CN116320810A - Movable mobile base station based on LaRa transmission technology - Google Patents

Abstract

The invention discloses a movable base station based on LaRa transmission technology, which relates to the related field of communication technology and comprises a movable base, wherein a driving component with a driving function and a base station main box with bolts arranged at the top of the movable base are arranged at the bottom of the movable base, an adjusting component is arranged at the top of the movable base, external air is driven by an adjusting air pump to respectively enter a plurality of groups of rotary cylinders through a straight pipe exhaust valve, at the moment, the flow of the introduced air flow can be monitored through a flow valve body and is pushed to rotate so as to drive the rotary component and a detecting component to rotate, and meanwhile, a stabilizing buffer effect can be provided for the rotary cylinder, the rotary component and the like through a stabilizing component, so that the adjusting effect on components such as signal pieces, transmission pieces and the like can be improved.

Description

Movable mobile base station based on LaRa transmission technology

Technical Field

The invention relates to the field of communication technology, in particular to a movable base station based on LaRa transmission technology.

Background

The LaRa transmission technology is a long-distance and low-power consumption wireless transmission technology based on a spread spectrum technology, and the network is suitable for constructing a safer and low-cost private Internet of things, and has the advantages of low power consumption, wide transmission distance, strong signal penetrability, high sensitivity, low cost, easy expansion and the like; along with the high-speed development of mobile communication, the number of communication base stations is continuously increased, the technical content and the complexity of equipment are also higher and higher, and correspondingly, higher requirements are also put forward on the stability and the reliability of the power supply of the communication base stations; communication power supplies are an important component of the communication network infrastructure.

In the prior art, a folding component such as a supporting rod is mostly adopted to provide a height adjusting action for a signal transmission box body, the overall adjusting mode of the mode is single, the up-down overturning direction can be mostly realized, meanwhile, the overall moving base station is easy to have larger volume due to the length of the supporting rod, and meanwhile, the adjusting action is difficult to complete due to the shape or characteristics of the supporting rod, and the prior art mostly lacks a frequency expanding component for an electric signal, so that the existing phenomenon of poor overall transmission efficiency of the electric signal is caused;

meanwhile, the prior art has poor effects on the shock absorption and buffering of parts such as a transmission part, a signal part and the like, so that the phenomenon that the existing high-precision parts such as the transmission part and the like are easy to damage due to vibration is caused; the prior art lacks a detection component for surrounding electric waves, so that the influence of the surrounding environment or equipment on electric wave output is difficult to know, and the base station is required to be positioned and fixed for many times due to signal problems.

Disclosure of Invention

Accordingly, in order to solve the above-mentioned shortcomings, the present invention provides a mobile base station based on the LaRa transmission technology.

The invention is realized in such a way, a movable base station based on LaRa transmission technology is constructed, the device comprises a movable base, a driving component playing a driving role and a base station main box with bolts arranged at the top of the movable base are arranged at the bottom of the movable base, and a push handle and a control panel with bolts arranged at the front end of the base station main box are arranged at the left end of the base station main box;

the method is characterized in that: the adjusting assembly is arranged at the top of the movable base;

the adjustment assembly includes: the left bolt at the top of the movable base is provided with the protective box; the right end bolt in the protective box body is provided with an adjusting air pump which plays a role in guiding air pressure; the flow valve body is arranged on the air outlet pipeline at the rear end of the air adjusting pump; the linear pipe exhaust valve is arranged at the air outlet pipeline at the rear end of the flow valve body; the stabilizing component is arranged on the top side of the protective box body; the top of the straight line pipe row valve is connected with a rotating cylinder pipeline through a connecting pipe; the left end and the right end of the rotary cylinder are respectively provided with a rotary component through bolts; the detection assembly is arranged on the top side of the rotary cylinder; wherein, adjust air pump, flow valve body and sharp pipe row valve all with control panel electricity connection.

