WO2015043179A1 - 昆虫诱捕器 - Google Patents

昆虫诱捕器 Download PDF

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Publication number
WO2015043179A1
WO2015043179A1 PCT/CN2014/076282 CN2014076282W WO2015043179A1 WO 2015043179 A1 WO2015043179 A1 WO 2015043179A1 CN 2014076282 W CN2014076282 W CN 2014076282W WO 2015043179 A1 WO2015043179 A1 WO 2015043179A1
Authority
WO
WIPO (PCT)
Prior art keywords
insect trap
air inlet
housing
trap according
bait
Prior art date
Application number
PCT/CN2014/076282
Other languages
English (en)
French (fr)
Inventor
方向前
刘宪雄
Original Assignee
荣金集团有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 荣金集团有限公司 filed Critical 荣金集团有限公司
Priority to US15/024,922 priority Critical patent/US20160212984A1/en
Publication of WO2015043179A1 publication Critical patent/WO2015043179A1/zh

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Classifications

    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01MCATCHING, TRAPPING OR SCARING OF ANIMALS; APPARATUS FOR THE DESTRUCTION OF NOXIOUS ANIMALS OR NOXIOUS PLANTS
    • A01M1/00Stationary means for catching or killing insects
    • A01M1/10Catching insects by using Traps
    • A01M1/106Catching insects by using Traps for flying insects
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01MCATCHING, TRAPPING OR SCARING OF ANIMALS; APPARATUS FOR THE DESTRUCTION OF NOXIOUS ANIMALS OR NOXIOUS PLANTS
    • A01M1/00Stationary means for catching or killing insects
    • A01M1/02Stationary means for catching or killing insects with devices or substances, e.g. food, pheronones attracting the insects
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01MCATCHING, TRAPPING OR SCARING OF ANIMALS; APPARATUS FOR THE DESTRUCTION OF NOXIOUS ANIMALS OR NOXIOUS PLANTS
    • A01M1/00Stationary means for catching or killing insects
    • A01M1/02Stationary means for catching or killing insects with devices or substances, e.g. food, pheronones attracting the insects
    • A01M1/023Attracting insects by the simulation of a living being, i.e. emission of carbon dioxide, heat, sound waves or vibrations
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01MCATCHING, TRAPPING OR SCARING OF ANIMALS; APPARATUS FOR THE DESTRUCTION OF NOXIOUS ANIMALS OR NOXIOUS PLANTS
    • A01M1/00Stationary means for catching or killing insects
    • A01M1/08Attracting and catching insects by using combined illumination or colours and suction effects
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A50/00TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE in human health protection, e.g. against extreme weather
    • Y02A50/30Against vector-borne diseases, e.g. mosquito-borne, fly-borne, tick-borne or waterborne diseases whose impact is exacerbated by climate change

Definitions

  • the invention relates to an insect trap.
  • the present invention relates to an insect trap that attracts and captures insects such as mosquitoes and fruit flies by a light source and/or bait. Background technique
  • mosquito-borne diseases such as malaria, dengue fever, encephalitis and West Nile virus infection.
  • the bites of mosquitoes often interfere with humans, causing discomfort to human body and sleep.
  • the use of chemical insecticides to kill mosquitoes is harmful to human health and has environmentally damaging consequences.
  • the use of mosquito coils and the like can only temporarily remove mosquitoes without reducing their number.
  • mosquitoes find the source of blood through the concentration of carbon dioxide to determine the target of biting, the researchers also studied mosquito traps that use carbon dioxide to trap mosquitoes.
  • a photocatalyst mosquito trap that has been commercially used, which adds a titanium dioxide coating inside the mosquito trap, claiming that titanium dioxide can react with ultraviolet rays to generate negative ion oxygen, and negative ion oxygen chemically reacts with floating microorganisms in the air to form carbon dioxide and water. .
  • the attraction of ultraviolet light combined with carbon dioxide enhances the mosquito trapping effect.
  • no scientific instrument has detected the carbon dioxide produced by photocatalyst mosquito traps.
  • the mosquito trapping effect of this mosquito trap is similar to that of a mosquito trap with only a light source.
  • U.S. Patent No. 6,145,243 to Wigton et al. discloses a convection insect trapping device for attracting mosquitoes by carbon dioxide.
  • the device uses carbon dioxide generated by combustion and catalysis of a fuel such as helium hydrocarbon as a bait, and carbon dioxide is discharged through an exhaust pipe, and mosquitoes attracted to the vicinity of the exhaust pipe outlet by carbon dioxide are sucked by a suction pipe concentrically around the exhaust pipe.
  • a Kun the insect trapping device uses carbon dioxide as a bait to attract insects, the convective layout makes the structure very complicated.
  • Non-Patent Document 1 Nasci, RS, CW. Harris and CK Porter. 1983. Failure of an insect electrocuting device to reduce mosquito biting. Mosquito News. 43:180- 184
  • Patent Document 2 US Patent US 6,145,243
  • the present invention provides a insect trap capable of overcoming the above disadvantages, having a small size, a simple structure, and an effective insect trap.
