CN216357330U - Low-power consumption termite and termite situation monitoring system - Google Patents

Abstract

The utility model discloses a low-power consumption termite and termite condition monitoring system, which comprises: a bait section including a trigger; a near field communication module connected to the trigger. The utility model solves the problem that termite condition signal transmission blind spots exist in termite monitoring and controlling areas.

Description

Low-power consumption termite and termite situation monitoring system

Technical Field

The utility model relates to the field of detection equipment, in particular to a low-power-consumption termite and ant condition monitoring system.

Background

With the continuous destruction of human activities, the invasion of termite habitats and global warming, termites have increasingly serious influence on human society and economy, and show a trend of increasing year by year. In response to termite damage, the most common method is to use a trap box to trap and kill termites.

The existing control technology adopts an intelligent termite monitoring and controlling method combined with the Internet of things, and can master termite situation information of termite invasion in real time. Meanwhile, the technical method also has the following disadvantages:

data transmission of the Internet of things is limited by the strength of local wireless signals, and when signal transmission blind spots exist in termite control areas, the termite situation monitoring information is lost, and a termite monitoring task cannot be normally completed. The problem of signal transmission blind spots is a ubiquitous phenomenon.

SUMMERY OF THE UTILITY MODEL

Therefore, the embodiment of the utility model provides a low-power consumption termite and termite condition monitoring system, which effectively solves the problem that signal transmission blind spots exist in termite control areas.

The utility model provides a low-power consumption termite and termite condition monitoring system, which comprises: a bait section including a trigger; a near field communication module connected to the trigger.

The technical effect achieved after the technical scheme is adopted is as follows: the near field communication module has no signal transmission blind spot in a local space range, so that the smooth transmission of ant feeling information can be ensured, and the loss of the ant feeling information is avoided; meanwhile, the near field communication module and the transponder are small in size, low in power consumption, convenient to install and low in construction difficulty, and therefore flexible combination according to actual installation scene requirements is facilitated.

In one embodiment of the present invention, the near field communication module is a 433M near field communication module or a 315M near field communication module.

The technical effect achieved after the technical scheme is adopted is as follows: the 433M near field communication module or the 315M near field communication module is convenient for covering a local range, and the problem of signal transmission blind spots is solved; meanwhile, the 433M near field communication module or the 315M near field communication module is convenient to install and maintain, can adapt to different installation scenes, and is low in cost.

In one embodiment of the utility model, the trigger is provided with a first switch, the first switch is a temperature control switch, and the temperature control switch is used for controlling the on-off of a circuit of the trigger according to the ambient temperature; and/or the near field communication module is provided with a first timing module and a second switch, and the first timing module controls the on-off of the second switch in a timing mode so as to control the on-off of a circuit of the near field communication module.

The technical effect achieved after the technical scheme is adopted is as follows: when the first switch is a temperature control switch, the trigger realizes the function of intermittent detection so as to achieve the effect of saving energy consumption; the near field communication module controls the on-off of the second switch through the timing module, so that the timing transmission of the coded data is realized, and the energy consumption is further reduced.

In one embodiment of the present invention, the low power consumption termite condition monitoring system further comprises: at least one repeater; monitoring a terminal; wherein, under the condition that the number of the repeaters is one, the repeaters are connected with the monitoring terminal; and when the number of the repeaters is multiple, at least one of the repeaters is connected with the monitoring terminal.

The technical effect achieved after the technical scheme is adopted is as follows: the transponder is used for forwarding the coded data of the ant condition information to the detection terminal, so that the ant condition information can be acquired in time; meanwhile, the repeaters can be cascaded, so that the transmission distance of the coded data is prolonged, the problem of signal transmission blind spots is thoroughly solved, and the remote detection is convenient.

In one embodiment of the utility model, a plurality of said transponders are communicatively connected between said near field communication module and said monitoring terminal.

The technical effect achieved after the technical scheme is adopted is as follows: the plurality of repeaters retransmit the coded data, so that the transmission distance of the coded data is further prolonged, and ant situation information can be conveniently acquired in a long distance.