Preferably, the stabilizing assembly comprises a mounting substrate, and the mounting substrate is mounted on the top side of the protective box body through a connecting plate bolt; the extrusion sealing plates are arranged on the upper side and the lower side of the mounting substrate through bolts; the middle side bolt at the right end of the mounting substrate is provided with a limiting side plate; the side slot in the limiting side plate is welded and fixed with a permanent magnet; the iron casting rod is arranged in the through hole at the middle side of the permanent magnet in a sliding manner; the left end bolt at the top of the extrusion sealing plate is provided with the miniature vibration generator; the sliding groove in the mounting base plate is in sliding connection with the sliding block at the left end of the mounting side plate; damping spring rods which play a damping role are respectively arranged at the upper end and the lower end of the sliding block at the left end of the mounting side plate; the miniature vibration generator is connected with the bottom of the cast iron rod through a cable.

Preferably, the rotating assembly includes: the rotary piece at the right end of the rotary cylinder is fixedly connected with the first clamping block in a plugging manner; the screw thread column is welded and fixed at the top of the first clamping block; the electromagnetic plate is arranged on the inner through hole wall bolt of the threaded column; the stretching rod is rotatably arranged in the electromagnetic plate; the screw thread cylinder is arranged at the top of the stretching rod, and the cylinder body bolt at the top of the stretching rod is arranged at the inner top of the screw thread cylinder; the top of the threaded cylinder is fixedly welded with a second clamping block; wherein, the electromagnetic plate is connected with the control panel electricity.

Preferably, four groups of rotating assemblies and five groups of rotating cylinders are arranged at the top of the mounting substrate, and the rotating angle of the rotating cylinders is 180 degrees.

Preferably, the detection assembly includes: the protection shell is mounted on the rotary piece bolt at the right end of the rotary cylinder above the base station main box; the spread spectrum assembly is mounted in the protective shell through bolts; the left end of the protective shell is fixedly connected with the signal transmitter in a plugging manner; the side plates are mounted on the top sides of the front end and the rear end of the protective shell through bolts; the electric wave detectors are respectively mounted on the front side and the rear side of the side mounting plate through bolts; the front end and the rear end of the electric wave detector are respectively inserted and fixed with the signal receiver; the signal transmitter, the electric wave detector and the signal receiver are all electrically connected with the control panel.

Preferably, the lateral surfaces of the left side and the right side of the side mounting plate are respectively provided with a wave absorbing material with a wave absorbing effect, and the left end and the right end of the protective shell are respectively provided with two groups of side mounting plates, an electric wave detector and a signal receiver.

Preferably, the spreading component comprises: the control main board is fixed on the left wall in the protective shell through bolts; the signal input source is fixed on the bottom side soldering tin of the right end of the control main board; the carrier module is fixed on the bottom side soldering tin of the right end of the control main board and plays a role of carrier; the middle side of the right end of the control main board is fixedly provided with a frequency division module which plays a role in controlling frequency division; the top side of the frequency division module is fixedly provided with the shift register through a connecting tin bar; and the code generator is fixed at the right end of the control main board through soldering tin.

Preferably, the spreading module further comprises: the top of the code generator is fixedly provided with a spread spectrum modulation module through a connecting tin bar; the time delay controller is fixed on the top side solder of the right end of the control main board; the signal output module is fixed on the top side solder of the right end of the control main board; wherein, control mainboard and control panel electricity are connected.

Preferably, the bottom of the signal input source is fixedly connected with the controller in the base station main box through a signal cable, and the top side of the signal output module is fixedly connected with a signal transmitter in a plugging manner.

Preferably, the signal transmitter and the signal receiver are distributed in a right angle and included angle, and the control main board and the electric wave detector are connected in series.

The invention has the following advantages: the invention provides a movable base station based on LaRa transmission technology by improving the technology, which has the following improvements compared with the same type of equipment:

according to the movable base station based on the LaRa transmission technology, the adjusting component is arranged at the top of the movable base, the air pump is adjusted to drive external air to respectively enter the plurality of groups of rotary air cylinders through the linear pipe exhaust valve, at the moment, the flow valve body can be used for monitoring the introduced airflow and pushing the flow valve body to rotate so as to drive the rotary component and the detecting component to rotate, meanwhile, the stabilizing component can be used for providing a stable buffering effect for the rotary air cylinders, the rotary component and other components, and the adjusting effect on the components such as signal components and transmission components is improved.

