WO2015117279A1 - 一种天线调节装置和电调天线 - Google Patents

一种天线调节装置和电调天线 Download PDF

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Publication number
WO2015117279A1
WO2015117279A1 PCT/CN2014/071930 CN2014071930W WO2015117279A1 WO 2015117279 A1 WO2015117279 A1 WO 2015117279A1 CN 2014071930 W CN2014071930 W CN 2014071930W WO 2015117279 A1 WO2015117279 A1 WO 2015117279A1
Authority
WO
WIPO (PCT)
Prior art keywords
gear
antenna
adjusting device
rotating shaft
output
Prior art date
Application number
PCT/CN2014/071930
Other languages
English (en)
French (fr)
Inventor
段方清
Original Assignee
华为技术有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 华为技术有限公司 filed Critical 华为技术有限公司
Priority to CN201480000444.3A priority Critical patent/CN104170165B/zh
Priority to MX2016010364A priority patent/MX357346B/es
Priority to EP14881921.2A priority patent/EP3098904B1/en
Priority to PCT/CN2014/071930 priority patent/WO2015117279A1/zh
Publication of WO2015117279A1 publication Critical patent/WO2015117279A1/zh
Priority to US15/232,060 priority patent/US10461419B2/en
Priority to US16/599,993 priority patent/US11128042B2/en

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q3/00Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system
    • H01Q3/26Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture
    • H01Q3/30Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture varying the relative phase between the radiating elements of an array
    • H01Q3/32Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture varying the relative phase between the radiating elements of an array by mechanical means
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/12Supports; Mounting means
    • H01Q1/22Supports; Mounting means by structural association with other equipment or articles
    • H01Q1/24Supports; Mounting means by structural association with other equipment or articles with receiving set
    • H01Q1/241Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM
    • H01Q1/246Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for base stations

Definitions

  • the invention relates to an antenna adjusting device and an electric adjustable antenna. Background technique
  • the electric adjustment is relatively manual adjustment.
  • the advantage is that there is no need to manually climb the tower, and there is no need to operate at the antenna end, which has great convenience and easy realization.
  • electric regulation has gradually become a mainstream, and its application is more and more extensive.
  • the current mainstream electric adjustment method uses a down-tilt adjustment device for each frequency band antenna, that is, a multi-frequency antenna requires multiple down-tilt adjustment devices.
  • the downtilt angle adjustment method of such a multi-frequency antenna requires a plurality of downtilt angle adjusting devices to cause the antenna downtilt adjusting device to have a large overall size, and cannot satisfy the trend of miniaturization.
  • Embodiments of the present invention provide an antenna adjusting apparatus and an electrical adjustment antenna, which can reduce the overall size of the antenna.
  • an antenna adjustment apparatus for adjusting a downtilt angle of an antenna assembly, the antenna assembly including a plurality of phase shifters.
  • the antenna adjusting device includes a first driving wheel, a first gear, a second driving wheel, a second gear, and a plurality of output gears, the first driving wheel meshing with the first gear, and the second driving wheel is The second gear meshes, an axis of the second gear coincides with an axis of the first drive wheel, the output gear is coupled to the phase shifter, and the second drive wheel is configured to drive the second
  • the gear rotates and drives the first gear to revolve relative to the axis of the second gear to selectively engage the first gear with the output gear, the first drive wheel for driving the first A gear rotates and drives the output gear that meshes with the first gear to rotate, the output gear for driving the phase shifter coupled thereto.
  • the second drive wheel is used to lock the second gear.
  • the antenna adjusting device further includes a plurality of output shafts parallel to each other, the output gear and The output shaft is fixedly connected.
  • the antenna adjusting device further includes a first rotating shaft, the first driving wheel and the first rotating shaft are fixedly connected, and the first rotating shaft is parallel to the output shaft.
  • the second gear is sleeved on the first rotating shaft.
  • the antenna adjusting device further includes a second rotating shaft, the second driving wheel and the second rotating shaft are fixedly connected, and the second rotating shaft is parallel to the first rotating shaft and the output shaft.
  • the antenna adjusting device further includes a third rotating shaft, the first gear is mounted on the third rotating shaft, and the third rotating shaft is parallel to the second rotating shaft, the first rotating shaft and the output shaft.
  • the third rotating shaft is coupled to the second gear, and the first gear and the third rotating shaft are movably connected.
  • the antenna adjusting device further includes a first fixing frame, and the output shaft is mounted on the first fixing frame.
  • the antenna adjusting device further comprises a plurality of screws, a plurality of nuts and a plurality of guiding rods, the screw is fixedly connected with the output shaft, the nut is engaged with the screw and fixedly connected with the phase shifter
  • the guide rod is movably connected to the nut, and the guide rod is mounted to the first holder.
  • the antenna adjusting device further includes a plurality of nuts and a plurality of guiding rods, the nut is engaged with the thread of the output shaft and fixedly connected with the phase shifting device, The guide rod is movably connected to the nut, and the guide rod is mounted to the first holder.
  • the antenna adjusting device further comprises a first driving structure for providing power to the first driving wheel.
  • the antenna adjusting device further includes a second driving structure for providing power to the second driving wheel.
  • an electrical tune antenna that includes an antenna assembly and the above-described antenna adjustment device integrated with the antenna assembly.
  • the antenna assembly comprises a casing, and the antenna adjusting device is installed in the casing.
  • the housing is provided with a receiving space, and the receiving space is provided with an opening at one end of the housing.
  • the antenna adjusting device includes a driving device, and the driving device is inserted into the receiving space through the opening.
  • the antenna adjusting device and the electric adjustable antenna provided by the embodiment of the invention drive the second through the second driving wheel
  • the rotation of the gear can change the position of the first gear, so that the first gear can mesh with different output gears, that is, the selective driving of the output gear of the first gear is realized, so that the antenna adjustment adjusting device of the embodiment of the invention can be multiple
  • the downtilt angle of the antenna is adjusted, thereby solving the problem in the prior art that the overall size of the antenna adjusting device is large due to the need for multiple antenna adjusting devices to adjust the downtilt angle of the multi-frequency antenna.
  • FIG. 1 is a partial assembly diagram of a transmission device of an antenna adjusting device according to an embodiment of the present invention
  • FIG. 2 is a partial assembly view of FIG.
  • FIG. 3 is a schematic view showing the assembly of the driving device of the antenna adjusting device according to the embodiment of the present invention
  • FIG. 4 is a plan view showing the driving device shown in FIG.
  • Figure 5 is an assembled view of another angle of the driving device shown in Figure 3;
  • FIG. 6 is a schematic diagram of assembly of an antenna adjusting device according to an embodiment of the present invention.
  • Fig. 7 is a schematic view showing the assembly of the antenna adjusting device and the antenna assembly shown in Fig. 6. detailed description
  • an antenna adjusting apparatus 100 is configured to adjust a downtilt angle of the antenna assembly 200.
  • the antenna assembly 200 includes a plurality of phase shifters that are coupled to the antenna adjustment device 100.
