CN115218097A - Remote meteorological data acquisition and transmission method and system - Google Patents

Abstract

The invention relates to the technical field of meteorological data acquisition and transmission, in particular to a meteorological data remote acquisition and transmission method and a system, wherein the meteorological data remote acquisition and transmission system comprises an acquisition camera and an adjusting device, and the adjusting device comprises an installation base, a first motor, a screw rod, a sliding block, a lifting assembly and a rotating assembly; gather the camera and be used for gathering external meteorological environment and pass through wireless network transmission path with data upload to the high in the clouds, the installation base is used for installing and fixes on the plane, the first motor of control rotates and makes the lead screw rotate, the lead screw rotates and drives slider shift position, thereby adjust the transverse position who gathers the camera, lifting unit is used for adjusting the upper and lower position height of gathering the camera, rotating unit is used for rotating the field of vision angle of gathering the camera, thereby it is more convenient when gathering the camera to make adjusting.

Description

Remote meteorological data acquisition and transmission method and system

Technical Field

The invention relates to the technical field of meteorological data acquisition and transmission, in particular to a meteorological data remote acquisition and transmission method and system.

Background

According to the meteorological data remote acquisition and transmission method and system, the data acquisition camera is fixedly arranged outdoors, records the surrounding environment condition, uploads the data to the cloud end through the wireless transmission channel, and then receives the data through other electronic equipment.

However, the existing data acquisition camera is fixedly arranged outdoors, and the position angle of the acquisition camera cannot be adjusted according to needs, so that the setting of the position of the acquisition camera is not convenient enough.

Disclosure of Invention

The invention aims to provide a meteorological data remote acquisition and transmission method and a meteorological data remote acquisition and transmission system, and aims to solve the problem that the existing meteorological data remote acquisition and transmission method and system are inconvenient to set the position of an acquisition camera because the data acquisition camera is fixedly arranged outdoors and the position angle of the acquisition camera cannot be adjusted according to needs.

In order to achieve the above object, in a first aspect, the present invention provides a meteorological data remote acquisition and transmission system, which includes an acquisition camera and an adjustment device

The adjusting device comprises an installation base, a first motor, a screw rod, a sliding block, a lifting assembly and a rotating assembly;

the first motor is fixedly connected with the mounting base and is positioned on one side of the mounting base; the screw rod is fixedly connected with the output end of the first motor; and is positioned at one side of the first motor; the sliding block is in threaded connection with the screw rod and is positioned on one side of the screw rod; the lifting assembly is arranged on one side of the sliding block; the rotating assembly is arranged between the lifting assembly and the collecting camera.

Wherein, meteorological data remote acquisition transmission system still includes temperature sensor, temperature sensor set up in gather the camera side.

The lifting assembly comprises a sleeve, a second motor, a first gear, a screw, a second gear and a lifting rod, wherein the sleeve is fixedly connected with the sliding block and is positioned on one side of the sliding block; the second motor is fixedly connected with the sleeve and is positioned in the sleeve; the first gear is fixedly connected with the output end of the second motor and is positioned on one side of the second motor; the screw rod is rotationally connected with the sleeve and is positioned on one side of the sleeve; the second gear is fixedly connected with the screw and meshed with the first gear; the lifting rod is in threaded connection with the screw rod, is in sliding connection with the sleeve, is fixedly connected with the rotating assembly and is positioned on one side of the screw rod.

The rotating assembly comprises a supporting seat, a third motor and a turntable, and the supporting seat is fixedly connected with the lifting rod and is positioned on one side of the lifting rod; the third motor is fixedly connected with the supporting seat and is positioned on one side of the supporting seat; the turntable is fixedly connected with the output end of the third motor and is fixedly connected with the acquisition camera; and is located at one side of the third motor.

The meteorological data remote acquisition and transmission system further comprises a cooling assembly, and the cooling assembly is arranged on one side of the acquisition camera.