According to the movable base station based on the LaRa transmission technology, the stabilizing component is arranged at the top of the protective box body, the permanent magnet and the cast iron rod are fixed in the sliding groove of the installation base plate through the limiting side plate, and the cast iron rod is inserted into the bottom side of the connecting block of the installation side plate synchronously, so that vibration is transmitted to the miniature vibration generator through the installation side plate to electrify the cast iron rod, and vibration reduction and buffering actions are carried out on a cutting magnetic field formed by the permanent magnet and the cast iron rod.

According to the movable base station based on the LaRa transmission technology, the rotating assembly is arranged at the right end of the rotating cylinder, and the plurality of groups of electromagnetic plates are electrified by pulse so as to absorb the stretching rod, so that the stretching rod is connected with the threaded column and the threaded cylinder and slowly rotates, and the connection fixing and rotation adjusting effects on the first clamping block and the second clamping block are improved.

According to the movable base station based on the LaRa transmission technology, the detection assembly is arranged at the right end of the rotary cylinder, the spread spectrum assembly is used for controlling the electric signal to be emitted through the signal emitter after spread spectrum, the electric wave detector and the signal receiver are used for monitoring surrounding electric waves, and the detection influence effect of the surrounding electric waves on the electric wave detector is reduced under the material wave absorption effect of the side plate.

The movable base station based on LaRa transmission technology has the advantages that the spread spectrum component is arranged in the protective shell, the frequency division module controls the electric signals to enter the shift register, the code generator and other parts respectively to perform signal processing, spread spectrum action is performed under the operation action, and then signal output is performed through the signal output module and the signal transmitter.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic perspective exploded view of the adjustment assembly of the present invention;

FIG. 3 is a schematic perspective view of the stabilizing assembly and rotary cylinder of the present invention;

FIG. 4 is a schematic perspective exploded view of the stabilizing assembly of the present invention;

FIG. 5 is a schematic perspective exploded view of the rotary assembly of the present invention;

FIG. 6 is a schematic diagram of an exploded view of a sensing assembly of the present invention;

fig. 7 is a schematic perspective view of a spreading module according to the present invention;

fig. 8 is a schematic flow chart of a spreading component of the present invention.

Wherein: the device comprises a moving base-1, a driving component-2, a base station main box-3, a push handle-4, a regulating component-5, a control panel-6, a protective box-51, a regulating air pump-52, a flow valve body-53, a straight pipe row valve-54, a stabilizing component-55, a rotating air cylinder-56, a rotating component-57, a detecting component-58, a mounting base plate-551, a pressing sealing plate-552, a limiting side plate-553, a permanent magnet-554, a cast iron rod-555, a miniature vibration generator-556, a mounting side plate-557, a damping spring rod-558, a first clamping block-571, a threaded column-572, an electromagnetic plate-573, a stretching rod-574, a threaded cylinder-575, a second clamping block-576, a protective shell-581, a frequency expanding component-582, a signal transmitter-583, a side mounting plate-584, an electric wave detector-585, a signal receiver-586, a control main plate-5821, a signal input source-5822, a carrier module-5823, a frequency dividing module-5824, a shift register-5825, a code generator-5826, a code modulator-5828 and a time-delay module 5828.

Detailed Description

The principles and features of the present invention are described below with reference to fig. 1-8, the examples being provided for illustration only and not for limitation of the scope of the invention. The invention is more particularly described by way of example in the following paragraphs with reference to the drawings. Advantages and features of the invention will become more apparent from the following description and from the claims. It should be noted that the drawings are in a very simplified form and are all to a non-precise scale, merely for convenience and clarity in aiding in the description of embodiments of the invention.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When a component is considered to be "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Embodiment one:

referring to fig. 1 to 8, the mobile base station based on the LaRa transmission technology of the present invention comprises a mobile base 1, wherein a driving component 2 playing a driving role and a base station main box 3 mounted on the top of the mobile base 1 by bolts are arranged at the bottom of the mobile base 1, a push handle 4 is mounted on the left end bolt of the base station main box 3, and a control panel 6 is mounted on the front end of the base station main box 3 by bolts, and the driving component 2 consists of a motor and a gear box;

