comprises a first antenna feed point and a first antenna grounding point, wherein the first antenna feed point is rectangular and is positioned at the top end of the first antenna radiation unit and parallel to the bottom of the WIFI antenna, the first antenna grounding point is annular and is arranged at the joint between the antenna radiation units and parallel to the bottom of the WIFI antenna, a round hole is further formed under the first antenna grounding point, and the inner diameter of the round hole is equal to that of the first antenna grounding point.
Optionally, the second antenna radiation unit includes: the second antenna feed point is rectangular and is positioned at the top end of the second antenna radiation unit and parallel to the bottom of the WIFI antenna, the second antenna ground point is circular and is arranged at the joint between the antenna radiation units and parallel to the bottom of the WIFI antenna, a round hole is further formed under the second antenna ground point, and the inner diameter of the round hole is equal to that of the second antenna ground point.
Optionally, the third antenna radiation unit includes: the third antenna feed point is rectangular and is positioned at the top end of the third antenna radiation unit and parallel to the bottom of the WIFI antenna, the third antenna ground point is circular and is arranged at the joint between the antenna radiation units and parallel to the bottom of the WIFI antenna, a round hole is further formed under the third antenna ground point, and the inner diameter of the round hole is equal to that of the third antenna ground point.
Optionally, the fourth antenna radiation unit includes: the antenna comprises a fourth antenna feed point and a fourth antenna ground point, wherein the fourth antenna feed point is rectangular, is positioned at the top end of the fourth antenna radiation unit and is parallel to the bottom of the WIFI antenna, the fourth antenna ground point is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna, a round hole is further formed under the fourth antenna ground point, and the inner diameter of the round hole is equal to that of the fourth antenna ground point.
Optionally, the fourth antenna radiation unit further includes: a fourth coupled antenna located below the fourth antenna feed point and a fourth antenna ground point.
Optionally, the fifth antenna radiation unit includes: the antenna comprises a fifth antenna feed point and a fifth antenna grounding point, wherein the fifth antenna feed point is rectangular, is positioned at the top end of the fifth antenna radiation unit and is parallel to the bottom of the WIFI antenna, the fifth antenna grounding point is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna, a round hole is further formed under the fifth antenna grounding point, and the inner diameter of the round hole is equal to that of the fifth antenna grounding point.
Optionally, the fifth antenna radiation unit further includes: a fifth coupled antenna located below the fifth antenna feed point and a fifth antenna ground point.
Optionally, the sixth antenna radiation unit includes: the antenna comprises a sixth antenna feed point and a sixth antenna grounding point, wherein the sixth antenna feed point is rectangular, is positioned at the top end of the sixth antenna radiation unit and is parallel to the bottom of the WIFI antenna, the sixth antenna grounding point is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna, a round hole is further arranged under the sixth antenna grounding point, and the inner diameter of the round hole is equal to that of the sixth antenna grounding point.
Optionally, the sixth antenna radiation unit further includes: a sixth coupled antenna located below the sixth antenna feed point and a sixth antenna ground point.
Optionally, the seventh antenna radiation unit includes: the antenna comprises a seventh antenna feed point and a seventh antenna grounding point, wherein the seventh antenna feed point is rectangular, is positioned at the top end of the seventh antenna radiation unit and is parallel to the bottom of the WIFI antenna, the seventh antenna grounding point is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna, a round hole is further arranged under the seventh antenna grounding point, and the inner diameter of the round hole is equal to that of the seventh antenna grounding point.
Optionally, the seventh antenna radiation unit further includes: the feed-side seventh coupling antenna is close to the seventh antenna feed point, is far away from the seventh antenna grounding point, and is located below the seventh antenna feed point, and the ground-side seventh coupling antenna is close to the seventh antenna grounding point, is far away from the seventh antenna feed point, and is located below the seventh antenna grounding point.
Optionally, the eighth antenna radiation unit includes: the antenna comprises an eighth antenna feed point and an eighth antenna ground point, wherein the eighth antenna feed point is rectangular, is positioned at the top end of the eighth antenna radiation unit and is parallel to the bottom of the WIFI antenna, the eighth antenna ground point is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna, a round hole is further formed under the eighth antenna ground point, and the inner diameter of the round hole is equal to that of the eighth antenna ground point.
