CN203645600U - Wind and solar complementation power supply system used for high mountain monitoring station - Google Patents

Abstract

The utility model relates to a wind and solar complementation power supply system used for a high mountain monitoring station. The system comprises a power generating apparatus, a charging control apparatus, an electric energy storage apparatus and an inversion control apparatus. The power generating apparatus is formed by a solar cell and a wind driven generator. The charging control apparatus is formed by a solar charging controller and a wind driven generator charging controller. The electric energy storage apparatus is formed by a storage battery. The inversion control apparatus is formed by a main inverter, a standby inverter and a main/standby inverter conversion control device. A combination of the solar cell and the wind driven generator is used to provide power for a monitoring station. A monitoring station site can be flexibly selected, a monitoring network structure can be fully optimized, a single station monitoring cover scope is enlarged, monitoring network overall performance is increased and the number of network sites are reduced. The system is clean, environmental-protection, safe and reliable and also is energy with low cost.

Description

A kind of electric power system for high mountain monitoring station wind light mutual complementing

Technical field

The utility model relates to a kind of electric power system for high mountain monitoring station wind light mutual complementing, and this system can provide electric power for the equipment that install in the areas such as high mountain, belongs to solar energy, wind energy complementary applied technical field.

Background technology

Because City's Construction And Development speed is very fast, along with the rise of radio guard periphery high building, the usefulness of the city high rise building monitoring station of originally building up weakens the function that has even lost monitoring.For this reason, in the time that monitoring net is planned, ordinary priority selects high mountain as site, radio guard.Build radio guard at high mountain and need to solve the problem of power supply, the supply power mode of known radio guard is to adopt electric main, it need to set up aerial open-wire line, the long-period cost producing is as the electricity charge, the risings such as place rent, back-up source storage battery is by interruption duration configuration capacity, and the expense that infrastructure cost comprises electric power system raises.Due near high-power emission source, do with signal and lose authenticity mutually, also often there is the situation of power breakdown and communication disruption.Adopt the solar wind-energy power supply of natural environmental-protective, for the builders of current high mountain radio guard provide a kind of clean environment firendly, safe and reliable, cheap energy supply again.

Summary of the invention

The purpose of this utility model is to provide a kind of electric power system for high mountain monitoring station wind light mutual complementing, and it comprises Blast Furnace Top Gas Recovery Turbine Unit (TRT), battery charge controller, apparatus for storing electrical energy, inversion control device.Blast Furnace Top Gas Recovery Turbine Unit (TRT) is made up of solar cell and wind-driven generator, battery charge controller is made up of solar charging controller and charge controller of wind turbine generator, apparatus for storing electrical energy is made up of storage battery, and inversion control device is made up of main inverter, inverter for subsequent use and active and standby inverter conversion control device.Adopt solar cell and combination of wind-driven generator that the supply power mode of monitoring station is provided, can select flexibly site, monitoring station, fully optimization monitoring network configuration, expands single station monitoring coverage, improves monitoring net overall efficiency, reduces website quantity.Itself or a kind of clean environment firendly, safe and reliable, the cheap energy again.

The utility model is done in such a manner, and it comprises Blast Furnace Top Gas Recovery Turbine Unit (TRT) 1, battery charge controller 2, energy storage device 3, inversion control device 4.Blast Furnace Top Gas Recovery Turbine Unit (TRT) 1 produces electric energy, and battery charge controller 2 is responsible for the electric energy producing to be stored in 3 li of apparatus for storing electrical energy, and inversion control device 4 is responsible for the electric energy of 3 li of apparatus for storing electrical energy to be converted to and to be suitable for the required electric pressure of radio monitoring equipment.