The cooling assembly comprises a radiating shell, a radiating copper sheet and a radiating fan, the radiating shell is fixedly connected with the acquisition camera and is positioned on one side of the acquisition camera, the radiating shell is provided with an air inlet, and the air inlet is positioned on the side edge of the radiating shell; the heat dissipation copper sheet is fixedly connected with the acquisition camera and is positioned inside the heat dissipation shell; the heat radiation fan is fixedly connected with the heat radiation shell and is positioned on one side of the heat radiation shell.

The cooling assembly further comprises heat dissipation fins, a support rod and a sun shield, wherein the heat dissipation fins are fixedly connected with the heat dissipation copper sheet and are positioned on one side of the heat dissipation copper sheet; the support rod is fixedly connected with the heat dissipation shell and is positioned on one side of the heat dissipation shell; the sun shield is fixedly connected with the support rod and is positioned on one side of the support rod, which is far away from the heat dissipation shell.

In a second aspect, the present invention further provides a method for remotely acquiring and transmitting meteorological data, including:

controlling a first motor to drive a screw rod to start rotating, driving a sliding block to move, and adjusting the transverse position of the acquisition camera;

a second motor is controlled to drive a first gear to rotate, a second gear is driven to rotate, and a screw is driven to rotate, so that a lifting rod moves up and down to adjust the vertical height of the acquisition camera;

controlling a third motor to drive the turntable to rotate, and rotating the acquisition camera to adjust the view angle of the acquisition camera;

gather the camera rigidity back, gather the camera and pass through wireless network transmission channel with the meteorological data of external environment after with the meteorological data acquisition of external environment and upload to the high in the clouds and collect.

According to the meteorological data remote acquisition and transmission system, the acquisition camera is used for acquiring an external meteorological environment and uploading data to a cloud end through a wireless network transmission channel, the mounting base is used for being mounted on a plane for fixing, the first motor is controlled to rotate so that the screw rod rotates, the screw rod rotates to drive the sliding block to move, the transverse position of the acquisition camera is adjusted, the lifting assembly is used for adjusting the height of the upper position and the lower position of the acquisition camera, and the rotating assembly is used for rotating the view angle of the acquisition camera, so that the adjustment of the acquisition camera is more convenient.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

FIG. 1 is an overall cutaway view of a first embodiment of a meteorological data remote acquisition and transmission system of the present invention.

FIG. 2 is a cutaway view of the entirety of a second embodiment of a meteorological data remote acquisition and transmission system of the present invention.

FIG. 3 is a flow chart of a method for remotely acquiring and transmitting meteorological data in accordance with the present invention.

101-acquisition camera, 102-installation base, 103-first motor, 104-screw rod, 105-sliding block, 106-lifting component, 107-rotating component, 108-temperature sensor, 109-sleeve, 110-second motor, 111-first gear, 112-screw rod, 113-second gear, 114-lifting rod, 115-supporting seat, 116-third motor, 117-rotating disk, 118-moving structure, 119-supporting component, 120-first rod, 121-second rod, 122-first spring, 123-universal wheel, 124-first cylinder, 125-supporting plate, 201-cooling component, 202-cooling shell, 203-cooling copper sheet, 204-cooling fan, 205-cooling fin, 206-supporting rod, 207-sun shield and 208-air inlet.

Detailed Description

In a first aspect, the present invention provides a remote meteorological data acquisition and transmission system, a first embodiment of the remote meteorological data acquisition and transmission system of the present application is:

referring to fig. 1, in which, fig. 1 is an overall cross-sectional view of a first embodiment of a meteorological data remote acquisition and transmission system of the present invention, the meteorological data remote acquisition and transmission system of the present invention includes an acquisition camera 101, an adjusting device and a temperature sensor 108, the adjusting device includes a mounting base 102, a first motor 103, a lead screw 104, a slider 105, a lifting assembly 106 and a rotating assembly 107, the lifting assembly 106 includes a sleeve 109, a second motor 110, a first gear 111, a screw 112, a second gear 113 and a lifting rod 114, and the rotating assembly 107 includes a supporting seat 115, a third motor 116 and a turntable 117.