the method is characterized in that: the device also comprises an adjusting component 5 arranged at the top of the movable base 1;

the adjusting component 5 comprises a protective box body 51, the left side bolt at the top of the mobile base 1 is provided with the protective box body 51, the right end bolt inside the protective box body 51 is provided with an adjusting air pump 52 playing a role of guiding air pressure, the air outlet pipeline at the rear end of the adjusting air pump 52 is provided with a flow valve body 53, the flow valve body 53 is used for providing flow monitoring for output air flow of the adjusting air pump 52, the air outlet pipeline at the rear end of the flow valve body 53 is provided with a straight pipe exhaust valve 54, the top side of the protective box body 51 is provided with a stabilizing component 55, the top of the straight pipe exhaust valve 54 is connected with a revolving cylinder 56 through a connecting pipe, the air flow guiding effect is provided for a plurality of groups of revolving cylinders 56 through the straight pipe exhaust valve 54, the left end and the right end of the revolving cylinder 56 are respectively provided with a rotating component 57 through bolts, the top side of the revolving cylinder 56 is provided with a detecting component 58, and the adjusting air pump 52, the flow valve body 53 and the straight pipe exhaust valve 54 are electrically connected with a control panel 6 to provide electric energy for the adjusting air pump 52, the flow valve body 53 and the straight pipe exhaust valve 54.

The working principle of a mobile base station based on the LaRa transmission technology of the embodiment 1 is:

firstly, when the equipment is used, the equipment is firstly placed in a working area, and then the device is connected with an external power supply, so that the power supply required by the work of the equipment can be provided.

Secondly, when the base station main box 3 is displaced, a worker can drive the movable base 1 through the driving component 2 to provide driving power, and then when the placement position of the base station main box 3 is confirmed, the worker can control the adjusting air pump 52 to work through the control panel 6, so that the adjusting air pump 52 drives external air to enter the plurality of groups of rotary air cylinders 56 through the linear pipe exhaust valves 54 respectively;

thirdly, the flow rate of the air flow which can be led in through the flow valve body 53 is monitored at the moment, so that the rotating air cylinder 56 drives the rotating assembly 57 at the top of the rotating air cylinder to rotate 180 degrees, the rotating assembly 57 drives the rotating air cylinder 56 at the top of the rotating air cylinder to rotate upwards, air supply is controlled in the straight line pipe row valve 54 in sequence, a plurality of groups of rotating air cylinders 56 work in sequence, and the detecting assembly 58 can move upwards to a proper height under the adjustment action of the rotating air cylinder 56 and the rotating assembly 57;

fourth, the stable buffering effect is provided for the rotating cylinder 56, the rotating component 57 and other components through the stabilizing component 55, so that the adjusting effect on the detecting component 58 signal component, the transmitting component and other components is improved.

Embodiment two:

referring to fig. 1-8, the movable base station based on the LaRa transmission technology of the present invention comprises a stabilizing assembly 55, the stabilizing assembly 55 comprises a mounting base plate 551, a connecting plate bolt on the top side of a protective box 51 is provided with the mounting base plate 551, the upper and lower sides of the mounting base plate 551 are both provided with extrusion sealing plates 552 through bolts, the upper and lower sides of the mounting base plate 551 are provided with a limiting effect through the extrusion sealing plates 552, the middle side bolt on the right end of the mounting base plate 551 is provided with a limiting side plate 553, a side slot in the limiting side plate 553 is fixedly welded with a permanent magnet 554, the permanent magnet 554 is provided with a mounting limiting effect through the limiting side plate 553, a cast iron rod 555 is slidably arranged in the side through hole in the permanent magnet 554, the left end bolt on the top of the extrusion sealing plates 552 is provided with a micro vibration generator 556, the mounting limiting effect is provided for the micro vibration generator 556, an inner sliding chute of the mounting base plate 551 is slidably connected with a sliding block on the left end of the mounting side plate 557, the upper and lower ends of the sliding blocks of the mounting side plate 557 are respectively provided with damping spring rods 558 playing a damping role, the micro vibration generator 556 is connected with the bottom of the cast iron rod 555 through cables, the micro vibration generator 556 provides electric energy for the cast iron rod 555, and a rotating with the permanent magnet 554, thus the micro vibration generator 554 and the permanent magnet rotating assembly is provided with a rotating cylinder assembly 56, and the rotating at the same degree as a rotating cylinder assembly of a rotating assembly of a cylinder, and a cylinder rotating assembly 180, and a rotating at a rotating angle, and a cylinder assembly, and a rotating at a rotating assembly, and a rotating assembly and a rotating at and a rotating assembly.