  • the antenna assembly 200 is a multi-frequency antenna and includes a plurality of antennas.
  • the antenna assembly 200 is five dual-polarized antennas, and each dual-polarized antenna is provided with a pair of radio frequency interfaces.
  • one antenna corresponds to one phase shifter.
  • one shift The phaser can correspond to two or more antennas.
  • the antenna adjusting device 100 includes a transmission device 30 including a first driving wheel 31, a first gear 32, a first rotating shaft (37), and a carrier ( 34a), a second drive wheel 33, a second gear 34 and a plurality of output gears 35, the first drive wheel 31 meshes with the first gear 32, the second drive wheel 33 and the second gear 34 Engaging, the axis of the second gear 34 coincides with the axis of the first drive wheel 31, and each of the output gears 35 is coupled to each of the phase shifters, and the carrier 34a is set to the first a rotating shaft 37, the second gear 34 is fixedly coupled to the carrier 34a, the first gear 32 rotates with the carrier (34a), and when the second driving wheel 33 drives the second gear When rotated 34, the first gear 32 revolves with respect to the axis of the second gear 34 and selectively engages one of the output gears 35, the first drive wheel 31 driving the first gear 32 Rotating and driving the said meshing with the first
  • the second drive wheel 33 is first driven to rotate the second gear 34, since the first gear 32 can be opposite the second gear
  • the axis of 34 revolves so that the first gear 32 can be rotated into position with the output gear 35 corresponding to the antenna phase shifter to be adjusted, and then the first drive wheel 31 drives the first gear 32 to rotate and drive
  • the output gear 35 meshed by the first gear 32 rotates, and the output gear 35 drives the phase shifter connected thereto to operate, thereby changing the downtilt angle of the antenna connected to the phase shifter.
  • the antenna adjusting device 100 of the present invention can change the position of the first gear 32 by driving the second gear 34 to rotate, so that the first gear 32 can be meshed with the different output gear 35, that is, The selective driving of the output gear 35 by the first gear 32 is implemented, so that the antenna adjusting device 100 of the present invention can adjust the downtilt angle of the plurality of antennas, thereby solving the problem of requiring multiple antenna adjusting devices in the prior art. 100 can adjust the downtilt angle of the multi-frequency antenna to cause a large overall size of the antenna adjusting device.
  • one antenna adjusting device 100 can adjust the downtilt angle of a plurality of antennas
  • the present invention greatly reduces the number of antenna adjusting devices 100, and thus greatly reduces the number of antenna adjusting devices 100. The cost of manufacturing the antenna adjustment device 100 is reduced.
  • the antenna adjusting device is mounted The space required for 100 is correspondingly reduced.
  • one output gear 35 corresponds to one phase shifter, that is, the phase shifter and the output gear 35 have a corresponding relationship, and at the same time, one first gear 32 corresponds to the plurality of output gears 35.
  • a first gear 32 corresponds to a plurality of phase shifters, so that the antenna adjusting device 100 of the present invention can adjust the downtilt angle of a plurality of antennas.
  • one output gear 35 may correspond to two or more phase shifters.
  • the second gear 34 in the process in which the first drive wheel 31 drives the first gear 32 to rotate and drives the output gear 35 that meshes with the first gear 32, the second gear 34 The second drive wheel 33 is locked and cannot be rotated.
  • the first drive is driven when the second drive wheel 33 drives the second gear 34 to rotate and rotates the first gear 32 relative to the axis of the second gear 34.
  • the wheel 31 drives the first gear 32 to rotate.
  • the first drive wheel 31 drives the first gear 32 to rotate accordingly, so that the first gear 32 does not drive.
  • the output gear 35 rotates, and the phase shifter connected to the output gear 35 does not operate, that is, the downtilt angle of the antenna does not change.
  • the first gear 32 does not drive the output gear 35 that it passes to cause the antenna phase shift corresponding to the output gear 35.
  • the device operates to optimize the downward tilt angle of the antenna during which the first gear 32 is selectively engaged with the output gear 35.
  • the antenna adjusting device 100 further includes a plurality of output shafts 36 that are parallel to each other, and the output gear 35 and the output shaft 36 are fixedly coupled.
  • the output gear 35 and the output shaft 36 are integral gear shafts. In other embodiments, the output gear 35 and the output shaft 36 are secured together by a mating means, such as a pin-engagement.
  • the first driving wheel 31 and the first rotating shaft 37 are fixedly connected, the second gear 34 is mounted on the first rotating shaft 37, and the first rotating shaft 37 is parallel to the output.
  • Axis 36 is
  • the two ends of the carrier 34a are respectively embedded in the first fixing frame 301 and the second fixing frame 302, so that the carrier 34a can be sleeved on the first rotating shaft 37.
  • the fixing frame 301 and the second fixing frame 302 are non-fixed connection, and the diameter of the circular hole in the first fixing frame 301 and the second fixing frame 302 for the carrier 34a is slightly larger than the diameter of the two ends of the carrier 34a, so that the carrier 34a can be
  • the rotation is stably performed under the support of the first holder 301 and the second holder 301 while the carrier 34a is stably fixed between the first holder 301 and the second holder 302.
  • the second gear 34 is sleeved on the first rotating shaft 37 through the carrier 34a, that is, when the first rotating shaft 37 rotates, the second gear 34 does not follow the first rotating shaft.
  • the first driving wheel 31 and the first rotating shaft 37 are fixedly connected, that is, when the first rotating shaft 37 rotates, the first driving wheel 31 and the first rotating shaft 37 rotate together.
  • the first drive wheel 31 and the first rotating shaft 37 are integral gear shafts.
  • the first drive wheel 31 and the first rotating shaft 37 are integrally fixed by a mating manner, such as a pin keying.
  • the antenna adjusting device 30 further includes a third rotating shaft 38, the second driving wheel 33 and the third rotating shaft 38 are fixedly connected, and the third rotating shaft 38 is parallel to the first rotating shaft 37 and the output shaft 36.
  • the second drive wheel 33 and the third rotating shaft 38 are integral gear shafts.
  • the second drive wheel 33 and the third rotating shaft 38 are integrally fixed by a mating manner, such as a pin keying.
  • the antenna adjusting device 30 further includes a second rotating shaft 39, the first gear 32 is mounted on the second rotating shaft 39, and the second rotating shaft 39 is parallel to the third rotating shaft 38, The first rotating shaft 37 and the output shaft 36.
  • the second rotating shaft 39 is connected to the carrier 34a, and a sufficient space is left in the circumference of the carrier 34a for placing the second rotating shaft 39 and the first gear 32 mounted on the second rotating shaft 39, and the second rotating shaft 39 .
  • the first gear 32 and the second rotating shaft 39 are movably connected, and when the second rotating shaft 39 and the second gear 34 rotate together, the first gear 32 is not only opposite to the second gear 34
  • the axis rotates and rotates relative to the second shaft 39.
  • the first Rotation of the gear 32 relative to the axis of the second gear 34 is referred to as revolution
  • rotation of the first gear 32 relative to the second shaft 39 is referred to as autorotation.
