CN114223630A

CN114223630A - Ultrasonic double-effect mosquito repelling lamp

Info

Publication number: CN114223630A
Application number: CN202111586319.3A
Authority: CN
Inventors: 李永勇; 吴亚明
Original assignee: Deqing Oushang Lighting Co ltd
Current assignee: Deqing Oushang Lighting Co ltd
Priority date: 2021-12-23
Filing date: 2021-12-23
Publication date: 2022-03-25
Anticipated expiration: 2041-12-23
Also published as: CN114223630B

Abstract

The invention relates to the technical field of mosquito-repellent lamps, in particular to an ultrasonic double-effect mosquito-repellent lamp which comprises a lamp holder, a lamp holder groove and a lamp body, wherein the lamp holder groove is formed in the lamp holder; the bottom of the lampshade is provided with a first lampshade opening, the side wall of the lampshade is provided with a second lampshade opening, and the first lampshade opening is communicated with the lamp holder groove; the sound wave generator is arranged in the lamp holder groove and used for emitting sound wave signals for attracting mosquitoes; the mosquito-lured lamp is arranged in the lampshade and is used for emitting light wave signals for luring mosquitoes; the power grid is connected with the second opening of the lampshade and used for electrically shocking mosquitoes; and the power supply is arranged in the lamp holder groove and used for supplying power to the sound wave generator, the mosquito-lured lamp and the power grid. The mosquito repelling lamp can repel mosquitoes in a manner of attracting the mosquitoes and killing the mosquitoes electrically, and can be placed in a place far away from a user in a bedroom, so that the light of the mosquito repelling lamp does not influence the sleep of the user; this application shields the sound that the mosquito electricity killed the in-process and produced through the subassembly that gives sound insulation, has further reduced the influence of mosquito repellent lamp to user's sleep.

Description

Ultrasonic double-effect mosquito repelling lamp

Technical Field

The invention relates to the technical field of mosquito repelling lamps, in particular to an ultrasonic double-effect mosquito repelling lamp.

Background

People usually use mosquito coils or mosquito coil liquid to repel and kill mosquitoes, but the long-term use of the mosquito coils or mosquito coil liquid can cause damage to human bodies. For this reason, the prior art proposes to repel mosquitoes by mosquito repelling lamps, for example, patent application No. CN202011036758.2 discloses an intelligent household mosquito repelling lamp; patent application No. CN202022390810.6 discloses a mosquito-repellent lamp with an ultrasonic wave light wave mosquito-repellent structure.

Most of mosquito repelling lamps in the prior art repel mosquitoes through light and sound waves, but the mosquito repelling lamp is not good in using effect in a bedroom, because if the mosquito repelling lamp is placed in the bedroom close to a user, the light can affect the sleep of the user; if the mosquito-repellent lamp is placed in a bedroom at a position which is not close to or far away from a user, the mosquito-repellent effect of the mosquito-repellent lamp is greatly deteriorated; if the mosquito-repellent lamp is placed at a place far away from the user in the bedroom, the mosquito-repellent lamp may repel the mosquitoes in the bedroom to the user, and negative effects are generated.

Therefore, it is highly desirable to provide a mosquito-repelling lamp that can be used in bedrooms.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides the ultrasonic double-effect mosquito repelling lamp suitable for the bedroom, which can attract and kill mosquitoes in the bedroom, so that a user can sleep at ease.

The technical scheme adopted by the invention for solving the technical problems is as follows: an ultrasonic dual-effect mosquito-repelling lamp comprises

A lamp holder provided with a lamp holder groove;

the bottom of the lampshade is provided with a first lampshade opening, the side wall of the lampshade is provided with a second lampshade opening, and the first lampshade opening is communicated with the lamp holder groove;

the sound wave generator is arranged in the lamp holder groove and used for emitting sound wave signals for attracting mosquitoes;

the mosquito-lured lamp is arranged in the lampshade and is used for emitting light wave signals for luring mosquitoes;

the power grid is connected with the second opening of the lampshade and used for electrically shocking mosquitoes;

and the power supply is arranged in the lamp holder groove and used for supplying power to the sound wave generator, the mosquito-lured lamp and the power grid.