In this embodiment:

firstly, the moving base 1 and the driving assembly 2 are moved to enable the moving base 1 and the base station main box 3 to transmit vibration force to the mounting base plate 551, at the moment, the permanent magnet 554 and the cast iron rod 555 are fixed in the sliding groove of the mounting base plate 551 by the limiting side plate 553, and the cast iron rod 555 is inserted into the bottom side of the connecting block of the mounting side plate 557, so that the mounting base plate 551 and the mounting side plate 557 transmit vibration to the micro vibration generator 556 to enable the micro vibration generator 556 to generate electricity to electrify the cast iron rod 555;

second, at this time, the cast iron rod 555 is energized to generate a magnetic field, and vertical vibration of the cast iron rod 555 is absorbed by a vertical cutting magnetic field formed by the permanent magnet 554 and the cast iron rod 555, so that the cast iron rod 555 drives the mounting side plate 557 to perform a vibration absorbing and buffering action, and further the vibration absorbing effect of the rotating assembly 57, the rotating cylinder 56 and other components is improved.

Embodiment III:

referring to fig. 1-8, the mobile base station based on the LaRa transmission technology of the present invention includes a rotating assembly 57, wherein the rotating assembly 57 includes a first clamping block 571, a rotating member at the right end of a rotating cylinder 56 is fixedly inserted into the first clamping block 571, a threaded column 572 is fixedly welded at the top of the first clamping block 571, an electromagnetic plate 573 is mounted on a through hole wall bolt inside the threaded column 572, an installation limiting effect is provided for the electromagnetic plate 573 through the threaded column 572, a stretching rod 574 is rotatably disposed inside the electromagnetic plate 573, a barrel bolt at the top of the stretching rod 574 is mounted at the top inside the threaded barrel 575, the stretching rod 574 provides connection sliding for the electromagnetic plate 573 and the threaded barrel 575, a second clamping block 576 is fixedly welded at the top of the threaded barrel 575, and the electromagnetic plate 573 is electrically connected with a control panel 6 to provide electric energy for the electromagnetic plate 573.

In this embodiment:

when the detection assembly 58 is subjected to horizontal rotation adjustment, a worker can supply pulse power to the plurality of groups of electromagnetic plates 573 through the control panel 6 at this time, so that the four groups of electromagnetic plates 573 are powered on successively, and then the four groups of electromagnetic plates 573 are adsorbed or pushed by a magnetic field to perform fixing or rotation, so that the four groups of electromagnetic plates are connected and slowly rotated to the threaded column 572 and the threaded cylinder 575, and further the connection fixing and rotation adjustment effects between the first clamping block 571 and the second clamping block 576 are improved.

Embodiment four:

referring to fig. 1 to 8, in comparison with the first embodiment, the mobile base station based on the LaRa transmission technology of the present invention further includes: the detection assembly 58, the detection assembly 58 includes a protection casing 581, a protection casing 581 is installed on a right end rotating piece bolt of the rotary cylinder 56 above the base station main box 3, a spread spectrum component 582 is installed on an inner bolt of the protection casing 581, a signal emitter 583 is fixedly connected to the left end of the protection casing 581 in a plugging mode, a side plate 584 is installed on the top side of the front end and the rear end of the protection casing 581 through the protection casing 581 in a bolt mode, an electric wave detector 585 is installed on the front side and the rear side of the side plate 584 through the bolt mode, a limiting effect is installed on the electric wave detector 585 through the side plate 584, a signal receiver 586 is fixedly connected to the front end and the rear end of the electric wave detector 585 through the bolt mode, and the signal receiver 583, the electric wave detector 585 and the signal receiver 586 are all electrically connected with the control panel 6, and electric energy is provided for the signal emitter 583, the electric wave detector 585 and the signal receiver 586.