  • the second rotating shaft 39 is fixedly coupled to the second gear 34.
  • the second shaft 39 is movably coupled to the second gear 34. Regardless of whether the second rotating shaft 39 is fixedly coupled or movably connected to the second gear 34, the second rotating shaft 39 rotates with the second gear 34 when the second gear 34 rotates.
  • the antenna adjusting device 100 further includes a first fixing frame 301 and a second fixing frame spaced apart from the first fixing frame 301 by a certain distance.
  • first rotating shaft 37 and the output shaft 36 are mounted on the first fixing frame 301 and the second fixing frame 302, and the third rotating shaft 38 is mounted on the second fixing frame. 302.
  • first rotating shaft 37 and the output shaft 36 are mounted on the first fixing frame 301, but are not mounted on the second fixing frame 302, or the first rotating shaft 37 is installed in the The second mount 302 is not mounted to the first mount 301.
  • the third rotating shaft 38 is mounted to the first fixing frame 301 and the second fixing frame 302.
  • the antenna adjusting device 100 further includes a plurality of screws 40, a plurality of nuts 50 and a plurality of guiding rods 60, the screw 40 and the
  • the output shaft 36 is fixedly coupled to the screw 40 and is fixedly coupled to the phase shifter.
  • the nut 50 is movably coupled to the guide rod 60, and the guide rod 60 is mounted to the first
  • the fixing frame 301 is used for restricting the rotation of the nut 50 and guiding the linear movement of the nut 50.
  • the rotation of the nut 50 is restricted by the guide rod 60 to be linearly movable only along the guide rod 60, i.e., the nut 50 is moved relative to the screw 40.
  • the rotation of the output shaft 36 is converted into a linear motion of the nut 50 by the cooperation between the screw 40, the nut 50 and the guide rod 60, so that the movement of the nut 50 is fixedly connected.
  • the phase device operates to achieve adjustment of the downtilt angle of the antenna assembly 200.
  • the screw 40 is integrally formed with the output shaft 36, i.e., the screw 40 and the output shaft 36 are integrated, but only one end of the output shaft 36 is threaded, and the other end of the output shaft 36 is provided with an output gear 35.
  • the screw 40, the output shaft 36, and the output gear 35 are integrated.
  • the antenna adjusting device 100 further includes a driving device 10, and the driving device 10 receives a control signal and a power from a mobile communication base station.
  • the driving device 10 includes a first interface 11 and a second interface 12, and both the first interface 11 and the second interface 12 can receive a control signal and a power source from the mobile communication base station.
  • the first interface 11 is a male connector
  • the second interface 12 is a female connector.
  • the first interface 11 is used, and in other words, regardless of whether the connector that interfaces with the driving device 10 is a male connector or a female connector, the driving device 10 can receive a control signal and a power source from the mobile communication base station, thereby facilitating the use.
  • the driving device 10 is provided with two sets of interfaces, one of which is a standby interface.
  • Each set of interfaces includes a first interface 11 and a second interface 12.
  • the drive unit 10 can also be provided with only one set of interfaces or one interface.
  • the driving device 10 further includes a first driving structure 13 and a second driving structure 14, and the first driving structure 13 is for supplying power to the first rotating shaft 37 and the first driving wheel 31.
  • the second drive structure 14 is for powering the third shaft 38 and the second drive wheel 33.
  • the first drive wheel 31 and the second drive structure 14 are both motors.
  • the second drive structure 14 has a self-locking moment.
  • the third shaft 38 is locked.
  • the second driving wheel 33 fixedly connected to the third rotating shaft 38 is locked, and the second driving wheel 33 engaged with the second gear 34 is locked, thereby locking the second gear 34, thereby ensuring the locking.
  • the meshing relationship between the first gear 32 and the output gear 35 is not changed, so that the first drive wheel 31 can drive the first gear 32 to rotate, and drive the output gear 35 meshed with it to drive the phase shifter to work, thereby changing The downtilt angle of the antenna corresponding to the phase shifter.
  • the second gear 34 is locked, so that the first driving wheel 31 drives the first gear 32 to rotate.
  • the meshing relationship between the first gear 32 and the output shaft gear 35 is not changed.
  • the driving device 10 includes a first output interface 15 and a second output interface 16, the first output interface 15 is connected to the first rotating shaft 37, and the second output interface 16 is connected to the third rotating shaft 38, that is, The driving device 10 is connected to the transmission device 30 through the first output interface 15 and the second output interface 16 , so that the driving device 10 is plugged and unplugged with the transmission device 30 . connection.
  • the first rotating shaft 37, the third rotating shaft 38, the second rotating shaft 39 and the output shaft 36 are mounted to the first fixing frame 301 and the second fixing frame 302, the first driving The wheel 31 and the second gear 34 are both mounted on the first rotating shaft 37, the second driving wheel 33 is mounted on the third rotating shaft 38 and meshes with the second gear 34, and the first gear 32 is mounted on a second rotating shaft 39 is engaged with the first driving wheel 31, the output gear 35 is mounted on the output shaft 36, and then the screw 40 is fixed to the output shaft 36, and the nut 50 is engaged with the screw 40
  • the guiding rod 60 is fixed to the first fixing frame 301, and the nut 50 is slidably connected to the guiding rod 60, so that the first fixing frame 301, the second fixing frame 302, the first rotating shaft 37, the third rotating shaft 38, and the second a rotating shaft 39, an output shaft 36, a first driving wheel 31, a first gear 32, a second driving wheel 33, a second gear 34,
  • the control signal and the power supply are first received, that is, the driving device 10 receives the control signal and the power source from the mobile communication base station through the first interface 11 or the second interface 12 to make the first driving structure 13 and the second driving structure. 14 work; Secondly, select the output gear 35 with output demand, that is, select the antenna that needs to adjust the downtilt angle according to the indication of the control signal, and select the output gear 35 according to the phase shifter of the antenna with the downtilt angle as needed, the process is as follows: The second driving structure 14 drives the third rotating shaft 38 connected to the second output interface 16 to rotate, and the second driving wheel 33 is coupled with the third rotating shaft 38 to drive the second gear 34 meshing with the second gear 34 to rotate, thereby driving the connection to the carrier 34a.
  • the upper second shaft 39 rotates, forcing the first gear 32 mounted on the second shaft 39 to rotate to the position of the output gear 35 having the output demand; finally, adjusting the downtilt angle of the antenna, the process is as follows:
  • the first driving structure 13 Driving the first rotating shaft 37 connected to the first output interface 15 to rotate, the first driving wheel 31 and the first rotating shaft 37 are interlocked, and
  • the first gear 31 rotates, thereby driving the output gear 35 meshing with the first gear 31 to rotate, causing the screw 40 to rotate, and linearly moving the nut 50 relative to the guide rod 60, so that the phase shifter fixedly connected with the nut 50 works, and further Change the downtilt angle of the antenna.