Preferably, the mosquito repelling lamp further comprises a sound insulation component; the sound insulation assembly comprises

The movable sound-proof shield comprises a rotating plate and a movable shield cylinder arranged around the rotating plate, wherein a first axial gap is formed in the movable shield cylinder;

the rotating motor is connected with the top of the lampshade, and an output shaft of the rotating motor is connected with the rotating plate and used for driving the movable sound-proof shield to rotate;

the static sound-proof shield comprises a supporting plate and a static shield cylinder which is arranged around the supporting plate and is sleeved with the peripheral wall of the movable shield cylinder, and a second axial gap is formed in the static shield cylinder;

the mosquito sensor is arranged inside the movable shield cylinder and used for sensing whether mosquitoes enter the movable sound-proof shield or not;

the controller is connected with the mosquito sensor and the rotating motor;

when the movable sound-proof shield rotates to a first state, the first axial gap and the second axial gap are completely overlapped; when the dynamic sound enclosure rotates to a second state, the first axial gap is completely staggered from the second axial gap.

Preferably, the support plate is provided with a lamp holder sleeve opening sleeved with the lamp holder, and the static sound-proof shield further comprises a static sound-proof shield mounting plate connected with the support plate and surrounding the lamp holder sleeve opening.

Preferably, the supporting plate is further provided with a limiting guide groove, and the bottom of the movable cover cylinder is provided with a limiting guide bulge which is connected with the limiting guide groove in a matched mode.

Preferably, an arc-shaped light-scattering slope I is arranged on the side, facing the rotating plate, of the supporting plate, and a reflective film I is arranged on the arc-shaped light-scattering slope I;

the rotating plate is provided with a second arc-shaped light-scattering slope on the side facing the supporting plate, and the second arc-shaped light-scattering slope is provided with a second reflective film.

Preferably, the mosquito repelling lamp further comprises a dust removing component; the dust removing component comprises

The dust suction head is connected with the dust removal hole of the rotating plate and comprises a dust suction port arranged inside the movable sound-proof shield and a threaded butt joint port arranged outside the movable sound-proof shield;

the cap is detachably connected with the threaded butt joint;

the dust collector is provided with a dust collection hose which is detachably connected with the threaded butt joint.

Preferably, the controller comprises

A dynamic sound-proof housing state detection unit for detecting whether the dynamic sound-proof housing is in a second state;

and the power grid power supply control unit is connected with the dynamic sound-proof shield state detection unit and is used for electrifying the power grid when the dynamic sound-proof shield is in the second state.

Preferably, the outer peripheral wall of the static cover cylinder is provided with a reinforcing outer stirrup; the inner circumferential wall of the movable cover cylinder is provided with a reinforced inner stirrup.

Preferably, the electric wire netting include with the electric wire netting frame that the lamp shade dismantlement formula is connected, install electric wire netting line on the electric wire netting frame, with the power supply line that the electric wire netting line is connected, with the power supply connector that the power supply line is connected, and install the lamp stand inslot and be used for with the joint connecting seat that the power supply connector is connected, the joint connecting seat pass through control switch with the power is connected.

Preferably, the top of the lampshade is provided with a handle.

Advantageous effects

The mosquito repelling lamp can repel mosquitoes in a manner of attracting the mosquitoes and killing the mosquitoes electrically, and can be placed in a place far away from a user in a bedroom, so that the light of the mosquito repelling lamp does not influence the sleep of the user; this application shields the sound that the mosquito electricity killed the in-process and produced through the subassembly that gives sound insulation, has further reduced the influence of mosquito repellent lamp to user's sleep, makes the mosquito repellent lamp have fine result of use.