To this specific embodiment, the collection camera 101 is used for collecting external meteorological environment and uploading data to a cloud end through a wireless network transmission channel.

The first motor 103 is fixedly connected with the mounting base 102 and is located on one side of the mounting base 102; the screw rod 104 is fixedly connected with the output end of the first motor 103; and is positioned at one side of the first motor 103; the sliding block 105 is in threaded connection with the screw rod 104 and is positioned on one side of the screw rod 104; the lifting assembly 106 is arranged on one side of the sliding block 105; the rotating assembly 107 set up in lifting assembly 106 with gather between the camera 101, installation base 102 is used for installing and fixes on the plane, control first motor 103 rotates and makes lead screw 104 rotates, lead screw 104 rotates and drives slider 105 shift position, thereby adjusts gather camera 101's transverse position, lifting assembly 106 is used for adjusting gather camera 101's upper and lower position height, rotating assembly 107 is used for rotating gather camera 101's field of vision angle.

Secondly, temperature sensor 108 set up in gather camera 101 side, temperature sensor 108 is used for receiving the temperature variation transmission of external climate and gives gather the inside wireless network transmission channel of camera 101.

Thirdly, the sleeve 109 is fixedly connected with the sliding block 105 and is positioned on one side of the sliding block 105; the second motor 110 is fixedly connected with the sleeve 109 and is located inside the sleeve 109; the first gear 111 is fixedly connected with the output end of the second motor 110 and is positioned on one side of the second motor 110; the screw 112 is rotatably connected with the sleeve 109 and is positioned on one side of the sleeve 109; the second gear 113 is fixedly connected with the screw rod 112 and is meshed with the first gear 111; lifter 114 with screw rod 112 threaded connection, and with sleeve 109 sliding connection, and with runner assembly 107 fixed connection, and be located screw rod 112 one side, sleeve 109 is used for supporting second motor 110 rotates, second motor 110 rotates and drives first gear 111 rotates, first gear 111 rotates and drives second gear 113 rotates, second gear 113 rotates and drives screw rod 112 is in sleeve 109 internal rotation, thereby drives lifter 114 reciprocates and adjusts the position height of gathering camera 101

In addition, the supporting seat 115 is fixedly connected with the lifting rod 114 and is positioned on one side of the lifting rod 114; the third motor 116 is fixedly connected with the support seat 115 and is positioned on one side of the support seat 115; the turntable 117 is fixedly connected with the output end of the third motor 116 and is fixedly connected with the acquisition camera 101; and is located third motor 116 one side, third motor 116 rotates in supporting seat 115, third motor 116 control carousel 117 rotates and is used for adjusting the field of view angle of gathering camera 101.

Furthermore, the adjusting device further comprises a plurality of moving structures 118 and a supporting part 119, wherein the plurality of moving structures 118 are respectively located at one side of the mounting base 102; the moving structure 118 includes a first rod 120, a second rod 121, a first spring 122 and a universal wheel 123, wherein the first rod 120 is fixedly connected to the mounting base 102 and is located on one side of the mounting base 102; the second rod 121 is slidably connected with the first rod 120 and is positioned on one side of the first rod 120; the first spring 122 is fixedly connected to the first rod 120 and the second rod 121, and is located between the first rod 120 and the second rod 121; the universal wheel 123 is rotatably connected with the second rod 121 and is positioned on one side of the second rod 121 far away from the first rod 120; the supporting component 119 is disposed on one side of the mounting base 102, the first rod 120 is used for supporting the second rod 121, and the second rod is matched with the first spring 122 to provide a movement buffering effect, the universal wheel 123 is used for moving the position of the collecting camera 101, and the supporting component 119 is used for fixing the position after moving to a proper position, so that the position of the collecting camera 101 is more convenient to move.