  • the phase shifter of the antenna assembly 200 can be selectively operated, so that the antenna adjusting device 100 of the present invention can selectively select the downtilt angle of the antenna in the antenna assembly 200.
  • Adjustment that is, an antenna adjustment device 100 can adjust the downtilt angle of a plurality of antennas.
  • the first gear 32 of the present invention can be used for the output gear
  • the selective driving of 35 so that the antenna adjusting device 100 of the present invention can adjust the downtilt angle of a plurality of antennas, that is, one-to-many is realized, instead of one antenna adjusting device 100 in the prior art, only one antenna can be adjusted.
  • the tilt angle further solves the problem that the overall size of the antenna adjusting device 100 is large due to the excessive amount of the antenna adjusting device 100 in the prior art.
  • the present invention also provides an electrical adjustment antenna 300.
  • the electrical adjustment antenna 300 includes the antenna adjustment device 100 and the antenna assembly 200.
  • the antenna assembly 200 is provided with a housing 201.
  • the housing 201 is provided with a receiving space (obscured by the antenna adjusting device 100), and the receiving space is in the housing 201.
  • One end face is provided with an opening (blocked by the antenna adjusting device 100).
  • the transmission 30 of the antenna adjusting device 100 is fixed in the housing 201, and the driving device 10 of the antenna adjusting device 100 is inserted into the receiving space through an opening and connected to the transmission device 30, that is, the antenna adjusting device 100
  • the drive unit 10 is mounted in the housing 201 of the antenna assembly 200 in a pluggable manner.
  • the driving device 10 Since the driving device 10 is mounted in the housing 201 of the antenna assembly 200 in a pluggable manner, if the driving device 10 fails during use, such as the first driving structure 13 and the second driving structure 14 (Refer to FIG. 5) In the event of a malfunction, the user can pull out the drive unit 10 from the accommodating space through the opening for maintenance or replacement. In other words, in the process of maintaining or replacing the driving device 10, it is not necessary to disassemble the entire ESC antenna 300, that is, the driving device 10 can be maintained or replaced without disassembling the antenna assembly 200, so that the ESC is adjusted. The maintenance of the antenna 300 becomes more convenient, thereby improving the convenience of the user.
  • the antenna adjusting device 100 is mounted in the outer casing 201 of the antenna assembly 200, that is, the antenna adjusting device 100 and the antenna assembly 200 are integrated, the structure of the electric adjusting antenna 300 is more compact, and the development trend of miniaturization is satisfied.
  • the ESC 300 of the present invention requires only one antenna adjustment device 100 to adjust the tilt angle of all the antennas in the antenna assembly 200, thereby reducing the number of antenna adjustment devices 100 and the space required to mount the antenna adjustment device 100.