  • the present invention provides an insect trap that can include a housing having an air inlet and an exhaust port; a fan device disposed in the housing and configured to pass through the housing from the air inlet Airflow to the exhaust port to inhale insects from the air inlet; collecting device connected to the exhaust port of the casing to collect insects sucked into the casing; and bait box having a cavity for placing the bait And an opening for dispersing the bait volatiles.
  • the bait box is arranged such that the opening of the bait box is in the vicinity of the air inlet, upstream of the flow direction of the air inlet in the flow direction of the air flow, and toward the outer side of the housing.
  • the housing may be a hollow cylinder, the fan device is disposed in the hollow portion of the cylinder, the intake port and the exhaust port are in communication with the hollow portion, and the intake port and the exhaust port are in the barrel
  • the position and orientation are set such that the exhaust of the exhaust port does not cause turbulence near the intake port.
  • the air inlet may be located at one end of the cylinder, and the air outlet may be located at the other end of the cylinder Department. Further, the intake port may be provided on the end surface at one end of the cylinder.
  • the housing may also include an air inlet cover forming one end of the barrel, and the air inlet cover may include at least one opening for forming the air inlet.
  • the air inlet may also be provided on a side surface at one end of the cylinder.
  • the air inlet cover may be formed with a grille at its end surface to form an air inlet, the bait box is mounted to the center of the end surface, and the center of the end surface is aligned with the center of the fan unit.
  • the bait box is detachably mounted to the housing.
  • the bait box can be placed adjacent to the air inlet.
  • the bait box may be mounted in the housing, the bait box may be mounted to the end surface of the barrel at one end, and the bait box may be mounted to the center of the end surface of the barrel at one end.
  • the bait box may include a plurality of, and the plurality of bait boxes may be arranged at equal intervals.
  • the collecting device may be a gas permeable bag or a box including a gas permeable net, and the collecting device is detachably mounted to the housing.
  • the collection device can include a valve that opens when the collection device is coupled to the housing such that insects drawn through the intake port can pass through the valve into the collection device, and when the collection device is detached from the housing, the valve is closed, causing the collection device The insects inside cannot leave the collection device from the valve.
  • the housing may also include a thimble
  • the collection device may further include a spring device rotatably coupled to the collection device by a hinge, and the spring device applies a force to the valve to close the valve, the thimble forcing when the collection device is mounted to the housing The valve rotates in the direction of opening.
  • the bait may be one or a combination of the following: pheromone, lactic acid, octenol, a compound that cleaves ammonia, and a compound that cleaves carbon dioxide.
  • the compound which cleaves the ammonia gas may be ammonia hydrogencarbonate.
  • the compound which can cleave carbon dioxide can be ammonia hydrogencarbonate.
  • the aperture of the opening of the bait box can be configured such that the bait has a volatility between 0.1 mg/hr and 10 mg/hr.
  • the insect trap further includes a light emitting device that can be used to emit light that attracts the insect.
  • the light emitting device may be at least one of the following: a light emitting diode, a fluorescent lamp, or a cold cathode ray tube.
  • the illuminating device may be a light emitting diode that emits ultraviolet light.
  • the power of the light emitting diode can range from 0.01 W to 1 W.
  • the power of the light emitting diode can be 0.06w.
  • the light emitting diode may include a plurality of.
  • the light emitting device may include a plurality of light emitting diodes mounted to the air inlet cover, and emit light The diode can emit ultraviolet light.
  • the insect may be a mosquito or a fruit fly.
  • the fan means generates an air flow from the air inlet through the casing to the exhaust port to inhale the mosquito from the air inlet.
  • the insect trap of the present invention generates only a single direction of airflow at the air inlet, can capture mosquitoes in a simpler structure and avoid turbulence, and is easy to make bait volatiles.
  • the concentration reaches the requirement to attract mosquitoes.
  • the insect trap of the present invention arranges the outlet of the bait box in the vicinity of the intake port of the casing, upstream of the flow port in the flow direction of the air flow, and toward the outer side of the casing. In such a configuration, the concentration of the bait volatiles near the air inlet is highest.
  • the bait box is disposed at an end surface of the intake end of the casing, the end surface is formed with a grille, and the center of the end surface is aligned with the center of the fan device.
  • the pressure is directly in front of the bait box, so that a negative pressure caused by the air flow caused by the fan unit is generated around the bait box.
  • the pressure distribution is beneficial to appropriately increasing the volatilization amount of the bait volatiles in the bait box, and is beneficial to prolonging the residence time of the bait volatiles near the opening of the bait box, thereby increasing the vicinity of the opening of the bait box (ie, The concentration of bait volatiles in the vicinity of the upstream of the gas port.
  • the collecting device is detachably mounted to the casing and automatically opened and closed when being mounted to and detached from the casing.
  • the collecting device can be easily disassembled, and the mosquito can be prevented from escaping when disassembled.
  • the insect trap according to the present invention has a simple structure, a small size, a low cost, and the bait used is non-toxic and does not pollute the environment, and is environmentally friendly. Further, the insect trap of the present invention is suitable for indoor use.