Optionally, the working frequency bands of the first antenna radiation unit and the second antenna radiation unit are located at a WIFI 2.4GHz frequency band.
Optionally, the working frequency bands of the third antenna radiation unit, the fourth antenna radiation unit, the fifth antenna radiation unit, the sixth antenna radiation unit, the seventh antenna radiation unit, and the eighth antenna radiation unit are located at a WIFI 5GHz frequency band.
Optionally, the support is a plastic support.
According to the above technical scheme, the present application provides an integrative radium carving of many antenna combinations plates structure antenna and includes: support and WIFI antenna. The WIFI antenna is plated on the surface of the support through laser etching. The WIFI antenna includes: the antenna comprises a first antenna radiation unit, a second antenna radiation unit, a third antenna radiation unit, a fourth antenna radiation unit, a fifth antenna radiation unit, a sixth antenna radiation unit, a seventh antenna radiation unit and an eighth antenna radiation unit, wherein the eight antenna radiation units are sequentially connected end to form a closed ring. The first antenna radiating element and the second antenna radiating element are higher than the third antenna radiating element, the fourth antenna radiating element, the fifth antenna radiating element, the sixth antenna radiating element, the seventh antenna radiating element and the eighth antenna radiating element.
In practical application, the application provides an integrative radium carving of many antenna combinations plates structure antenna, through eight antenna radiating element's ground point and the round hole of below, as the hole that the screw lock was paid, usable screw assembles the antenna that this application provided to router or route signal intensifier product the inside, the antenna feed point of every antenna radiating element is through bullet foot direct and PCB contact intercommunication, the antenna that this application provided after the switch-on can provide 2.4G-5 GWIFISI channel, and the wide coverage, because many antennas work simultaneously, for the router has increased a plurality of passageways and signal strength, dial the line that required wire rod needs in the technology of having saved production, beat the terminal, bend, the tin sticky, and with required welding between the antenna body.
Drawings
In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.
FIG. 1 is a schematic view of a stent provided herein;
fig. 2 is an overall frame diagram of an integrated antenna with a laser etching and plating structure of a multi-antenna combination according to an embodiment of the present application;
fig. 3 is a top view of an integrated antenna with a laser etching and plating structure of a multi-antenna combination according to an embodiment of the present disclosure;
fig. 4 is an exploded schematic view of a WIFI antenna provided in the embodiment of the present application;
fig. 5 is a partial schematic view of a first antenna radiating element;
fig. 6 is a partial schematic view of a second antenna radiating element;
fig. 7 is a partial schematic view of a third antenna radiating element;
fig. 8 is a partial schematic view of a fourth antenna radiating element;
fig. 9 is a partial schematic view of a fifth antenna radiating element;
fig. 10 is a partial schematic view of a sixth antenna radiating element;
fig. 11 is a partial schematic view of a seventh antenna radiation unit;
fig. 12 is a partial schematic view of an eighth antenna radiating element.
In the figure:
1-stand, 2-WIFI antenna, 21-first antenna radiating element, 211-first antenna feed point, 212-first antenna ground point, 22-second antenna radiating element, 221-second antenna feed point, 222-second antenna ground point, 23-third antenna radiating element, 231-third antenna feed point, 232-third antenna ground point, 24-fourth antenna radiating element, 241-fourth antenna feed point, 242-fourth antenna ground point, 25-fifth antenna radiating element, 251-fifth antenna feed point, 252-fifth antenna ground point, 26-sixth antenna radiating element, 261-sixth antenna feed point, 262-sixth antenna ground point, 27-seventh antenna radiating element, 271-seventh antenna feed point, 272-seventh antenna ground point, 28-eighth antenna radiating element, 281-eighth antenna feed, 282-eighth antenna ground.
Detailed Description
The technical solutions in the embodiments of the present application will be described clearly and completely with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
Referring to fig. 1, a schematic view of a stent provided herein is shown.
Referring to fig. 2, an overall frame diagram of an integrated antenna with a multi-antenna combination and laser etching plating structure is provided in the embodiment of the present application.
Referring to fig. 3, a top view of an integrated antenna with a multi-antenna combination and a laser etching structure provided in the embodiment of the present application is shown.