  • the volume of the ESC antenna 300 is reduced, which solves the problem of the prior art that the size of the ESC antenna 300 is large due to the need for the plurality of antenna adjustment devices 100 to adjust the downtilt angle of the multi-frequency antenna.
  • the cost of manufacturing the antenna adjusting device 100 is also greatly reduced, thereby also reducing the cost of manufacturing the electric adjustable antenna 300.

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  • Variable-Direction Aerials And Aerial Arrays (AREA)

Abstract

本发明实施例提供了一种天线调节装置,用于调节天线组件的下倾角,天线组件包括多个移相器。天线调节装置包括第一驱动轮、第一齿轮、第二驱动轮、第二齿轮和多个输出齿轮。第一驱动轮与第一齿轮啮合,第二驱动轮与第二齿轮啮合,第二齿轮的轴线与第一驱动轮的轴线重合,输出齿轮与移相器连接。当第二驱动轮驱使第二齿轮转动时,第一齿轮相对第二齿轮的轴线公转并选择性地与输出齿轮啮合,并在第一驱动轮的驱动下驱使输出齿轮转动并带动与输出齿轮连接的移相器。本发明通过第一齿轮可以对输出齿轮进行选择性驱动,从而实现了一个天线调节装置可以对多个天线的下倾角进行调节,进而降低了天线调节装置的整体尺寸。

Description

一种天线调节装置和电调天线
技术领域
本发明涉及一种天线调节装置和电调天线。 背景技术
在移动基站通信系统中, 关于天线下倾角的调整方式, 目前常用手动调节 和电动调节两种。 电动调节相对手动调节, 优势在于不需要人工爬塔, 不需要 在天线端去操作, 具有很大的便利性和易实现性。 目前, 特别在经济发达和较 发达地区, 电动调节已经逐渐成为一种主流, 其应用越来越广泛。
随着移动基站站址资源的限制, 多频天线已越来越成为一种需求趋势。 对 于多频天线,目前主流的电动调节方式是每一个频段的天线分别采用一个下倾 角调节装置, 即一个多频天线需要多个下倾角调节装置。 但是, 这种多频天线 的下倾角调节方式因需要多个下倾角调节装置致使天线下倾角调节装置的整 体尺寸较大, 不能满足小型化的发展趋势。 发明内容
本发明实施例提供了一种天线调节装置和电调天线, 能够减小天线的整体 尺寸。
为了实现上述目的, 本发明实施方式提供如下技术方案:
一方面, 提供了一种天线调节装置, 用于调节天线组件的下倾角, 所述天 线组件包括多个移相器。 所述天线调节装置包括第一驱动轮、 第一齿轮、 第二 驱动轮、 第二齿轮和多个输出齿轮, 所述第一驱动轮与所述第一齿轮啮合, 所 述第二驱动轮与所述第二齿轮啮合,所述第二齿轮的轴线与所述第一驱动轮的 轴线重合, 所述输出齿轮与所述移相器连接, 所述第二驱动轮用于驱使所述第 二齿轮转动并带动所述第一齿轮相对所述第二齿轮的所述轴线公转,以使所述 第一齿轮选择性地与所述输出齿轮啮合,所述第一驱动轮用于驱使所述第一齿 轮转动并带动与所述第一齿轮啮合的所述输出齿轮转动,所述输出齿轮用于驱 使与之相连的所述移相器。
其中, 所述第二驱动轮用于锁止所述第二齿轮。
其中, 所述天线调节装置还包括多个相互平行的输出轴, 所述输出齿轮与 所述输出轴固定连接。
其中, 所述天线调节装置还包括第一转轴, 所述第一驱动轮和所述第一转 轴固定连接, 所述第一转轴平行于所述输出轴。
其中, 所述第二齿轮空套在所述第一转轴。
其中, 所述天线调节装置还包括第二转轴, 所述第二驱动轮和所述第二转 轴固定连接, 所述第二转轴平行于所述第一转轴和所述输出轴。
其中, 所述天线调节装置还包括第三转轴, 所述第一齿轮安装于所述第三 转轴, 所述第三转轴平行于所述第二转轴、 所述第一转轴和所述输出轴。
其中, 所述第三转轴与所述第二齿轮连接, 所述第一齿轮和所述第三转轴 活动连接。
其中, 所述天线调节装置还包括第一固定架, 所述输出轴安装于所述第一 固定架。
其中, 所述天线调节装置还包括多个螺杆、 多个螺母和多个导向杆, 所述 螺杆与所述输出轴固定连接,所述螺母与所述螺杆啮合并与所述移相器固定连 接, 所述导向杆与所述螺母活动连接, 所述导向杆安装于所述第一固定架。
其中, 所述输出轴的一端设有螺纹, 所述天线调节装置还包括多个螺母和 多个导向杆, 所述螺母与所述输出轴的螺纹啮合并与所述移相器固定连接, 所 述导向杆与所述螺母活动连接, 所述导向杆安装于所述第一固定架。
其中, 天线调节装置还包括第一驱动结构, 用于给所述第一驱动轮提供动 力。
其中, 天线调节装置还包括第二驱动结构, 用于给所述第二驱动轮提供动 力。
其中, 所述第二驱动结构具有自锁力矩, 用于锁止所述第二驱动轮。 另一方面, 提供了一种电调天线, 其包括天线组件和集成于所述天线组件 的上述天线调节装置。
其中, 所述天线组件包括外壳, 所述天线调节装置安装于所述外壳内。 其中, 所述外壳设有收容空间, 所述收容空间在所述外壳的一个端部设有 开口, 所述天线调节装置包括驱动装置, 所述驱动装置通过所述开口插入所述 收容空间中。
本发明实施例提供的天线调节装置和电调天线, 通过第二驱动轮驱动第二 齿轮转动可以改变第一齿轮的位置,从而使第一齿轮可以与不同的输出齿轮啮 合, 即实现第一齿轮对输出齿轮的选择性驱动,使得本发明实施例的天线调节 调节装置可以对多个天线的下倾角进行调节,进而解决了现有技术中因需要多 个天线调节装置才能调节多频天线的下倾角而导致的天线调节装置整体尺寸 较大的问题。 附图说明
为了更清楚地说明本发明实施例中的技术方案,下面将对实施例中所需要 使用的附图作筒单地介绍,显而易见地, 下面描述中的附图仅仅是本发明的一 些实施例, 对于本领域普通技术人员来讲, 在不付出创造性劳动的前提下, 还 可以根据这些附图获得其他的附图。
图 1是本发明实施例提供的天线调节装置的传动装置的部分组装示意图; 图 2是图 1的部分组装示意图;
图 3是本发明实施例的提供的天线调节装置的驱动装置组装示意图; 图 4是图 3所示的驱动装置平面示意图;
图 5是图 3所示的驱动装置的另一个角度的组装示意图;
图 6是本发明实施例的提供的天线调节装置的组装示意图;
图 7是图 6所示的天线调节装置和天线组件的组装示意图。 具体实施方式
下面将结合本发明实施方式中的附图,对本发明实施方式中的技术方案进 行清楚、 完整地描述。
请一并参考图 1至图 7, 本发明实施例提供的天线调节装置 100, 用于调 节天线组件 200的下倾角。所述天线组件 200包括多个移相器, 所述移相器与 所述天线调节装置 100连接。
在本实施方式中, 所述天线组件 200为多频天线并包括多个天线。
如图 7所示, 在本实施方式中, 所述天线组件 200为 5个双极化天线, 每 一个双极化天线设有一对射频接口。
在本实施方式中, 一个天线对应一个移相器。 在其它实施方式中, 一个移 相器可以对应 2个或 2个以上的天线。
