CN209898084U - Electronic full-automatic continuous mouse killer - Google Patents

Abstract

The embodiment of the utility model discloses full-automatic continuous mouse killer of electron relates to equipment technical field that kills mouse, and its technical scheme main points include the shell, set up the inboard arrow that just can outwards shoot the arrow of shell is vector subassembly, setting and is in the inboard drive of shell the drive arrangement and the setting of component are in to the arrow the response subassembly in the shell outside works as when response subassembly signals, drive arrangement drives the arrow is fired the subassembly. The utility model discloses be used for solving among the prior art problem that mouse killer operation is complicated.

Description

Electronic full-automatic continuous mouse killer

Technical Field

The embodiment of the utility model provides a relate to equipment technical field that kills mouse, concretely relates to full-automatic continuous mouse killer of electron.

Background

The damage of mice to food, damaged articles, and infected diseases is multifaceted and very serious. 106 cases of interpersonal plague were found in 1991-1994, with a fatality rate of 24.5%. 3 cases of plague, 8996 cases of hemorrhagic fever and 281 cases of leptospirosis occur nationwide 10 months before 2014. Particularly, the disease incidence is more than 1 case after the occurrence of the plague in 2010, and the reason may be directly related to the high incidence period of the plague in rural areas. With the increasing density of rats in most areas, the rural areas have already entered the advanced disease-transmission stage of rats.

The mouse reproductive capacity is extremely strong, and the determined plague source of China is distributed in 201 counties (cities) of 17 provinces and autonomous regions, and the area reaches more than 60 ten thousand square kilometers. Although records about rat damage and deratization in China can be traced back to thousands of years, the organized rat damage treatment is not started until the end of the 40 s, and the records are tortuous for a half century. The first large-scale rat eradication started in the 50 s, takes the suppression of interpersonal plague and the patriotic hygiene sports as a trigger, actively participates in various organizations and masses, and weakens the prevalence of plague and plague to a certain extent under the conditions of lack of medical instruments and low technology.

Despite the observation of the existing deratization devices, these devices have achieved a certain deratization effect in long-term practice, but it cannot be denied that there are many disadvantages or drawbacks, among them:

killing mice with the medicine: the secondary poisoning is the biggest defect of drug deratization, and meanwhile, the dispersion of dead rats is not easy to control, thereby causing environmental pollution.

Electric shock deratization: high voltage easily causes personnel injury and most dead mice of the rat killing operation are left on the site. Because mice are sensitive and suspicious, live mice left with dead mice basically do not enter any more, and the continuous killing is difficult to realize.

Mouse killing by using a mousetrap: single operation and high labor intensity, and continuous killing can not be realized.

Ultrasonic deratization: only drives and does not kill, and the problem cannot be fundamentally solved.

Sticking a plate to kill rats: influenced by factors such as aging of the adhesive, ambient temperature, humidity and dust, the hit rate of deratization is not easy to guarantee.

Live mice and dead mice are left on the site and are generally difficult to kill continuously.

Biological deratization: the use of natural enemies of rats (e.g., cats, ferrets, snakes, hawks, etc.) is an ancient traditional approach, with the most common being the maintenance of cats and rats. But investigations have shown that there are still rats around the cat-raised population, whose rat density is only about one-third lower than that of the non-raised population. Because the killing of cats may cause people to be infected with epidemic hemorrhagic fever, the raising of cats for killing rats should not be advocated, and the raising should be prohibited in the epidemic areas of rat-borne diseases.

Killing mice by microorganisms: in the field of killing mice by microorganisms, the experiment for trying the varicella virus is not successful at present.

The plague brucella strain is considered as an effective deratization strain because it is not pathogenic to middle and large animals (the strain is not isolated from human body so far), and the plague bacteria have fleas as transmission media and are easy to spread, although theoretically, the plague strain can be used for killing small rats, and unfortunately, the plague strain can not be verified in the field.

Other deratization instruments: in long-term practice, mankind has made a lot of "self-made" deratization tools, and the principle mostly adopts the modes of "buckle, trap, tie" and the like, but these "self-made" deratization tools generally need certain skill in use, are complicated to operate, have different application effects, and are difficult to realize wide spread.

