CN115500332B

CN115500332B - Induction type termite control device and induction control method thereof

Info

Publication number: CN115500332B
Application number: CN202211397927.4A
Authority: CN
Inventors: 张云
Original assignee: Wuxi Institute of Commerce
Current assignee: Wuxi Institute of Commerce
Priority date: 2022-11-09
Filing date: 2022-11-09
Publication date: 2023-09-05
Anticipated expiration: 2042-11-09
Also published as: CN115500332A

Abstract

The invention discloses an induction termite control device, which comprises a shell, an inner core and a driving device, wherein the inner core is movably sleeved in the shell, a bait bin is arranged in the inner core, and bait bin is filled with bait for attracting; a plurality of termite entering channels are formed on the combined body of the outer shell and the inner core, and a termite escaping part is arranged at one end of the combined body formed by the outer shell and the inner core; when a plurality of termite entering channels on the combination body formed by the outer shell and the inner core are opened, the termite escaping part is in a closed state, so that the termite escaping part can play a cumulative attracting role on termites, and then the termites adhered with the poison bait can be repelled at one time, so that the effects of larger trapping and killing dosage and complete trapping and killing are achieved.

Description

Induction type termite control device and induction control method thereof

Technical Field

The invention relates to the termite control field.

Background

Trapping termite control has been widely used in construction, wood and other industries; the principle of trapping termites is that termites are adhered to the bait, termites contacted with the bait do not die immediately, and when the termites return to the termite holes, termites can contact each other, eat the bait separately, and clean the bodies of the silkworm feeding bodies after death, so that the bait is transmitted to the whole termite colony, and the termite colony is killed; however, to achieve the best effect, a large enough number of termites are required to be attracted and accumulated at one time, and the bodies of the large enough termites carry the toxicant in the same time period to achieve the perfect and thorough trapping effect; the specific formulation of the bait powder can refer to the existing patent CN200510019709.7 termite attractant and CN201510029227.3, namely a termite pheromone attractant and a termite attractant adopting the attractant;

in the existing trapping and killing modes, toxic agents are directly added into the attractants, all termites cannot be attracted at one time in the attracting process, a certain time accumulating process is needed, the termites contacted with the bait do not die immediately, but die quickly, the quantity of the termites attracted by the attracting device cannot be accumulated, and a small quantity of termites run back into the nest to cause dilution of the colony poisoning process, so that the termite nest cannot be thoroughly destroyed; meanwhile, the trapping and killing drugs of the existing termite trapping and killing device are exposed to the air, and the trapping and killing drugs can deteriorate due to damp or mildew for a long time, so that the trapping and killing effect of the trapping and killing drugs is not ideal or the trapping and killing effect is lost.

Disclosure of Invention

The invention aims to: in order to overcome the defects in the prior art, the invention provides the induced termite control device and the induced termite control method, which can play a cumulative attracting role on termites, and then can drive ants adhered with poison bait at one time, so that the effects of larger trapping and killing dosage and complete killing are achieved.

The technical scheme is as follows: in order to achieve the aim, the induction termite control device comprises a shell, an inner core and a driving device, wherein the inner core is movably sleeved in the shell, a bait bin is arranged in the inner core, and bait is filled in the bait bin; a plurality of termite entering channels are formed on the combined body of the outer shell and the inner core, and a termite escaping part is arranged at one end of the combined body formed by the outer shell and the inner core; when a plurality of termite entering channels on the combined body formed by the outer shell and the inner core are opened, the termite escaping part is in a closed state; the driving device can drive the inner core to displace relative to the outer shell, so that a plurality of termite entering channels formed on the combination of the outer shell and the inner core are closed, and the termite escaping part is changed from a closed state to an open state; the termite escaping part is provided with a poison bait on an escaping path.

Further, one end of the bait bin, which is far away from the termite escape part, is provided with an oscillation driving unit.

Further, the outer shell comprises an arc outer tube body with both ends facing upwards, and an outer tube inner channel penetrating along an arc path is arranged in the arc outer tube body;

the inner core comprises an arc inner pipe body with both ends facing upwards, the arc inner pipe body is movably arranged in the outer pipe inner channel, and the outer wall of the arc inner pipe body is in sliding fit with the inner wall of the arc outer pipe body; the bait bin is an arc bait channel in the arc inner tube; the side wall of the circular arc inner pipe body is provided with a plurality of a hollowed holes which are arrayed equidistantly along the circular arc path of the circular arc inner pipe body; the side wall of the arc outer tube body is provided with a plurality of b hollowed holes which are arrayed equidistantly along the arc path of the side wall; the a hollow holes are respectively communicated with the b hollow holes in a superposition way, and the a hollow holes and the b hollow holes which are communicated in a superposition way form termite entering channels.