  • FIG. 1 is a schematic view showing the overall structure of an insect trap according to a first embodiment of the present invention
  • FIG. 2 is a schematic exploded view of an insect trap according to a first embodiment of the present invention
  • FIG. 3 is a first embodiment of the present invention. Schematic diagram of the installation structure of the bait box of the insect trap of the example;
  • FIG. 4 is a schematic view showing a related structure in which a collecting device is detached from a housing and mounted to a housing according to a first embodiment of the present invention, wherein A of FIG. 4 shows a state in which the collecting device is detached from the housing, FIG. B of 4 shows a state in which the collecting device is mounted to the casing;
  • Figure 5 is a schematic view showing the working state of the insect trap according to the first embodiment of the present invention
  • a of Figure 6 is a schematic view showing the position of the insect trap and the bait box according to the first embodiment of the present invention
  • B of Figure 6 Is a schematic diagram of different effective placement positions of the insect trap and the bait box according to the first embodiment of the present invention
  • FIG. 7 is a schematic view showing the position of the insect trap and the bait box according to the second embodiment of the present invention
  • A, B, and C of Fig. 7 are the insect trap and the bait box according to the second embodiment of the present invention.
  • FIG. 1 is a schematic view showing the overall structure of an insect trap 10 according to a first embodiment of the present invention.
  • FIG. 2 is a schematic exploded view showing the insect trap 10 according to the first embodiment of the present invention.
  • the insect trap 10 includes a bait box 20, a light emitting device 30, a housing 40, a fan unit 50, and a collecting unit 60.
  • the bait box 20 is for placing the bait and attracting the mosquito by dispersing the bait volatiles, and the illuminating device 30 attracts the mosquito by illuminating.
  • the housing 40 is formed as a hollow cylinder having a substantially circular cross section.
  • Housing 40 includes settings An intake port 401 at one end thereof (hereinafter referred to as "air intake end") and an exhaust port 402 disposed at the other end, an intake port 401 and an exhaust port 402 are The hollow portion of the cylinder is in communication.
  • the fan unit 50 is disposed in the above-described hollow portion of the housing 40 for generating an air flow from the air inlet 401 to the exhaust port 402 through the housing 40 to inhale mosquitoes from the air inlet 401.
  • the collection device 60 is coupled to the exhaust port 402 of the housing 40 for collecting mosquitoes that are drawn into the housing 40 and exhausting airflow generated by the fan assembly 50.
  • the housing 40 of the insect trap 10 includes an air inlet cover 41 and an air outlet cover 42, wherein the air inlet cover 41 is formed as an end of the air inlet, and the air inlet cover 41 forms a grille on the end surface thereof.
  • the openings between the grids form an air inlet 401.
  • the intake hood 41 and the vent cover 42 are fixed to the outer ring 70, and the outer ring 70 is fixed to the base 80 to constitute the casing 40.
  • the bait box 20 has one or more cavities for placing the bait and one or more openings for dispensing the decoy volatiles, wherein different cavities can be used to place the same or different types of baits.
  • the bait box 20 is detachably mounted to the housing 40 such that the opening of the bait box 20 is adjacent the air inlet 401, upstream of the air inlet 401 in the flow direction of the air flow, and toward the outer side of the housing 40.
  • the bait cartridge 20 is attached to the center of the end surface of the air intake cover 41 (i.e., the end surface of the air intake end of the housing 40), and the center of the end surface is The center of the fan unit 50 is aligned.
  • the bait box 20 disperses the bait volatiles through its opening to attract the mosquitoes to the vicinity of the air inlet 401, so that the airflow generated by the fan unit 50 draws the mosquitoes into the casing 40 through the air inlets 401.
  • Fig. 3 is a schematic view showing a connection structure between a bait box and a casing according to the first embodiment of the present invention.
  • the bait box 20 is detachably mounted to the housing 40 by the connecting structure shown in FIG.
  • the bait box 20 is formed in a cylindrical shape, and an opening is provided on an end surface of the bait box 20 facing the outer side of the casing 40.
  • the bait box 20 is provided with a cassette 201 on the other end surface opposite to the opening side end surface.
  • the air inlet cover 41 of the housing 40 is formed with a groove at the center of the end surface on which the air inlet 401 is provided, and the bottom of the groove is provided with a groove 411 which can be used with the card provided on the bait box 20. ⁇ 201 is cooperatively connected.
  • the bait box 20 can be secured to the air inlet cover 41 of the housing 40 by snapping the cassette 201 on the bait box 20 into the slot 411 on the air inlet cover 41 of the housing 40 and rotating the bait box 20. In the reverse operation, the bait box 20 can be detached from the air inlet main body 41 of the housing 40.
  • the bait in the bait box 20 may include a substance capable of attracting mosquitoes, such as alcohol, acid, ammonia, and the like.
  • the bait may be one or a combination of the following: pheromones, lactic acid, octenol, compounds capable of cleaving ammonia gas (eg, ammonium bicarbonate, etc.), and compounds capable of cleaving and releasing carbon dioxide (eg, hydrogencarbonate) Ammonia, etc.).
