CN210270171U - A solar power supply device for RTK base station - Google Patents

Abstract

The utility model relates to a solar power supply unit for RTK basic station, including fixing at subaerial toughened glass protection casing (1), setting up solar panel (2) at toughened glass protection casing (1) surface to and arrange storage battery (9) and solar controller (8) in toughened glass protection casing (1), storage battery (9) and solar panel (2) all are connected with solar controller (8). Compared with the prior art, the utility model adopts solar energy as a power supply, can continuously and stably supply power, and solves the problem of power supply of base stations in areas without power such as western regions and other areas with difficult power supply; the toughened glass is used as the material of the protective cover, so that high-strength external impact can be effectively avoided, and special personnel is not needed; the splicing part of the toughened glass is bonded by glass cement, and the whole protective cover is fixed in concrete, so that the dustproof and waterproof effect is excellent.

Description

Solar power supply device for RTK base station

Technical Field

The utility model relates to a base station power supply unit especially relates to a solar energy power supply unit for RTK basic station.

Background

The RTK technology is short for GPS real-time carrier phase difference. The method is a service which combines GPS and data transmission technology, carries out real-time calculation for data processing and obtains high-precision position information within 1-2 s.

The RTK system reference station comprises a reference station receiver, a satellite receiving antenna, a radio data link radio station, a transmitting antenna, a direct current power supply and the like. The function of the method is to obtain the real-time phase difference correction value of the GPS. And then the correction value is transmitted to the mobile station through the data transmission radio station in time so as to refine the GPS observation value of the mobile station and obtain the more accurate real-time position of the mobile station after differential correction.

At present, in order to ensure the transmitting distance, an RTK base station is generally erected in a mode of externally hanging a radio station on a base station, and the transmitting power of a radio data link radio station is high, so that the power consumption is large. When the outdoor mobile terminal works in the field for a long time, charging is inconvenient, and when the electric quantity of the external storage battery is exhausted, the base station cannot work continuously and stably. In order to avoid natural and artificial damage, after the base station is erected, a person needs to watch the base station, and human resources are wasted.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a solar energy power supply unit for RTK base station in order to overcome the defect that above-mentioned prior art exists.

The purpose of the utility model can be realized through the following technical scheme:

the utility model provides a solar power supply unit for RTK basic station, is including fixing the toughened glass protection casing that covers in the RTK basic station subaerial, setting up the solar panel at toughened glass protection casing surface to and arrange storage battery and the solar control ware in the toughened glass protection casing, storage battery and solar panel all are connected with the solar control ware, solar panel is storage battery and RTK basic station power supply

Furthermore, the thickness of toughened glass protection casing is 8mm, the toughened glass protection casing is formed by 5 pieces of 8mm thick toughened glass concatenation, and the gap is glued with the glass.

Furthermore, a GNSS receiver and a radio station are installed in the toughened glass protective cover, and the GNSS receiver and the radio station are connected through a data line.

Furthermore, a tripod is fixed on the ground in the tempered glass protective cover, a base is arranged at the top end of the tripod, the GNSS receiver is installed on the base, and the tripod is buried underground for 300 mm.

Furthermore, transmitting antenna is installed on toughened glass protection casing top, transmitting antenna is connected with the radio station through the cable, transmitting antenna bottom has the spiral head of external screw thread, and is fixed through the internal thread interface that runs through solar panel and toughened glass protection casing.

Furthermore, the GNSS receiver and the radio station are respectively connected with the solar controller through wires.

Further, the output power of the solar panel is 100W.

Furthermore, the toughened glass protection casing is prismoid, solar panel installs the top and the both sides of toughened glass protection casing.

Furthermore, the solar panel is fixed on the surface of the toughened glass protective cover through a clamping groove.

When illumination is sufficient, the solar panel charges the storage battery to supply power to the GNSS receiver and the radio station, and when the illumination is insufficient, the storage battery supplies power to the GNSS receiver and the radio station.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. solar energy is used as a power supply, power can be continuously and stably supplied, and the problem of power supply of base stations in areas without power or other areas with difficult power supply such as the west and the like is solved;

2. the toughened glass is used as the material of the protective cover, so that high-strength external impact can be effectively avoided, and special personnel is not needed;

3. the splicing part of the toughened glass is bonded by glass cement, and the whole protective cover is fixed in concrete, so that the dustproof and waterproof effect is excellent.

Drawings

Fig. 1 is a front view of the present invention;

fig. 2 is a left side view of the present invention.