Further, an end sealing wall is arranged at the clockwise end of the circular arc inner pipe body in a sealing manner, and a pressure plate is integrally plugged at the anticlockwise end of the circular arc inner pipe body; an electric vibrator is arranged at the pressure plate at the anticlockwise end of the arc bait channel.

Further, the termite escaping part comprises an escaping funnel integrally connected to the clockwise end of the circular arc outer pipe body, a funnel cavity is arranged in the escaping funnel, an inclined escaping ring disc is integrally arranged at the outer edge of the upper end of the escaping funnel, a ring of poison bait ring grooves are arranged on the upper surface of the escaping ring disc, a sealing cover is arranged on the upper surface of the escaping ring disc in a parallel cover mode, and under the cover of the sealing cover, independent cavities are formed by the poison bait ring grooves and the funnel cavity; the poison bait ring groove is filled with poison bait powder;

the end sealing wall of the circular arc inner pipe body is fixedly connected with the sealing cover through a linkage rod; the driving device comprises a vertical electric telescopic device, the electric telescopic device is fixedly connected with the arc outer pipe body through a bracket, and the top of the tail end of a telescopic rod of the electric telescopic device contacts and presses the upper surface of the pressure plate;

taking one a hollow Kong Ji at the most clockwise end of the circular arc path of the circular arc inner pipe body in the plurality of a hollow holes as an escape port; the downward extension of telescopic link promotes the pressure disk to make circular arc inner tube body along self circular arc route clockwise displacement a section of distance in circular arc outer tube body, until the pressure disk contacts the anticlockwise end of circular arc outer tube body, a plurality of a fretwork holes become mutually staggered from original coincidence intercommunication state with a plurality of b fretwork holes respectively, except the escape mouth, all remaining a fretwork holes all are by the inner wall shutoff of circular arc outer tube body, the escape mouth rises to the intercommunication funnel chamber by original and b fretwork hole intercommunication, the closing cap is separated with the escape ring dish under the linkage of gangbar.

Further, the device also comprises a tension spring, one end of the tension spring is fixedly connected with the pressure plate, the tension spring forms upward tension to the pressure plate, and when the telescopic rod is retracted upwards, the tension spring pulls the pressure plate upwards, so that the arc inner pipe body moves anticlockwise in the arc outer pipe body along the arc path of the tension spring.

Further, when the arc outer pipe body is buried under the ground, the lower end of the inclined plane of the escape ring disc just contacts the ground.

Furthermore, the arc bait channel is filled with a plurality of pine blocks, each pine block is soaked with a nontoxic termite attractant, and gaps between every two adjacent pine blocks are enough for termites to walk freely in the arc bait channel;

further, termite trapping and killing control method comprises the following steps:

burying the circular arc outer pipe body with soft soil at the bottom surface of the area where termites frequently go out or suspected, and enabling the lower end of the inclined surface of the escape ring disc to just contact the ground; when the set time is reached, the electric telescopic device and the electric vibrator are started in sequence, and the electric telescopic device started firstly enables the telescopic rod to extend downwards to push the pressure plate, so that the circular arc inner pipe body moves clockwise for a certain distance in the circular arc outer pipe body along the circular arc path of the electric telescopic device until the pressure plate contacts the anticlockwise end of the circular arc outer pipe body; and then the electric vibrator generates vibration at the anticlockwise end of the arc bait channel after being electrified.

The beneficial effects are that: the attractant is nontoxic, so that the attractant has an accumulation effect, and more termites can be accumulated and enter the device; in the process of unified driving, the a hollow holes and a plurality of b hollow holes are respectively staggered from the original coincident communication state in the unified driving process, all the rest a hollow holes except for escape openings are blocked by the inner wall of the circular arc outer tube body, and the escape openings are communicated with the b hollow holes and rise to a communicating funnel cavity; the termites in the arc bait channel are driven clockwise towards the arc bait channel after the electric vibrator is electrified, and only the escape ports can escape from the arc bait channel clockwise at the moment, so that the termites in the arc bait channel can escape to the funnel cavity outwards through only one escape port when the electric vibrator is driven down, the termites escaping to the funnel cavity are enabled to climb up to the upper surface of the escape ring disc along the inner wall of the escape funnel under the action of vibration, and finally climb down to the ground along the inclined plane of the upper surface of the escape ring disc so as to leave the escape ring disc, and as the escape ring disc is provided with a whole ring of poison bait ring grooves on the upper surface, the termites which want to leave the escape ring disc need to climb over the poison bait ring grooves once, and all the termites which leave the escape ring disc and reach the ground can at least climb over the poison bait ring grooves once, so that a certain amount of poison bait is adhered to the termites which climb up to the escape ring disc; based on the driving process, all termites escaping from the device carry the poison bait, the termites contacting the poison bait cannot die immediately, and when the termites escaping from the device return to the termite holes, the termites can contact each other, eat the poison bait separately, clean the silkworm food corpse after death, so that the poison bait is spread to the whole termite colony, and the termite colony is killed.

