CN112056285A - Deinsectization lamp system and deinsectization lamp - Google Patents

Abstract

The invention discloses a deinsectization lamp system which comprises a microprocessor, a light control circuit, a humidity sensor, a trap lamp, a power grid, a first relay and a third relay, wherein the light control circuit is electrically connected with a first input end of the microprocessor, and converts an induced illumination signal into an electric signal and inputs the electric signal to the microprocessor; the humidity sensor is electrically connected with a third input end of the microprocessor, and converts the sensed humidity signal into an electric signal and inputs the electric signal to the microprocessor; the trap lamp is arranged at the first output end of the microprocessor, and the level signal output by the first output end controls the on/off state of the first relay contact switch so as to control the trap lamp to work; the power grid is arranged at the eighth output end of the microprocessor, and the level signal output by the eighth output end controls the on/off state of the third relay contact switch so as to control the power grid to work. The invention can realize that the trap lamp is turned off in the daytime and turned on at night, and can realize that the power grid is turned on in sunny days and turned off in rainy days.

Description

Deinsectization lamp system and deinsectization lamp

Technical Field

The invention belongs to the technical field of insect killing, and particularly relates to an insect killing lamp system and an insect killing lamp.

Background

Because the plants planted in the Chinese herbal medicine plantation are Chinese herbal medicines, most of the Chinese herbal medicines have edibility or aromatic odor, and are very easy to attract insects, such as the problem of mosquito harassment and the problems of invasion of various pests for eating, home-keeping, breeding and the like. In the prior art, a special insect repelling device is provided to solve the problem, for example, a trap lamp is adopted, but in the prior art, the most common trap lamp is used for killing insects by sticking mosquitoes and insects through sticky substances after attracting insects through light, the method usually needs manual cleaning, and the cleaning process is troublesome and unsanitary. The electric mosquito swatter is used for continuously using the electric net, so that potential safety hazards are caused, and the insect attracting lamp is usually unobvious in lighting during the day, so that the insect attracting function cannot be realized; under the general condition, when the environment is not allowed, the trap lamp and the power grid are manually closed, so that electric energy can be saved or potential safety hazards can be relieved, but the insects cannot be normally killed during closing, and certain planting burden is brought to a plantation.

Disclosure of Invention

The invention aims to solve the problems and provides a deinsectization lamp system which can be turned off in the daytime and turned on at night, and can be turned on in fine days and turned off in rainy days.

The invention is realized by the following technical scheme: the invention provides a deinsectization lamp system which comprises a microprocessor, a light-operated circuit, a humidity sensor, a trap lamp, a power grid, a first relay and a third relay, wherein the microprocessor comprises a plurality of input ends and a plurality of output ends; the light control circuit is electrically connected with a first input end of the microprocessor, and converts the sensed illumination signal into an electric signal and inputs the electric signal to the microprocessor; the humidity sensor is electrically connected with a third input end of the microprocessor, and converts the sensed humidity signal into an electric signal and inputs the electric signal to the microprocessor; the trap lamp is arranged at a first output end of the microprocessor, the microprocessor controls the output state of the first output end according to the output result of the light control circuit, and a level signal output by the first output end controls the on/off state of a first relay contact switch; controlling the connection state between the trap lamp and a direct current power supply through the on/off state of the first relay contact, thereby controlling the trap lamp to work; the power grid is arranged at an eighth output end of the microprocessor, the microprocessor controls the output state of the eighth output end according to the output result of the humidity sensor, and a level signal output by the eighth output end controls the on/off state of a contact switch of a third relay; and controlling the connection state between the power grid and the direct-current power supply through the on/off state of the third relay contact, so as to control the power grid to work.

Optionally, the device further comprises an insect repellent storage unit, an insect repellent storage unit and an insecticide storage unit; the insect repellent storage unit is used for storing insect repellent, and comprises a first gravity sensor which is electrically connected with the fourth input end of the microprocessor, and the first gravity sensor converts the gravity signal of the residual insect repellent in the insect repellent unit into an electric signal and inputs the electric signal to the microprocessor; the insect attractant storage unit is used for storing an insect attractant, the insect attractant storage unit comprises a second gravity sensor, the second gravity sensor is electrically connected with a fifth input end of the microprocessor, and the second gravity sensor converts the gravity signals of the residual insect attractant in the insect attractant unit into electric signals and inputs the electric signals to the microprocessor; the pesticide storage unit is used for storing pesticides, the pesticide storage unit comprises a third gravity sensor, the third gravity sensor is electrically connected with a sixth input end of the microprocessor, and the third gravity sensor converts gravity signals of residual pesticides in the pesticide storage unit into electric signals and inputs the electric signals to the microprocessor.

Optionally, the system also comprises an insect expelling sprayer, an insect attracting sprayer, an insect killing sprayer, a remote server and an RS485 communication interface; the insect expelling sprayer, the insect attracting sprayer and the insect killing sprayer are all arranged at the output end of the microprocessor and controlled to work by the output signal of the microprocessor; the RS485 communication interface is electrically connected with a third output end of the microprocessor, and the remote server and the microprocessor transmit signals through the RS485 communication interface; the RS485 communication interface is electrically connected with a third output end of the microprocessor, and the remote server and the microprocessor transmit signals through the RS485 communication interface; .