Referring to fig. 4, an exploded schematic view of a WIFI antenna provided in the embodiment of the present application is shown.
In order to increase a plurality of channels and signal strength of the router, wire dialing, terminal punching, bending and tin adhering required by wire materials in the production process are omitted, and welding required by the wire materials and the antenna body is omitted. The embodiment of the application provides a structure antenna is plated to integrative radium carving of many antenna combinations, includes: support 1 and WIFI antenna 2.
The WIFI antenna 2 is plated on the surface of the support 1 through laser etching.
The WIFI antenna 2 includes: the antenna comprises a first antenna radiation unit 21, a second antenna radiation unit 22, a third antenna radiation unit 23, a fourth antenna radiation unit 24, a fifth antenna radiation unit 25, a sixth antenna radiation unit 26, a seventh antenna radiation unit 27 and an eighth antenna radiation unit 28, wherein the eight antenna radiation units are sequentially connected end to form a closed ring.
The first antenna radiation element 21 and the second antenna radiation element 22 are higher than the third antenna radiation element 23, the fourth antenna radiation element 24, the fifth antenna radiation element 25, the sixth antenna radiation element 26, the seventh antenna radiation element 27 and the eighth antenna radiation element 28.
It should be noted that, the bracket 1 provided in the embodiment of the present application is made of plastic, and has a relative dielectric constant of 4 and a tangent loss of 0.005. Use neotype modified plastic injection moulding that can radium carving chemical plating, the radium carving of accomplishing the surface at same platform radium carving machine in the time of making things convenient for antenna production walks the line, reduces the product time and the difference that a plurality of antenna products clamping increases alone.
The antenna that this application embodiment provided uses the annular design, and the mid portion is left for other accessories equipment use of product, can reduce occupation in space, simultaneously, WIFI antenna 2 plates through radium carving the ization 1 surface of support, support 1 provides certain structural strength for this application embodiment antenna, and the structure to support 1 simultaneously is hollowed as far as possible to alleviate the weight of whole antenna.
Referring to fig. 5, a partial schematic view of the first antenna radiating element is shown.
Referring to fig. 6, a partial schematic diagram of the second antenna radiation unit is shown.
Referring to fig. 7, a partial schematic diagram of the third antenna radiation element is shown.
Referring to fig. 8, a partial schematic view of a fourth antenna radiation element is shown.
Referring to fig. 9, a partial schematic diagram of a fifth antenna radiation unit is shown.
Referring to fig. 10, a partial schematic diagram of a sixth antenna radiation element is shown.
Referring to fig. 11, a partial schematic view of the seventh antenna radiation unit is shown.
Referring to fig. 12, a partial schematic diagram of an eighth antenna radiating element is shown.
In order to achieve the overall connectivity of the antenna, reduce the assembly process, provide a wider coverage area for the router or the expander, and provide signal strength, the first antenna radiation unit 21 includes: a first antenna feed point 211 and a first antenna ground point 212, where the first antenna feed point 211 is rectangular, is located at the top end of the first antenna radiation unit 21, and is parallel to the bottom of the WIFI antenna 2; the second antenna radiation element 22 includes: a second antenna feed point 221 and a second antenna ground point 222, where the second antenna feed point 221 is rectangular, is located at the top end of the second antenna radiation unit 22, and is parallel to the bottom of the WIFI antenna 2; the third antenna radiation element 23 includes: a third antenna feed point 231 and a third antenna ground point 232, where the third antenna feed point 231 is rectangular, is located at the top end of the third antenna radiation unit 23, and is parallel to the bottom of the WIFI antenna 2; the fourth antenna radiation element 24 comprises: a fourth antenna feed point 241 and a fourth antenna ground point 242, where the fourth antenna feed point 241 is rectangular, is located at the top end of the fourth antenna radiation unit 24, and is parallel to the bottom of the WIFI antenna 2; the fifth antenna radiation element 25 includes: a fifth antenna feed point 251 and a fifth antenna ground point 252, where the fifth antenna feed point 251 is rectangular, is located at the top end of the fifth antenna radiation unit 25, and is parallel to the bottom of the WIFI antenna 2; the sixth antenna radiation element 26 comprises: a sixth antenna feed point 261 and a sixth antenna ground point 262, where the sixth antenna feed point 261 is rectangular, is located at the top end of the sixth antenna radiation unit 26, and is parallel to the bottom of the WIFI antenna 2; the seventh antenna radiation unit 27 includes: a seventh antenna feed point 271 and a seventh antenna ground point 272, where the seventh antenna feed point 271 is rectangular, is located at the top end of the seventh antenna radiation unit 27, and is parallel to the bottom of the WIFI antenna 2; the eighth antenna radiation element 28 includes: an eighth antenna feed point 281 and an eighth antenna ground point 282, where the eighth antenna feed point 281 is rectangular and is located at the top end of the eighth antenna radiating element 28 and is parallel to the bottom of the WIFI antenna 2.