SUMMERY OF THE UTILITY MODEL

Therefore, the embodiment of the utility model provides a full-automatic continuous mouse killer of electron to solve the problem that mouse killer operates complicacy among the prior art.

In order to achieve the above object, the embodiment of the present invention provides the following technical solutions:

an electronic full-automatic continuous mouse killer comprises a shell, an arrow component, a driving device and an induction component, wherein the arrow component is arranged on the inner side of the shell and can shoot arrows outwards, the driving device is arranged on the inner side of the shell and drives the arrow component, the induction component is arranged on the outer side of the shell, and when the induction component sends a signal, the driving device drives the arrow component to shoot.

The embodiment of the utility model is also characterized in that one end of the shell is provided with a U-shaped cavity; two openings are formed in two sides, which are relatively far away from the cavity, of the cavity, a bait box is arranged in the cavity, and the bait box is located in the induction area of the induction assembly.

The embodiment of the utility model is further characterized in that, the induction component comprises an infrared transmitting tube and an infrared receiving tube which are arranged at the inner side of the cavity, and the infrared transmitting tube and the infrared receiving tube are respectively positioned on the vertical side walls of the two openings of the vertical cavity; and when the infrared ray is shielded to send out a signal, the arrow component can hit the target position of the shielded infrared ray.

The embodiment of the utility model is further characterized in that, a vertical arrow storage groove is arranged on the shell, an arrow outlet is arranged at the bottom of the arrow storage groove and at one side close to the cavity, the arrow outlet can be used for a group of arrow components to fly out, a driving opening is arranged at one side far away from the arrow outlet, and the driving device passes through the driving opening to drive the arrow components; a plurality of groups of arrow components are sequentially arranged in the vertical direction of the arrow storage groove; the driving device pushes one group of arrow assemblies to fly out of the arrow outlet at a time.

An embodiment of the present invention is also characterized in that the arrow assembly includes a arrow head, a trace spool, and an indicator tab; the cornice comprises a pointed cone at the end part, an inserting rod connected with the pointed cone and an agnail positioned on one side of the pointed cone close to the inserting rod; the middle part of the tracing spool is provided with an insertion hole for the insertion of the insertion rod, a connecting wire is wound on the outer side, and a wire end at the outer end of the connecting wire is bound with the insertion rod; the indicating sheet is made of bright-colored materials and is connected with the thread end on the inner side of the connecting line.

The utility model discloses the characteristic still lies in, drive arrangement slides in order to drive along the straight line including setting up in the shell the arrow subassembly rectilinear motion's striker, fixed just be located with the striker is kept away from the frame of arrow subassembly one end, is driven the energy storage subassembly that the frame removed and is worked as behind the frame energy storage right the locking subassembly that the frame locked carries out.

The embodiment of the utility model is further characterized in that, the energy storage component comprises a micro motor, a lead screw connected with the output shaft of the micro motor and a square nut sleeved on the lead screw, an energy storage spring is arranged between the square nut and the micro motor, the energy storage spring is sleeved on the lead screw, and two limiting plates are arranged on two sides of the square nut; the frame comprises a connecting section connected with the firing pin, transmission sections arranged on the inner sides of the two limiting plates and located on two sides of the screw rod, and a control section located on one side far away from the connecting section, wherein one side, close to one end of the square nut, of each transmission section is abutted against the square nut, and one side of each transmission section is abutted against the energy storage spring; and sensing assemblies are arranged at two ends of the lead screw in the length direction and control the micro motor to rotate forwards or reversely.

The embodiment of the utility model is further characterized in that, the energy storage component comprises a micro motor, a lead screw connected with the output shaft of the micro motor and a square nut sleeved on the lead screw, a coil spring is arranged in the shell, and the coil spring applies elastic tension to one side of the cavity to the frame; two limiting plates are arranged on two sides of the square nut; the frame comprises a connecting section connected with the firing pin, transmission sections arranged on the inner sides of the two limiting plates and positioned on two sides of the screw rod, and a control section positioned on one side far away from the connecting section; and sensing assemblies are arranged at two ends of the lead screw in the length direction and control the micro motor to rotate forwards or reversely.

