CN210579333U - Solar insecticidal lamp control system capable of remotely controlling selection of multiple wave bands - Google Patents

Abstract

The utility model discloses a solar insecticidal lamp control system capable of remotely controlling selection of various wave bands, which comprises an MCU logic control system; the MCU logic control system is respectively connected with the high-voltage generation system, the GPRS data processing system, the solar charging system and the LED lamp tube insect-trapping light source system; the MCU logic control system is an STM32 singlechip; the GPRS data processing system is electrically connected with a UART1 serial port of an STM32 singlechip through a JP1 plug-in; the solar charging and discharging system comprises a solar charging control system and a solar discharging control system; the high-voltage generation system is connected with a VCC _ BAT pin of JP5, and the high-voltage generation system is connected with a high-voltage power grid through a JP7 plug-in; the LED lamp tube insect-attracting light source system comprises at least three spectrum driving circuits, and each driving circuit comprises a plurality of LED lamp tubes.

Description

Solar insecticidal lamp control system capable of remotely controlling selection of multiple wave bands

Technical Field

The utility model belongs to the technical field of the insecticidal lamp, concretely relates to but solar energy insecticidal lamp control system of multiple wave band selection of remote control.

Background

The insect-attracting light source and the control mode of the insecticidal lamp occupy important positions in the whole insecticidal lamp, and the insect-attracting light source and the control mode of the current insecticidal lamp have the following problems and disadvantages:

1. the light source of the insecticidal lamp is the key for successfully trapping insects, the current insect trapping light source of the insecticidal lamp is single or can not trap and kill the insects in a targeted manner, and fluorescent lamp tubes (T8, E27 and the like), single-band LED lamp tubes or LED lamp tubes with multiple spectrums are mainly adopted;

2. the adopted common fluorescent lamp tube has the following defects that a, the light source spectrum is too miscellaneous, the targeted trapping and killing cannot be realized, and b, the effective service life is short;

3. the LED light source with single spectrum can only trap and kill the harmful insects which are sensitive to the light source, but the application range is narrow;

4. the multispectral LED lamp tubes on the market at present are only lighted simultaneously or only in a single working mode;

5. at present, the insecticidal lamps on the market do not have remote control, one or more insect-attracting light sources are selected in a targeted manner, and the lamp tubes with different types of light sources are troublesome to replace in the field.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to the above-mentioned among the prior art not enough, provide a but solar energy insecticidal lamp control system of multiple wave band selection of remote control to solve or improve foretell problem.

In order to achieve the purpose, the utility model adopts the technical proposal that:

a solar insecticidal lamp control system capable of remotely controlling selection of multiple wave bands comprises an MCU logic control system; the MCU logic control system is respectively connected with the high-voltage generation system, the GPRS data processing system, the solar charging system and the LED lamp tube insect-trapping light source system;

the MCU logic control system is an STM32 singlechip; the GPRS data processing system is electrically connected with a UART1 serial port of the STM32 singlechip through a JP1 plug-in, and is in communication connection with a remote server through GPRS or short messages;

the solar charging and discharging system comprises a solar charging control system and a solar discharging control system; the solar energy charging and discharging system is connected with a PB7 pin in the STM32 singlechip through a JP6 plug-in, and the solar energy discharging control system is connected with a PB6 pin in the STM32 singlechip through a JP5 plug-in; the high-voltage generation system is connected with a VCC _ BAT pin of JP5, and the high-voltage generation system is connected with a high-voltage power grid through a JP7 plug-in;

the LED lamp tube insect-attracting light source system comprises at least three spectrum driving circuits, and each driving circuit comprises a plurality of LED lamp beads.

Preferably, the LED lamp tube insect-attracting light source system comprises three spectrum driving circuits, and DIMI ends of the three spectrum driving circuits are respectively and electrically connected with PB8, PB9 and PB10 of an STM32 singlechip.

Preferably, the three spectral drive circuits are connected in parallel.

Preferably, the spectrum driving circuit comprises a PT4115 voltage-reducing constant-current module, and the PT4115 voltage-reducing constant-current module is electrically connected with the LED lamp tube.

Preferably, the GPRS data processing system is a SIM808GPRS and GPS integral module.