  • the collecting device 60 is detachably mounted to the housing 40.
  • 4A shows a state in which the collecting device 60 of the insect trap 10 according to the first embodiment of the present invention is detached from the casing 40 (exhaust mask 42), and B of FIG. 4 shows a state according to the present invention.
  • the collecting device 60 of the insect trap 10 of the first embodiment is mounted to the state of the casing 40 (exhaust mask 42).
  • Collection device 60 includes a valve 61.
  • the valve 61 When the collecting device 60 is mounted to the housing 40, the valve 61 is opened so that mosquitoes sucked through the air inlet 401 can enter the collecting device 60, and when the collecting device 60 is detached from the housing 40, the valve 61 is closed to prevent the collecting device The mosquito inside 60 leaves the valve 61.
  • the collecting device 60 further includes a casing 62 and a gas permeable net 63, wherein the mosquitoes are collected inside the casing 62 and the gas permeable net 63, and the air current generated by the fan device 50 is discharged through the mesh of the gas permeable net 63.
  • the collecting device 60 is formed with a bayonet 621 on the edge of the casing 62, and the bayonet 621 can be coupled to the cassette 421 provided on the edge of the exhaust port cover 42 of the casing 40. .
  • the cartridge 421 on the vent 42 of the housing 40 is snapped into the bayonet 621 of the collection device 60 as shown in A of FIG. 4 and the collection device 60 is rotated as shown in B of FIG. It is fixed to the vent cover 42 of the housing 40.
  • the collection device 60 can be removed from the hood 42 of the housing 40.
  • the relevant structure of the switching operation of the valve 61 will be specifically described below.
  • the valve 61 is rotatably coupled to the casing 62 by a hinge.
  • the collection device 60 also includes a spring device (not shown) that applies a force to the valve 61 that causes it to close. Therefore, as shown in A of Fig. 4, when the collecting device 60 is detached from the housing 40, the valve 61 is closed by the force of the spring means.
  • the housing 40 is further provided with a thimble 422 corresponding to the valve 61 inside the edge of the vent cover 42.
  • the thimble 422 forces the corresponding valve 61 to rotate in the opening direction, causing the valve 61 to open, so that the mosquitoes sucked from the air inlet 401 can pass.
  • the open valve 61 enters the collection device 60.
  • the spring means applies a force to close the valve 61 to the valve 61 to close the valve 61, thereby preventing the mosquito collected in the collecting device 60 from leaving the valve 61. .
  • the casing 62 of the collecting device 60 may be plastic, and the gas permeable mesh 63 may be a wire mesh (such as stainless steel or the like), a plastic mesh or the like.
  • the mesh of the screen is preferably 250 mesh. The mesh is too small, and the resistance to the airflow is too large, so that the suction force of the airflow is too weak, and the trapped mosquitoes or dust easily block the mesh, causing the suction force of the airflow to decrease. If the mesh is too large, mosquitoes and the like are easily escaped. Further, the combination of the casing 62 and the gas permeable mesh 63 can also be replaced with a gas permeable bag.
  • the insect trap 10 further includes a light-emitting device 30.
  • the illuminating device 30 emits light for attracting mosquitoes.
  • the position and number of the light-emitting devices 30 are not particularly limited as long as they can emit light to the outside of the insect trap 10.
  • the light-emitting device 30 is caused to emit light toward the outside of the air inlet end of the insect trap 10, and more preferably, the light-emitting device 30 is disposed near the air inlet or adjacent to the air inlet.
  • the light-emitting device 30 is disposed on the end surface of the air intake cover 41 of the casing 40 to attract the mosquitoes to the vicinity of the air inlet 401.
  • the illumination device 30 can be a light emitting diode, a fluorescent or cold cathode ray tube, and other suitable illumination devices.
  • the light emitting device is a light emitting diode that emits ultraviolet light; more preferably, the light emitting diode emits ultraviolet light having a wavelength of 385 nm.
  • the illumination device 30 preferably uses a low power source.
  • the illuminating device 30 may be a light emitting diode having a power between 0.01 W and 0.1 W, and more preferably, the power of the light emitting diode is 0.06 W.
  • the light-emitting device 30 includes four light-emitting diodes of 0.06 W and emitting ultraviolet light having a wavelength of 385 nm.
  • FIG. Fig. 5 is a schematic view showing the operation of the insect trap 10 according to the first embodiment of the present invention.
  • the bait needs to be placed in the cavity of the bait box.
  • the bait box containing the bait is mounted to the housing and the insect trap 10 is activated. Thereafter, the illuminating device 30 emits light outward, the fan device 50 operates and generates and flows the airflow from the air inlet through the housing to the exhaust port as indicated by the dashed arrow b, and as indicated by the solid arrow a, the bait box 20 passes The opening emits bait volatiles outward. Since the opening of the bait box 20 is located in the vicinity of the air inlet and is located upstream of the air inlet b in the direction of the air flow b, a concentration is generated near the opening of the bait box 20 (i.e., near the upstream of the helium port). The bait volatiles of mosquitoes.