The reference numbers in the figures indicate:

1. toughened glass protection casing, 2, solar panel, 3, draw-in groove 4, transmitting antenna, 5, GNSS receiver, 6, base, 7, tripod, 8, solar control ware, 9, storage battery, 10, radio station.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

Examples

A solar power and mounting apparatus for an RTK base station, comprising: toughened glass protection casing 1, solar panel 2, draw-in groove 3, transmitting antenna 4, GNSS receiver 5, base 6, tripod 7, solar control ware 8, storage battery 9, radio station 10.

The toughened glass protective cover 1 is in a prismoid shape and is formed by splicing 5 pieces of toughened glass with the thickness of 8mm, and the gaps are bonded by glass cement; the toughened glass protective cover 1 is buried about 100mm underground and integrally poured in concrete. On toughened glass protection casing 1, the left side is fixed with 3 solar panel 2 through draw-in groove 3 with the right side, and solar panel 2's output is 100W. Transmitting antenna 4 is installed on the top of toughened glass protection casing 1, and transmitting antenna 4 bottom has the spiral head of external screw thread, fixes in toughened glass protection casing 1 top one side through the internal thread interface that runs through solar panel 2 and toughened glass protection casing 1. Set up GNSS receiver 5 in toughened glass protection casing 1, GNSS receiver 5 installs on base 6, and tripod 7 buries about underground 300mm, and is fixed with concrete placement, and solar control 8 installs at 1 inside left concrete subaerially of toughened glass protection casing, and storage battery 9 is subaerial between solar control 8 and tripod 7, and radio station 10 is located the subaerial on tripod 7 right side. Storage battery 9, solar panel 2, GNSS receiver 5 and radio station 10 are connected with solar control ware 8 through the wire respectively, and GNSS receiver 5 and radio station 10 pass through the data line and link to each other, and radio station 10 passes through cable junction with transmitting antenna 4.

When illumination is sufficient, the solar panel 2 charges the storage battery 9 to supply power to the GNSS receiver 5 and the radio station 10, and when the illumination is insufficient, the storage battery supplies power to the GNSS receiver 5 and the radio station 10.

Solar energy is used as a power supply, power can be continuously and stably supplied, and the problem of power supply of base stations in areas without power or other areas with difficult power supply such as the west and the like is solved; the toughened glass is used as the material of the protective cover, so that high-strength external impact can be effectively avoided, and special personnel is not needed; the splicing part of the toughened glass is bonded by glass cement, and the whole protective cover is fixed in concrete, so that the dustproof and waterproof effect is excellent.

The embodiments described above are intended to facilitate the understanding and use of the invention by those skilled in the art. It will be readily apparent to those skilled in the art that various modifications to these embodiments may be made, and the generic principles described herein may be applied to other embodiments without the use of the inventive faculty. Therefore, the present invention is not limited to the above embodiments, and those skilled in the art should make improvements and modifications within the scope of the present invention according to the disclosure of the present invention.

Claims (9)

1. A solar power supply device for an RTK base station, characterized in that it comprises a tempered glass protective cover (1) fixed on the ground and covered outside the RTK base station, a solar panel arranged on the outer surface of the tempered glass protective cover (1) (2), and a battery (9) and a solar controller (8) arranged in the tempered glass protective cover (1), the battery (9) and the solar panel (2) are both connected to the solar controller (8) , the solar panel (2) supplies power to the battery (9) and the RTK base station. 2 . The solar power supply device for RTK base stations according to claim 1 , wherein the thickness of the tempered glass protective cover ( 1 ) is 8 mm. 3 . 3 . The solar power supply device for RTK base station according to claim 1 , wherein, a GNSS receiver ( 5 ) and a radio station ( 10 ) are installed in the tempered glass protective cover ( 1 ). 4 . 4. A solar power supply device for RTK base station according to claim 3, characterized in that, a tripod (7) is fixed on the ground in the tempered glass protective cover (1), and the tripod (7) The top end is provided with a base (6), and the GNSS receiver (5) is mounted on the base (6). 5. A solar power supply device for an RTK base station according to claim 3, wherein a transmitting antenna (4) is installed on the top of the tempered glass protective cover (1), and the transmitting antenna (4) passes through the The cable is connected to the radio (10). 6. A solar power supply device for RTK base stations according to claim 3, characterized in that the GNSS receiver (5) and the radio station (10) are respectively connected to the solar controller (8) through wires. 7 . The solar power supply device for RTK base station according to claim 1 , wherein the output power of the solar panel ( 2 ) is 100W. 8 . 8 . The solar power supply device for RTK base station according to claim 1 , wherein the tempered glass protective cover ( 1 ) is in the shape of a prism, and the solar panel ( 2 ) is installed on the tempered glass. 9 . Top and sides of the protective cover (1). 9 . The solar power supply device for RTK base station according to claim 1 , wherein the solar panel ( 2 ) is fixed on the surface of the tempered glass protective cover ( 1 ) through a card slot ( 3 ). 10 .

Images