Drawings

FIG. 1 is a schematic view of the overall structure of an ultrasonic double-effect mosquito-repellent lamp of the invention;

FIG. 2 is an exploded view of the ultrasonic dual-effect mosquito-repellent lamp of the present invention;

FIG. 3 is a schematic view of a mosquito repellent lamp of the present invention with a sound isolation assembly and a movable sound enclosure in a first state;

FIG. 4 is a schematic view of a mosquito repellent lamp of the present invention with a sound isolation assembly and a movable sound isolation cover in a second state;

FIG. 5 is a schematic structural view of the dynamic sound enclosure of the present invention;

FIG. 6 is a schematic structural view of the static acoustic enclosure of the present invention;

FIG. 7 is a schematic structural view of a static sound enclosure of the present invention with a position-limiting guide slot;

FIG. 8 is a schematic structural view of a first stationary sound enclosure having an arcuate diffuser ledge according to the present invention;

FIG. 9 is a schematic structural view of a second stationary sound enclosure provided with an arc-shaped diffuser;

FIG. 10 is a schematic view of the structure of the rotating plate with the cleaning head attached to the cap of the present invention;

FIG. 11 is a schematic view of the connection between the suction head and the vacuum cleaner on the rotating plate according to the present invention;

FIG. 12 is a schematic structural view of a static sound enclosure incorporating the outer reinforcement stirrup of the present invention;

FIG. 13 is a schematic structural view of the dynamic sound enclosure with reinforcing inner stirrups of the present invention;

fig. 14 is a schematic structural diagram of the power grid of the present invention.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

The first embodiment is as follows: as shown in fig. 1 and 2, the ultrasonic double-effect mosquito-repellent lamp comprises a lamp holder 1, a lampshade 2, a sound wave generator 3, a mosquito-lured lamp 4, an electric network 5 and a power supply 6. The top of the lamp holder 1 is provided with a lamp holder groove 1-1. The bottom of the lampshade 2 is provided with a first lampshade opening, the side wall of the lampshade is provided with a second lampshade opening, and the first lampshade opening is communicated with the lamp holder groove 1-1. The sound wave generator 3 is arranged in the lamp holder groove 1-1 and used for emitting sound wave signals for attracting mosquitoes. The mosquito-lured lamp 4 is arranged in the lampshade 2 and is used for emitting light wave signals for luring mosquitoes. And the power grid 5 is connected with the second opening of the lampshade and used for electrically shocking mosquitoes. The power supply 6 is arranged in the lamp holder groove 1-1 and used for supplying power to the sound wave generator 3, the mosquito-lured lamp 4 and the power grid 5. The top of the lampshade 2 is also provided with a handle 2-1, which is convenient for the mosquito-repellent lamp to move.

The application method of the mosquito-repellent lamp comprises the following steps of firstly closing doors and windows of a bedroom, then placing the mosquito-repellent lamp at a place far away from a user in the bedroom (so that the light of the mosquito-repellent lamp cannot affect the sleep of the user), then turning on a power supply switch on the mosquito-repellent lamp, and enabling the sound wave generator 3, the mosquito-luring lamp 4 and the power grid 5 to be powered on. The acoustic wave generator 3 can send out acoustic wave signals (which can be acoustic waves with specific frequency) capable of attracting mosquitoes, the mosquito-luring lamp 4 can send out optical wave signals (which can be purple light) capable of attracting mosquitoes, and the acoustic wave generator 3 and the mosquito-luring lamp 4 jointly act to lure the mosquitoes to the mosquito-repelling lamp. When the mosquitoes touch the power grid 5, the mosquitoes can be killed, so that the purpose of effectively repelling the mosquitoes is achieved.

Further, as shown in fig. 14, the power grid 5 includes a power grid frame 5-1 detachably connected to the lamp shade 2, a power grid line 5-2 installed on the power grid frame 5-1, a power supply line 5-3 connected to the power grid line 5-2, a power supply connector 5-4 connected to the power supply line 5-3, and a connector connecting seat installed in the lamp holder groove 1-1 and used for being connected to the power supply connector 5-4, and the connector connecting seat is connected to the power supply 6 through a control switch.

In the application, the power grid 5 and the lampshade 2 are detachable, the specific detaching process is as follows, the power supply connector 5-4 and the connector connecting seat are detached firstly, and then the connecting screw of the power grid 5-1 and the lampshade 2 is taken down, so that the mounting operation is opposite. When one power grid 5 is damaged, the power grid is only required to be disassembled and replaced by a new power grid 5, and the maintenance is very convenient.