  • a portion of the bait volatiles then passes through the casing from the inlet to the vent as the gas stream b, due to the dilution of the bait volatiles by the gas stream b, downstream of the inlet to the vent, the concentration of the bait volatiles Significantly lower. Therefore, the mosquito is easily attracted by the bait volatiles and light, and flies to the vicinity of the air inlet 401.
  • the airflow generated by the fan unit 50 draws mosquitoes attracted to the vicinity of the air inlet 401 from the air inlet 401 into the casing 40, and the sucked mosquito passes through the air outlet 402 together with the air flow and enters through the open valve 61.
  • the collecting device 60 the airflow is discharged from the venting mesh 63 of the collecting device 60, and the mosquitoes are collected in the collecting device 60. At the same time, due to the airflow generated by the fan unit 50, it is difficult for the mosquito to fly back from the collecting device 60 against the airflow.
  • the bait cartridge 20 is attached to the center of the end surface of the air inlet cover 41 of the casing 40, and the center of the fan device 30 and the center of the end surface of the air inlet cover 41 of the casing 40 quasi.
  • the end surface is formed as an annular grille to form a plurality of openings serving as the intake port 401.
  • the pressure is directly small in front of the bait box 20, so that a negative pressure caused by the air flow caused by the fan unit 50 is generated around the bait box 20.
  • This pressure distribution is advantageous for appropriately increasing the amount of volatilization of the bait volatiles in the bait box 20, and is advantageous for prolonging the residence time of the bait volatiles near the opening of the bait box 20, thereby increasing the vicinity of the opening of the bait box 20 ( That is, the concentration of the bait volatiles in the vicinity of the upstream of the intake port. As a result, the efficiency of trapping mosquitoes is further improved.
  • the size and number of the apertures of the opening of the bait box 20 can be set according to the difference in the volatility of the various baits to control the volatility of the bait.
  • the volatility of the bait is preferably controlled between 0.1 mg/hr and 10 mg/hr.
  • the bait can be naturally volatilized at room temperature, and a suitable heating concentration can be achieved by temperature control using a heating device or the like.
  • the airflow generated by the fan device 50 is appropriately controlled, and the specification of the fan device 50 is determined in accordance with the demand for the airflow.
  • the airflow generated by the fan unit 50 should be large enough to allow mosquitoes attracted by the bait and light to the vicinity of the air inlet to be inhaled.
  • the airflow generated by the fan unit 50 should be small enough so that the mosquitoes attracted to the vicinity of the air inlet do not fly away from the air inlet due to the feeling of turbulence.
  • the airflow generated by the fan unit 50 should also be such as to ensure that mosquitoes that have entered the collection unit 60 do not fly back from the collection unit 60.
  • the insect trap 10 can employ a six-inch fan of 12V, 200 ⁇ , 2000 rpm.
  • the insect trap 10 can also be a fan device of other specifications, as long as the airflow generated by the fan device can satisfy the above conditions.
  • FIG. 7 shows a second embodiment of an insect trap in accordance with the present invention.
  • the second embodiment differs from the first embodiment mainly in the position of the air inlet and the position of the bait box.
  • the insect trap according to the second embodiment is an upright layout in which the casing 400 is formed as a hollow cylinder, and the fan unit 500 is disposed in the hollow portion of the cylinder.
  • the housing 400 has an intake port at one end (hereinafter referred to as "air intake end") and an exhaust port at the other end.
  • the housing 400 is supported at the end of the intake port by an end cap 900 through a plurality of struts 800 such that a gap between the plurality of struts 800 is formed as an intake port.
  • the light emitting device 300 is suspended below the end cap 900.
  • FIG. 7 various possible arrangements of the bait cartridge 200 are shown.
  • the bait box is disposed outside the end cap 900, and the opening of the bait box faces the outside of the end cap 900.
  • the bait cartridge 200 is disposed at the bottom of the end cap 900.
  • the bait cartridge 200 is disposed on a surface of the housing 400 opposite to the end cap 900.
  • the bait cartridge 200 is disposed on a side surface of the casing 400.
  • the bait box may be disposed at various positions of the housing as long as the opening of the bait box is near the air inlet of the housing, upstream of the air inlet in the flow direction of the air flow, and facing the housing The outside can be.
  • the housing 40 is a cylinder having a substantially circular cross section.
  • the cross section of the housing may be other shapes such as square, polygonal or other irregular shapes.
  • the intake port is formed at one end of the housing, and the exhaust port is formed at the other end of the housing.
  • the intake port and/or the exhaust port may be formed at other positions of the housing, such as the side surface of the middle portion of the housing, etc., as long as the position and orientation of the intake port and the exhaust port are such that the exhaust port is not exhausted. It will cause turbulence near the air inlet.
  • the present invention employs a parallel flow design in which the airflow passes from the air inlet through the housing to the exhaust port, the exhaust port is only arranged when the air inlet and the exhaust port are facing or closely adjacent. Gas will cause turbulence affecting insects at the air inlet.