如图 1、 图 2和图 6所示, 所述天线调节装置 100包括传动装置 30, 所述 传动装置 30包括第一驱动轮 31、 第一齿轮 32、 第一转轴 (37)、 齿轮架 (34a)、 第二驱动轮 33、 第二齿轮 34和多个输出齿轮 35 , 所述第一驱动轮 31与所述 第一齿轮 32啮合, 所述第二驱动轮 33与所述第二齿轮 34啮合, 所述第二齿 轮 34的轴线与所述第一驱动轮 31的轴线重合, 每一个所述输出齿轮 35与每 一个所述移相器连接, 所述齿轮架 34a套装于所述第一转轴 37, 所述第二齿 轮 34与所述齿轮架 34a固定连接,所述第一齿轮 32随所述齿轮架 (34a)—起转 动, 当所述第二驱动轮 33驱使所述第二齿轮 34转动时, 所述第一齿轮 32相 对所述第二齿轮 34 的所述轴线公转并选择性地与其中一个所述输出齿轮 35 啮合, 所述第一驱动轮 31驱使所述第一齿轮 32转动并带动与所述第一齿轮 32啮合的所述输出齿轮 35转动, 所述输出齿轮 35带动与之相连的所述移相 器, 从而改变所述天线组件 200的下倾角。
当需要其中一个移相器工作来调节与之相连的天线的下倾角时,先使第二 驱动轮 33驱使所述第二齿轮 34转动, 因所述第一齿轮 32可以相对所述第二 齿轮 34的轴线公转,从而第一齿轮 32可以转动到与需要调整的天线移相器所 对应的输出齿轮 35位置啮合, 再使第一驱动轮 31驱使所述第一齿轮 32转动 并带动与所述第一齿轮 32啮合的所述输出齿轮 35转动, 所述输出齿轮 35带 动与之相连的所述移相器工作,从而改变与移相器相连的天线的下倾角。换而 言之,本发明的天线调节装置 100通过第二驱动轮 33驱使第二齿轮 34转动可 以改变第一齿轮 32的位置, 从而使第一齿轮 32与可以与不同的输出齿轮 35 啮合, 即实现第一齿轮 32对输出齿轮 35的选择性驱动,使得本发明的天线调 个天线调节装置 100可以对多个天线的下倾角进行调节,进而解决了现有技术 中因需要多个天线调节装置 100 才能调节多频天线的下倾角而导致的天线调 节装置的整体尺寸较大的问题。
更进一步, 因一个天线调节装置 100可以对多个天线的下倾角进行调节, 相对现有技术中一个天线需要一个天线调节装置而言,本发明大大减少了天线 调节装置 100的数量, 从而极大地降低了制造天线调节装置 100的成本。
更进一步, 因减少了天线调节装置 100 的数量, 从而安装天线调节装置 100所需要的空间也相应地减少了。
在本实施方式中, 一个输出齿轮 35对应一个移相器, 即移相器与输出齿 轮 35为——对应的关系, 同时, 一个第一齿轮 32对应多个输出齿轮 35。 换 而言之, 一个第一齿轮 32对应多个移相器, 使得本发明的天线调节装置 100 可以调节多个天线的下倾角。
在其它实施方式中, 一个输出齿轮 35可以对应 2个或 2个以上移相器。 作为本发明的进一步改进, 在所述第一驱动轮 31 驱使所述第一齿轮 32 转动并带动与所述第一齿轮 32啮合的所述输出齿轮 35转动的过程中,所述第 二齿轮 34被所述第二驱动轮 33锁止不能转动。
作为本发明的进一步改进, 在所述第二驱动轮 33 驱使所述第二齿轮 34 转动并带动所述第一齿轮 32相对所述第二齿轮 34的所述轴线公转时,所述第 一驱动轮 31驱使所述第一齿轮 32转动。
因第二驱动轮 33在驱使第二齿轮 34转动并带动第一齿轮 32改变位置的 过程中, 第一驱动轮 31驱动所述第一齿轮 32也相应地旋转, 从而第一齿轮 32不会驱使输出齿轮 35转动, 进而与输出齿轮 35连接的移相器不会工作, 即天线的下倾角没有变化。 换而言之, 在所述第一齿轮 32选择性地与输出齿 轮 35啮合的过程中, 第一齿轮 32不会驱使其所经过的输出齿轮 35转动而导 致与输出齿轮 35对应的天线移相器工作,从而优化了第一齿轮 32在选择性地 与输出齿轮 35啮合的过程中, 天线的下倾角不会变化。
如图 1和图 2所示, 作为本发明的进一步改进, 所述天线调节装置 100 还包括多个相互平行的输出轴 36, 所述输出齿轮 35和所述输出轴 36固定连 接。
在本实施方式中, 所述输出齿轮 35和所述输出轴 36为一体式的齿轮轴。 在其它实施方式中,所述输出齿轮 35和所述输出轴 36通过配合的方式固 定为一体, 如销键配合。
作为本发明的进一步改进,所述第一驱动轮 31和所述第一转轴 37固定连 接, 所述第二齿轮 34安装于所述第一转轴 37 , 所述第一转轴 37平行于所述 输出轴 36。
在本实施方式中,齿轮架 34a两端分别嵌入于第一固定架 301和第二固定 架 302, 使得齿轮架 34a能够空套在第一转轴 37。 齿轮架 34a的两端与第一固 定架 301和第二固定架 302为非固定连接, 第一固定架 301和第二固定架 302 中供齿轮架 34a嵌入的圆孔的直径略大于齿轮架 34a两端的直径,使得齿轮架 34a可在第一固定架 301和第二固定架 301的支撑下稳定转动, 同时保持齿轮 架 34a稳定的固定于第一固定架 301和第二固定架 302之间。
在本实施方式中, 所述第二齿轮 34通过齿轮架 34a空套在所述第一转轴 37 , 即当所述第一转轴 37转动时, 所述第二齿轮 34不跟随所述第一转轴 37 转动。 所述第一驱动轮 31和所述第一转轴 37 固定连接, 即当所述第一转轴 37转动时, 所述第一驱动轮 31和所述第一转轴 37—起转动。
在本实施方式中,所述第一驱动轮 31和所述第一转轴 37为一体式的齿轮 轴。
在其它实施方式中,所述第一驱动轮 31和所述第一转轴 37通过配合的方 式固定为一体, 如销键配合。
作为本发明的进一步改进, 所述天线调节装置 30还包括第三转轴 38 , 所 述第二驱动轮 33和所述第三转轴 38固定连接, 所述第三转轴 38平行于所述 第一转轴 37和所述输出轴 36。
在本实施方式中, 因所述第二驱动轮 33和所述第三转轴 38固定连接, 当 所述第三转轴 38转动时, 所述第二驱动轮 33和所述第三转轴 38—起转动。
在本实施方式中,所述第二驱动轮 33和所述第三转轴 38为一体式的齿轮 轴。
在其它实施方式中,所述第二驱动轮 33和所述第三转轴 38通过配合的方 式固定为一体, 如销键配合。
作为本发明的进一步改进, 所述天线调节装置 30还包括第二转轴 39, 所 述第一齿轮 32安装于所述第二转轴 39, 所述第二转轴 39平行于所述第三转 轴 38、 所述第一转轴 37和所述输出轴 36。
更进一步, 所述第二转轴 39与所述齿轮架 34a连接, 齿轮架 34a圆周留 有足够的空间用于放置第二转轴 39及安装于第二转轴 39的第一齿轮 32, 第 二转轴 39。 当所述第二齿轮 34转动时, 所述第二转轴 39和所述第二齿轮 34 一起转动。 所述第一齿轮 32和所述第二转轴 39活动连接, 当所述第二转轴 39和所述第二齿轮 34—起转动时, 所述第一齿轮 32不仅相对所述第二齿轮 34的轴线转动, 而且相对所述第二转轴 39转动。 在本实施方式中, 所述第一 齿轮 32相对所述第二齿轮 34的轴线转动被称为公转, 所述第一齿轮 32相对 所述第二转轴 39转动被称为自转。
在本实施方式中, 所述第二转轴 39与所述第二齿轮 34固定连接。
在其它实施方式中, 所述第二转轴 39与所述第二齿轮 34活动连接。 不管 所述第二转轴 39与所述第二齿轮 34是固定连接还是活动连接,当所述第二齿 轮 34转动时, 所述第二转轴 39随所述第二齿轮 34—起转动。
如图 1和图 6所示, 作为本发明的进一步改进, 所述天线调节装置 100 还包括第一固定架 301和与所述第一固定架 301相隔一定距离的第二固定架
302。