Optionally, a repellent increment indicator lamp for indicating when the residual repellent in the repellent storage unit is lower than a minimum threshold value; the third output end of the microprocessor is connected with the input end of the first NOT gate circuit and is also connected with the insect repellent increment indicator lamp; a second output end of the microprocessor and an output end of the first NOT gate circuit are jointly connected to two input ends of a first AND gate circuit, the output end of the first AND gate circuit is connected with a base electrode of a second triode, a collector electrode of the second triode is connected with a direct-current power supply, and an emitting electrode of the second triode is grounded; a first water pump is connected between the collector electrode of the second triode and the direct-current power supply in series, and the first water pump is electrically connected with the insect-repelling sprayer and drives the insect-repelling sprayer to spray; two sides of the first water pump are also connected with a first protection capacitor in parallel; the output level of the second output end controls the starting of the insect-repellent sprayer, and the output level of the third output end controls the insect-repellent agent increment indicator lamp to light up; when the residual anthelmintic agent in the anthelmintic agent storage unit is lower than the minimum threshold value, the anthelmintic agent increment indicator lamp is turned on, and the anthelmintic sprayer stops working.

Optionally, the pest attractant storage unit further comprises a pest attractant increment indicator light for indicating when the residual pest attractant in the pest attractant storage unit is lower than a minimum threshold value; the fourth output end of the microprocessor is connected with the input end of the second NOT gate circuit and is also connected with the insect-attracting pesticide increment indicator lamp; a fifth output end of the microprocessor and an output end of the second NOT gate circuit are jointly connected to two input ends of a second AND gate circuit, an output end of the second AND gate circuit is connected with a base electrode of a third triode, a collector electrode of the third triode is connected with a direct-current power supply, and an emitting electrode of the third triode is grounded; a second water pump is connected between the collector of the third triode and the direct-current power supply in series, and the second water pump is electrically connected with the insect-attracting spraying machine and drives the insect-attracting spraying machine to spray; two sides of the second water pump are also connected with a second protection capacitor in parallel; the output level of the fourth output end controls the starting of the insect-attracting sprayer, and the output level of the fifth output end controls the insect-attracting pesticide increment indicator lamp to light up; when the residual insect attractant in the insect attractant storage unit is lower than the minimum threshold value, the insect attractant increment indicator lamp is turned on, and the insect attracting sprayer stops working.

Optionally, an insecticide increment indicator light for indicating that the insecticide left in the insecticide storage unit is lower than the minimum threshold value; a sixth output end of the microprocessor is connected with an input end of a third NOT gate circuit and is simultaneously connected with the pesticide increment indicator lamp; a seventh output end of the microprocessor and an output end of the third NOT gate circuit are jointly connected with two input ends of a third AND gate circuit, an output end of the third AND gate circuit is connected with a base electrode of a fourth triode, a collector electrode of the fourth triode is connected with a direct-current power supply, and an emitting electrode of the fourth triode is grounded; a third water pump is connected between the collector of the fourth triode and the direct-current power supply in series, and the third water pump is electrically connected with the insecticidal sprayer and drives the insecticidal sprayer to spray; both sides of the third water pump are also connected with a third protection capacitor in parallel; the output level of the sixth output end controls the starting of the insecticidal sprayer, and the output level of the seventh output end controls the insecticide increment indicator lamp to light up; when the pesticide left in the pesticide storage unit is lower than the lowest threshold value, the pesticide increment indicating lamp is turned on, and the pesticide spraying machine stops working.

Optionally, an eighth output end of the microprocessor is connected with a base electrode of a sixth triode, a collector electrode of the sixth triode is connected with a direct-current power supply, and an emitter electrode of the sixth triode is grounded; a third relay is connected between the collector of the sixth triode and the direct-current power supply in series, and a contact switch of the third relay is connected between the direct-current power supply and the power grid; when the level output by the eighth output end enables the third relay contact switch to be closed, the power grid is conducted with the power supply and starts to work; and when the level output by the eighth output end enables the third relay contact switch to be disconnected, the power grid is disconnected from the power supply and stops working.

Optionally, a clock signal generator, a counter and a T-flip-flop are further connected in series between the contact end of the third relay contact switch close to the power grid and the power grid, the contact end of the third relay contact switch close to the power grid is electrically connected to the clock generator, and the connection between the clock signal generator and the dc power supply is controlled by the contact switch of the third relay; the output end of the clock signal generator is connected with the clock signal input end of the counter and the clock signal input end of the T trigger; the output of counter is connected the input of T flip-flop, the output of T flip-flop is connected the electric wire netting, the output level signal control of T flip-flop the electric wire netting starts work, electric wire netting and DC power supply electric connection and from the operating voltage who pins DC power supply and acquire.

Optionally, a common connection end of the T-trigger and the power grid is further electrically connected to a base of a fifth triode, a collector of the fifth triode is electrically connected to a direct-current power supply, a second relay is connected in series between an emitter of the fifth triode and a ground, and a contact switch of the second relay is connected between an output end of the third and-gate circuit and the base of the fourth triode; and after the output level of the output end of the T trigger passes through the current amplification effect of a fifth triode, the conduction state between the output end of the third AND gate circuit and the base electrode of the fourth triode is controlled through the second relay, so that the working state of the insecticidal sprayer is controlled. The light control circuit comprises a photoresistor and an inverter, wherein the photoresistor changes the current in the light control circuit by sensing the change of the intensity of illumination from outside to outside so as to change the input voltage of the inverter, and the output voltage of the inverter changes along with the change of the input voltage.

The invention also discloses a deinsectization lamp, which adopts the deinsectization lamp system and is characterized in that the electric network surrounds the outside of the trap lamp, and the insect repellent storage unit, the insect attractant storage unit, the insecticide storage unit, the insect repellent sprayer, the insect attractant sprayer and the insect insecticide sprayer are all fixedly arranged on the upper end surface of the trap;

the insect repelling sprayer is connected with the insect repelling agent storage unit and is used for acquiring the insect repelling agent from the insect repelling agent storage unit to spray;

the insect-attracting sprayer is connected with the insect-attracting agent storage unit and acquires the insect-attracting agent from the insect-attracting agent storage unit for spraying;

the insecticidal sprayer is connected with the insecticide storage unit and acquires the insecticide from the insecticide storage unit to spray.