In the second embodiment, when the mosquitoes touch the power grid 5, the mosquitoes can make an electric shock sound, and the sound can still influence the sleep of the user to a certain extent. Therefore, under the premise of the first embodiment (the handle 2-1 is removed), the sound insulation component is additionally arranged on the mosquito-repellent lamp. Specifically, as shown in fig. 3 to 6, the sound insulation assembly includes a moving sound insulation cover, a rotating motor 7-3, a static sound insulation cover, a mosquito sensor and a controller. Wherein, the dynamic sound-proof housing and the static sound-proof housing are made of transparent sound-proof materials.

The movable sound-proof shield comprises a rotating plate 7-1 and a movable shield cylinder 7-2 arranged around the rotating plate 7-1, wherein a first axial gap is formed in the movable shield cylinder 7-2, and the first axial gap axially penetrates through the whole movable shield cylinder 7-2, so that mosquitoes can enter the movable shield cylinder 7-2. The rotating motor 7-3 is connected with the top of the lampshade 2, and the output shaft of the rotating motor is connected with the rotating plate 7-1 and used for driving the movable sound-proof shield to rotate. The static sound-proof shield comprises a supporting plate 7-4, a static shield cylinder 7-5 which surrounds the supporting plate 7-4 and is sleeved with the peripheral wall of the movable shield cylinder 7-2, a second axial gap is formed in the static shield cylinder 7-5, and the second axial gap axially penetrates through the whole static shield cylinder 7-5, so that mosquitoes can enter the movable shield cylinder 7-2 (in an initial state, the first axial gap and the second axial gap are completely overlapped, so that the mosquitoes can enter the movable shield cylinder 7-2 and correspond to the first state of the movable sound-proof shield).

The mosquito sensor is arranged inside the movable cover cylinder 7-2 and can be arranged on the lampshade 2 and used for sensing whether mosquitoes enter the movable sound-proof cover or not, wherein the mosquito sensor can be a sound sensor. The controller is connected with the mosquito sensor and connected with the rotating motor 7-3, when the mosquito sensor senses that mosquitoes exist in the movable cover cylinder 7-2, a mosquito signal is sent to the controller, the controller can control the rotating motor 7-3 to drive the movable sound-proof cover to rotate from the first state to the second state after receiving the mosquito signal (when the movable sound-proof cover is in the second state, the first axial gap and the second axial gap are completely staggered), and at the moment, the static cover cylinder 7-5 can completely block the first axial gap of the movable cover cylinder 7-2, so that the movable cover cylinder 7-2 is in a closed state.

When the movable cover cylinder 7-2 is in a closed state, electric shock sounds generated when mosquitoes touch the power grid 5 can be isolated, and therefore the sleeping of a user cannot be influenced. When no live mosquitoes exist in the movable cover cylinder 7-2, the mosquito sensor sends a mosquito-free signal to the controller, and the controller controls the rotating motor 7-3 to drive the movable sound-proof cover to rotate from the second state to the first state after receiving the mosquito-free signal, so that other mosquitoes can enter the movable cover cylinder 7-2 and are killed by the power grid 5.

The sound insulation assembly can isolate the sound of mosquito electric shock, and the using effect of the mosquito repelling lamp is better.

Further, as shown in fig. 6, the supporting plate 7-4 is provided with a lamp socket sleeve opening sleeved with the lamp socket 1, and the static sound-proof housing further comprises a static sound-proof housing mounting plate 7-6 connected with the supporting plate 7-4 and arranged around the lamp socket sleeve opening. The static sound-proof cover mounting plate 7-6 is provided with mounting plate connecting holes, the lamp holder 1 is provided with mounting plate butt-joint holes, the mounting plate butt-joint holes in the lamp holder 1 are not communicated with the inside of the lamp holder groove 1-1, and the mounting plate connecting holes and the mounting plate butt-joint holes can be connected through fastening screws.

The static sound-proof housing mounting plate 7-6 is arranged to enable the static sound-proof housing to be very convenient to assemble and disassemble, and the static sound-proof housing mounting plate 7-6 has a positioning effect, so that the position accuracy of the installed static sound-proof housing is high, and the sound-proof assembly cannot be deteriorated in use effect due to the fact that the static sound-proof housing is deviated from the lamp holder 1. In addition, the bottom surface of the static sound-proof housing mounting plate 7-6 can be flush with the bottom surface of the lamp holder 1, so that the gravity of the static sound-proof housing acts directly on the ground.