Finally, the supporting member 119 comprises a first cylinder 124 and a supporting plate 125, wherein the first cylinder 124 is fixedly connected with the mounting base 102 and is positioned on one side of the mounting base 102; the supporting plate 125 is fixedly connected to the output end of the first cylinder 124, is located at one side of the first cylinder 124, and controls the first cylinder 124 to move downward after moving to a proper position, so that the supporting plate 125 moves downward to jack up the mounting base 102, thereby fixing the position of the capturing camera 101.

In the system for remotely acquiring and transmitting meteorological data according to this embodiment, the acquisition camera 101 is configured to acquire external meteorological environment and upload data to a cloud end through a wireless network transmission channel, the temperature sensor 108 is configured to receive temperature change of the external climate and transmit the temperature change to the wireless network transmission channel inside the acquisition camera 101, the first rod 120 is configured to support the second rod 121 in cooperation with the first spring 122 to provide a movement buffering effect, the universal wheel 123 is configured to move the position of the acquisition camera 101, and after moving to a proper position, the first cylinder 124 moves downward to enable the supporting plate 125 to move downward, so as to jack up the installation base 102, thereby completing the position fixing of the acquisition camera 101, and after completing the position fixing, the first motor 103 is controlled to rotate in the installation base 102 so that the lead screw 104 rotates, the lead screw 104 rotates to drive the sliding block 105 to move, thereby adjusting the transverse position of the acquisition camera 101, the sleeve 109 is configured to support the second motor 110 to rotate, the second motor 110 rotates to drive the first gear 111 to rotate, the first gear 111 rotates to drive the second gear 113, the second gear 113 rotates to drive the second gear 113 to rotate, the second gear 113 rotates to adjust the lifting control motor 116 to rotate in the lifting control the lifting and the lifting control of the acquisition camera 101, thereby adjusting the lifting control the lifting and adjusting the lifting control the third lifting and adjusting screw 116 to rotate in the vertical movement of the acquisition camera 101, thereby adjusting the lifting and adjusting the lifting control of the lifting and adjusting motor 116 to rotate the lifting and adjusting screw 116 to adjust the lifting and adjusting of the lifting and adjusting screw 116.

The second embodiment of a meteorological data remote acquisition and transmission system of the present application is:

referring to fig. 2, wherein fig. 2 is a sectional view of an entirety of a meteorological data remote acquisition and transmission system according to a second embodiment of the present invention, based on the first embodiment, the meteorological data remote acquisition and transmission system of the present embodiment further includes a cooling component 201, and the cooling component 201 includes a heat dissipation shell 202, a heat dissipation copper sheet 203, a heat dissipation fan 204, a heat dissipation fin 205, a support rod 206, and a sun visor 207.

To this embodiment, the cooling component 201 set up in gather camera 101 one side, the cooling component 201 is used for reducing gather camera 101's temperature prevents gather camera 101 takes place to damage because of high temperature in long-time the use.

The heat dissipation shell 202 is fixedly connected with the acquisition camera 101 and is located on one side of the acquisition camera 101, the heat dissipation shell 202 is provided with an air inlet 208, and the air inlet 208 is located on the side edge of the heat dissipation shell 202; the heat dissipation copper sheet 203 is fixedly connected with the acquisition camera 101 and is positioned inside the heat dissipation shell 202; the heat dissipation fan 204 is fixedly connected with the heat dissipation shell 202 and located on one side of the heat dissipation shell 202, the heat dissipation shell 202 is used for covering the heating end of the acquisition camera 101, the heat dissipation copper sheet 203 is used for covering the surface of the heating end of the acquisition camera 101 and is used for quickly absorbing heat and transmitting the heat to the outside, the temperature inside the heat dissipation shell 202 is discharged through the heat dissipation fan 204 to achieve the effect of reducing the temperature of the acquisition camera 101, and the air inlet 208 is used for carrying out air interaction.