It should be noted that the antenna provided in the embodiments of the present application is not limited to eight antenna radiation elements, and may be any other number of antenna radiation elements, which can implement the problem to be solved in the embodiments of the present application, and may also be 10, 12, 14 or more antenna radiation elements. The shape of the antenna radiation unit can be adjusted according to the actual production requirement.
The single antenna radiation unit is provided with independent signal contacts (antenna feed points), and the contacts are contacted with the PCB of the product through an elastic sheet to complete signal transmission. All antennas can be formed by only one set of injection mold at present, and the independent mold opening of each antenna is not needed, so that the mold cost and the test mold finished product of a single antenna are saved, and meanwhile, the timeliness of the antenna design is guaranteed.
In addition, according to the antenna provided by the embodiment of the application, the insertion of a wire rod is eliminated in the test of a designed finished product, the VSWR (voltage standing wave ratio) test is performed in a mode of directly contacting with a contact, and the risk caused by poor terminals in the process is reduced. When the standing-wave ratio is equal to 1, the impedance of the feeder line and the antenna is completely matched, and at the moment, high-frequency energy is radiated by the antenna completely without energy reflection loss; when the standing-wave ratio is infinite, the total reflection is shown, and the energy is not radiated at all. If the SWR value is greater than 1, it means that a part of the electric wave is reflected back and finally becomes heat, so that the feed line is heated up. The reflected waves may also generate a relatively high voltage at the launch pad output, potentially damaging the launch pad.
The antenna can be conveniently assembled in a router or a routing signal enhancer product, and later-stage assembly, positioning and fixing of the product are facilitated. The first antenna grounding point 212 is annular, is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna 2, a circular hole is further arranged right below the first antenna grounding point 212, and the inner diameter of the circular hole is equal to the size of the first antenna grounding point 212. The second antenna grounding point 222 is annular, is arranged at a joint between the antenna radiation units, and is parallel to the bottom of the WIFI antenna 2, a circular hole is further arranged right below the second antenna grounding point 222, and the inner diameter of the circular hole is equal to that of the second antenna grounding point 222. The third antenna grounding point 232 is annular and is arranged at the joint between the antenna radiation units and parallel to the bottom of the WIFI antenna 2, a circular hole is further arranged right below the third antenna grounding point 232, and the inner diameter of the circular hole is equal to that of the third antenna grounding point 232. The fourth antenna grounding point 242 is annular, is arranged at a joint between the antenna radiation units, and is parallel to the bottom of the WIFI antenna 2, a circular hole is further arranged right below the fourth antenna grounding point 242, and the inner diameter of the circular hole is equal to the size of the fourth antenna grounding point 242. The fifth antenna grounding point 252 is annular, is arranged at a joint between the antenna radiation units, and is parallel to the bottom of the WIFI antenna 2, a circular hole is further arranged right below the fifth antenna grounding point 252, and the inner diameter of the circular hole is equal to the size of the fifth antenna grounding point 252. The sixth antenna grounding point 262 is annular, is arranged at a joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna 2, a circular hole is further arranged right below the sixth antenna grounding point 262, and the inner diameter of the circular hole is equal to the size of the sixth antenna grounding point 262. The seventh antenna ground point 272 is annular and is disposed at a joint between the antenna radiation units, and is parallel to the bottom of the WIFI antenna 2, a circular hole is further disposed under the seventh antenna ground point 272, and the inner diameter of the circular hole is equal to the size of the seventh antenna ground point 272. The eighth antenna ground point 282 is annular, is disposed at a joint between the antenna radiation units, and is parallel to the bottom of the WIFI antenna 2, and a circular hole is further disposed under the eighth antenna ground point 282, and an inner diameter of the circular hole is equal to that of the eighth antenna ground point 282.