Drawings

FIG. 1 is a schematic diagram of the whole structure of the device in the initial state;

FIG. 2 is a cross-sectional view of the device in an initial state;

FIG. 3 is a schematic illustration of the closure being separated from the escape ring disc under the linkage of the linkage rod;

FIG. 4 is a schematic diagram showing the escape opening rising to the communicating funnel cavity from the original communicating with the hollow hole b;

FIG. 5 is a schematic diagram of the explosive structure of the device;

fig. 6 is a cross-sectional view of fig. 5.

Detailed Description

The invention will be further described with reference to the accompanying drawings as an inducible termite control device; the general structure and scheme of the package are as follows:

the bait box comprises a shell, an inner core and a driving device, wherein the inner core is movably sleeved in the shell, a bait box is arranged in the inner core, and bait is filled in the bait box; a plurality of termite entering channels are formed on the combined body of the outer shell and the inner core, and a termite escaping part is arranged at one end of the combined body formed by the outer shell and the inner core; when a plurality of termite entering channels on the combined body formed by the outer shell and the inner core are opened, the termite escaping part is in a closed state; the driving device can drive the inner core to displace relative to the outer shell, so that a plurality of termite entering channels formed on the combination of the outer shell and the inner core are closed, and the termite escaping part is changed from a closed state to an open state; the termite escaping part is provided with a poison bait on an escaping path; an oscillation driving unit is arranged at one end of the termite bin, which is far away from the termite escape part; the specific structure of the above general scheme is described in detail later;

the specific structure and scheme of the scheme are shown in fig. 1, 2, 5 and 6:

the outer shell comprises an arc outer pipe body 5 with both ends facing upwards, and an outer pipe inner channel 21 penetrating along an arc path is arranged in the arc outer pipe body 5; the inner core comprises an arc inner pipe body 6 with both ends facing upwards, the arc inner pipe body 6 moves in the outer pipe inner channel 21, and the outer wall of the arc inner pipe body 6 is in sliding fit with the inner wall of the arc outer pipe body 5;

as shown in fig. 2, the bait bin is an arc bait channel 20 in the arc inner pipe body 6, a plurality of pine wood blocks 9 are filled in the arc bait channel 20, termite attractants are soaked in each pine wood block 9, and note that the termite attractants soaked in the pine wood blocks 9 are nontoxic and only have the purpose of attracting, so that termites accumulate in the arc bait channel 20 without poisoning, and gaps between adjacent pine wood blocks 9 are enough for the termites to walk in the arc bait channel 20 at will;

a plurality of a hollowed holes 23 are arranged on the side wall of the circular arc inner pipe body 6 in an equidistant array along the circular arc path of the side wall; a plurality of b hollowed holes 22 are arranged on the side wall of the arc outer tube body 5 in an equidistant array along the arc path of the side wall; the a hollow holes 23 are respectively overlapped and communicated with the b hollow holes 22, and the a hollow holes 23 and the b hollow holes 22 which are mutually overlapped and communicated form termite entering channels;

as shown in fig. 1, the counterclockwise end of the circular arc inner tube body 6 is higher than the counterclockwise end of the circular arc outer tube body 5, and a section of the circular arc inner tube body 6, whose counterclockwise end is higher than the counterclockwise end of the circular arc outer tube body 5, is denoted as an exposed section 6.1 of the circular arc inner tube body; an end sealing wall 13 is arranged at the clockwise end of the circular arc inner pipe body 6 in a sealing way, and a pressure plate 12 is arranged at the anticlockwise end of the circular arc inner pipe body 6 in an integrated sealing way; an electric vibrator 10 is arranged at the pressure plate 12 at the anticlockwise end of the arc bait channel 20, and after the electric vibrator 10 is electrified, vibration is generated at the anticlockwise end of the arc bait channel 20, so that termites in the arc bait channel 20 are driven clockwise towards the arc bait channel 20;