An embodiment of the present invention is further characterized in that the sensing assembly includes a rear position sensor fixed inside the housing and located near one side of the control section, and a front position sensor near one side of the chamber; the front position sensor is positioned on the moving track of the square nut; the rear position sensor is arranged on one side, far away from the cavity, of the shell, when the control section abuts against the rear position sensor, the micro motor drives the square nut to start to move reversely, meanwhile, the locking assembly locks the frame, the square nut moves to abut against the position, close to the front position sensor, of the square nut, and the micro motor stops rotating to finish the energy storage process; when the infrared transmitting tube is shielded, the locking assembly loosens the frame, and after the micro motor delays for a period of time, the square nut is driven to move towards one side far away from the front position sensor, and secondary energy storage is started.

The embodiment of the utility model provides a characterized in that still, the locking subassembly is including fixing the frame is kept away from the swing electro-magnet of micro motor one side and is held up with swing electro-magnet fixed connection's lock the draw-in groove has been seted up in the lock, the draw-in groove can the joint on the frame.

The embodiment of the utility model provides a have following advantage:

the embodiment of the utility model provides a mouse killer adopts mechanical structure to kill mouse, through a plurality of sensors that set up, whole automatic operation kills mouse. Through a plurality of arrow that place in the arrow groove that sets up, can realize placing multiunit arrow subassembly, realize killing rats in succession in the use. Simultaneously, through the energy storage subassembly that sets up, can carry out the energy storage automatically, prepare, do not need the manual work to operate and can accomplish the preparation of killing mouse. The use is simple and convenient, and secondary toxicity is avoided. Simultaneously the utility model discloses a mouse killer in the use, can not leave the mouse corpse basically in mouse killer position to can realize follow-up continuous deratization, at a lot of deratization in-process, do not need manual operation, realized once arranging can continuous automatic operation. When in use, the structure has better effect, and the mouse killer has lower cost and is suitable for popularization.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structure, ratio, size and the like shown in the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by people familiar with the technology, and are not used for limiting the limit conditions which can be implemented by the present invention, so that the present invention has no technical essential significance, and any structure modification, ratio relationship change or size adjustment should still fall within the scope which can be covered by the technical content disclosed by the present invention without affecting the efficacy and the achievable purpose of the present invention.

Fig. 1 is a schematic view of an overall structure of an electronic full-automatic continuous mouse killer provided by an embodiment of the present invention;

fig. 2 is a bottom view of an electronic full-automatic continuous mouse killer provided by the embodiment of the present invention;

fig. 3 is a schematic view of a salient arrow component in the electronic full-automatic continuous mouse killer provided by the embodiment of the present invention;

fig. 4 is a sectional view along the direction a-a in fig. 3, in the electronic full-automatic continuous mouse killer provided by the embodiment of the present invention;

fig. 5 is a schematic view of a salient arrow component in the electronic full-automatic continuous mouse killer provided by the embodiment of the present invention;

fig. 6 is an exploded view of a salient arrow component in the electronic full-automatic continuous mouse killer provided by the embodiment of the present invention;

fig. 7 is a schematic view of a protrusion driving device in an electronic full-automatic continuous mouse killer according to an embodiment of the present invention;

fig. 8 is an exploded view of a protrusion driving device in the electronic full-automatic continuous mouse killer according to the embodiment of the present invention;

fig. 9 is a schematic view of a protruding coil spring in an electronic full-automatic continuous mouse killer according to an embodiment of the present invention.