In the process of debugging a certain antenna, when the performance of the antenna is not excellent enough, under the condition that the structural space of a support of a radiation area of an antenna body is insufficient, the radiation area of the antenna is increased, and therefore the performance and the bandwidth of the antenna are increased. The fourth antenna radiation element 24 further comprises: a fourth coupled antenna 243, said fourth coupled antenna 243 being located below said fourth antenna feed point 241 and a fourth antenna ground point 242. The fifth antenna radiation element 25 further comprises: a fifth coupling antenna 253, said fifth coupling antenna 253 being located below said fifth antenna feed point 251 and a fifth antenna ground point 252. The sixth antenna radiation element 26 further comprises: a sixth coupled antenna 263, said sixth coupled antenna 263 being located below said sixth antenna feed point 261 and a sixth antenna ground point 262. The seventh antenna radiation unit 27 further includes: a feed-side seventh coupled antenna 273 and a ground-side seventh coupled antenna 274, the feed-side seventh coupled antenna 273 being close to the seventh antenna feed point 271 being distant from the seventh antenna ground point 272 and being located below the seventh antenna feed point 271, the ground-side seventh coupled antenna 274 being close to the seventh antenna ground point 272 being distant from the seventh antenna feed point 271 and being located below the seventh antenna ground point 272.
In order to achieve multi-band signal coverage, the operating frequency bands of the first antenna radiation unit 21 and the second antenna radiation unit 22 are located in the WIFI 2.4GHz band. The working frequency bands of the third antenna radiation unit 23, the fourth antenna radiation unit 24, the fifth antenna radiation unit 25, the sixth antenna radiation unit 26, the seventh antenna radiation unit 27 and the eighth antenna radiation unit 28 are located at the WIFI 5GHz frequency band.
Above technical scheme can know, this application embodiment provides an integrative radium carving of many antenna combinations plates structure antenna and includes: support and WIFI antenna. The WIFI antenna is plated on the surface of the support through laser etching. The WIFI antenna includes: the antenna comprises a first antenna radiation unit, a second antenna radiation unit, a third antenna radiation unit, a fourth antenna radiation unit, a fifth antenna radiation unit, a sixth antenna radiation unit, a seventh antenna radiation unit and an eighth antenna radiation unit, wherein the eight antenna radiation units are sequentially connected end to form a closed ring. The first antenna radiating element and the second antenna radiating element are higher than the third antenna radiating element, the fourth antenna radiating element, the fifth antenna radiating element, the sixth antenna radiating element, the seventh antenna radiating element and the eighth antenna radiating element.
In practical application, the integrative radium carving of this application embodiment provides a many antennas combination plates structure antenna, through eight antenna radiating element's ground point and the round hole of below, as the hole that the screw lock was paid, usable screw assembles the antenna that this application provided to router or route signal intensifier product the inside, the antenna feed point of every antenna radiating element directly communicates with the contact of PCB through the bullet foot, the antenna that this application provided after the switch-on can provide 2.4G-5 GWIFIDI channel, and the wide coverage, because many antennas simultaneous working, for the router has increased a plurality of passageways and signal strength, dial the line that required wire rod needs in the technology of having saved production, beat the terminal, bend, the tin sticky, and with the required welding between the antenna body.
The present application has been described in detail with reference to specific embodiments and illustrative examples, but the description is not intended to limit the application. Those skilled in the art will appreciate that various equivalent substitutions, modifications or improvements may be made to the presently disclosed embodiments and implementations thereof without departing from the spirit and scope of the present disclosure, and these fall within the scope of the present disclosure. The protection scope of this application is subject to the appended claims.