Further, as shown in fig. 7, the supporting plate 7-4 is further provided with a limiting guide groove 7-7, and the bottom of the movable cover cylinder 7-2 is provided with a limiting guide protrusion in fit connection with the limiting guide groove 7-7.

When the rotating motor 7-3 is used for a long time, the control precision is reduced, and the rotating radian of the moving cover cylinder 7-2 is larger or smaller. That is, the rotating motor 7-3 theoretically controls the dynamic noise insulation cover to reach the second state, but actually the first axial gap and the second axial gap are not completely staggered (that is, the dynamic noise insulation cover does not reach the second state, and the dynamic noise insulation cover is not completely closed), so that the noise insulation effect of the noise insulation assembly is weakened.

Therefore, the rotation radian of the rotating motor 7-3 is controlled by the limiting guide protrusion and the limiting guide groove 7-7 (namely, the rotation state of the movable sound-proof cover is determined), when the movable cover barrel 7-2 rotates until the limiting guide protrusion is contacted with the arc first end of the limiting guide groove 7-7, the movable sound-proof cover is in a first state, and when the movable cover barrel 7-2 rotates until the limiting guide protrusion is contacted with the arc second end of the limiting guide groove 7-7, the movable sound-proof cover is in a second state. The arrangement of the limiting guide protrusions and the limiting guide grooves 7-7 enables the accuracy of the determination of the rotating state of the movable cover cylinder 7-2 to be higher.

Further, as shown in fig. 8 and 9, an arc-shaped light-scattering slope i is arranged on the side of the supporting plate 7-4 facing the rotating plate 7-1, and a reflective film i 7-8 is arranged on the arc-shaped light-scattering slope i. The rotating plate 7-1 is provided with a second arc-shaped light-scattering slope on the side facing the supporting plate 7-4, and the second arc-shaped light-scattering slope is provided with a second reflective film 7-9.

The lampshade 2 and the power grid 5 can block part of light of the mosquito-lured lamp 4, in order to enable the mosquito-repellent lamp to generate light with enough intensity to attract mosquitoes, the power of the mosquito-lured lamp 4 needs to be increased, and a large amount of electric energy can be consumed at night. Under the premise of not improving or slightly improving the power of the mosquito-lured lamp 4, the light utilization rate is directly improved through the arc-shaped light-scattering slope I, the reflective film I7-8, the arc-shaped light-scattering slope II and the reflective film II 7-9, so that the purpose of attracting mosquitoes can be achieved even if part of light of the mosquito-lured lamp 4 is shielded.

Further, as shown in fig. 10 and 11, the mosquito repellent lamp further includes a dust removing assembly. The dust removal assembly comprises a dust collection head, a cover cap 8-3 and a dust collector 8-4. The dust suction head is connected with the dust removal hole of the rotating plate 7-1 and comprises a dust suction port 8-1 arranged inside the movable sound-proof shield and a threaded butt joint port 8-2 arranged outside the movable sound-proof shield. The cap 8-3 is detachably connected with the thread butt joint port 8-2, and the cap 8-3 is also made of sound insulation materials. The dust collector 8-4 is provided with a dust collection hose 8-4a detachably connected with the threaded butt joint port 8-2.

In a non-dust removal state, the thread butt joint port 8-2 is connected with the cap 8-3, so that the movable sound-proof shield can be normally used. When dust removal is needed, the cover cap 8-3 and the threaded butt joint port 8-2 are detached, then the dust collection hose 8-4a of the dust collector 8-4 is connected with the threaded butt joint port 8-2, finally the dust collector 8-4 is turned on, and the mosquito debris in the movable sound-proof cover and dust in the lamp holder groove 1-1 are completely cleaned through the dust collector 8-4.

Compare and to clear up its inside after will driving the mosquito lamp and dismantle, clear up driving the mosquito lamp through the dust removal subassembly, it is more convenient, and can not cause the damage to the spare part of driving the mosquito lamp, make and drive the mosquito lamp and can use for a long time.