The lateral surfaces of the left side and the right side of the side plate 584 are respectively provided with a wave absorbing material which plays a role in absorbing waves, and the left end and the right end of the protective shell 581 are respectively provided with two groups of side plates 584, a wave detector 585 and a signal receiver 586, so that the wave absorbing effect of the side plate 584 is improved.

The frequency expansion assembly 582 comprises a control main board 5821, a control main board 5821 is fixed on the left wall of the protective shell 581 through bolts, a signal input source 5822 is fixed on the bottom side soldering tin of the right end of the control main board 5821, a switching effect is provided for input signals through the signal input source 5822, a carrier module 5823 playing a role of carrier is fixed on the bottom side soldering tin of the right end of the control main board 5821, a frequency division module 5824 playing a role of controlling frequency division is fixedly arranged on the middle side of the right end of the control main board 5821, a signal source division effect is provided through the frequency division module 5824, a shift register 5825 is fixedly arranged on the top side of the frequency division module 5824 through connecting tin bars, a code generator 5826 is fixedly arranged on the top of the code generator 5826 through connecting tin bars, a frequency expansion modulation module 5827 is provided for input signals, a delay controller 5828 is fixed on the top side soldering tin of the right end of the control main board 5821, a signal output module 5829 is fixedly arranged on the top side tin of the right end of the control main board 5821, and the control main board 5821 is electrically connected with a control panel 6, and electric energy is provided for the control main board 5821.

The bottom of the signal input source 5822 is fixedly connected with an internal controller of the base station main box 3 through a signal cable, a signal transmitter 583 is fixedly connected to the top side of the signal output module 5829 in a plugging manner, and a signal output enhancement effect is provided for the signal output module 5829 through the signal transmitter 583; the signal transmitter 583 and the signal receiver 586 are distributed at right angles, and the control main board 5821 and the electric wave detector 585 are connected in series.

In this embodiment:

the electric signal calculated by the base station main box 3 is input into the signal input source 5822 through a signal cable, the electric signal is input into the frequency division module 5824 under the control action of the control main board 5821, the electric signal is respectively controlled by the frequency division module 5824 to enter the components such as the shift register 5825, the code generator 5826 and the like for signal processing, the spread spectrum action is carried out under the operation action of the spread spectrum modulation module 5827, at the transmitting end, the spread spectrum result is actually obtained by multiplying the two components in the time domain or the mode two components, and a 63-bit pn code sequence is realized by synchronizing a data symbol, the symbol synchronization modulation mode is completed, then the code sequence is added with the pseudo code sequence from the pn code generator in the mode 2, the spectrum spreading of the signal is completed, then the signal is output through the signal output module 5829 and the signal transmitter 583, the electric signal is controlled through the spread spectrum component 582 to be transmitted out through the signal transmitter 583 after the spread spectrum, the surrounding electric wave is monitored through the electric wave detector 585 and the signal receiver 586, and the surrounding electric wave detection effect is reduced under the material absorbing action of the side 584.