Claims (16)
1. The utility model provides a structure antenna is plated in integrative radium carving ization of many antenna combinations which characterized in that includes: the WIFI wireless communication device comprises a bracket (1) and a WIFI antenna (2);
the WIFI antenna (2) is plated on the surface of the bracket (1) through laser etching;
the WIFI antenna (2) comprises: the antenna comprises a first antenna radiation unit (21), a second antenna radiation unit (22), a third antenna radiation unit (23), a fourth antenna radiation unit (24), a fifth antenna radiation unit (25), a sixth antenna radiation unit (26), a seventh antenna radiation unit (27) and an eighth antenna radiation unit (28), wherein the eight antenna radiation units are sequentially connected end to form a closed ring;
the first antenna radiation unit (21) and the second antenna radiation unit (22) are higher than the third antenna radiation unit (23), the fourth antenna radiation unit (24), the fifth antenna radiation unit (25), the sixth antenna radiation unit (26), the seventh antenna radiation unit (27) and the eighth antenna radiation unit (28).
2. The integrated multi-antenna combined laser etching structure antenna according to claim 1, wherein the first antenna radiation unit (21) comprises: the antenna comprises a first antenna feed point (211) and a first antenna grounding point (212), wherein the first antenna feed point (211) is rectangular and is positioned at the top end of the first antenna radiation unit (21) and parallel to the bottom of the WIFI antenna (2), the first antenna grounding point (212) is circular and is arranged at the joint between the antenna radiation units and parallel to the bottom of the WIFI antenna (2), a round hole is further formed under the first antenna grounding point (212), and the inner diameter of the round hole is equal to that of the first antenna grounding point (212).
3. The integrated multi-antenna combined laser etching structure antenna as recited in claim 1, wherein the second antenna radiation unit (22) comprises: the antenna comprises a second antenna feed point (221) and a second antenna grounding point (222), wherein the second antenna feed point (221) is rectangular, is located at the top end of the second antenna radiation unit (22) and is parallel to the bottom of the WIFI antenna (2), the second antenna grounding point (222) is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna (2), a circular hole is further formed right below the second antenna grounding point (222), and the inner diameter of the circular hole is equal to the size of the second antenna grounding point (222).
4. The integrated multi-antenna combined laser etching structure antenna as recited in claim 1, wherein the third antenna radiation unit (23) comprises: the third antenna feed point (231) is rectangular, is located at the top end of the third antenna radiation unit (23) and is parallel to the bottom of the WIFI antenna (2), the third antenna ground point (232) is circular and is arranged at the joint of the antenna radiation units and is parallel to the bottom of the WIFI antenna (2), a round hole is further formed under the third antenna ground point (232), and the inner diameter of the round hole is equal to that of the third antenna ground point (232).
5. The integrated multi-antenna combined laser etching structure antenna according to claim 1, wherein the fourth antenna radiation unit (24) comprises: the antenna comprises a fourth antenna feed point (241) and a fourth antenna grounding point (242), wherein the fourth antenna feed point (241) is rectangular, is positioned at the top end of the fourth antenna radiation unit (24) and is parallel to the bottom of the WIFI antenna (2), the fourth antenna grounding point (242) is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna (2), a round hole is further arranged under the fourth antenna grounding point (242), and the inner diameter of the round hole is equal to that of the fourth antenna grounding point (242).
6. The integrated multi-antenna combined laser etching structure antenna according to claim 5, wherein the fourth antenna radiation unit (24) further comprises: a fourth coupling antenna (243), the fourth coupling antenna (243) being located below the fourth antenna feed point (241) and a fourth antenna ground point (242).
7. The integrated multi-antenna combined laser etching structure antenna according to claim 1, wherein the fifth antenna radiation unit (25) comprises: the antenna comprises a fifth antenna feed point (251) and a fifth antenna grounding point (252), wherein the fifth antenna feed point (251) is rectangular, is located at the top end of the fifth antenna radiation unit (25) and is parallel to the bottom of the WIFI antenna (2), the fifth antenna grounding point (252) is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna (2), a circular hole is further formed right below the fifth antenna grounding point (252), and the inner diameter of the circular hole is equal to the size of the fifth antenna grounding point (252).
8. The integrated multi-antenna combined laser etching structure antenna according to claim 7, wherein the fifth antenna radiation unit (25) further comprises: a fifth coupling antenna (253), the fifth coupling antenna (253) being located below the fifth antenna feed point (251) and a fifth antenna ground point (252).