The utility model provides a but solar energy insecticidal lamp control system of multiple wave band of remote control selection has following beneficial effect:

the utility model supplies power to the system by converting solar energy into electric energy, and is provided with a plurality of parallel spectrum circuits, namely a plurality of LED lamp tubes, so that light source spectrum wave bands can be selected according to actual requirements, and pests can be trapped and killed in a targeted manner; and a plurality of light source spectrum wave bands can be set, and a certain LED lamp tube, a certain LED lamp tube or a plurality of LED lamp tubes can be selectively controlled to be opened to trap and kill pests, so that the lamp tube control of the system has more flexibility and wider application range.

Drawings

Fig. 1 is a schematic block diagram of a solar insecticidal lamp control system capable of remotely controlling a plurality of band selections.

Fig. 2 and 3 are overall circuit diagrams of a solar insecticidal lamp control system capable of remotely controlling various waveband selections.

Fig. 4 is a circuit diagram of a solar insecticidal lamp control system GPRS data processing system capable of remotely controlling a plurality of band selections.

Fig. 5 is a solar energy charge-discharge circuit diagram of a solar insecticidal lamp control system capable of remotely controlling various band selections.

Fig. 6 is a circuit diagram of a high voltage generating system of a solar insecticidal lamp control system capable of remotely controlling a plurality of band selections.

Fig. 7 is a spectrum driving circuit diagram of a solar insecticidal lamp control system capable of remotely controlling a plurality of band selections.

Fig. 8 is a circuit diagram of a single chip microcomputer of the solar insecticidal lamp control system capable of remotely controlling the selection of various wave bands.

Detailed Description

The following description of the embodiments of the present invention is provided to facilitate the understanding of the present invention by those skilled in the art, but it should be understood that the present invention is not limited to the scope of the embodiments, and various changes may be made apparent to those skilled in the art within the spirit and scope of the present invention as defined and defined by the appended claims.

According to an embodiment of the application, referring to fig. 1-3, the solar insecticidal lamp control system capable of remotely controlling multiple band selections comprises an MCU logic control system; the MCU logic control system is respectively connected with the high-voltage generation system, the GPRS data processing system, the solar charging system and the LED lamp tube insect-luring light source system.

Referring to fig. 8, the MCU logic control system is an STM32 single chip microcomputer, and its specific model is STM32F103C8, for implementing the control function of the system.

Referring to fig. 4, the GPRS data processing system is an SIM808GPRS and GPS integrated module, which can be used to implement wireless communication and wireless positioning of a lamp tube, and is electrically connected to a UART1 serial port of an STM32 single chip microcomputer through a JP1 plug-in, and is in communication connection with a remote client through a GPRS network or a short message. The GPRS data processing system can realize communication with a remote client, receive control instruction information of the remote client and transmit the control instruction information to the STM32 single chip microcomputer, and the STM32 single chip microcomputer further controls one or more LED lamp tubes to be turned on or turned off.

Referring to fig. 5, a solar charging and discharging system is used to realize the power supply of the present system, which includes a solar charging control system and a solar discharging control system.

The solar charging control system is connected with a PB7 pin in the STM32 singlechip through a JP6 plug-in, is used for carrying out charging management on the storage battery of the system, avoids overcharging of the storage battery and realizes overvoltage protection.

Solar energy discharge control system is connected through the PB6 pin in JP5 plug-in and the STM32 singlechip for realize the battery to the management of discharging of system's power supply, avoid the battery to discharge over.

Referring to fig. 6, the high voltage generating system is connected to VCC _ BAT pin of JP5, and the high voltage generating system is connected to the high voltage network through JP7 plug-in for providing high voltage electricity for the system, and the high voltage electricity acts on wire netting or other metals, cooperates with the LED lamp tube, and the pest that will be lured by the lamp tube carries out the high voltage and destroys.

The wire mesh can be arranged around the periphery of the LED lamp tube, and the wire mesh (or other metals) is matched with the LED lamp tube to kill insects, which is a common means in the field, so the details are not repeated.