Fig. 2 is circuit connection diagram of the present utility model, the Blast Furnace Top Gas Recovery Turbine Unit (TRT) 1 of 1300W solar cell, 600W wind-driven generator, 2000W wind-driven generator composition whole system, the battery charge controller 2 of solar charging controller, 600W wind driven generator controller, 2000W wind driven generator controller composition whole system, 48V batteries has formed the apparatus for storing electrical energy 3 of system, and main inverter, inverter for subsequent use, active and standby inverter switching controller have formed the inversion control device 4 of system.The anodal SV+ of 1300W solar cell, negative pole SV-respectively with the electrode input end PV+ of solar charging controller, negative input PV-is connected, the three-phase alternating current terminal U1 of 600W wind-driven generator, V1, W1 respectively with the three-phase alternating current input terminal WU1 of 600W wind driven generator controller, WV1, WW1 is connected, the three-phase alternating current terminal U2 of 2000W wind-driven generator, V2, W2 respectively with the three-phase alternating current input terminal WU2 of 2000W wind driven generator controller, WV2, WW2 is connected, the cathode output end PB+ of solar charging controller, cathode output end PB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the cathode output end WB1+ of 600W wind driven generator controller, cathode output end WB1-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the cathode output end WB2+ of 2000W wind driven generator controller, cathode output end WB2-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the electrode input end MB+ of main inverter, negative input MB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the electrode input end SB+ of inverter for subsequent use, negative input SB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the live wire output ML of main inverter, zero line output MN respectively with first group of live wire input InL1 of active and standby inverter switching controller, first group of zero line input InN1 is connected, the live wire output SL of inverter for subsequent use, zero line output SN respectively with second group of live wire input InL2 of active and standby inverter switching controller, second group of zero line input InN2 is connected, the live wire L of main inverter switching controller and zero line N access monitoring equipment.

Operation principle

As shown in Figure 2, the direct current that 300W solar panel produces charges to 48V batteries by solar charging controller; The three-phase alternating current that 600W wind-driven generator and 2000W wind-driven generator produce carries out rectification, step-down through 600W wind driven generator controller and 2000W wind driven generator controller respectively, then 48V batteries is charged, wind driven generator controller can also be wind speed be excessive cause wind-driven generator stall in the situation that, to the wind-driven generator protection of braking; Because batteries provides direct voltage, and the power supply of monitoring equipment is all alternating voltages, the 48V direct voltage of batteries, is converted to 50Hz/220V alternating voltage to adapt to the electric pressure of monitoring equipment by inverter; Complete voltage transitions work by active and standby control device for inverter operation main inverter at ordinary times, in the time that main inverter breaks down, active and standby control device for inverter is switched to inverter for subsequent use, completes voltage transitions work by inverter for subsequent use.

Advantage and good effect

The utility model adopts solar cell and combination of wind-driven generator that the supply power mode of monitoring station is provided, can select flexibly site, monitoring station, fully optimization monitoring network configuration, expands single station monitoring coverage, improve monitoring net overall efficiency, reduce website quantity.Itself or a kind of clean environment firendly, safe and reliable, the cheap energy again.

Brief description of the drawings

Fig. 1 is theory diagram of the present utility model;

In figure, 1 is Blast Furnace Top Gas Recovery Turbine Unit (TRT), the 2nd, and battery charge controller, the 3rd, energy storage device, the 4th, inversion control device.Fig. 2 is circuit structure connection layout of the present utility model.

Embodiment

The utility model comprises Blast Furnace Top Gas Recovery Turbine Unit (TRT) 1, battery charge controller 2, energy storage device 3, inversion control device 4.Blast Furnace Top Gas Recovery Turbine Unit (TRT) 1 produces electric energy, and battery charge controller 2 is responsible for the electric energy producing to be stored in 3 li of apparatus for storing electrical energy, and inversion control device 4 is responsible for the electric energy of 3 li of apparatus for storing electrical energy to be converted to and to be suitable for the required electric pressure of radio monitoring equipment.