Further, the controller comprises a movable sound-proof housing state detection unit and a power grid power supply control unit. And the movable sound-proof shield state detection unit is used for detecting whether the movable sound-proof shield is in the second state or not, and when the rotating motor 7-3 drives the movable sound-proof shield to rotate until the limiting guide bulge of the movable sound-proof shield contacts with the arc second end of the limiting guide groove 7-7, the movable sound-proof shield is in the second state. And the power grid power supply control unit is connected with the dynamic sound-proof shield state detection unit and is used for electrifying the power grid 5 when the dynamic sound-proof shield is in the second state.

After the total power source of this application mosquito repellent lamp was opened, acoustic generator 3 can be got electric in order to send the sound wave of attracting the mosquito, and mosquito luring lamp 4 can be got electric in order to send the light wave of attracting the mosquito, rotates motor 7-3 and can get electric in order to drive move the sound-proof housing and rotate to first state (first axial clearance with second axial clearance coincidence completely), notice electric wire netting 5 is uncharged this moment. When mosquitoes enter the movable sound-proof shield, the mosquito sensor senses that mosquito signals are sent to the controller, and the controller controls the rotating motor 7-3 to drive the movable sound-proof shield to rotate from the first state to the second state after receiving the mosquito signals. When the movable sound-proof shield state detection unit detects that the movable sound-proof shield is in the second state, a corresponding signal is sent to the power grid power supply control unit, and the power grid power supply control unit controls the power grid 5 to be electrified so as to electrocute mosquitoes. When the mosquitoes in the movable sound-proof shield die, the mosquito sensor can send a mosquito-free signal to the controller, and the controller can control the rotating motor 7-3 to drive the movable sound-proof shield to rotate from the first state to the second state after receiving the mosquito-free signal. When the movable sound-proof shield state detection unit detects that the movable sound-proof shield is not in the second state, a corresponding signal is sent to the power grid power supply control unit, and the power grid power supply control unit enables the power grid 5 to lose power.

The arrangement of the dynamic sound-proof shield state detection unit and the power grid power supply control unit enables the power grid 5 to be electrified when mosquitoes are killed by electricity on the one hand, and the power grid is not electrified at other times, so that electric energy can be effectively saved, and the waste of electricity resources is avoided. On the other hand, the movable sound-proof housing starts to kill mosquitoes by electricity when entering a completely closed state, so that the phenomenon that the sound of killing mosquitoes by electricity is generated when the movable sound-proof housing is not closed yet is avoided, and the sound-proof assembly cannot effectively insulate sound.

Further, as shown in fig. 12 and 13, the outer peripheral wall of the static cover cylinder 7-5 is provided with a reinforcing outer stirrup 7-5a, and the inner peripheral wall of the movable cover cylinder 7-2 is provided with a reinforcing inner stirrup 7-2 a. The reinforced outer stirrups 7-5a are arranged at the axial end, far away from the supporting plate 7-4, of the static cover cylinder 7-5 and used for enhancing the structural strength of the free end of the static cover cylinder 7-5, and the reinforced inner stirrups 7-2a are arranged at the axial end, far away from the rotating plate 7-1, of the movable cover cylinder 7-2 and used for enhancing the structural strength of the free end of the movable cover cylinder 7-2, so that the relative rotation of the movable cover cylinder 7-2 and the static cover cylinder 7-5 is smoother.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and do not limit the spirit and scope of the present invention. Various modifications and improvements of the technical solutions of the present invention may be made by those skilled in the art without departing from the design concept of the present invention, and the technical contents of the present invention are all described in the claims.

Claims

1. The utility model provides an ultrasonic wave economic benefits and social benefits mosquito repellent lamp which characterized in that: comprises that

The lamp holder (1) is provided with a lamp holder groove (1-1);

the bottom of the lampshade (2) is provided with a first lampshade opening, the side wall of the lampshade is provided with a second lampshade opening, and the first lampshade opening is communicated with the lamp holder groove (1-1);

the sound wave generator (3) is arranged in the lamp holder groove (1-1) and is used for emitting sound wave signals for attracting mosquitoes;

the mosquito-lured lamp (4) is arranged in the lampshade (2) and is used for emitting light wave signals for luring mosquitoes;

the power grid (5) is connected with the second opening of the lampshade and is used for electrically shocking mosquitoes;

and the power supply (6) is arranged in the lamp holder groove (1-1) and used for supplying power to the sound wave generator (3), the mosquito-lured lamp (4) and the power grid (5).