In one embodiment of the utility model, the repeater includes: the signal receiving end is used for receiving the signal of the trigger; the decoding module is connected with the signal receiving end; the transmission module is connected with the decoding module and used for sending signals to the monitoring terminal; when the monitoring terminal is a local platform, the transmission module is one of the following: built-in 433M near field communication module or 315M near field communication module; when the monitoring terminal is a mobile terminal, a PC, a cloud platform or a monitoring device, at least one of the transmission modules is a GPRS communication module, an NB communication module or a 4G communication module, and the rest of the transmission modules are built-in 433M near field communication modules or 315M near field communication modules.

The technical effect achieved after the technical scheme is adopted is as follows: the signal receiving end is used for acquiring signals; encoded data such as a status code and an address code including ant feeling information; the decoding module acquires the coded data, filters the coded data of which the state codes do not accord with the preset state codes, and stores the coded data which accord with the preset state codes; the GPRS communication module, the NB communication module or the 4G communication module can be remotely connected with a mobile terminal, a PC, a cloud platform or monitoring equipment.

In an embodiment of the present invention, the repeater further includes a control module, and the control module is connected to the transmission module and is configured to control on/off of the transmission module.

The technical effect achieved after the technical scheme is adopted is as follows: the control module is used for realizing the timing transmission of the transmission module or the quantitative transmission of the coded data. For example, the control module controls the transmission module to work in a preset time period and transmits encoded data; or the coded data of the preset quantity is received and sent to the monitoring terminal at the same time, so that the running time of the transmission module is reduced, and the energy consumption is reduced.

In an embodiment of the present invention, the monitoring terminal is a mobile terminal, a PC, a cloud platform, or a local platform, or a monitoring device.

The technical effect achieved after the technical scheme is adopted is as follows: when the detection terminal is a mobile terminal, a PC (personal computer) or a cloud platform, the ant situation information can be conveniently transmitted in a long distance; when the detection terminal is a local platform or a monitoring device, ant situation information can be received in time without transmission through a public network, and a response is made.

In one embodiment of the utility model, the flip-flop comprises: a bait layer; the conductive piece is arranged in the bait layer or at least one side of the bait layer; the controller is electrically connected with the end part of the conductive piece; and the signal coding transmitting terminal is electrically connected with the controller and is used for sending signals to the near field communication module.

The technical effect achieved after the technical scheme is adopted is as follows: the bait layer is convenient for attracting termites to gnaw; the conductive piece and the bait layer are gnawed by termites together, so that the resistance of the conductive piece is changed; the controller detects and acquires the resistance of electrically conductive piece judges whether the resistance of electrically conductive piece changes, according to the judged result, through signal coding transmitting terminal sends ant condition information to near field communication module to in time let monitor terminal obtain ant condition information, be convenient for in time control ant condition.

In one embodiment of the utility model, the bait station further comprises: the trigger is arranged in the bait bin.

The technical effect achieved after the technical scheme is adopted is as follows: the bait bin accommodates the trigger, facilitating installation and replacement of the trigger.

In summary, the above embodiments of the present application may have one or more of the following advantages or benefits: i) the bait part attracts termites through the bait layer, the termites gnaw the bait layer and the conductive piece, the resistance of the conductive piece changes after the conductive piece is gnawed, and termite situation information can be obtained in time by detecting the resistance of the conductive piece; ii) the near field communication module can avoid signal transmission blind spots in a local space range, guarantee the smooth transmission of ant feeling information and avoid the loss of the ant feeling information; iii) the near field communication module and the transponder have small volume, low power consumption, convenient installation and low construction difficulty, and are convenient for flexibly replacing an installation scheme according to the actual installation scene requirement; iv) the transmission module of the repeater does not work at ordinary times, and when the preset time is reached or the ant situation information reaches the preset number, the control module controls the transmission module to transmit the ant situation information, so that the energy consumption can be reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic block diagram of a low-power termite/ant condition monitoring system according to an embodiment of the present invention.

Fig. 2 is a block schematic diagram of another low power termite condition monitoring system of fig. 1.

Fig. 3 is another connection diagram of the transponder, the near field communication module and the monitoring terminal in fig. 2.

Fig. 4 is a block diagram of the repeater of fig. 1.

Fig. 5 is a schematic block diagram of the repeater shown in fig. 4.

Fig. 6 is a block diagram of the flip-flop of fig. 1.