The invention has the beneficial effects that:

1. according to the invention, the light control circuit and the humidity sensor are used for observing the external illumination intensity and humidity, so that the functions of turning off the trap lamp in the daytime and turning on the trap lamp at night can be realized, the functions of turning off the power grid in the rainy day and turning on the power grid in the sunny day can be realized, the problem of electric energy waste caused by the fact that the trap lamp does not work during the daytime when emitting light is avoided, and the possible electric shock hazard caused by turning on the power grid in the rainy day is also avoided.

2. The invention also controls the work of the insect attracting sprayer and the insect killing sprayer through the remote server, when the trap lamp or the power grid can not work due to external weather reasons, the insect attracting sprayer sprays the medicament capable of attracting insects, and the insect killing sprayer sprays the medicament capable of killing the insects, thereby realizing the insect killing effect.

3. The invention also has the advantages that the power grid is intermittently started under the condition that the weather allows the power grid to be started, so that the potential safety hazard problem caused by long-time power grid starting is prevented.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

fig. 1 is a schematic structural view of a bug lamp system according to a first embodiment of the invention;

FIG. 2 is a logic relationship table of the first water pump, the insect repellant dosing indicator light, the second output terminal output level, and the third output terminal output level according to the first embodiment of the present invention;

FIG. 3 is a table of the logical relationship between the second water pump and the insect repellent dosing indicator light, the output level of the fourth output terminal, and the output level of the fifth output terminal according to the first embodiment of the present invention;

fig. 4 is a logic relationship table of the first water pump, the insect repellent dosing indicator light, the power grid 200, and the output levels of the second output terminal, the third output terminal, and the T-flip flop according to the first embodiment of the present invention;

fig. 5 is a pulse line graph showing the change of the clock signal generator, the counter, the output terminal of the T flip-flop and the working state of the power grid with time according to the first embodiment of the present invention;

FIG. 6 is a schematic view of a bug lamp according to a second embodiment of the present invention;

100-a trap lamp; 200-a power grid; 300-an insect repellent storage unit; 400-insect attractant storage unit; 500-insecticide storage unit; 600-insect repellant sprayer; 700-insect-attracting sprayer; 800-insect killing sprayer.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the drawings of the embodiments of the present invention. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the invention without any inventive step, are within the scope of protection of the invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this invention belongs. The use of "first," "second," and similar terms in the description and claims of the present application do not denote any order, quantity, or importance, but rather the terms are used to distinguish one element from another. Also, the use of the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one.

The first embodiment is as follows:

the embodiment discloses a disinfestation lamp system, which is provided with a photosensitive device and a humidity sensor, insects are lured through the insect luring lamp 100 and the insect guiding spray, insects are subjected to disinfestation treatment through the power grid 200 and the disinfestation spraying machine 800, the luring lamp can be turned off and used in the daytime and turned on and used in the evening, and the power grid 200 can be turned off and used in the rainy day and turned on and used in the evening.

The embodiment discloses a disinfestation lamp system, which comprises a microprocessor, a light-operated circuit 01, a humidity sensor, a trap lamp 100 and a power grid 200, wherein the microprocessor comprises a plurality of input ends and a plurality of output ends. The light control circuit 01 is electrically connected with a first input end X1 of the microprocessor, and the light control circuit 01 is used for converting the sensed illumination signal into an electric signal and inputting the electric signal to the microprocessor. The humidity sensor is electrically connected with a third input end X3 of the microprocessor, and the humidity sensor converts the sensed humidity signal into an electric signal and inputs the electric signal to the microprocessor. The microprocessor carries out operation of an internal program of the microprocessor through the illumination intensity signal (namely a day/night signal) and the humidity signal (namely a raining signal) received by the input end of the microprocessor, and then controls corresponding equipment to work through the output end. The trap lamp 100 of the present embodiment adopts an energy-saving wide-spectrum trap lamp 100, and the energy-saving wide-spectrum trap lamp 100 is a special trap light source developed for an insect killing lamp on the basis of a compact single-ended fluorescent lamp, and is a prior art, so that redundant description is not repeated in the present embodiment.

In addition, the trap lamp 100 of the present embodiment is disposed at the first output terminal P1 of the microprocessor, the microprocessor controls the output state of the first output terminal P1 according to the output result of the light control circuit 01, and the output state of the first output terminal P1 controls the operation of the trap lamp 100. As shown in fig. 1, the first output terminal P1 is first connected to the base of the first transistor Q1, the collector of the first transistor Q1 is connected to the dc power supply, a trap lamp 100 is connected between the collector of the first transistor Q1 and the dc power supply, a first relay K1 is also connected in parallel with the trap lamp 100 and also connected between the collector of the first transistor Q1 and the dc power supply, a contact switch of the first relay K1 is connected to the line where the trap lamp 100 is located, and the relay can control whether the circuit between the dc power supply and the trap lamp 100 is turned on or off. In popular terms, when the light control circuit 01 senses that the illumination is changed from weak to strong (i.e. from night to day), the output end of the light control circuit 01 is changed from high level to low level, after the microprocessor receives the illumination change information, the microprocessor outputs high level from the first output end P1 through internal calculation, the high level drives the first relay K1 to be conducted to work after the amplification effect of the first triode, and the first relay K1 drives the internal contact (which is also arranged between the trap lamp 100 and the direct-current power supply) to be closed because of conduction, so that the trap lamp 100 successfully obtains the power supply to shine.