在本实施方式中,所述第一转轴 37和所述输出轴 36安装于所述第一固定 架 301和所述第二固定架 302, 所述第三转轴 38安装于所述第二固定架 302。
在其它实施方式中,所述第一转轴 37和所述输出轴 36安装于所述第一固 定架 301 ,但不安装于所述第二固定架 302, 或者所述第一转轴 37安装于所述 第二固定架 302而不安装于所述第一固定架 301。 所述第三转轴 38安装于所 述第一固定架 301和所述第二固定架 302。
如图 1、 图 2和图 6所示, 作为本发明的进一步改进, 所述天线调节装置 100还包括多个螺杆 40、 多个螺母 50和多个导向杆 60, 所述螺杆 40与所述 输出轴 36固定连接, 所述螺母 50与所述螺杆 40啮合并与所述移相器固定连 接, 所述螺母 50与所述导向杆 60活动连接, 所述导向杆 60安装于所述第一 固定架 301 , 用于限制螺母 50的转动并对螺母 50的直线运动起导向作用。
当所述螺杆 40在输出轴 36的带动下转动时, 螺母 50的转动被导向杆 60 限制只能沿着导向杆 60直线移动, 即螺母 50相对螺杆 40移动。 换而言之, 通过螺杆 40、 螺母 50及导向杆 60三者之间的配合将所述输出轴 36的转动转 换为螺母 50的直线运动, 从而使与所述螺母 50固定连接的所述移相器工作, 进而实现了对天线组件 200下倾角的调节。
在其它实施方式中, 螺杆 40与输出轴 36—体成型, 即螺杆 40与输出轴 36合并为一体, 只是在输出轴 36的一端设有螺纹, 输出轴 36的另一端安装 有输出齿轮 35。 或者, 螺杆 40、 输出轴 36及输出齿轮 35三者为一体。
如图 3至图 7所示, 作为本发明的进一步改进, 所述天线调节装置 100 还包括驱动装置 10, 所述驱动装置 10接收来自移动通信基站的控制信号和电 源, 并驱使传动装置 30工作, 进而驱使天线组件 200的移相器工作, 实现对 天线组件 200的下倾角调节。
更进一步, 所述驱动装置 10包括第一接口 11和第二接口 12, 所述第一 接口 11和第二接口 12均可以接收来自移动通信基站的控制信号和电源。其中, 第一接口 11为公连接器, 第二接口 12为母连接器。 当与所述驱动装置 10对 接的连接器为公连接器时, 则使用第二接口 12, 当与所述驱动装置 10对接的 连接器为母连接器时, 则使用第一接口 11 , 换而言之, 不管与所述驱动装置 10对接的连接器为公连接器还是母连接器, 所述驱动装置 10均可以接收来自 移动通信基站的控制信号和电源, 从而给使用带来了方便。
在本实施方式中,所述驱动装置 10设有两组接口, 其中一组为备用接口。 每一组接口包括第一接口 11和第二接口 12。
在其它实施方式中,所述驱动装置 10也可以只设有一组接口或一个接口。 更进一步, 所述驱动装置 10还包括第一驱动结构 13和第二驱动结构 14, 第一驱动结构 13用于给第一转轴 37和第一驱动轮 31提供动力。 第二驱动结 构 14用于给第三转轴 38和第二驱动轮 33提供动力。
在本实施方式中, 第一驱动轮 31和第二驱动结构 14均为电机。
具体地, 第二驱动结构 14具有自锁力矩。在第一驱动轮 31驱使第一齿轮 32转动并驱使与第一齿轮 32啮合的输出齿轮 35转动的过程中, 因为驱动第 三转轴 38的电机, 具有自锁力矩, 锁止了第三转轴 38, 进而锁止了与第三转 轴 38固定连接的第二驱动轮 33 , 通过锁止了与第二齿轮 34啮合的第二驱动 轮 33 , 实现了对第二齿轮 34的锁止, 从而保证了第一齿轮 32与输出齿轮 35 的啮合关系不会被改变, 从而可以实现第一驱动轮 31驱使第一齿轮 32转动, 并驱使与之啮合的输出齿轮 35转动并带动移相器工作, 进而改变移相器所对 应天线的下倾角。 换而言之, 在调节天线下倾角的过程中, 因第二驱动结构 14具有自锁力矩, 使得第二齿轮 34被锁止, 从而在第一驱动轮 31驱使第一 齿轮 32转动的过程中,第一齿轮 32与输出轴齿轮 35的啮合关系不会被改变。
更进一步, 所述驱动装置 10包括第一输出接口 15和第二输出接口 16, 所述第一输出接口 15与第一转轴 37连接, 第二输出接口 16与所述第三转轴 38连接, 即所述驱动装置 10通过第一输出接口 15和第二输出接口 16和所述 传动装置 30连接, 使得所述驱动装置 10通过插拔的方式与所述传动装置 30 连接。
如图 1至图 7所示, 安装时, 将第一转轴 37、 第三转轴 38、 第二转轴 39 及输出轴 36安装于第一固定架 301和第二固定架 302, 所述第一驱动轮 31和 所述第二齿轮 34均安装于所述第一转轴 37 , 所述第二驱动轮 33安装于所述 第三转轴 38并与第二齿轮 34啮合,所述第一齿轮 32安装于第二转轴 39并与 第一驱动轮 31啮合, 所述输出齿轮 35安装于所述输出轴 36, 接着将所述螺 杆 40固定于所述输出轴 36, 所述螺母 50与所述螺杆 40啮合,所述导向杆 60 固定于第一固定架 301 , 所述螺母 50与导向杆 60滑动连接, 从而第一固定架 301、 第二固定架 302、 第一转轴 37、 第三转轴 38、 第二转轴 39、 输出轴 36、 第一驱动轮 31、 第一齿轮 32、 第二驱动轮 33、 第二齿轮 34、 多个输出齿轮 35、 所述螺杆 40、 所述螺母 50及所述导向杆 60便组装为传动装置 30。 接着 将第一转轴 37与第一输出接口 15连接,第一转轴 38与第二输出接口 16连接, 从而驱动装置 10和传动装置 30便组装为天线调节装置 100。
使用时, 首先接受控制信号和接电源, 即所述驱动装置 10通过第一接口 11或第二接口 12接收来自移动通信基站的控制信号和电源, 以使第一驱动结 构 13和第二驱动结构 14工作; 其次, 选择有输出需求的输出齿轮 35 , 即根 据控制信号的指示选择需要调节下倾角的天线,并根据需要调节下倾角的天线 的移相器来选择输出齿轮 35 , 过程如下: 第二驱动结构 14驱使与第二输出接 口 16连接的第三转轴 38转动,第二驱动轮 33与第三转轴 38连动并驱使与之 啮合的第二齿轮 34转动, 进而带动连接于齿轮架 34a上的第二转轴 39旋转, 迫使安装在第二转轴 39上的第一齿轮 32旋转到有输出需求的输出齿轮 35的 位置啮合; 最后, 调节天线的下倾角, 过程如下: 第一驱动结构 13驱使与第 一输出接口 15连接的第一转轴 37转动, 第一驱动轮 31和第一转轴 37连动, 并带动第一齿轮 31旋转, 进而驱使与第一齿轮 31啮合的输出齿轮 35转动, 导致螺杆 40转动,且使螺母 50相对导向杆 60直线运动,从而与螺母 50固定 连接的移相器工作, 进而改变天线的下倾角。
因第一齿轮 32可以选择性地与输出齿轮 35啮合,从而天线组件 200的移 相器可以选择性工作, 使得本发明的天线调节装置 100 可以对天线组件 200 中的天线的下倾角进行选择性调节,即实现一个天线调节装置 100可以对多个 天线的下倾角进行调节。 换而言之, 因本发明的第一齿轮 32可以对输出齿轮 35的选择性驱动, 从而本发明的天线调节装置 100可以对多个天线的下倾角 进行调节, 即实现了一对多, 而不是现有技术中一个天线调节装置 100只能调 节一个天线的下倾角,进而解决了现有技术中因天线调节装置 100过多而导致 的天线调节装置 100整体尺寸较大的问题。