Fig. 7 is a schematic structural diagram of the flip-flop in fig. 1.

Fig. 8 is a schematic view showing the connection between the bait layer and the conductive layer in fig. 7.

Fig. 9 is a schematic structural view of the bait part in fig. 1.

Description of the main element symbols:

100 is a low-power consumption termite and termite condition monitoring system; 110 is a bait part; 111 is a trigger; 111a is a first switch; 111b is a bait layer; 111c is a conductive member; 111d is a first control module; 111e is a signal coding transmitting terminal; 112 is a first timing module; 113 is a second switch; 114 is a bait bin; 114a is a termite inlet; 120 is a near field communication module; 130 is a repeater; 131 is a signal receiving end; 132 is a decoding module; numeral 133 denotes a transmission module; 134 is a second control module; 134a is a power supply changeover switch; 134b is a second timing module; 134c is a memory; 140 is a monitoring terminal; numeral 141 denotes a display.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a low power consumption termite condition monitoring system 100 according to an embodiment of the present invention includes: bait 110 and near field communication module 120. Wherein, the bait part 110 comprises a trigger 111; the near field communication module 120 is connected to the flip-flop 111.

In the present embodiment, the bait part 110 is installed in an environment where termite conditions are likely to occur, for attracting termites, and the trigger 111 detects and transmits termite condition information to the near field communication module 120, thereby obtaining the termite condition information in time and facilitating the response. The near field communication module 120 can avoid the problem of signal transmission blind spots and completely cover the signal transmission blind spots in a local range, so that the ant condition information is smoothly transmitted.

In a specific embodiment, the near field communication module 120 is, for example, a 433M near field communication module or a 315M near field communication module. For example, the near field communication module 120 is, for example, a 433M near field communication module, and performs information transmission by using 433M communication technology, where the 433M communication technology can avoid a signal transmission blind spot problem; moreover, the 433M communication scheme is flexible and changeable, and can adapt to various application scenes; the 433M near field communication module is small in size and convenient to install, reduces construction difficulty, and reduces production cost and maintenance cost of equipment and communication cost of the Internet of things. Similarly, the 315M nfc module also has the above-mentioned effects, and is not described herein again.

In a specific embodiment, referring to fig. 1, the trigger 111 has a first switch 111a, and the first switch 111a is a temperature-controlled switch for controlling the on/off of the circuit of the trigger according to the ambient temperature. When the environment temperature is low, termites cannot move, and at the moment, the trigger is turned off through the temperature control switch, so that the power consumption of the trigger 111 can be reduced.

In another specific embodiment, referring to fig. 2, the near field communication module 120 has a first timing module 112 and a second switch 113, and the first timing module 112 controls on/off of the second switch 113 in a timing manner to control on/off of a circuit of the near field communication module 120. The near field communication module 120 intermittently acquires and transmits the ant situation information, so that the encoded data of the trigger 111 are transmitted at regular time, and the energy consumption is further reduced.

Preferably, the encoded data of the flip-flop 111 includes, for example, a status code and an address code. The status codes include, for example, a high level code OXF and a low level code OXE, the high level code OXF and the low level code OXE correspond to different termite situation information, for example, the high level code OXF indicates termite invasion, and the low level code OXE indicates no termite invasion. In addition, the address code realizes fixed address coding through a 1527 coding circuit.

Further, the high level code OXF and the low level code OXE are detected by the upper bias resistor R. The trigger 111 is prone to false alarm due to the environmental resistance, for example, the low-power consumption termite/ant condition monitoring system 100 is water inlet or the bait part 110 is affected with damp, and the upper bias resistor R adopts a smaller resistor, so that errors caused by the environmental resistance can be effectively reduced, and the false alarm rate of the trigger 111 is reduced. For example, the upper bias resistor R has a value of 2K Ω -10K Ω.

Further, the near field communication module 120 performs intermittent detection through the on/off of the second switch 113, which can effectively reduce the energy consumption of the upper bias resistor R. For example, the second switch 113 is turned on every 6h to 12h, for example 8 h; each time for 0.5s to 3s, for example 1 s.