2. The ultrasonic double-effect mosquito repelling lamp according to claim 1, characterized in that: the mosquito repelling lamp further comprises a sound insulation component; the sound insulation assembly comprises

The movable sound-proof shield comprises a rotating plate (7-1) and a movable shield cylinder (7-2) arranged around the rotating plate (7-1), wherein a first axial gap is formed in the movable shield cylinder (7-2);

the rotating motor (7-3) is connected with the top of the lampshade (2), and an output shaft of the rotating motor is connected with the rotating plate (7-1) and used for driving the movable sound-proof cover to rotate;

the static sound-proof shield comprises a supporting plate (7-4), and a static shield cylinder (7-5) which is arranged around the supporting plate (7-4) and is sleeved with the peripheral wall of the movable shield cylinder (7-2), wherein a second axial gap is formed in the static shield cylinder (7-5);

the mosquito sensor is arranged inside the movable shield cylinder (7-2) and used for sensing whether mosquitoes enter the movable sound-proof shield or not;

the controller is connected with the mosquito sensor and the rotating motor (7-3);

3. The ultrasonic double-effect mosquito repelling lamp according to claim 2, characterized in that: the lamp holder looping that backup pad (7-4) seted up with lamp holder (1) cup joints, still include with backup pad (7-4) are connected and around static sound-proof housing mounting panel (7-6) that the lamp holder looping set up.

4. The ultrasonic double-effect mosquito repelling lamp according to claim 2, characterized in that: the supporting plate (7-4) is further provided with a limiting guide groove (7-7), and the bottom of the movable cover cylinder (7-2) is provided with a limiting guide bulge which is connected with the limiting guide groove (7-7) in a matched manner.

5. The ultrasonic double-effect mosquito repelling lamp according to claim 2, characterized in that: the side, facing the rotating plate (7-1), of the supporting plate (7-4) is provided with a first arc-shaped light-scattering slope, and the first arc-shaped light-scattering slope is provided with a first reflective film (7-8);

and the rotating plate (7-1) is provided with a second arc-shaped light-scattering slope on the side facing the supporting plate (7-4), and the second arc-shaped light-scattering slope is provided with a second reflecting film (7-9).

6. The ultrasonic double-effect mosquito repelling lamp according to claim 2, characterized in that: the mosquito repelling lamp also comprises a dust removing component; the dust removing component comprises

The dust suction head is connected with the dust removal hole of the rotating plate (7-1) and comprises a dust suction port (8-1) arranged inside the movable sound-proof shield and a threaded butt joint port (8-2) arranged outside the movable sound-proof shield;

the cap (8-3) is detachably connected with the threaded butt joint port (8-2);

the dust collector (8-4) is provided with a dust collection hose (8-4 a) detachably connected with the threaded butt joint port (8-2).

7. The ultrasonic double-effect mosquito repelling lamp according to claim 2, characterized in that: the controller comprises

and the power grid power supply control unit is connected with the dynamic sound-proof shield state detection unit and is used for electrifying the power grid (5) when the dynamic sound-proof shield is in the second state.

8. The ultrasonic double-effect mosquito repelling lamp according to claim 2, characterized in that: the outer peripheral wall of the static cover cylinder (7-5) is provided with a reinforced outer stirrup (7-5 a); the inner circumferential wall of the movable cover cylinder (7-2) is provided with a reinforced inner stirrup (7-2 a).

9. The ultrasonic double-effect mosquito repelling lamp according to claim 1, characterized in that: electric wire netting (5) include with electric wire netting frame (5-1) that lamp shade (2) dismantlement formula is connected, install electric wire netting line (5-2) on electric wire netting frame (5-1), with power supply line (5-3) that electric wire netting line (5-2) are connected, with power supply connector (5-4) that power supply line (5-3) are connected, and install in lamp holder groove (1-1) and be used for with the joint connecting seat that power supply connector (5-4) are connected, connect the connecting seat pass through control switch with power (6) are connected.

10. The ultrasonic double-effect mosquito repelling lamp according to claim 1, characterized in that: the top of the lampshade (2) is provided with a handle (2-1).