The invention provides a movable base station based on LaRa transmission technology through improvement, external air is driven by an adjusting air pump 52 to respectively enter a plurality of groups of rotary air cylinders 56 through a straight pipe exhaust valve 54, at the moment, the flow valve body 53 can be used for monitoring the flow of the introduced air and pushing the air to rotate so as to drive a rotary assembly 57 and a detection assembly 58 to rotate, meanwhile, the stabilizing assembly 55 can be used for providing a stabilizing buffer effect for the rotary air cylinder 56, the rotary assembly 57 and other parts, thereby being beneficial to improving the adjusting effect for the signal parts, the transmission parts and other parts, the permanent magnet 554 and the cast iron rod 555 are fixed in a chute of a mounting base plate 551 through a limiting side plate 553, the cast iron rod 555 is synchronously inserted at the bottom side of a connecting block of the mounting side plate 557, so that vibration is transmitted to a miniature vibration generator 556 through the mounting side plate 557 to electrify the cast iron rod 555, the vibration damping and buffering action is carried out on the cutting magnetic field formed by the permanent magnet 554 and the cast iron rod 555, the pulse energizing is provided for a plurality of groups of electromagnetic plates 573 to enable the electromagnetic plates to absorb the stretching rod 574, so that the electromagnetic plates are connected with the threaded column 572 and the threaded cylinder 575 and slowly rotate, the connection fixing and rotation adjusting effects on the first clamping block 571 and the second clamping block 576 are improved, the electric signals are controlled by the spread spectrum component 582 to be emitted by the signal emitter 583 after spread spectrum, the surrounding electric waves are monitored by the electric wave detector 585 and the signal receiver 586, the influence effect of the surrounding electric waves on the detection of the electric wave detector 585 is reduced under the wave absorbing action of the material of the side plate 584, the electric signals are controlled by the frequency division module 5824 to enter the components such as the shift register 5825, the code generator 5826 and the like respectively, the signal processing is carried out, the spread spectrum action is carried out under the operation action, and then signal output is performed through the signal output module 5829 and the signal transmitter 583.

The basic principle and main characteristics of the invention and the advantages of the invention are shown and described above, standard parts used by the invention can be purchased from market, special-shaped parts can be customized according to the description of the specification and the drawings, the specific connection modes of the parts adopt conventional means such as mature bolt rivets and welding in the prior art, the machinery, the parts and the equipment adopt conventional models in the prior art, and the circuit connection adopts conventional connection modes in the prior art, so that the description is omitted.

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

Claims (10)

1. The movable base station based on the LaRa transmission technology comprises a movable base (1), wherein a driving assembly (2) playing a driving role and a base station main box (3) mounted on the top of the movable base (1) are arranged at the bottom of the movable base (1), a push handle (4) is mounted on a bolt at the left end of the base station main box (3), and a control panel (6) is mounted at the front end of the base station main box (3) through the bolt;

the method is characterized in that: the device also comprises an adjusting component (5) arranged at the top of the movable base (1);

the adjusting assembly (5) comprises:

the protection box body (51) is arranged on the left side bolt at the top of the movable base (1);

an adjusting air pump (52), wherein an adjusting air pump (52) playing a role of guiding air pressure is arranged at the right end bolt in the protective box body (51);

the flow valve body (53) is arranged at the air outlet pipeline at the rear end of the air adjusting pump (52);

the linear pipe discharge valve (54) is arranged at the air outlet pipeline at the rear end of the flow valve body (53); the stabilizing assembly (55) is arranged on the top side of the protective box body (51); the top of the straight line pipe row valve (54) is connected with the rotary cylinder (56) through a connecting pipe; the rotary assembly (57) is arranged at the left end and the right end of the rotary cylinder (56) through bolts respectively; the detection assembly (58) is arranged on the top side of the rotary cylinder (56); wherein, the air pump (52), the flow valve body (53) and the straight tube discharge valve (54) are all electrically connected with the control panel (6).

2. The mobile base station according to claim 1, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the stabilizing assembly (55) comprises:

the mounting substrate (551), the mounting substrate (551) is mounted on the top side connecting plate bolt of the protective box body (51);

the extrusion sealing plates (552) are arranged on the upper side and the lower side of the mounting substrate (551) through bolts;

a limiting side plate (553), wherein a limiting side plate (553) is mounted on the middle side bolt at the right end of the mounting substrate (551);

the permanent magnet (554) is welded and fixed at a side slot opening in the limiting side plate (553); the iron casting rod (555) is arranged in the middle through hole of the permanent magnet (554) in a sliding manner; the miniature vibration generator (556) is arranged at the left end bolt at the top of the extrusion sealing plate (552); the mounting side plate (557), wherein an inner chute of the mounting base plate (551) is in sliding connection with a sliding block at the left end of the mounting side plate (557); damping spring rods (558), wherein damping spring rods (558) playing a damping role are respectively arranged at the upper end and the lower end of the sliding block at the left end of the mounting side plate (557); wherein, miniature vibration generator (556) is connected with cast iron stick (555) bottom through the cable.