  • the bait cartridge is single and disposed at the center of the end surface of the intake end of the casing.
  • the position and number of the bait box are not limited.
  • a plurality of bait boxes may also be provided.
  • the end surface of the intake end of the casing is formed as an annular grille, and an opening between the grilles forms the intake port.
  • the end surface of the inlet end of the housing may also be formed in other suitable shapes and configurations.
  • the bait box is detachably mounted to the housing by the structure of the cassette and the tongue and groove, but the bait box can also be detachably mounted to the housing by other suitable connection structures, for example Buckle, magnetic connection, friction connection, etc.
  • the bait box can also be attached to the housing, and the bait can be added to its cavity through the opening or the openable lid structure.
  • the collecting device is detachably mounted to the housing through the bayonet and the latch structure, but the collecting device may also be detachably mounted to the housing by other suitable connecting structures, such as a buckle , magnetic connection, friction connection, etc.
  • the collecting device realizes automatic opening and closing of the valve by the ejector pin and the spring device, but the present invention can also adopt other means to realize automatic opening and closing of the valve, for example, a mechanical structure or an electromagnetic structure such as a cam groove structure.
  • the insect trap includes a light emitting device.
  • the light-emitting device may not be included as needed, or a switch may be provided for the light-emitting device.
  • the insect trap of the present invention can also be used to capture other kinds of flying insects, such as fruit flies, etc., by the wavelength of the light emitted by the optical device and the mesh size of the collecting device.
  • Drosophila baits commonly used in the art include banana baits, bayberry baits, and sweet and sour baits.
  • Chinese patent application disclosure includes banana baits, bayberry baits, and sweet and sour baits.
  • CN102805110A discloses a fruit fly bait and a preparation method thereof.
  • the insect trap of the present invention has the following advantages.
  • the fan means generates an air flow from the air inlet through the casing to the exhaust port to inhale the mosquito from the air inlet.
  • the insect trap of the present invention generates only a single direction of airflow at the air inlet, thereby enabling the capture of mosquitoes and avoiding turbulence with a simpler structure, and easily causing bait volatiles. The concentration reaches the requirement to attract mosquitoes.
  • the insect trap of the present invention arranges the outlet of the bait box in the vicinity of the air inlet of the casing, upstream of the air inlet in the flow direction of the air flow, and toward the outer side of the casing.
  • the concentration of the bait volatiles near the air inlet is highest. Although a portion of the bait volatiles enters the inlet with the gas stream and flows to the downstream vent, these bait volatiles are rapidly diluted by the gas stream. As a result, the mosquito is more attracted to the bait volatiles near the air inlet than the vicinity of the exhaust port, so that the structure of the present invention can effectively improve the mosquito catching efficiency.
  • the bait box is disposed at an end surface of the inlet end of the casing, the end surface being formed with a grille, and the center of the end surface being aligned with the center of the fan unit.
  • the pressure is directly in front of the bait box, so that a negative pressure caused by the air flow caused by the fan unit is generated around the bait box.
  • the pressure distribution is beneficial to appropriately increasing the volatilization amount of the bait volatiles in the bait box, and is beneficial to prolonging the residence time of the bait volatiles near the opening of the bait box, thereby increasing the vicinity of the opening of the bait box (ie, The concentration of bait volatiles in the vicinity of the upstream of the gas port.
  • the collecting device of the insect trap of the present invention includes a valve that opens when the collecting device is mounted to the housing, so that mosquitoes sucked from the air inlet can enter the collecting device, and when the collecting device is detached from the housing, The valve is closed to prevent mosquitoes in the collection device from escaping from the valve. Therefore, the insect trap according to the embodiment of the present invention has a simple structure, a small size, a low cost, and the bait used is non-toxic and does not pollute the environment, and is environmentally friendly. Moreover, the insect trap of the present invention is suitable for indoor use.
  • the insect trap was tested with the insect trap as Comparative Example 2; wherein, Comparative Example 1 is an insect trap after the insect trap shown in A of Fig. 6 was removed from the bait box, and Comparative Example 2 was environmentally friendly from Taiwan.
  • the second generation of the mosquito-trapper commercially available from the home, Comparative Example 2 does not have the bait box shown in the present invention.
  • the insect trap shown in A of Fig. 6 and Comparative Example 1 employ a light-emitting diode as a light source device, and the insect trap shown in D of Fig.
  • Comparative Example 2 employ a cold cathode ray tube as a light-emitting device. Since the power of the illuminating devices of the two groups of insect traps in the experiment was different, in order to avoid mutual interference, the two groups of insect traps were placed at different locations for experiments.
  • insect traps that use both the bait box and the illuminating device to attract mosquitoes are much more efficient in catching mosquitoes than the insect traps that do not use the illuminating device to attract mosquitoes. It should be noted that the same insect traps increase mosquito efficiency by about 10% in a smaller electrical house than in a larger plant. This difference is mainly related to the higher concentration of bait volatiles in a small space.