The eighth output end P8 of the microprocessor is connected to the third relay K3, the third relay K3 is electrically connected to the power grid 200, the microprocessor controls the output state of the eighth output end P8 according to the output result of the humidity sensor, and the level signal output by the eighth output end P8 controls the on or off state of the contact of the third relay K3. As shown in fig. 1, the eighth output terminal P8 is connected to the base of the sixth transistor Q6, the collector of the sixth transistor Q6 is connected to the dc power supply, and the emitter is grounded; the third relay K3 is connected between the collector of the sixth transistor Q6 and the dc power source, while the contact switch of the third relay K3 is connected between the grid 200 and the dc power source, and the connection state between the grid 200 and the power source is controlled by the on or off state of the contact of the third relay K3. In a popular way, when the humidity sensor senses a humidity signal (i.e., a rain signal), the output end of the humidity sensor outputs a high-level signal, the high-level signal is acquired by the microprocessor through the second input end X2, the microprocessor outputs a high-level signal through the eighth output end P8 after an internal calculation process, so that the sixth triode Q6 is turned on, the high-level signal drives the third relay K3 to be turned on and operate after the amplification effect of the sixth triode, the third relay K3 drives the internal contact (which is also arranged between the power grid 200 and the direct-current power supply) to be turned on due to the conduction, and the power grid 200 acquires the direct-current power supply to operate.

Specifically, the present embodiment further includes a repellent storage unit 300, an insect repellent storage unit 400, and an insecticide storage unit 500.

The repellent storage unit 300 is used for storing the repellent, and the repellent storage unit 300 includes a first gravity sensor electrically connected to the fourth input terminal X4 of the microprocessor, and the first gravity sensor converts the gravity signal of the remaining repellent in the repellent unit into an electrical signal and inputs the electrical signal to the microprocessor. The insect attractant storage unit 400 is used for storing an insect attractant, the insect attractant storage unit 400 comprises a second gravity sensor, the second gravity sensor is electrically connected with a fifth input end X5 of the microprocessor, and the second gravity sensor converts the gravity signals of the residual insect attractant in the insect attractant storage unit into electric signals and inputs the electric signals to the microprocessor. The insecticide storage unit 500 is used for storing insecticides, the insecticide storage unit 500 comprises a third gravity sensor, the third gravity sensor is electrically connected with a sixth input end X6 of the microprocessor, and the third gravity sensor converts gravity signals of residual insecticides in the insecticide storage unit into electric signals and inputs the electric signals to the microprocessor.

Correspondingly, the present embodiment further includes a vermin sprayer 600, a vermin attracting sprayer 700, and an insect killing sprayer 800 for spraying the chemicals inside the three chemical storage units. The insect expelling sprayer 600, the insect attracting sprayer 700 and the insect killing sprayer 800 are all arranged at the output end of the microprocessor and controlled to work by the output signal of the microprocessor. In addition, this embodiment still include with remote server and RS485 communication interface, RS485 communication interface and microprocessor's third output P3 electric connection, remote server and microprocessor carry out the transmission of signal through RS485 communication interface, and the content of the information transfer that this embodiment goes on through RS485 communication interface and remote server includes: the instruction information of the remote server for each device that can be controlled by the microprocessor, including instructions to command the operation of the insect repellant sprayer 600, insect attractant sprayer 700, and insect repellant sprayer 800; and the microprocessor acquires an illumination signal, a humidity signal and pressure signals of the gravity sensors. In popular terms, the remote server transmits signals with the microprocessor through the RS485 communication interface, and the remote server sends command signals to the microprocessor to enable the output end of the microprocessor to output corresponding level signals for controlling the sprayers to start to work.

Specifically, the present embodiment further includes a repellent increment indicator lamp for indicating when the remaining repellent in the repellent storage unit 300 is below the minimum threshold value. The third output terminal P3 of the microprocessor is connected to the input terminal of the first not gate circuit a1 and is also connected to the insecticide incremental indicator lamp. A second output end P2 of the microprocessor and an output end of the first not gate circuit a1 are jointly connected to two input ends of a first and gate circuit B1, an output end of the first and gate circuit B1 is connected to a base of a second triode Q2, a collector of the second triode Q2 is connected to a direct-current power supply, and an emitter of the second triode Q2 is grounded. A first water pump is connected in series between the collector of the second triode Q2 and the dc power supply, and the first water pump is electrically connected to the insect-repelling sprayer 600 and drives the insect-repelling sprayer 600 to perform spraying. And two sides of the first water pump are also connected with a first protective capacitor C1 in parallel. The output level of the second output terminal P2 controls the start of the insect spray machine 600 and the output level of the third output terminal P3 controls the insecticide increment indicator light to light up. When the remaining repellent in the repellent storage unit 300 is lower than the minimum threshold value, the repellent increment indicator lamp is turned on, and the insect spray machine 600 stops operating. The insect repellent storage unit 300 and the insect repellent sprayer 600 function: when plants in a plantation need to be seasonally propagated by the insects and too many insects are not needed to be gathered to avoid planting influence, the insect expelling sprayer 600 is controlled to be started through the remote server to spray the insect expelling medicament, so that the purpose of expelling the insects without injuring the insects is achieved, the medicament stored in the insect expelling medicament storage unit 300 is the medicament capable of expelling the insects, and the insect expelling medicament can be selected according to actual conditions. In a colloquial way, the relationship table of the output level results of the second output terminal P2 and the third output terminal P3 to the insect repellent dosing indicator light, the output terminal of the first not gate circuit a1, the output terminal of the first and gate circuit B1 and the operating state of the first water pump is shown in fig. 2, that is, according to the logics of the not gate circuit and the and gate circuit (the logics are the functional characteristics of the not gate circuit and the and gate circuit, the present embodiment is only a connecting circuit designed by the functional characteristics thereof, so that the present embodiment does not give much explanation about how to realize the logic, and it should be understood by those skilled in the art that the first water pump will start to operate and drive the insect repellent 600 to spray only when the second output terminal P2 outputs a high level and the third output terminal P3 outputs a low level; when the third output terminal P3 outputs a high level, the first water pump stops working and the vermin exterminating agent addition amount indicating lamp is turned on regardless of whether the output state of the second output terminal P2 is a high level or a low level.