In one particular embodiment, referring to fig. 1-2, a low power termite condition monitoring system 100, for example, further comprises: at least one repeater 130, and a monitoring terminal 140. When there is one repeater 130, the repeater 130 is connected to the monitoring terminal 140; in the case where there are a plurality of repeaters 130, at least one of the plurality of repeaters 130 is connected to the monitoring terminal 140. The repeater 130 forwards the ant condition information of the near field communication module 120 to the monitoring terminal 140, and the monitoring terminal 140 displays the ant condition information, so that the monitoring of the ant condition information is realized.

Preferably, referring to fig. 3, a plurality of repeaters 130 are communicatively connected between the near field communication module 120 and the monitoring terminal 140. In particular, n repeaters 130 are sequentially connected and sequentially repeat ant feeling information, where n is a constant, thereby extending a transmission distance.

Certainly, the repeater 130 may also receive ant condition information of a plurality of near field communication modules 120 or a plurality of repeaters 130, for example, the ant condition information of a plurality of near field communication modules 120 is transmitted to the same repeater 130 after passing through a plurality of repeaters 130 respectively; the monitoring terminal 140 may also receive ant condition information from a plurality of repeaters 130, which is not limited herein.

Preferably, the monitoring terminal 140 is, for example, a mobile terminal, a PC, a cloud platform, a local platform, or a monitoring device. When the monitoring terminal 140 is a mobile terminal, a PC or a cloud platform, the power consumption of the mobile terminal, the PC or the cloud platform can be reduced by the intermittent detection of the near field communication module 120; when the monitoring terminal 140 is a local platform, the communication cost of the internet of things can be saved.

In a specific embodiment, referring to fig. 4, the repeater 130 includes, for example: a signal receiving end 131, a decoding module 132 and a transmission module 133. The signal receiving terminal 131 is configured to receive a signal of the flip-flop 111; the decoding module 132 is connected to the signal receiving terminal 131, and is configured to decode the encoded information received by the signal receiving terminal 131; the transmission module 133 is connected to the decoding module 132, and is used for transmitting signals to the monitoring terminal 140. When a plurality of repeaters 130 are connected in sequence, the transmission module 133 may also be connected to the signal receiving terminal 131 of the next repeater 130.

Preferably, when the monitoring terminal 140 is a local platform, the transmission module 133 is one of the following: built-in 433M near field communication module or 315M near field communication module. For example, when there is one repeater 130, the repeater 130 is communicatively connected to the trigger 111 and transmits the trigger to the monitoring terminal 140 through the built-in 433M nfc module or 315M nfc module; when a plurality of repeaters 130 are provided, any one repeater 130 is in communication connection with the trigger 111, is in communication connection with the repeater 130 in sequence through a built-in 433M near field communication module or 315M near field communication module, and is finally transmitted to the monitoring terminal 140.

Preferably, when the monitoring terminal 140 is a mobile terminal, a PC, a cloud platform, or a monitoring device, at least one of the transmission modules 133 is a GPRS communication module, an NB communication module, or a 4G communication module, and the other transmission modules 133 are built-in 433M near field communication modules or 315M near field communication modules. For example, when there is one repeater 130, the repeater 130 is communicatively connected to the trigger 111 and transmits the data to the monitoring terminal 140 through a GPRS communication module, an NB communication module or a 4G communication module; when a plurality of repeaters 130 are provided, at least one repeater 130 is in communication connection with the trigger 111, is in communication connection with other repeaters 130 in sequence through built-in 433M near field communication modules and 315M near field communication modules, and is finally transmitted to the monitoring terminal through a GPRS communication module, an NB communication module or a 4G communication module. Of course, any one transponder 130 may receive the encoded data of multiple triggers 111 and/or multiple transponders 130 at the same time, and then transmit the encoded data to other transponders 130 through the built-in 433M near field communication module and 315M near field communication module.

Preferably, the operation time of the repeater 130 is longer than the operation time of the near field communication module 120 and covers the operation time of the near field communication module 120, so that the repeater 130 can receive all the encoded information transmitted from the near field communication module 120.

Preferably, the repeater 130 is powered by, for example, 3 18650/2200MAH batteries in parallel, and is provided with an external 5.25V/2.5A or 5V/2A charging waterproof interface, which is adapted to a 220V/5V, 2A power supply of a 10W solar battery, but not limited thereto.