  • the insect trap according to the first embodiment of the present invention shown in A of Fig. 6 of the present invention was tested with the insect traps of Comparative Example 3 and Comparative Example 4; wherein Comparative Example 3 is the A of Fig. 6
  • Comparative Example 3 is the A of Fig. 6
  • the bait box of the illustrated insect trap is placed in an insect trap in the collection device net
  • Comparative Example 4 is an insect trap after the insect trap shown in A of FIG. 6 is removed from the bait box, in addition, the insect
  • the windows of the experimental site were free of mosquito screens. This At an ambient temperature of 23 ° C to 33 ° C, and the time has entered September, there are fewer mosquitoes.
  • insect trap that places the bait box near the air inlet is more efficient than the insect trap that places the bait box away from the air inlet (for example, closer to the exhaust port).
  • insect trap that places the bait box away from the air inlet for example, closer to the exhaust port.

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Abstract

一种昆虫诱捕器,其包括:壳体(40),其具有进气口(401)和排气口(402);风扇装置(50),其布置在所述壳体(40)中,并用于产生穿过壳体(40)的气流,以从进气口(401)吸入蚊虫;收集装置(60),其连接到壳体(40)的排气口(402),以收集被吸入壳体(40)的昆虫;以及诱饵盒(20)和发光装置(30),其用于引诱蚊虫;其中,引诱盒(20)布置在进气口(401)的附近,以在进气口(401)的沿气流流动方向的上游朝向壳体(40)的外侧散发诱饵。本昆虫诱捕器,尺寸小,结构简单,而且能够有效地诱捕蚊虫。

Description

昆虫诱捕器 技术领域
本发明涉及一种昆虫诱捕器。 具体地, 本发明涉及一种通过光源和 /或 诱饵来吸引并捕捉例如蚊虫和果蝇之类的昆虫的昆虫诱捕器。 背景技术
全球每年超过一百万人死于诸如疟疾、 登革热、 脑炎和西尼罗河病毒 感染等由蚊虫传播的疾病。 除了可能带来疾病以外, 蚊虫的叮咬也时常干 扰人类, 给人类的身体和睡眠等带来不适。 使用化学杀虫剂灭蚊有害人体 健康并且具有破坏环境的后果。 使用蚊香等仅能暂时驱赶蚊虫而不能减少 其数量。
己知通过特定波长的光源来诱捕蚊虫的捕蚊器。 但是, 研究显示 (文 献 1 ) , 一种利用紫外线光来吸引蚊虫的捕蚊蝇器所杀死的昆虫中仅有约 3%-4%是叮人的雌蚊, 而约 96%-97%不是叮人的蚊虫。 仅依光源捕蚊器的 捕蚊效果并不理想。
由于蚊虫通过二氧化碳的浓度来找到血源, 从而确定叮咬的目标, 因 此, 研究者也研究了利用二氧化碳来诱捕蚊虫的捕蚊器。 己知己经商业应 用的一种光触媒捕蚊器, 其在捕蚊器内部增加二氧化钛涂层, 宣称二氧化 钛可与紫外线发生作用产生负离子氧, 负离子氧与空气中浮游微生物发生 化学作用从而形成二氧化碳与水。 通过紫外线结合二氧化碳的引诱可增强 捕蚊效果。 但是, 至今没有任何科学仪器可侦测到由光触媒捕蚊器产生的 二氧化碳, 这种捕蚊器的捕蚊效果与只有光源的捕蚊器相差不大。
此外, Wigton等的美国专利申请 No. 6,145,243公开了一种通过二氧化 碳来吸引蚊虫的对流式昆虫捕捉装置。 该装置通过将垸烃等燃料经燃烧与 催化而产生的二氧化碳作为诱饵, 二氧化碳通过排气管排出, 而被二氧化 碳吸引到排气管出口附近的蚊虫被同心围绕排气管的吸入管吸入。 这种昆 虫捕捉装置虽然采用二氧化碳作为诱饵来吸引昆虫, 但是对流式布局使其 结构非常复杂。 而且, 由于二氧化碳随气流排出而被稀释, 因此, 为了使 排气管出口处经稀释的二氧化碳的浓度达到吸引昆虫的水平, 需要在装置 内部产生大量的二氧化碳。 此外, 由于装置所需的大量燃料、 所产生的大 量二氧化碳以及较大的尺寸, 这种装置只适用于户外。 而且, 这种昆虫捕 捉装置生产工艺复杂, 售价昂贵, 其普及受到限制。