Fig. 2 is device connection layout of the present utility model, the Blast Furnace Top Gas Recovery Turbine Unit (TRT) 1 of 1300W solar cell, 600W wind-driven generator, 2000W wind-driven generator composition whole system, the battery charge controller 2 of solar charging controller, 600W wind driven generator controller, 2000W wind driven generator controller composition whole system, 48V batteries has formed the apparatus for storing electrical energy 3 of system, and main inverter, inverter for subsequent use, active and standby inverter switching controller have formed the inversion control device 4 of system.The anodal SV+ of 1300W solar cell, negative pole SV-respectively with the electrode input end PV+ of solar charging controller, negative input PV-is connected, the three-phase alternating current terminal U1 of 600W wind-driven generator, V1, W1 respectively with the three-phase alternating current input terminal WU1 of 600W wind driven generator controller, WV1, WW1 is connected, the three-phase alternating current terminal U2 of 2000W wind-driven generator, V2, W2 respectively with the three-phase alternating current input terminal WU2 of 2000W wind driven generator controller, WV2, WW2 is connected, the cathode output end PB+ of solar charging controller, cathode output end PB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the cathode output end WB1+ of 600W wind driven generator controller, cathode output end WB1-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the cathode output end WB2+ of 2000W wind driven generator controller, cathode output end WB2-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the electrode input end MB+ of main inverter, negative input MB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the electrode input end SB+ of inverter for subsequent use, negative input SB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the live wire output ML of main inverter, zero line output MN respectively with first group of live wire input InL1 of active and standby inverter switching controller, first group of zero line input InN1 is connected, the live wire output SL of inverter for subsequent use, zero line output SN respectively with second group of live wire input InL2 of active and standby inverter switching controller, second group of zero line input InN2 is connected, the live wire L of main inverter switching controller and zero line N access monitoring equipment.

Claims (1)

1. the electric power system for high mountain monitoring station wind light mutual complementing, it is characterized in that: it comprises Blast Furnace Top Gas Recovery Turbine Unit (TRT) (1), battery charge controller (2), energy storage device (3), inversion control device (4), Blast Furnace Top Gas Recovery Turbine Unit (TRT) (1) produces electric energy, it is inner that battery charge controller (2) is responsible for that the electric energy producing is stored in to apparatus for storing electrical energy (3), inversion control device (4) is responsible for the inner electric energy of apparatus for storing electrical energy (3) to be converted to and to be suitable for the required electric pressure of radio monitoring equipment, 1300W solar cell, 600W wind-driven generator, the Blast Furnace Top Gas Recovery Turbine Unit (TRT) (1) of 2000W wind-driven generator composition whole system, solar charging controller, 600W wind driven generator controller, the battery charge controller (2) of 2000W wind driven generator controller composition whole system, 48V batteries has formed the apparatus for storing electrical energy (3) of system, main inverter, inverter for subsequent use, active and standby inverter switching controller has formed the inversion control device (4) of system, the anodal SV+ of 1300W solar cell, negative pole SV-respectively with the electrode input end PV+ of solar charging controller, negative input PV-is connected, the three-phase alternating current terminal U1 of 600W wind-driven generator, V1, W1 respectively with the three-phase alternating current input terminal WU1 of 600W wind driven generator controller, WV1, WW1 is connected, the three-phase alternating current terminal U2 of 2000W wind-driven generator, V2, W2 respectively with the three-phase alternating current input terminal WU2 of 2000W wind driven generator controller, WV2, WW2 is connected, the cathode output end PB+ of solar charging controller, cathode output end PB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the cathode output end WB1+ of 600W wind driven generator controller, cathode output end WB1-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the cathode output end WB2+ of 2000W wind driven generator controller, cathode output end WB2-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the electrode input end MB+ of main inverter, negative input MB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the electrode input end SB+ of inverter for subsequent use, negative input SB-respectively with the anodal Bat+ of 48V batteries, negative pole Bat-is connected, the live wire output ML of main inverter, zero line output MN respectively with first group of live wire input InL1 of active and standby inverter switching controller, first group of zero line input InN1 is connected, the live wire output SL of inverter for subsequent use, zero line output SN respectively with second group of live wire input InL2 of active and standby inverter switching controller, second group of zero line input InN2 is connected, the live wire L of main inverter switching controller and zero line N access monitoring equipment.

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