9. The integrated multi-antenna combined laser etching structure antenna as recited in claim 1, wherein the sixth antenna radiation unit (26) comprises: the antenna comprises a sixth antenna feed point (261) and a sixth antenna grounding point (262), wherein the sixth antenna feed point (261) is rectangular, is located at the top end of the sixth antenna radiation unit (26) and is parallel to the bottom of the WIFI antenna (2), the sixth antenna grounding point (262) is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna (2), a circular hole is further formed under the sixth antenna grounding point (262), and the inner diameter of the circular hole is equal to the size of the sixth antenna grounding point (262).
10. The integrated multi-antenna combined laser etching structure antenna according to claim 9, wherein the sixth antenna radiation unit (26) further comprises: a sixth coupling antenna (263), the sixth coupling antenna (263) being located below the sixth antenna feed point (261) and a sixth antenna ground point (262).
11. The integrated multi-antenna combined laser etching structure antenna according to claim 1, wherein the seventh antenna radiation unit (27) comprises: the antenna comprises a seventh antenna feed point (271) and a seventh antenna grounding point (272), wherein the seventh antenna feed point (271) is rectangular, is positioned at the top end of the seventh antenna radiation unit (27) and is parallel to the bottom of the WIFI antenna (2), the seventh antenna grounding point (272) is circular and is arranged at the joint between the antenna radiation units and is parallel to the bottom of the WIFI antenna (2), a round hole is further arranged under the seventh antenna grounding point (272), and the inner diameter of the round hole is equal to the size of the seventh antenna grounding point (272).
12. The integrated multi-antenna combined laser etching structure antenna according to claim 11, wherein the seventh antenna radiation unit (27) further comprises: a feed-side seventh coupled antenna (273) and a ground-side seventh coupled antenna (274), the feed-side seventh coupled antenna (273) being proximate to the seventh antenna feed (271) and distal from the seventh antenna ground point (272) and being located below the seventh antenna feed (271), the ground-side seventh coupled antenna (274) being proximate to the seventh antenna ground point (272) and distal from the seventh antenna feed (271) and being located below the seventh antenna ground point (272).
13. The integrated multi-antenna combined laser etching structure antenna according to claim 1, wherein the eighth antenna radiation unit (28) comprises: the antenna comprises an eighth antenna feed point (281) and an eighth antenna grounding point (282), wherein the eighth antenna feed point (281) is rectangular, is located at the top end of the eighth antenna radiation unit (28) and is parallel to the bottom of the WIFI antenna (2), the eighth antenna grounding point (282) is circular and is arranged at the joint of the antenna radiation units and is parallel to the bottom of the WIFI antenna (2), a circular hole is further arranged under the eighth antenna grounding point (282), and the inner diameter of the circular hole is equal to the size of the eighth antenna grounding point (282).
14. The integrated multi-antenna combined laser etching structure antenna is characterized in that the working frequency bands of the first antenna radiation unit (21) and the second antenna radiation unit (22) are located in a WIFI 2.4GHz frequency band.
15. The integrated multi-antenna combined laser etching structure antenna as recited in claim 1, wherein the operating frequency bands of the third antenna radiation unit (23), the fourth antenna radiation unit (24), the fifth antenna radiation unit (25), the sixth antenna radiation unit (26), the seventh antenna radiation unit (27) and the eighth antenna radiation unit (28) are located in a WIFI 5GHz band.
16. The integrated multi-antenna combined laser etching and plating structure antenna as claimed in claim 1, wherein the support (1) is a plastic support.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202123226471.9U CN216563534U (en) | 2021-12-21 | 2021-12-21 | Integrative radium carving of many antennas combination plates structure antenna |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202123226471.9U CN216563534U (en) | 2021-12-21 | 2021-12-21 | Integrative radium carving of many antennas combination plates structure antenna |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN216563534U true CN216563534U (en) | 2022-05-17 |
Family
ID=81545802
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202123226471.9U Active CN216563534U (en) | 2021-12-21 | 2021-12-21 | Integrative radium carving of many antennas combination plates structure antenna |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN216563534U (en) |
-
2021
- 2021-12-21 CN CN202123226471.9U patent/CN216563534U/en active Active
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