In a specific embodiment, the repeater 130 further includes, for example: a second control module 134. The second control module 134 is connected to the transmission module 133 and configured to control on/off of the transmission module 133, so as to achieve a timing or quantitative operation effect of the transmission module 133, and reduce energy consumption of the transmission module 133. For example, the transmission module 133 sends all signals to the monitoring terminal 140 every 8h to 16h, for example, 12 h; alternatively, the transmission module 133 transmits all signals to the monitoring terminal 140 after receiving 10 to 30 signals, for example, 20 or 30 signals.

Preferably, referring to fig. 5, the second control module 134 includes, for example, a YX8951 chip having functions of solar charging management, light control management, and over-discharge protection. The second control module 134 includes a power switch 134a, and the power switch 134a is connected 18650/2200 to the positive battery terminal of the MAH battery. The power supply changeover switch 134a includes, for example: the power supply manual switching gear shifting, the power supply automatic switching gear shifting and the idle running shutdown gear. When the power supply switching switch 134a is in the state of manual switching and gear shifting of the power supply, the power supply switching switch can be switched to 18650/2200MAH battery for direct power supply; when the power supply switching switch 134a is in the state of automatic switching of the power supply, the power supply can be switched to light-operated 18650/2200MAH battery power supply. For example, the second control module 134 is charged only by sunlight during the day and is directly powered by the 18650/2200MAH battery during the night.

In an embodiment, the decoding module 132 is independently inserted into a motherboard of the transponder 130, the decoding module 132 and the motherboard are fixed by sealing, and the antenna of the decoding module 132 may be an external antenna, which is not limited herein.

Preferably, the decoding module 132 can receive data by using LR45B, and is decoded by an STC8G1K08-SOP8 single chip microcomputer, which is not limited herein. The decoding module 132 is used for decoding through the STC8G1K08-SOP8 single chip microcomputer, so that the state code and the address code of the ant feeling information can be conveniently converted into hexadecimal data, the hexadecimal data are transmitted to the monitoring terminal 140 to be displayed, and the ant feeling information can be conveniently checked.

In a specific embodiment, the second control module 134 further includes, for example, an MCU (STM32F030), and the power supply of the transmission module 133 is implemented by a MOS transistor controlled by the MCU.

Preferably, the MCU is configured to filter the received data, i.e. filter the data with status codes other than 0X0F and 0X 0E. The MCU is provided with a second timing module 134b and a memory 134c, stores the data with the state codes of 0X0F and 0X0E in the memory 134c, but does not store the same data within the set time; meanwhile, when the MCU is turned on, the second timing module 134b performs timing T1.

Further, when the data amount in the memory 134c reaches a preset amount, for example, 30, at this time, the MCU turns on the MOS transistors, the MOS transistors supply power to the transmission module 133 to enable the transmission module 133 to operate, the transmission module 133 sequentially transmits all the data to the monitoring terminal 140, and the second timing module 134b performs timing T2; when the data transmission is finished, or T2 reaches a preset time, for example, 5 minutes, the MCU turns off the MOS transistor, turns off the transmission module 133, and clears the data in the memory 134c, and the operation is repeated.

Further, when T1 reaches 9 hours and the MCU does not turn on the MOS transistor within the time T1, the MCU turns on the MOS transistor at this time, and the second timing module 134b starts to time T2, and sequentially transmits all data to the monitor terminal 140; when the data transmission is finished, or T2 reaches a preset time, for example, 5 minutes, the MCU turns off the MOS transistor, turns off the transmission module 133, and clears the data in the memory 134c, and the operation is repeated.

In one particular embodiment, the monitor terminal 140 has a display 141. When the monitoring terminal 140 is powered on, if no signal is received, words such as no signal are displayed, which is not limited herein; if the signal is received, the state code, the address code and the serial number of the signal are displayed.

Further, when the monitoring terminal 140 receives an abnormal signal indicating that the termite invades, the monitoring terminal may display an alarm message intermittently, drive a buzzer to sound, or drive an LED lamp to blink, which is not limited herein.