the termite escaping part comprises an escaping funnel 3 integrally connected to the clockwise end of an arc outer pipe body 5, a funnel cavity 4 is arranged in the escaping funnel 3, an inclined escaping ring disk 1 is integrally arranged at the outer edge of the upper end of the escaping funnel 3, a circle of poison bait ring grooves 2 are arranged on the upper surface of the escaping ring disk 1, a sealing cover 15 is arranged on the upper surface of the escaping ring disk 1 in a parallel cover manner, and under the cover of the sealing cover 15, independent cavities are formed by the poison bait ring grooves 2 and the funnel cavity 4; the bait ring groove 2 is filled with bait powder, the formula of the bait powder can refer to the prior patent CN200510019709.7 termite attractant, CN201510029227.3 termite pheromone attractant and termite attractant adopting the attractant, and the termite attractant is characterized in that termites contacting with the bait do not die immediately, and when the termites escaping from the device return to the termite holes, the termites contact each other, eat the bait separately, and clean the silkworm bodies after death, so that the bait is spread to the whole termite colony, and the termite colony is killed;

the end sealing wall 13 of the circular arc inner pipe body 6 is fixedly connected with the sealing cover 15 through the linkage rod 14; the driving device comprises a vertical electric telescopic device 18, the electric telescopic device 18 is fixedly connected with the arc outer tube body 5 through a bracket 16, and the top of the tail end of a telescopic rod 19 of the electric telescopic device 18 contacts and presses the upper surface of the pressure plate 12;

as in fig. 3 and 4; one a hollow hole 23 at the most clockwise end along the circular path of the circular-arc inner pipe body 6 in the plurality of a hollow holes 23 is marked as an escape opening 23.1; the downward extension of the telescopic rod 19 pushes the pressure plate 12, so that the circular arc inner pipe body 6 moves clockwise in the circular arc outer pipe body 5 for a certain distance along the circular arc path of the telescopic rod until the pressure plate 12 contacts the anticlockwise end of the circular arc outer pipe body 5, at the moment, a plurality of a hollowed holes 23 and a plurality of b hollowed holes 22 are respectively changed from the original coincident communication state to be staggered with each other, as shown in fig. 4, all the rest a hollowed holes 23 except an escape opening 23.1 are blocked by the inner wall of the circular arc outer pipe body 5, the escape opening 23.1 is communicated with the b hollowed holes 22 from the original communication state to the communication funnel cavity 4, and the sealing cover 15 is separated from the escape ring 1 under the linkage of the linkage rod 14;

the device also comprises a tension spring 17, one end of the tension spring 17 is fixedly connected with the pressure plate 12, the tension spring 17 forms upward tension on the pressure plate 12, and when the telescopic rod 19 retracts upwards, the tension spring 17 pulls the pressure plate 12 upwards to enable the arc inner pipe body 6 to displace anticlockwise in the arc outer pipe body 5 along the arc path of the tension spring; when the arc outer pipe body 5 is buried under the ground, the lower end of the inclined plane of the escape ring disk 1 just contacts the ground, so that termites on the escape ring disk 1 can more smoothly escape to the ground; the lower side surface of the arc outer tube body 5 is fixedly provided with a plurality of soil-inserting spines 8 with tips facing downwards; plays a role in stabilizing and stabilizing.

The poisoning method comprises the following steps:

initial state setting:

under the elastic tension transmission of the tension spring 17, the sealing cover 15 is tightly covered on the upper surface of the escape ring disc 1, and under the covering of the sealing cover 15, the poison bait ring groove 2 and the funnel cavity 4 form independent cavities, so that the poison bait powder filled in the poison bait ring groove 2 is prevented from being blown away by wind and rain for a long time to lose efficacy; meanwhile, in an initial state, a plurality of a hollow holes 23 are respectively overlapped and communicated with a plurality of b hollow holes 22, and the a hollow holes 23 and the b hollow holes 22 which are mutually overlapped and communicated form termite entering channels;

the arrangement process comprises the following steps:

digging a soil pit with proper size on the bottom surface of a region where termites frequently go out or suspected, inserting a soil insertion spike 8 at the lower end of an arc outer pipe body 5 below the soil pit, completely fixing the device, lightly burying the arc outer pipe body 5 by using loose soil, and enabling the lower end of an inclined plane of an escape ring disc 1 to just contact the ground when the arc outer pipe body 5 is completely buried below the ground;