In the figure: 1. a housing; 11. a chamber; 111. an opening; 112. a bait case; 12. a vector storage groove; 121. arrow outlet; 122. a drive opening; 2. an arrow component; 21. a cornhead; 211. a pointed cone; 212. a plug rod; 213. a barb; 22. a tracing bobbin; 221. an interface; 222. a connecting wire; 23. an indicator sheet; 3. a drive device; 31. a firing pin; 32. a frame; 321. a connecting section; 322. a transmission section; 3221. a butt joint plate; 323. a control section; 324. a locking plate; 33. an energy storage assembly; 331. a micro motor; 332. a lead screw; 333. a square nut; 334. an energy storage spring; 335. a limiting plate; 336. a coil spring; 34. a locking assembly; 341. a swinging electromagnet; 342. locking; 3421. a card slot; 35. a sensing component; 351. a rear position sensor; 352. a front position sensor; 4. an inductive component; 41. an infrared emission tube; 42. an infrared receiving tube; 5. and (4) fixing the ring.

Detailed Description

The present invention is described in terms of specific embodiments, and other advantages and benefits of the present invention will become apparent to those skilled in the art from the following disclosure. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example one

An electronic full-automatic continuous mouse killer is shown in fig. 1 to 3 and comprises a shell 1, an arrow component 2, a driving device 3 and a sensing component 4, wherein the arrow component 2 is arranged on the inner side of the shell 1 and can shoot arrows outwards, the driving device 3 is arranged on the inner side of the shell 1 and is used for driving the arrow component 2 to work, the sensing component 4 is arranged on the outer side of the shell 1, and when the sensing component 4 sends a signal, the driving device 3 drives the arrow component 2 to shoot.

A cavity 11 in an inverted 'U' shape is formed at one side of the housing 1, two openings 111 are formed at two sides of the cavity 11 which are relatively far away from each other, and a bait box 112 is arranged at the inner side of the cavity 11 for holding bait and trapping rats. The bait cartridge 112 is placed at the sensing assembly 4 location.

The sensing assembly 4 includes an infrared transmitting tube 41 and an infrared receiving tube 42 disposed inside the chamber 11, the infrared transmitting tube 41 and the infrared receiving tube 42 are respectively disposed on the vertical side walls of the two openings 111 of the vertical chamber 11, and the height of the infrared transmitting tube 41 and the height of the infrared receiving tube 42 can be blocked by passing rats. And the mouse passed through the infrared covered area before eating the bait. When the infrared ray is sheltered from, send out the signal, arrow subassembly 2 launch arrow is vector, hits and shelters from the infrared target.

As shown in fig. 4 to 6, first, a vertical arrow storage groove 12 is formed on the housing 1, the arrow storage groove 12 is used for placing the arrow assembly 2, and the bottom of the arrow storage groove 12 is provided with an outlet along a straight direction, one side of the arrow storage groove is communicated with the chamber 11 and is an arrow outlet 121 for arrow flying out, and the other side of the arrow storage groove is provided with a driving opening 122 for communicating with the driving device 3 and providing power.

The arrow components 2 are provided with a plurality of groups, the arrow components are respectively and sequentially arranged in the vertical direction of the arrow storage groove 12, the driving device 3 only drives the arrow component 2 at the lowest side to fly out at each time, and meanwhile, the arrow outlet 121 only can provide one group of arrow components 2 to fly out, so that the arrow is automatically supplied in the using process.

The arrow assembly 2 includes a arrow head 21, a tracing spool 22, and an indicator piece 23.

The sagittal head 21 comprises a pointed cone 211 at the end and a plug-in rod 212 connected to the pointed cone 211. And barbs 213 located on the side of pointed cone 211 adjacent to bayonet rod 212, wherein pointed cone 211 is used to pierce a target and bayonet rod 212 is used to connect with tracking spool 22. With the barb 213 provided, it is not easily dislodged after piercing the target.

The trace spool 22 has a middle portion formed with a socket 221 for the plug rod 212 to be plugged, and an outer portion wound with a connection line 222, wherein the connection line 222 may be formed by winding a high-strength fine cotton thread or a chemical fiber thread. The external joint of the connecting line 222 is connected with the plug rod 212, the inner side joint is connected with the indicating sheet 23, the indicating sheet 23 can be made of bright-colored materials, discovery is convenient, and the target corpse can be cleaned along the connecting line 222 after discovery.