Specifically, the present embodiment further includes an insect attractant increment indicator light for indicating when the residual insect attractant in the insect attractant storage unit 400 is below the minimum threshold. The fourth output terminal P4 of the microprocessor is connected with the input terminal of the second NOT gate circuit A2 and is also connected with an insect-attracting medicine increment indicating lamp. A fifth output end P5 of the microprocessor and an output end of the second not gate circuit a2 are jointly connected to two input ends of a second and gate circuit B2, an output end of the second and gate circuit B2 is connected to a base of a third triode Q3, a collector of the third triode Q3 is connected to a direct-current power supply, and an emitter of the third triode Q3 is grounded. A second water pump is connected in series between the collector of the third triode Q3 and the dc power supply, and the second water pump is electrically connected to the pest attracting sprayer 700 and drives the pest attracting sprayer 700 to spray. And two sides of the second water pump are also connected with a second protective capacitor C2 in parallel. The output level of the fourth output terminal P4 controls the starting of the insect-attracting sprayer 700, and the output level of the fifth output terminal P5 controls the turning-on of the insect-attracting agent increment indicating lamp. When the residual attractant in the attractant storage unit 400 is lower than the minimum threshold, the attractant increment indicator lights are turned on, and the insect spraying machine 700 stops working. The insect-attracting pesticide storage unit 400 and the insect-attracting sprayer 700 function: when the trap lamp 100 cannot normally work due to weather, the remote server controls the insect attracting sprayer 700 to spray the insect attracting agent, so that the purpose of attracting insects to approach is achieved, the agent stored in the insect attracting agent storage unit 400 can be selected to attract the insects according to actual conditions. In a popular way, a relation table of the output level results of the fourth output end P4 and the fifth output end P5 to the working states of the insect-attracting medicine dosage indicator lamp, the output end of the second not gate circuit a2, the output end of the second and gate circuit B2 and the second water pump is shown in fig. 3, that is, according to the logic of the not gate circuit and the and gate circuit, the second water pump can start to work and drive the insect-attracting sprayer 700 to spray only when the fourth output end P4 outputs a high level and the fifth output end P5 outputs a low level; when the fifth output terminal P5 outputs a high level, the second water pump stops working and the insect-repellent chemical dosage indicator lamp lights no matter whether the output state of the fourth output terminal P4 is a high level or a low level.

Specifically, the present embodiment further includes an insecticide increment indicator lamp for indicating when the remaining insecticide in the insecticide storage unit 500 is below the minimum threshold. The sixth output terminal P6 of the microprocessor is connected to the input terminal of the third NOT gate circuit A3 and is also connected to the pesticide increment indicating lamp. A seventh output end P7 of the microprocessor and an output end of the third not gate circuit A3 are jointly connected to two input ends of a third and gate circuit B3, an output end of the third and gate circuit B3 is connected to a base of a fourth triode Q4, a collector of the fourth triode Q4 is connected to a direct-current power supply, and an emitter of the fourth triode Q4 is grounded. And a third water pump is connected between the collector of the fourth triode Q4 and the direct-current power supply in series, and the third water pump is electrically connected with the insecticidal sprayer 800 and drives the insecticidal sprayer 800 to spray. And both sides of the third water pump are also connected with a third protective capacitor C3 in parallel. The output level of the sixth output terminal P6 controls the start of the insecticide sprayer 800, and the output level of the seventh output terminal P7 controls the insecticide increment indicator lamp to light up. When the remaining insecticide in the insecticide storage unit 500 is lower than the minimum threshold value, the insecticide increment indicator lamp is turned on, and the insecticide sprayer 800 stops operating. The insecticide storage unit 500 and the insecticide sprayer 800 function: when the power grid 200 can not normally work due to weather, the remote server is used for controlling the insecticidal sprayer 800 to spray insecticide, so that the purpose of killing insects is achieved, and the insecticide stored in the insecticide storage unit 500 can be selected according to actual conditions for killing the insects.

Specifically, the eighth output terminal P8 of the microprocessor in this embodiment is connected to the base of the sixth transistor Q6, the collector of the sixth transistor Q6 is connected to the dc power supply, and the emitter is grounded. A third relay K3 is connected in series between the collector of the sixth transistor Q6 and the dc power source, and the contact switch of the third relay K3 is connected between the dc power source and the grid 200. When the level outputted from the eighth output terminal P8 closes the contact switch of the third relay K3, the grid 200 is connected to the power source and starts to operate. When the level outputted from the eighth output terminal P8 turns off the contact switch of the third relay K3, the grid 200 is disconnected from the power source and stops operating. A clock signal generator, a counter and a T-flip-flop are also connected in series between the contact terminal of the contact switch of the third relay K3 (i.e. the contact switch b terminal of the third relay K3 in fig. 1) near the power grid 200 and the power grid 200, the contact terminal b terminal of the contact switch of the third relay K3 near the power grid 200 is electrically connected with the clock generator, and the connection of the clock signal generator and the direct-current power supply is controlled by the contact switch of the third relay K3. The output end of the clock signal generator is connected with the clock signal input end of the counter and the clock signal input end of the T trigger. The output end of the counter is connected with the input end of the T trigger, the output end of the T trigger is connected with the power grid 200, the output end level signal of the T trigger controls the power grid 200 to start working, and the power grid 200 is electrically connected with the direct current power supply and obtains working voltage from the locked direct current power supply. In other words, the output result of the eighth output terminal P8 controls the on/off of the contact switch of the third relay K3, and since the contact switch of the third relay K3 is disposed between the dc power source and the power grid 200 as shown in fig. 1, the on/off of the contact switch of the third relay K3 controls the power setting of the dc power source on the power grid 200, that is, the output result of the eighth output terminal P8 of the microprocessor controls the operating state of the power grid 200. As shown in fig. 1 of this embodiment, in this embodiment, a clock signal generator is further connected in series between the contact end b of the contact switch of the third relay K3 and the power grid 200, the clock signal generator is configured to generate a clock signal, a counter and a T flip-flop are sequentially connected in series between the clock signal generator and the power grid 200, an output end of the clock signal generator is connected to clock signal input ends of the clock signal generator and the power grid 200, so as to drive the clock signal input ends of the clock signal generator and the power grid 200 to operate, a level signal output by a setting feedback end of the counter (after the counter completes one counting, the setting feedback end outputs a level signal for feeding back to the counter itself, so that the counter restarts the counting) is simultaneously input to an input end of the T flip-flop, so that an output end of the T flip-flop is. That is, as shown in fig. 5, after the T flip-flop outputs one level signal, the power grid 200 operates, and after the T flip-flop outputs the next level signal, the power grid 200 stops operating, and so on. Meanwhile, since the connection of the clock signal generator to the dc power source is controlled by the third relay K3, the operation/stop of the entire line device from the clock signal generator to the power grid 200 can be controlled through the eighth output terminal P8 of the microprocessor.