the trapping and killing process comprises the following steps:

over time, as in fig. 1 and 3; under the temptation of the termites nearby on the baits on the pine wood blocks 9 in the circular arc bait channel 20, the termites enter the circular arc bait channel 20 to gnaw and nest through the termite entering channels formed by the a hollow holes 23 and the b hollow holes 22 which are mutually overlapped and communicated, and more termites enter the circular arc bait channel 20 along with the accumulation of time; when the set time is reached, the electric telescopic device 18 and the electric vibrator 10 are started successively, the started electric telescopic device 18 enables the telescopic rod 19 to extend downwards to push the pressure plate 12, so that the circular arc inner pipe body 6 moves clockwise for a distance in the circular arc outer pipe body 5 along a circular arc path of the electric telescopic device until the pressure plate 12 contacts the anticlockwise end of the circular arc outer pipe body 5, at the moment, all the a hollow holes 23 and the b hollow holes 22 are respectively staggered from the original coincident communication state, all the rest of the a hollow holes 23 except the escape openings 23.1 are blocked by the inner wall of the circular arc outer pipe body 5, as shown in fig. 4, the escape openings 23.1 are communicated with the b hollow holes 22 originally and are lifted to the communicated funnel cavity 4, as shown in fig. 3, and the sealing cover 15 is separated from the escape ring 1 under the linkage of the linkage rod 14; then, after the electric vibrator 10 is electrified, high-frequency vibration is generated at the anticlockwise end of the circular arc bait channel 20, termites in the circular arc bait channel 20 are further driven clockwise towards the circular arc bait channel 20, and only the escape ports 23.1 can escape from the circular arc bait channel 20 at the moment, so that the termites originally in the circular arc bait channel 20 can escape to the funnel cavity 4 through only one escape port 23.1 under the driving of the electric vibrator 10, then the termites escaping into the funnel cavity 4 are driven by vibration to climb up to the upper surface of the escape ring disc 1 along the inner wall of the escape funnel 3, and finally climb down to the ground along the inclined plane of the upper surface of the escape ring disc 1 under the trend of vibration so as to leave the escape ring disc 1; based on the driving process, all termites escaping from the device carry poison baits, termites contacting the poison baits cannot die immediately, and when the termites escaping from the device return to the termite holes, termites can contact each other, feed the poison baits separately, clean the silkworm food corpses after death, so that the poison baits are spread to the whole termite colony, and the termite colony is killed;

the electric vibrator 10 is suspended after being driven for a preset time, then the electric vibrator 18 is controlled to enable the telescopic rod 19 to retract upwards, the sealing cover 15 is tightly covered on the upper surface of the escape ring disc 1 again under the transmission of elastic tension of the tension spring 17, the electric vibrator is restored to an initial state and enters an attracting state again, and the electric vibrator 10 and the electric vibrator 18 are started again after the preset time is reached, so that a second attracting and killing effect is achieved, and a more thorough attracting and killing effect is achieved.

The foregoing is only a preferred embodiment of the invention, it being noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the present invention, and such modifications and adaptations are intended to be comprehended within the scope of the invention.

Claims

1. An inducible termite control device, characterized in that: the bait box comprises a shell, an inner core and a driving device, wherein the inner core is movably sleeved in the shell, a bait box is arranged in the inner core, and bait is filled in the bait box; a plurality of termite entering channels are formed on the combined body of the outer shell and the inner core, and a termite escaping part is arranged at one end of the combined body formed by the outer shell and the inner core; when a plurality of termite entering channels on the combined body formed by the outer shell and the inner core are opened, the termite escaping part is in a closed state; the driving device can drive the inner core to displace relative to the outer shell, so that a plurality of termite entering channels formed on the combination of the outer shell and the inner core are closed, and termite escaping parts are changed from a closed state to an open state; a poisonous bait is arranged on the escape path of the termite escaping part;

an oscillation driving unit is arranged at one end of the bait bin far away from the termite escape part;

the shell comprises an arc outer pipe body (5) with both ends facing upwards, and an outer pipe inner channel (21) penetrating along an arc path is arranged in the arc outer pipe body (5);