In a particular embodiment, referring to fig. 6-8, flip-flop 111 comprises, for example: bait layer 111b, conductive piece 111c, second control module 111d and signal code transmitting end 111 e. Wherein, the conductive piece 111c is arranged in the bait layer 111b or at least one side of the bait layer 111 b; the second control module 111d is electrically connected to the end of the conductive member 111 c; the signal encoding transmitting terminal 111e is electrically connected to the second control module 111d, and is configured to send a signal to the near field communication module 120.

Preferably, the bait layer 111b is made of bait wood, for example, and the conductive member 111c is made of graphite, for example, without limitation.

Further, the conductive member 111c is, for example, a sheet structure, and is sandwiched between the plurality of bait layers 111b, or connected to one side of the bait layers 111 b; the conductive member 111c may also be a conductive paint, attached to the inner or outer side of the bait layer 111 b.

Still further, both ends of the conductive member 111c may be connected to a wire through a fastening member, and the wire is connected to the second control module 111d, wherein the fastening member is a drawing pin or a rivet, which is not limited herein. Of course, both ends of the conductive member 111c may also be fixed to the conductive wires by gluing or welding, and the utility model is not limited herein.

In a particular embodiment, the bait station 110 further includes: a bait chamber 114, in which the trigger 111 is located. Wherein the bait cartridge 114 has at least one termite inlet 114a, termites being able to enter the bait cartridge 114 from the termite inlet 114a to effect the trigger 111, e.g., the bait cartridge 114 is a grid structure.

Further, a plurality of triggers 111 can be accommodated in the bait chamber 114, so that the installation and replacement of the triggers 111 are facilitated, and the termite monitoring effect is improved.

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 such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A low-power consumption termite/ant condition monitoring system, comprising:

a bait section including a trigger;

a near field communication module connected to the trigger.

2. The low power termite condition monitoring system set forth in claim 1 wherein said near field communication module is a 433M near field communication module or a 315M near field communication module.

3. The low power consumption termite condition monitoring system set forth in claim 1 wherein,

the trigger is provided with a first switch which is a temperature control switch, and the temperature control switch is used for controlling the on-off of a circuit of the trigger according to the ambient temperature;

and/or the near field communication module is provided with a first timing module and a second switch, and the first timing module controls the on-off of the second switch in a timing mode so as to control the on-off of a circuit of the near field communication module.

4. The low power consumption termite condition monitoring system set forth in claim 1 further comprising:

at least one repeater;

monitoring a terminal;

wherein, under the condition that the number of the repeaters is one, the repeaters are connected with the monitoring terminal; and when the number of the repeaters is multiple, at least one of the repeaters is connected with the monitoring terminal.

5. The low power termite condition monitoring system set forth in claim 4 wherein a plurality of said transponders are communicatively connected between said near field communication module and said monitoring terminal.

6. The low-power consumption termite and ant condition monitoring system according to claim 4 wherein the monitoring terminal is a mobile terminal, a PC, a cloud platform, a local platform or a monitoring device.

7. The low power termite condition monitoring system set forth in claim 6 wherein said transponder includes:

the signal receiving end is used for receiving the signal of the trigger;

the decoding module is connected with the signal receiving end;

the transmission module is connected with the decoding module and used for sending signals to the monitoring terminal;

when the monitoring terminal is a local platform, the transmission module is one of the following: built-in 433M near field communication module or 315M near field communication module;

when the monitoring terminal is a mobile terminal, a PC, a cloud platform or a monitoring device, at least one of the transmission modules is a GPRS communication module, an NB communication module or a 4G communication module, and the rest of the transmission modules are built-in 433M near field communication modules and 315M near field communication modules.

8. The low power termite condition monitoring system set forth in claim 7 wherein said transponder further comprises: and the second control module is connected with the transmission module and is used for controlling the on-off of the transmission module.

9. The low power termite condition monitoring system set forth in any one of claims 1-8 wherein said trigger comprises:

a bait layer;

the conductive piece is arranged in the bait layer or at least one side of the bait layer;

the first control module is electrically connected with the end part of the conductive piece;

and the signal coding transmitting terminal is electrically connected with the first control module and is used for sending a coding signal to the near field communication module.

10. The low power consumption termite/ant condition monitoring system according to any one of claims 1 to 8 wherein,

bait portion still includes:

the trigger is arranged in the bait bin.

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