Specifically, the common connection end of the T-trigger and the power grid 200 (i.e., the output end of the T-trigger) of the embodiment is further electrically connected to the base of a fifth triode Q5, the collector of the fifth triode is electrically connected to a direct-current power supply, a second relay K2 is connected in series between the emitter of the fifth triode and the ground, and a contact switch of a second relay K2 is connected between the output end of the third and-gate circuit B3 and the base of the fourth triode Q4. After the output level of the output end of the T trigger is amplified by the current of the fifth triode Q5, the conduction state between the output end of the third AND gate circuit B3 and the base electrode of the fourth triode Q4 is controlled by the second relay K2, so that the working state of the insecticidal sprayer 800 is controlled, namely when the output end of the T trigger outputs a high level, the contact switch of the third relay K3 is switched off, and when the output end of the T trigger outputs a low level, the contact switch of the third relay K3 is switched on. In a popular way, the control relationship among the sixth output end P6, the seventh output end P7 and the output end of the T trigger to the pesticide dosage indicator light, the third water pump and the power grid 200 is shown in fig. 4, as long as the T trigger outputs a high level, the power grid 200 starts to work, and meanwhile, the third water pump stops working no matter whether the third water pump is started to work or not originally; when the T flip-flop outputs a low level, the third water pump is controlled by the sixth output terminal P6 and the seventh output terminal P7 due to the closing of the contact switch of the third relay K3.

Specifically, the light control circuit 01 of this embodiment includes a photo resistor and an inverter, where the photo resistor changes the current in the light control circuit 01 by sensing the change of the intensity of the light reaching the outside, so as to change the input voltage of the inverter, and the output voltage of the inverter changes with the change of the input voltage. In this embodiment, the comparison voltage input to the comparator is obtained by dividing the voltage of the fifth resistor and the sixth resistor, the resistance values of the fifth resistor and the sixth resistor are changed according to the comparison voltage input requirement of the type adopted by the comparator, when the external illumination intensity is changed from weak to strong, the resistance value of the photoresistor is increased, the voltage of the reverse input end of the comparator is increased, when the voltage of the reverse input end is increased to be greater than the comparison voltage, the output of the comparator is turned from a high level to a low level, similarly, the comparison voltage is obtained according to the influence relationship between the input voltage of the reverse input end and the comparison voltage, when the illumination intensity is changed from strong to weak, the output of the inverter is turned from the low level to the high level, and thus the microprocessor obtains the illumination information (i.e., the information of day or night). The light control circuit 01 further includes a protection resistor (a second resistor R2, a third resistor R3, and a fourth resistor R4) and a protection capacitor (a fourth protection capacitor C4) for protecting the operation of the circuit.

The embodiment observes the external illumination intensity and the humidity through the light control circuit 01 and the humidity sensor, can realize the functions of closing the trap lamp 100 in the daytime and opening the trap lamp in the evening, can realize the functions of closing the power grid 200 in the rainy day and opening the power grid 200 in the sunny day, avoids the problem of electric energy waste caused by the luminous and non-functional effect of the trap lamp 100 in the daytime, and also avoids the possible electric shock hazard caused by the opening of the power grid 200 in the rainy day. The operation of the insect attracting sprayer 700 and the insect killing sprayer 800 is controlled by the remote server, when the trap lamp 100 or the power grid 200 cannot work due to external weather, the insect attracting sprayer 700 sprays a medicament capable of attracting insects, and the insect killing sprayer sprays a medicament capable of killing insects, so that the insect killing effect is achieved. The embodiment also has the advantages that the power grid 200 is intermittently started under the condition that the weather allows the power grid 200 to be started, so that the potential safety hazard problem caused by long-time starting of the power grid 200 is prevented.

Example two:

the embodiment discloses a pest control lamp, which adopts the pest control lamp system described in the first embodiment, and fig. 6 is a schematic structural diagram of the embodiment, the embodiment includes an energy-saving broadleaf trap lamp 100 and an electric network 200, the periphery of the pest control lamp surrounds a layer of electric network 200, when the energy-saving broadleaf trap lamp 100 is turned on, the pest traps the insects into the electric network 200, at this time, the electric network 200 is in an on state, and the insects are killed by electricity. The top of the energy-saving broad-spectrum insect trap lamp 100 is further provided with an insect attractant storage unit 400, an insecticide storage unit 500, an insect attractant spraying machine 700 and an insecticide spraying machine 800, wherein the insect attractant storage unit 400, the insecticide storage unit 500, the insect attractant spraying machine 700 and the insecticide spraying machine 800 are all fixedly arranged on the upper end face of the insect trap lamp 100; the insect-attracting sprayer 700 is connected with the insect-attracting agent storage unit 400, and acquires the insect-attracting agent from the insect-attracting agent storage unit 400 for spraying; the insecticide sprayer 800 is connected to the insecticide storage unit 500, and takes the insecticide from the insecticide storage unit 500 to spray. In the present embodiment, when the energy-saving broadleaf trap lamp 100 or the power grid 200 cannot be started due to weather (the relation between the start/stop of the energy-saving broadleaf trap lamp 100 and the power grid 200 and the weather is described in the first embodiment, and the present embodiment adopts the system or the internal circuit structure in the first embodiment, so the present embodiment is not described again), the insect-attracting agent in the insect-attracting agent storage unit 400 is sprayed by the insect-attracting spraying machine 700 to attract insects to approach, and after a period of time (the time interval is set by the remote server to the microprocessor), the insecticide in the insecticide storage unit 500 is sprayed, and the insects are killed accordingly.