When the device is used, the tracing spool 22 and the cornfound head 21 fly out simultaneously, the cornfound head 21 shoots a target, the target cannot die immediately, the tracing spool 22 is dragged away in the escaping process, no corpse is left on the site, and the corpse which hits the target can be found conveniently in tracking.

As shown in fig. 7 and 8, the driving device 3 includes a striker 31, a frame 32, an energy accumulating assembly 33, and a locking assembly 34. The striker 31 is used for striking the tracing spool 22, one end of the frame 32 is connected with the striker 31, the other end of the frame 32 is connected with the energy storage assembly 33 and the locking assembly 34, the energy storage assembly 33 is used for driving the frame 32 to drive the striker 31 to move, and the locking assembly 34 is used for fixing the frame 32 after energy storage.

First, the striker 31 is formed in a long rod shape, and a stopper is provided inside the housing 1 so that the striker 31 can move only in a straight line, and during the movement, one end of the striker 31 can pass through the driving opening 122 to strike the arrow unit 2.

Frame 32 comprises a connecting section 321 connected to firing pin 31, a transmission section 322 connected to energy accumulating assembly 33, and a control section 323 located on the side remote from connecting section 321. Wherein, two transmission sections 322 are symmetrically arranged, one end is connected with the energy storage component 33, and the other end is connected with the firing pin 31 or the control section 323.

The energy storage component 33 comprises a micro motor 331 fixed on the inner side of the housing 1, a lead screw 332 connected with an output shaft of the micro motor 331, and a square nut 333 sleeved on the lead screw 332, wherein an energy storage spring 334 is arranged between the square nut 333 and the micro motor 331, meanwhile, two sides of the lead screw 332 are provided with a limiting plate 335 in parallel, and the limiting plate 335 is used for limiting the square nut 333, so that when the lead screw 332 rotates, the square nut 333 cannot rotate, and can only slide along the length direction of the lead screw 332. One side of the transmission section 322 is disposed between the limiting plates 335 and located at two sides of the screw 332, and the end of the transmission section 322 is abutted against one side of the square nut 333 close to the micro-motor 331. Therefore, the square nut 333 can drive the transmission section 322 to move linearly during moving.

An abutting plate 3221 is arranged on one side of the transmission section 322 close to the screw rod 332, one side of the abutting plate 3221 abuts against the square nut 333, and the other side abuts against the energy storage spring 334. The sensing assemblies 35 are arranged at two ends of the lead screw 332 in the length direction, and the sensing assemblies 35 are used for sensing the positions of the square nut 333 and the control section 323, and further sending signals to control the micro motor 331 to rotate forwards or backwards, so that the square nut 333 moves back and forth.

The sensing assembly 35 includes a rear position sensor 351 fixed inside the casing 1 at a side close to the control section 323, and a front position sensor 352 disposed at a side close to the chamber 11, wherein the front position sensor 352 is located on a locus along which the square nut 333 moves, and the rear position sensor 351 is disposed at a side away from the chamber 11 and on a locus along which the control section 323 moves.

When the square nut 333 is driven by the micro motor 331 to move toward the rear position sensor 351, the energy storage spring 334 is compressed, the striker 31 moves together with the frame 32, and when the control section 323 abuts against the rear position sensor 351, the micro motor 331 starts to rotate in the reverse direction, so that the square nut 333 starts to move in the reverse direction, and the locking assembly 34 locks the frame 32 so as not to rebound. When the micro motor 331 drives the square nut 333 to move to abut against the front position sensor 352, the front position sensor 352 sends a signal to control the micro motor 331 to stop, and at this time, the whole power accumulation process of the firing pin 31 is completed.

When the outside infrared emission tube 41 is shielded, a signal is sent, the locking assembly 34 is controlled to release the frame 32, and under the action of the energy storage spring 334, the frame 32 and the striker 31 are rapidly moved to the side close to the arrow assembly 2, so that the arrow assembly 2 is knocked out of the housing 1. Meanwhile, the micro motor 331 delays for a period of time, for example, 2 to 3 seconds, and then the operation of the control square nut 333 is started to move to the side away from the front position sensor 352, and secondary energy storage is started.