Secondly, the heat dissipation fins 205 are fixedly connected with the heat dissipation copper sheet 203 and are positioned on one side of the heat dissipation copper sheet 203; the support rod 206 is fixedly connected with the heat dissipation shell 202 and is located on one side of the heat dissipation shell 202; the sun shield 207 is fixedly connected with the support rod 206 and is located on one side of the support rod 206, which is far away from the heat dissipation shell 202, the heat dissipation fins 205 are provided with a plurality of heat dissipation fin grooves for rapidly dispersing heat, so that the cooling effect of the heat dissipation fan 204 is enhanced, the support rod 206 is installed on one side of the heat dissipation shell 202 and is used for supporting the sun shield 207, and the sun shield 207 is used for resisting the external sun to prevent the heating end of the acquisition camera 101 from being exposed to the sun, so as to reduce the temperature of the heating end of the acquisition camera 101.

In the system for remotely acquiring and transmitting meteorological data in this embodiment, the heat dissipation shell 202 is used for covering the heating end of the acquisition camera 101, the heat dissipation copper sheets 203 are used for covering the surface of the heating end of the acquisition camera 101 and are used for rapidly absorbing heat and transmitting the heat to the outside through the heat dissipation fan 204, the temperature inside the heat dissipation shell 202 is discharged to reduce the temperature of the acquisition camera 101, the air inlet 208 is used for carrying out gas interaction, the heat dissipation fins 205 are provided with a plurality of heat dissipation fin grooves and used for rapidly dispersing the heat, so that the cooling effect of the heat dissipation fan 204 is enhanced, the support rod 206 is installed on one side of the heat dissipation shell 202 and is used for supporting the sun shield 207, the sun shield 207 is used for resisting the external sun to prevent the heating end of the acquisition camera 101 from being exposed to the sun, the temperature of the acquisition camera 101 is reduced, and the acquisition camera 101 is prevented from being damaged due to high temperature after being used for a long time.

In a second aspect, the present invention further provides a method for remotely acquiring and transmitting meteorological data, please refer to fig. 3, fig. 3 is a flowchart of a method for remotely acquiring and transmitting meteorological data according to the present invention, the method for remotely acquiring and transmitting meteorological data includes:

s1, controlling a first motor 103 to drive a screw rod 104 to start rotating, driving a sliding block 105 to move, and adjusting the transverse position of a collecting camera 101;

the mounting base 102 is used for being mounted on a plane for fixing, the first motor 103 is controlled to rotate, so that the screw rod 104 rotates, the screw rod 104 rotates to drive the sliding block 105 to move, and therefore the transverse position of the collecting camera 101 is adjusted.

S2, controlling a second motor 110 to drive a first gear 111 to rotate, driving a second gear 113 to rotate, and driving a screw rod 112 to rotate, so that a lifting rod 114 moves up and down to adjust the up-and-down height of the acquisition camera 101;

the sleeve 109 is used for supporting the second motor 110 to rotate, the second motor 110 rotates to drive the first gear 111 to rotate, the first gear 111 rotates to drive the second gear 113 to rotate, and the second gear 113 rotates to drive the screw rod 112 to rotate in the sleeve 109, so that the lifting rod 114 is driven to move up and down to adjust the position height of the acquisition camera 101.

S3, controlling the third motor 116 to drive the turntable 117 to rotate, and adjusting the view angle of the acquisition camera 101 by the acquisition camera 101;

the third motor 116 rotates in the supporting seat 115, and the third motor 116 controls the turntable 117 to rotate so as to adjust the view angle of the collecting camera 101.

S4, after the position of the acquisition camera 101 is fixed, the acquisition camera 101 acquires meteorological data of the external environment and uploads the meteorological environment data to a cloud end for collection through a wireless network transmission channel;

the acquisition camera 101 is used for acquiring external meteorological environment and uploading data to a cloud terminal through a wireless network transmission channel.

While the above disclosure describes one or more preferred embodiments of the present invention, it is not intended to limit the scope of the claims to such embodiments, and one skilled in the art will understand that all or a portion of the processes performed in the above embodiments may be practiced without departing from the spirit and scope of the claims.