3. The mobile base station according to claim 1, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the rotating assembly (57) comprises: the right end rotating piece of the rotating cylinder (56) is fixedly connected with the first clamping block (571) in a plugging manner; a threaded column (572) is welded and fixed at the top of the first clamping block (571); an electromagnetic plate (573), wherein the electromagnetic plate (573) is mounted on the inner through hole wall of the threaded column (572) through bolts; a stretching rod (574), wherein the stretching rod (574) is rotatably arranged inside the electromagnetic plate (573); the top barrel bolt of the stretching rod (574) is arranged at the inner top of the threaded barrel (575); the second clamping block (576) is welded and fixed at the top of the threaded cylinder (575); wherein the electromagnetic plate (573) is electrically connected with the control panel (6).

4. A mobile base station according to claim 2, which is mobile based on the LaRa transmission technique, wherein: four groups of rotating assemblies (57) and five groups of rotating cylinders (56) are arranged at the top of the mounting substrate (551), and the rotating angle of the rotating cylinders (56) is 180 degrees.

5. The mobile base station according to claim 1, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the detection assembly (58) includes:

a protection shell (581), wherein the protection shell (581) is mounted on a right end rotating piece bolt of a rotating cylinder (56) above the base station main box (3);

a spread spectrum assembly (582), the spread spectrum assembly (582) being mounted to the inner bolt of the protective housing (581);

a signal emitter (583), wherein the left end of the protective shell (581) is fixedly connected with the signal emitter (583) in a plugging manner;

the side plates (584) are arranged on the top sides of the front end and the rear end of the protective shell (581) through bolts; a radio wave detector (585), wherein the radio wave detector (585) is mounted on the front and rear sides of the side mounting plate (584) by bolts; a signal receiver (586), wherein the front end and the rear end of the electric wave detector (585) are respectively inserted and fixed with the signal receiver (586); wherein, the signal transmitter (583), the electric wave detector (585) and the signal receiver (586) are all electrically connected with the control panel (6).

6. The mobile base station according to claim 5, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the outer side surfaces of the left side and the right side of the side mounting plate (584) are respectively provided with a wave absorbing material with a wave absorbing effect, and the left end and the right end of the protective shell (581) are respectively provided with two groups of side mounting plates (584), a radio wave detector (585) and a signal receiver (586).

7. The mobile base station according to claim 5, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the spreading component (582) includes:

a control main board (5821), wherein the control main board (5821) is fixed on the left wall of the protective shell (581) through bolts;

a signal input source (5822), wherein the signal input source (5822) is fixed on the bottom side soldering tin at the right end of the control main board (5821);

the carrier module (5823) is fixed on the bottom side solder of the right end of the control main board (5821) and plays a role of a carrier (5823); the middle side of the right end of the control main board (5821) is fixedly provided with a frequency division module (5824) which plays a role in controlling frequency division; the top side of the frequency division module (5824) is fixedly provided with the shift register (5825) through a connecting tin bar; and the code generator (5826) is fixed at the right end of the control main board (5821) by soldering tin.

8. The mobile base station according to claim 5, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the spreading component (582) further comprises: the top of the code generator (5826) is fixedly provided with the spread spectrum modulation module (5827) through a connecting tin bar; the time delay controller (5828) is fixed on the top side tin solder of the right end of the control main board (5821); the signal output module (5829) is fixed on the top side tin solder of the right end of the control main board (5821); wherein the control main board (5821) is electrically connected with the control panel (6).

9. The mobile base station according to claim 7, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the bottom of the signal input source (5822) is fixedly connected with an internal controller of the base station main box (3) through a signal cable, and a signal transmitter (583) is fixedly connected with the top side of the signal output module (5829) in a plugging manner.

10. The mobile base station according to claim 5, wherein the mobile base station is based on the LaRa transmission technology, and further comprising: the signal transmitter (583) and the signal receiver (586) are distributed in a right angle and included angle, and the control main board (5821) and the electric wave detector (585) are connected in series in a circuit.

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