A locking plate 324 is disposed on the frame 32 at a side close to the rear position sensor 351, and the locking assembly 34 includes a swing electromagnet 341 fixed inside the housing 1 and a locking latch 342 fixedly connected to the swing electromagnet 341. The locking pawl 342 can rotate along a horizontal axis in a vertical direction, a slot 3421 is disposed on the locking pawl 342, and the locking plate 324 can be locked by the slot 3421. So that the frame 32 does not move with the square nut 333, thereby allowing it to complete the energy storage. In control, when the frame 32 abuts against the rear position sensor 351, the swing electromagnet 341 drives the lock catch 342 to rotate, and the frame 32 is locked. When the infrared emission tube 41 is shielded, the swinging electromagnet 341 rotates reversely to unlock the frame 32, so that the striker 31 strikes the arrow unit 2 under the action of the energy storage spring 334.

Finally, a circuit board and a power supply are arranged inside the housing 1, and the power supply is used for supplying power to the electric components used in the device, and similarly, the power supply can be arranged outside the device.

In order to stabilize the position of the housing 1, a fixing ring 5 for fixing the housing 1 is provided on the outer side of the housing 1 and on the side away from the chamber 11.

Example two

An electronic full-automatic continuous mouse killer is shown in fig. 7 and 9, and is different from the embodiment in that an energy storage spring 334 is arranged.

In the present embodiment, by using the coil spring 336 instead of the energy storage spring 334 of the first embodiment, the frame 32 is provided with elastic tension by the coil spring 336 at a side away from the rear position sensor 351, so that the frame 32 reacts more timely when the frame 32 receives a signal.

Although the invention has been described in detail with respect to the general description and the specific embodiments, it will be apparent to those skilled in the art that modifications and improvements can be made based on the invention. Therefore, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (10)

1. An electronic full-automatic continuous mouse killer is characterized in that: the arrow shooting device comprises a shell (1), an arrow component (2) which is arranged on the inner side of the shell (1) and can shoot arrows outwards, a driving device (3) which is arranged on the inner side of the shell (1) and drives the arrow component (2), and a sensing component (4) which is arranged on the outer side of the shell (1), wherein when the sensing component (4) sends a signal, the driving device (3) drives the arrow component (2) to shoot.

2. The electronic full-automatic continuous mouse killer of claim 1, characterized in that: a U-shaped cavity (11) is arranged at one end of the shell (1);

two openings (111) are formed in two sides which are far away from each other in the cavity (11), a bait box (112) is arranged in the cavity (11), and the bait box (112) is located in a sensing area of the sensing assembly (4).

3. The electronic full-automatic continuous mouse killer of claim 1, characterized in that: the induction assembly (4) comprises an infrared transmitting tube (41) and an infrared receiving tube (42) which are arranged on the inner side of the chamber (11), and the infrared transmitting tube (41) and the infrared receiving tube (42) are respectively positioned on the vertical side walls of the two openings (111) vertical to the chamber (11); and when the infrared ray is shielded to send out a signal, the arrow component (2) can hit the infrared ray shielding target position.

4. The electronic full-automatic continuous mouse killer of claim 1, characterized in that: a vertical arrow storage groove (12) is formed in the shell (1), an arrow outlet (121) is formed in the bottom of the arrow storage groove (12) and on one side close to the cavity (11), the arrow outlet (121) can be used for a group of arrow assemblies (2) to fly out, a driving opening (122) is formed in one side far away from the arrow outlet (121), and the driving device (3) penetrates through the driving opening (122) to drive the arrow assemblies (2);

a plurality of groups of arrow components (2) are sequentially arranged in the vertical direction of the vector storage groove (12); the driving device (3) pushes one arrow assembly (2) to fly out of the arrow outlet (121) at a time.