Example three:

in this embodiment, on the basis of the second embodiment, the insect repellant storage unit 300 and the insect repellant sprayer 600 are additionally (fixedly) arranged on the top of the energy-saving broadleaf trap lamp 100, the insect repellant sprayer 600 is connected with the insect repellant storage unit 300, and the insect repellant is obtained from the insect repellant storage unit 300 and sprayed; under the setting of the remote server, when the plants need the insects to spread pollen but are not suitable for gathering excessive insects, the insects can be repelled seasonally without complete deinsectization.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

In summary, the above-mentioned embodiments are only preferred embodiments of the present invention, and all equivalent changes and modifications made in the claims of the present invention should be covered by the claims of the present invention.

Claims (10)

1. The deinsectization lamp system is characterized by comprising a microprocessor, a light-operated circuit, a humidity sensor, a trap lamp (100), a power grid (200), a first relay and a third relay, wherein the microprocessor comprises a plurality of input ends and a plurality of output ends;

the light control circuit is electrically connected with a first input end of the microprocessor, and converts the sensed illumination signal into an electric signal and inputs the electric signal to the microprocessor;

the humidity sensor is electrically connected with a third input end of the microprocessor, and converts the sensed humidity signal into an electric signal and inputs the electric signal to the microprocessor;

the trap lamp (100) is arranged at a first output end of the microprocessor, the microprocessor controls the output state of the first output end according to the output result of the light control circuit, and a level signal output by the first output end controls the on/off state of a first relay contact switch; controlling the connection state between the trap lamp (100) and a direct current power supply through the on/off state of the first relay contact, thereby controlling the trap lamp (100) to work;

the power grid (200) is arranged at an eighth output end of the microprocessor, the microprocessor controls the output state of the eighth output end according to the output result of the humidity sensor, and a level signal output by the eighth output end controls the on/off state of a contact switch of a third relay; and controlling the connection state between the power grid (200) and a direct current power supply through the on/off state of the third relay contact, thereby controlling the power grid (200) to work.

2. The insecticidal lamp system as in claim 1,

further comprises an insect repellent storage unit (300), an insect attractant storage unit (400) and an insecticide storage unit (500);

the insect repellent storage unit (300) is used for storing an insect repellent, the insect repellent storage unit (300) comprises a first gravity sensor, the first gravity sensor is electrically connected with a fourth input end of the microprocessor, and the first gravity sensor converts a gravity signal of the residual insect repellent in the insect repellent storage unit into an electric signal and inputs the electric signal to the microprocessor;

the insect attractant storage unit (400) is used for storing an insect attractant, the insect attractant storage unit (400) comprises a second gravity sensor, the second gravity sensor is electrically connected with a fifth input end of the microprocessor, and the second gravity sensor converts a residual insect attractant gravity signal in the insect attractant storage unit into an electric signal and inputs the electric signal to the microprocessor;

the pesticide storage unit (500) is used for storing pesticides, the pesticide storage unit (500) comprises a third gravity sensor, the third gravity sensor is electrically connected with a sixth input end of the microprocessor, and the third gravity sensor converts gravity signals of residual pesticides in the pesticide storage unit into electric signals and inputs the electric signals to the microprocessor.

3. The insecticidal lamp system as in claim 2,

the insect-repelling sprayer is characterized by further comprising an insect-repelling sprayer (600), an insect-attracting sprayer (700), an insect-killing sprayer (800), a remote server and an RS485 communication interface;

the insect expelling sprayer (600), the insect attracting sprayer (700) and the insect killing sprayer (800) are all arranged at the output end of the microprocessor and controlled to work by the output signal of the microprocessor;

the RS485 communication interface is electrically connected with a third output end of the microprocessor, and the remote server and the microprocessor transmit signals through the RS485 communication interface;

the RS485 communication interface is electrically connected with a third output end of the microprocessor, and the remote server and the microprocessor transmit signals through the RS485 communication interface; .

4. A deinsectization lamp system as defined in claim 3,

further comprising a repellent increment indicator lamp for indicating when the remaining repellent of the repellent storage unit (300) is below a minimum threshold value;

the third output end of the microprocessor is connected with the input end of the first NOT gate circuit and is also connected with the insect repellent increment indicator lamp; a second output end of the microprocessor and an output end of the first NOT gate circuit are jointly connected to two input ends of a first AND gate circuit, the output end of the first AND gate circuit is connected with a base electrode of a second triode, a collector electrode of the second triode is connected with a direct-current power supply, and an emitting electrode of the second triode is grounded; a first water pump is connected between the collector electrode of the second triode and the direct-current power supply in series, and the first water pump is electrically connected with the insect-repelling sprayer (600) and drives the insect-repelling sprayer (600) to spray; two sides of the first water pump are also connected with a first protection capacitor in parallel;

the output level of the second output end controls the starting of the insect-repellent sprayer (600), and the output level of the third output end controls the insect-repellent agent increment indicator lamp to light up; when the residual repellent agent in the repellent agent storage unit (300) is lower than a minimum threshold value, the repellent agent increment indicator lamp is turned on, and the repellent sprayer (600) stops operating.