Claims (8)

1. A meteorological data remote acquisition and transmission system comprises an acquisition camera and is characterized in that,

also comprises an adjusting device which is used for adjusting the position of the movable support,

the adjusting device comprises an installation base, a first motor, a screw rod, a sliding block, a lifting assembly and a rotating assembly;

the first motor is fixedly connected with the mounting base and is positioned on one side of the mounting base; the screw rod is fixedly connected with the output end of the first motor; and is positioned at one side of the first motor; the sliding block is in threaded connection with the screw rod and is positioned on one side of the screw rod; the lifting assembly is arranged on one side of the sliding block; the rotating assembly is arranged between the lifting assembly and the collecting camera.

2. The remote meteorological data collection and transmission system of claim 1,

the meteorological data remote acquisition and transmission system further comprises a temperature sensor, and the temperature sensor is arranged on the side edge of the acquisition camera.

3. The remote meteorological data collection and transmission system of claim 1,

the lifting assembly comprises a sleeve, a second motor, a first gear, a screw, a second gear and a lifting rod, and the sleeve is fixedly connected with the sliding block and is positioned on one side of the sliding block; the second motor is fixedly connected with the sleeve and is positioned in the sleeve; the first gear is fixedly connected with the output end of the second motor and is positioned on one side of the second motor; the screw rod is rotationally connected with the sleeve and is positioned on one side of the sleeve; the second gear is fixedly connected with the screw rod and meshed with the first gear; the lifting rod is in threaded connection with the screw rod, is in sliding connection with the sleeve, is fixedly connected with the rotating assembly and is positioned on one side of the screw rod.

4. The meteorological data remote acquisition and transmission system of claim 3,

the rotating assembly comprises a supporting seat, a third motor and a turntable, and the supporting seat is fixedly connected with the lifting rod and is positioned on one side of the lifting rod; the third motor is fixedly connected with the supporting seat and is positioned on one side of the supporting seat; the turntable is fixedly connected with the output end of the third motor and is fixedly connected with the acquisition camera; and is located at one side of the third motor.

5. The remote meteorological data collection and transmission system of claim 1,

the remote meteorological data acquisition and transmission system further comprises a cooling assembly, wherein the cooling assembly is arranged on one side of the acquisition camera.

6. The meteorological data remote acquisition and transmission system of claim 5,

the cooling assembly comprises a radiating shell, a radiating copper sheet and a radiating fan, the radiating shell is fixedly connected with the acquisition camera and is positioned on one side of the acquisition camera, the radiating shell is provided with an air inlet, and the air inlet is positioned on the side edge of the radiating shell; the heat dissipation copper sheet is fixedly connected with the acquisition camera and is positioned in the heat dissipation shell; the heat dissipation fan is fixedly connected with the heat dissipation shell and is positioned on one side of the heat dissipation shell.

7. The meteorological data remote acquisition and transmission system of claim 6,

the cooling assembly further comprises heat dissipation fins, a support rod and a sun shield, and the heat dissipation fins are fixedly connected with the heat dissipation copper sheet and are positioned on one side of the heat dissipation copper sheet; the support rod is fixedly connected with the heat dissipation shell and is positioned on one side of the heat dissipation shell; the sun shield is fixedly connected with the supporting rod and is positioned on one side, far away from the heat dissipation shell, of the supporting rod.

8. A remote meteorological data acquisition and transmission method applied to the remote meteorological data acquisition and transmission system of any one of claims 1 to 7, comprising:

controlling a first motor to drive a screw rod to start rotating, driving a sliding block to move, and adjusting the transverse position of the acquisition camera;

a second motor is controlled to drive a first gear to rotate, a second gear is driven to rotate, and a screw is driven to rotate, so that a lifting rod moves up and down to adjust the vertical height of the acquisition camera;

controlling a third motor to drive the turntable to rotate, and rotating the acquisition camera to adjust the view angle of the acquisition camera;

gather the camera rigidity back, gather the camera and pass through wireless network transmission channel with the meteorological data of external environment after with the meteorological data acquisition of external environment and upload to the high in the clouds and collect.

Images