5. The electronic full-automatic continuous mouse killer according to claim 1 or 4, characterized in that: the arrow assembly (2) includes a arrow head (21), a tracing spool (22), and an indicator tab (23);

the cornice head (21) comprises a pointed cone (211) at the end part, an insertion rod (212) connected with the pointed cone (211), and a barb (213) positioned on one side of the pointed cone (211) close to the insertion rod (212);

the middle part of the tracing spool (22) is provided with an insertion hole for the insertion of the insertion rod (212), a connecting wire (222) is wound on the outer side, and a wire end at the outer end of the connecting wire (222) is bound with the insertion rod (212);

the indicating sheet (23) is made of bright-colored materials and is connected with the thread end on the inner side of the connecting line (222).

6. The electronic full-automatic continuous mouse killer of claim 3, characterized in that: the driving device (3) comprises a striker (31) which is arranged in the shell (1) and slides along a straight line to drive the arrow component (2) to move linearly, a frame (32) which is fixed with the striker (31) and is positioned at one end of the striker (31) far away from the arrow component (2), an energy storage component (33) which drives the frame (32) to move, and a locking component (34) which locks the frame (32) after the frame (32) stores energy.

7. The electronic full-automatic continuous mouse killer of claim 6, characterized in that: the energy storage component (33) comprises a micro motor (331), a lead screw (332) connected with an output shaft of the micro motor (331), and a square nut (333) sleeved on the lead screw (332), wherein an energy storage spring (334) is arranged between the square nut (333) and the micro motor (331), the energy storage spring (334) is sleeved on the lead screw (332), and two limiting plates (335) are arranged on two sides of the square nut (333);

the frame (32) comprises a connecting section (321) connected with the firing pin (31), transmission sections (322) arranged on the inner sides of the two limiting plates (335) and located on two sides of the screw rod (332), and a control section (323) located on one side far away from the connecting section (321), one side, close to the square nut (333), of each transmission section (322) is abutted to the square nut (333), and one side of each transmission section is abutted to the energy storage spring (334);

sensing assemblies (35) are arranged at two ends of the lead screw (332) in the length direction, and the sensing assemblies (35) control the micro motor (331) to rotate forwards or reversely.

8. The electronic full-automatic continuous mouse killer of claim 6, characterized in that: the energy storage component (33) comprises a micro motor (331), a lead screw (332) connected with an output shaft of the micro motor (331), and a square nut (333) sleeved on the lead screw (332), wherein a coil spring (336) is arranged in the shell (1), and the coil spring (336) applies elastic tension to one side of the cavity (11) to the frame (32); two limiting plates (335) are arranged on two sides of the square nut (333);

the frame (32) comprises a connecting section (321) connected with the firing pin (31), transmission sections (322) arranged at the inner sides of the two limiting plates (335) and positioned at two sides of the screw rod (332), and a control section (323) positioned at one side far away from the connecting section (321);

sensing assemblies (35) are arranged at two ends of the lead screw (332) in the length direction, and the sensing assemblies (35) control the micro motor (331) to rotate forwards or reversely.

9. The electronic full-automatic continuous mouse killer according to claim 7 or 8, characterized in that: the sensing assembly (35) comprises a rear position sensor (351) fixed inside the casing (1) and positioned on the side close to the control section (323), and a front position sensor (352) positioned on the side close to the chamber (11); the front position sensor (352) is positioned on the moving track of the square nut (333);

the rear position sensor (351) is arranged on one side, far away from the cavity (11), of the shell (1), when the control section (323) abuts against the rear position sensor (351), the micro motor (331) drives the square nut (333) to start to move reversely, meanwhile, the locking assembly (34) locks the frame (32), the square nut (333) moves to the position close to the front position sensor (352) to abut against, and the micro motor (331) stops rotating to complete an energy storage process;

when the infrared emission tube (41) is shielded, the locking component (34) loosens the frame (32), and after the micro motor (331) delays for a period of time, the square nut (333) is driven to move to the side far away from the front position sensor (352) to start secondary energy storage.

10. The electronic full-automatic continuous mouse killer of claim 8, characterized in that: the locking assembly (34) comprises a swinging electromagnet (341) fixed on one side of the frame (32) far away from the micro motor (331) and a locking mechanism (342) fixedly connected with the swinging electromagnet (341), a clamping groove (3421) is formed in the locking mechanism (342), and the clamping groove (3421) can be clamped on the frame (32).

Images