Referring to fig. 7, the LED lamp insect-luring light source system includes at least three spectrum driving circuits, each of which includes a plurality of LED lamps, wherein the light source spectrum band of the LED lamp can be selected according to the actual geographical environment, and one or more light source spectrum bands can be selected according to one or more types of main pests in the environment. Since most regions have more than one pest species, multiple spectra of light may be selected. Namely, a plurality of LED lamp tubes arranged in parallel are selected, and each LED lamp tube only relates to one spectrum or a small-range spectrum, so that targeted trapping can be realized, and the trapping efficiency can be improved.

The LED lamp tube insect-attracting light source system comprises three spectrum driving circuits, wherein DIMI ends of the three spectrum driving circuits are respectively and electrically connected with PB8, PB9 and PB10 of an STM32 single chip microcomputer, namely, the LED lamp tube is controlled by the STM32 single chip microcomputer.

The spectrum driving circuit comprises a PT4115 voltage reduction constant current module, and the PT4115 voltage reduction constant current module is electrically connected with the LED lamp tube and used for driving the LED lamp tube.

The working flow of this embodiment is:

the remote client sends a control instruction, and the control instruction can be to start one LED lamp tube or a plurality of LED lamp tubes. The issued control instruction is transmitted to a GPRS data processing system through a short message or a GPRS network, the GPRS data processing system transmits the instruction information to an STM32 single chip microcomputer, and the STM32 single chip microcomputer controls one or more appointed LED lamp tubes to be opened.

The utility model supplies power to the system by converting solar energy into electric energy, and is provided with a plurality of parallel spectrum circuits, namely a plurality of LED lamp tubes, so that light source spectrum wave bands can be selected according to actual requirements, and pests can be trapped and killed in a targeted manner; and a plurality of light source spectrum wave bands can be set, and a certain LED lamp tube, a certain LED lamp tube or a plurality of LED lamp tubes can be selectively controlled to be opened to trap and kill pests, so that the lamp tube control of the system has more flexibility and wider application range.

While the present invention has been described in detail with reference to the embodiments, the scope of the present invention should not be limited to the embodiments. Various modifications and changes may be made by those skilled in the art without inventive step within the scope of the appended claims.

Claims (5)

1. The utility model provides a but solar energy insecticidal lamp control system of multiple wave band selection of remote control which characterized in that: comprises an MCU logic control system; the MCU logic control system is respectively connected with the high-voltage generation system, the GPRS data processing system, the solar charging system and the LED lamp tube insect-trapping light source system;

the MCU logic control system is an STM32 singlechip; the GPRS data processing system is electrically connected with a UART1 serial port of the STM32 single chip microcomputer through a JP1 plug-in, and is in communication connection with a remote server through GPRS or short messages;

the solar charging and discharging system comprises a solar charging control system and a solar discharging control system; the solar energy charging and discharging system is connected with a PB7 pin in an STM32 singlechip through a JP6 plug-in, and the solar energy discharging control system is connected with a PB6 pin in an STM32 singlechip through a JP5 plug-in; the high-voltage generation system is connected with a VCC _ BAT pin of JP5, and the high-voltage generation system is connected with a high-voltage power grid through a JP7 plug-in;

the LED lamp tube insect-attracting light source system comprises at least three spectrum driving circuits, and each driving circuit comprises a plurality of LED lamp beads.

2. The solar insecticidal lamp control system capable of remotely controlling multiple band selections as claimed in claim 1, wherein: the LED lamp tube insect-attracting light source system comprises three spectrum driving circuits, and DIMI ends of the three spectrum driving circuits are respectively and electrically connected with PB8, PB9 and PB10 of an STM32 single chip microcomputer.

3. The solar insecticidal lamp control system capable of remotely controlling multiple band selections as claimed in claim 2, wherein: the three spectrum driving circuits are connected in parallel.

4. The solar insecticidal lamp control system capable of remotely controlling multiple band selections as claimed in claim 3, wherein: the spectrum driving circuit comprises a PT4115 voltage reduction constant current module, and the PT4115 voltage reduction constant current module is electrically connected with the LED lamp tube.

5. The solar insecticidal lamp control system capable of remotely controlling multiple band selections as claimed in claim 1, wherein: the GPRS data processing system is an SIM808GPRS and GPS integrated module.

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