请参考图 7, 本发明还提供了一种电调天线 300。 所述电调天线 300包括 上述天线调节装置 100和天线组件 200, 所述天线组件 200设有外壳 201 , 所 述外壳 201设有收容空间 (被天线调节装置 100遮挡), 收容空间在外壳 201的 一个端面设有开口(被天线调节装置 100遮挡)。 安装时, 天线调节装置 100的 传动装置 30固定于外壳 201内,天线调节装置 100的所述驱动装置 10通过开 口插入所述收容空间中并与传动装置 30连接, 即天线调节装置 100的所述驱 动装置 10通过可插拔的方式安装于天线组件 200的外壳 201中。
因所述驱动装置 10通过可插拔的方式安装于天线组件 200的外壳 201中, 从而在使用过程中,如果所述驱动装置 10出现故障,如第一驱动结构 13和或 第二驱动结构 14(请参考图 5)出现故障, 用户可以通过开口从所述收容空间中 拔出所述驱动装置 10, 以进行维护或更换。 换而言之, 在维护或更换所述驱 动装置 10的过程中, 不需要拆卸整个所述电调天线 300, 即不需要拆卸天线 组件 200就可以维护或更换所述驱动装置 10, 使得电调天线 300的维护变得 更方便, 从而提高了用户使用的方便性。
更进一步, 因天线调节装置 100安装于天线组件 200的外壳 201中, 即天 线调节装置 100和天线组件 200集成为一体,使得电调天线 300的结构更加紧 凑, 满足了小型化的发展趋势。
而且,本发明的电调天线 300只需要一个天线调节装置 100就可以调节天 线组件 200中的所有天线的倾角,从而减少了天线调节装置 100的数量和安装 天线调节装置 100所需要的空间, 进而减少了电调天线 300的体积,解决了现 有技术中因需要多个天线调节装置 100 才能调节多频天线的下倾角而导致的 电调天线 300的尺寸较大的问题。 同时, 因减少了天线调节装置 100的数量, 使得制造天线调节装置 100 的成本也大大降低, 从而也降低了制造电调天线 300的成本。
以上所述是本发明的优选实施方式,应当指出,对于本技术领域的普通技 术人员来说, 在不脱离本发明原理的前提下, 还可以做出若干改进和润饰, 这 些改进和润饰也视为本发明的保护范围。

Claims

1.一种天线调节装置 (100),用于调节天线组件 (200)的下倾角,所述天线组 件 (200)包括多个移相器, 其特征在于: 所述天线调节装置 (100)还包括第一驱 动轮 (31)、 第一转轴 (37)、 齿轮架 (34a)、 第一齿轮 (32)、 第二驱动轮 (33)、 第二 齿轮 (34)和多个输出齿轮 (35), 所述第一驱动轮 (31)与所述第一齿轮 (32)啮合, 所述第二驱动轮 (33)与所述第二权齿轮 (34)啮合,所述第二齿轮 (34)的轴线与所述 第一驱动轮 (31)的轴线重合, 所述输出齿轮 (35)与所述移相器——对应连接, 利
所述齿轮架 (34a)套装于所述第一转轴 1 ( 237) , 所述第二齿轮 (34)与所述齿轮架 要
(34a)固定连接, 所述第一齿轮 (32)随所述齿轮架 (34a)—起转动, 所述第二驱动 轮 (33)用于驱使所述第二齿轮 (34)转动并带动求所述第一齿轮 (32)相对所述第二 齿轮 (34)的所述轴线公转, 以使所述第一齿轮 (32)选择性地与其中一个所述输 出齿轮 (35)啮合,所述第一驱动轮 (31)用于驱使所述第一齿轮 (32)转动并带动与 所述第一齿轮 (32)啮合的所述输出齿轮 (35)转动,所述输出齿轮 (35)用于驱动与 之相连的所述移相器。
2. 如权利要求 1所述的天线调节装置 (100), 其特征在于, 所述第二驱动 轮 (33)还用于锁止所述第二齿轮 (34)。
3. 如权利要求 1至 2任意一项所述的天线调节装置 (100), 其特征在于, 所述天线调节装置 (100)还包括多个相互平行的输出轴 (36), 所述输出齿轮 (35) 与所述输出轴 (36)固定连接,所述输出轴 (36)与所述第一驱动轮 (31)的轴线平 行。
4. 如权利要求 3所述的天线调节装置 (100), 其特征在于, 所述第一驱动 轮 (31)和所述第一转轴 (37)固定连接, 所述第一转轴 (37)平行于所述输出轴 (36)。
5. 如权利要求 4所述的天线调节装置 (100), 其特征在于, 天线调节装置 (100)还包括第二转轴 (39), 所述第一齿轮 (32)与所述第二转轴 (39)活动连接, 所述第二转轴 (39)与所述齿轮架 (34a)连接并随所述第二齿轮 (34)转动, 以使所 述第一齿轮 (32)随所述第二齿轮 (34)转动。
6. 如权利要求 5所述的天线调节装置 (100), 其特征在于, 所述第二转轴 (39)平行于所述第一转轴 (37)和所述输出轴 (36)。
7. 如权利要求 6所述的天线调节装置 (100), 其特征在于, 所述天线调节 装置 (100)还包括第三转轴 (38) , 所述第二驱动轮 (33)和所述第三转轴 (38)固定 连接, 所述第三转轴 (38)平行于所述第一转轴 (37)、所述第二转轴 (39)和所述输 出轴 (36)。
8. 如权利要求 3至 7任意一项所述的天线调节装置 (100), 其特征在于, 所述天线调节装置 (100)还包括第一固定架 (301),所述输出轴 (36)安装于所述第 一固定架 (301)。
9. 如权利要求 8所述的天线调节装置 (100), 其特征在于, 所述天线调节 装置 (100)还包括多个螺杆 (40)、 多个螺母 (50)和多个导向杆 (60), 所述螺杆 (40) 与所述输出轴 (36)固定连接,所述螺母 (50)与所述螺杆 (40)啮合并与所述移相器 固定连接, 所述导向杆 (60)与所述螺母 (50)活动连接, 所述导向杆 (60)安装于所 述第一固定架 (301)。
10. 如权利要求 8 所述的天线调节装置 (100),其特征在于,所述输出轴 (36) 的一端设有螺纹, 所述天线调节装置 (100)还包括多个螺母 (50)和多个导向杆 (60), 所述螺母 (50)与所述输出轴 (36)的螺纹啮合并与所述移相器固定连接, 所 述导向杆 (60)与所述螺母 (50)活动连接,所述导向杆 (60)安装于所述第一固定架 (301)。
11. 如权利要求 1至 10任一项所述的天线调节装置 (100), 其特征在于, 所述天线调节装置 (100)还包括第一驱动结构 (13), 用于给所述第一驱动轮 (31) 提供动力。
12. 如权利要求 1至 10任一项所述的天线调节装置 (100), 其特征在于, 所述天线调节装置 (100)还包括第二驱动结构 (14), 用于给所述第二驱动轮 (33) 提供动力。
13. 如权利要求 12所述的天线调节装置 (100), 其特征在于, 所述第二驱 动结构 (14)具有自锁力矩, 用于锁止所述第二驱动轮 (33)。
14.一种电调天线, 包括天线组件 (200), 其特征在于: 所述电调天线还包 括集成于所述天线组件 (200)内的如权利要求 1至 13任意一项所述的天线调节 装置 (100)。
15. 如权利要求 14所述的电调天线, 其特征在于, 所述天线组件 (200)包 括外壳, 所述天线调节装置 (100)安装于所述外壳内。
16. 如权利要求 15所述的电调天线, 其特征在于, 所述外壳设有收容空 间, 所述收容空间在所述外壳的一个端部设有开口, 所述天线调节装置 (100) 进一步包括驱动装置, 所述驱动装置通过所述开口插入所述收容空间中。
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