the inner core comprises an arc inner pipe body (6) with both ends facing upwards, the arc inner pipe body (6) is movably arranged in an outer pipe inner channel (21), and the outer wall of the arc inner pipe body (6) is in sliding fit with the inner wall of the arc outer pipe body (5); the bait bin is an arc bait channel (20) in the arc inner pipe body (6); a plurality of hollow holes (23) are arranged on the side wall of the circular arc inner pipe body (6) along the circular arc path of the circular arc inner pipe body at equal intervals; a plurality of b hollowed holes (22) are arranged on the side wall of the arc outer tube body (5) along the arc path of the side wall at equal intervals; the a hollowed holes (23) are respectively overlapped and communicated with the b hollowed holes (22), and the a hollowed holes (23) and the b hollowed holes (22) which are mutually overlapped and communicated form the termite entering channel;

an end sealing wall (13) is arranged at the clockwise end of the circular arc inner pipe body (6) in a sealing way, and a pressure plate (12) is arranged at the anticlockwise end of the circular arc inner pipe body (6) in an integrated sealing way; an electric vibrator (10) is arranged at a pressure plate (12) at the anticlockwise end of the arc bait channel (20);

the termite escaping part comprises an escaping funnel (3) which is integrally communicated and connected to the clockwise end of an arc outer pipe body (5), a funnel cavity (4) is arranged in the escaping funnel (3), an oblique escaping ring disc (1) is integrally arranged at the outer edge of the upper end of the escaping funnel (3), a ring of poison bait ring groove (2) is arranged on the upper surface of the escaping ring disc (1), a sealing cover (15) is arranged on the upper surface of the escaping ring disc (1) in a parallel cover mode, and under the condition that the sealing cover (15) is arranged, the poison bait ring groove (2) and the funnel cavity (4) form independent cavities; the poison bait ring groove (2) is filled with poison bait powder;

the end sealing wall (13) of the circular arc inner pipe body (6) is fixedly connected with the sealing cover (15) through the linkage rod (14); the driving device comprises a vertical electric telescopic device (18), and the top of the tail end of a telescopic rod (19) of the electric telescopic device (18) is contacted with and pressed against the upper surface of the pressure plate (12); one a hollow hole (23) closest to the clockwise end along the circular path of the circular arc inner pipe body (6) in the plurality of a hollow holes (23) is marked as an escape opening (23.1); the telescopic rod (19) stretches out downwards to push the pressure plate (12), thereby make circular arc inner tube body (6) along self circular arc route clockwise displacement a section distance in circular arc outer tube body (5), until when pressure plate (12) contacted circular arc outer tube body (5) anticlockwise end, a plurality of a fretwork holes (23) become mutually staggered from original coincidence intercommunication state with a plurality of b fretwork holes (22) respectively, except escape opening (23.1), all remaining a fretwork holes (23) are all by the inner wall shutoff of circular arc outer tube body (5), escape opening (23.1) are by original and b fretwork hole (22) intercommunication rise to intercommunication funnel chamber (4), closing cap (15) are separated with escape ring dish (1) under the linkage of gangbar (14).

2. The inducible termite control device of claim 1 wherein: the novel arc outer tube body is characterized by further comprising a tension spring (17), one end of the tension spring (17) is fixedly connected with the pressure plate (12), the tension spring (17) forms upward tension on the pressure plate (12), and when the telescopic rod (19) is retracted upwards, the tension spring (17) pulls the pressure plate (12) upwards, so that the arc inner tube body (6) moves anticlockwise in the arc outer tube body (5) along the arc path of the novel arc inner tube body.

3. The inducible termite control device of claim 2 wherein: when the arc outer pipe body (5) is buried under the ground, the lower end of the inclined plane of the escape ring disc (1) just contacts the ground.

4. The inducible termite control device of claim 3 wherein: the arc bait channel (20) is filled with a plurality of pine blocks (9), each pine block (9) is soaked with a nontoxic termite attractant, and gaps between every two adjacent pine blocks (9) are enough for termites to walk in the arc bait channel (20) at will.

5. The termite trapping and controlling method of the induced type termite controlling device according to claim 4, wherein:

burying the circular arc outer pipe body (5) on the ground of the area where termites frequently or suspected to be on the ground by using loose soil, and enabling the lower end of the inclined plane of the escape ring disc (1) to just contact the ground; when the set time is reached, the electric telescopic device (18) and the electric vibrator (10) are started in sequence, the electric telescopic device (18) started firstly enables the telescopic rod (19) to extend downwards to push the pressure plate (12), so that the circular arc inner pipe body (6) moves clockwise for a certain distance in the circular arc outer pipe body (5) along the circular arc path of the electric telescopic device until the pressure plate (12) contacts the anticlockwise end of the circular arc outer pipe body (5); and then the electric vibrator (10) generates vibration at the anticlockwise end of the arc bait channel (20) after being electrified.