5. The insecticidal lamp system as in claim 4,

further comprises an insect attractant increment indicator light for indicating that the residual insect attractant in the insect attractant storage unit (400) is lower than a minimum threshold value;

the fourth output end of the microprocessor is connected with the input end of the second NOT gate circuit and is also connected with the insect-attracting pesticide increment indicator lamp; a fifth output end of the microprocessor and an output end of the second NOT gate circuit are jointly connected to two input ends of a second AND gate circuit, an output end of the second AND gate circuit is connected with a base electrode of a third triode, a collector electrode of the third triode is connected with a direct-current power supply, and an emitting electrode of the third triode is grounded; a second water pump is connected between the collector of the third triode and the direct-current power supply in series, and the second water pump is electrically connected with the insect-attracting spraying machine (700) and drives the insect-attracting spraying machine (700) to spray; two sides of the second water pump are also connected with a second protection capacitor in parallel;

the output level of the fourth output end controls the starting of the insect-attracting sprayer (700), and the output level of the fifth output end controls the insect-attracting pesticide increment indicator lamp to light up; when the residual attractant in the attractant storage unit (400) is lower than the minimum threshold value, the attractant increment indicator lamp is turned on, and the attractant spraying machine (700) stops working.

6. A deinsectization lamp system as defined in claim 5,

further comprising an insecticide increment indicator light for indicating when the insecticide remaining in the insecticide storage unit (500) is below a minimum threshold;

a sixth output end of the microprocessor is connected with an input end of a third NOT gate circuit and is simultaneously connected with the pesticide increment indicator lamp; a seventh output end of the microprocessor and an output end of the third NOT gate circuit are jointly connected with two input ends of a third AND gate circuit, an output end of the third AND gate circuit is connected with a base electrode of a fourth triode, a collector electrode of the fourth triode is connected with a direct-current power supply, and an emitting electrode of the fourth triode is grounded; a third water pump is connected between the collector of the fourth triode and the direct-current power supply in series, and the third water pump is electrically connected with the insecticidal sprayer (800) and drives the insecticidal sprayer (800) to spray; both sides of the third water pump are also connected with a third protection capacitor in parallel;

the output level of the sixth output end controls the starting of the insecticidal sprayer (800), and the output level of the seventh output end controls the insecticide increment indicator lamp to light up; when the pesticide left in the pesticide storage unit (500) is lower than the lowest threshold value, the pesticide increment indicating lamp is lightened, and the pesticide spraying machine (800) stops working.

7. The insecticidal lamp system as in claim 6,

the eighth output end of the microprocessor is connected with the base electrode of a sixth triode, the collector electrode of the sixth triode is connected with a direct-current power supply, and the emitting electrode of the sixth triode is grounded;

a third relay is connected in series between the collector of the sixth triode and the direct-current power supply, and a contact switch of the third relay is connected between the direct-current power supply and the power grid (200);

when the level output by the eighth output end enables the third relay contact switch to be closed, the power grid (200) is conducted with a power supply and starts to work;

and when the level output by the eighth output end enables the third relay contact switch to be disconnected, the power grid (200) is disconnected from the power supply and stops working.

8. The insecticidal lamp system as in claim 7,

a clock signal generator, a counter and a T trigger are connected in series between the contact end of the third relay contact switch close to the power grid (200) and the power grid (200), the contact end of the third relay contact switch close to the power grid (200) is electrically connected with the clock generator, and the connection between the clock signal generator and a direct current power supply is controlled by the contact switch of the third relay;

the output end of the clock signal generator is connected with the clock signal input end of the counter and the clock signal input end of the T trigger;

the output of counter is connected the input of T flip-flop, the output of T flip-flop is connected electric wire netting (200), the output level signal control of T flip-flop electric wire netting (200) start work, electric wire netting (200) and DC power supply electric connection and from the operating voltage who pins DC power supply and acquire.

9. The insecticidal lamp system as in claim 8,

the common connection end of the T trigger and the power grid (200) is also electrically connected with the base electrode of a fifth triode, the collector electrode of the fifth triode is electrically connected with a direct-current power supply, a second relay is connected between the emitter electrode of the fifth triode and the ground in series, and a contact switch of the second relay is connected and arranged between the output end of the third AND gate circuit and the base electrode of the fourth triode;

after the output level of the output end of the T trigger passes through the current amplification effect of a fifth triode, the conduction state between the output end of the third AND gate circuit and the base electrode of the fourth triode is controlled through the second relay, so that the working state of the insecticidal sprayer (800) is controlled;

the light control circuit comprises a photoresistor and an inverter, wherein the photoresistor changes the current in the light control circuit by sensing the change of the intensity of illumination from outside to outside so as to change the input voltage of the inverter, and the output voltage of the inverter changes along with the change of the input voltage.

10. A pest control lamp, which adopts the pest control lamp system as claimed in claim 2-9, wherein the power grid (200) is enclosed outside the pest control lamp (100), and the pest control agent storage unit (300), the insect attractant storage unit (400), the pesticide storage unit (500), the pest control sprayer (600), the pest control sprayer (700) and the pest control sprayer (800) are all fixedly arranged on the upper end face of the pest control lamp (100);

the insect repellent sprayer (600) is connected with the insect repellent storage unit (300) and acquires the insect repellent from the insect repellent storage unit (300) to spray the insect repellent;

the insect-attracting sprayer (700) is connected with the insect-attracting agent storage unit (400), and acquires the insect-attracting agent from the insect-attracting agent storage unit (400) for spraying;

the pesticide spraying machine (800) is connected with the pesticide storage unit (500) and acquires the pesticide from the pesticide storage unit (500) for spraying.

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