因此, 需要一种能够有效捕捉蚊虫、 结构简单、 尺寸较小且适于室内 使用的昆虫诱捕器。 参考文献列表
非专利文献 1 : Nasci, RS, CW. Harris and CK Porter. 1983. Failure of an insect electrocuting device to reduce mosquito biting. Mosquito News. 43:180- 184
专利文献 2: 美国专利 US 6,145,243 发明内容
本发明提供了一种能够克服以上缺点, 尺寸小、 结构简单而有效的昆 虫诱捕器。
本发明提供了一种昆虫诱捕器, 该昆虫诱捕器可以包括壳体, 其具有 进气口和排气口; 风扇装置, 其布置在壳体中, 并用于产生从进气口穿过 壳体到排气口的气流, 以从进气口吸入昆虫; 收集装置, 其连接到壳体的 排气口, 以收集被吸入壳体的昆虫; 以及诱饵盒, 其具有用于放置诱饵的 腔体和用于散发诱饵挥发物的开口。 其中, 诱饵盒布置为使得诱饵盒的开 口在进气口的附近, 位于进气口的沿气流的流动方向的上游, 并朝向壳体 的外侧。
根据本发明的一个方面, 壳体可以是中空的筒体, 风扇装置设置在筒 体的中空部分内, 进气口和排气口与中空部分连通, 并且进气口和排气口 在筒体的位置和朝向被设定为使得排气口的排气不会引起进气口附近的乱 流。 进气口可以位于筒体的一个端部处, 排气口可以位于筒体的另一个端 部处。 此外, 进气口可以设置在筒体的一个端部处的端表面上。 壳体还可 以包括形成筒体的一个端部的进气口罩, 进气口罩可以包括至少一个用于 形成进气口的开口。 进气口还可以设置在筒体的一个端部处的侧表面上。 进气口罩可以在其端表面形成有格栅, 从而形成进气口, 诱饵盒安装到端 表面的中心, 并且端表面的中心与风扇装置的中心对准。
根据本发明的又一个方面, 诱饵盒可拆卸地安装到壳体。 诱饵盒可以 与进气口相邻地设置。 诱饵盒可以安装在壳体内, 诱饵盒可以安装到筒体 的位于一个端部处的端表面, 并且诱饵盒还可以安装到筒体的位于一个端 部处的端表面的中心。 诱饵盒可以包括多个, 并且多个诱饵盒可以等间距 地布置。
根据本发明的又一个方面, 收集装置可以是透气的袋或包括透气网的 盒, 并且收集装置可拆卸地安装到所述壳体。 收集装置可以包括阀门, 当 收集装置与壳体连接时, 阀门开启, 使得通过进气口吸入的昆虫可以穿过 阀门进入收集装置, 并且当收集装置从壳体拆卸时, 阀门关闭, 使得收集 装置内的昆虫不能从阀门离开收集装置。 壳体还可以包括顶针, 并且收集 装置还可以包括弹簧装置, 阀门通过铰链可转动地连接到收集装置, 并且 弹簧装置向阀门施加使阀门关闭的力, 当收集装置安装到壳体时, 顶针迫 使阀门沿着开启的方向转动。
根据本发明的又一个方面, 诱饵可以是以下各项中的一者或其组合: 信息素、 乳酸、 辛烯醇、 可裂解氨气的化合物、 以及可裂解二氧化碳的化 合物。 可裂解氨气的化合物可以是碳酸氢氨。 可裂解二氧化碳的化合物可 以是碳酸氢氨。 诱饵盒的开口的孔径可以被配置为使得诱饵的挥发度在 0.1毫克 /小时到 10毫克 /小时之间。
根据本发明的又一方面, 昆虫诱捕器还包括发光装置, 其可以用于发 射引诱昆虫的光。 发光装置可以是以下各项中的至少一者: 发光二极管、 荧光灯或冷阴极射线管。
发光装置可以是发射紫外线的发光二极管。 发光二极管的功率可以在 0.01W-1W的范围内。 发光二极管的功率可以是 0.06w。 发光二极管可以包 括多个。 发光装置可以包括安装到进气口罩的多个发光二极管, 并且发光 二极管可以发射紫外线。
根据本发明的又一方面, 昆虫可以是蚊子或果蝇。
根据本发明的实施例的昆虫诱捕器, 风扇装置产生将从进气口穿过壳 体到排气口的气流, 以从进气口吸入蚊虫。 与对流式昆虫捕捉器相比, 本 发明的昆虫诱捕器在进气口处仅产生单一方向的气流, 能够以更简单的结 构实现对蚊虫的捕捉并且避免乱流, 而且容易使诱饵挥发物的浓度达到吸 引蚊虫的要求。 此外, 本发明的昆虫诱捕器将诱饵盒的出口布置在壳体的 进气口的附近, 位于进气口的沿气流的流动方向的上游, 并朝向壳体的外 侧。 以这样的配置, 在进气口附近的诱饵挥发物的浓度最高。 虽然诱饵挥 发物的一部分随着气流进入进气口, 并向下游的排气口流动, 但是这些诱 饵挥发物被气流迅速地稀释。 结果, 相比排气口附近, 蚊虫更容易被进气 口附近的诱饵挥发物所吸引, 从而本发明的结构可以有效地提高蚊虫的捕 获效率。
此外, 根据本发明, 将诱饵盒布置在壳体的进气口端部的端表面处, 该端表面形成有格栅, 并且端表面的中心与风扇装置的中心对准。 在这种 情形下, 在诱饵盒的正前方压强较小, 从而在诱饵盒的周围产生了由风扇 装置引起的气流所造成的负压。 这种压强分布, 既有利于适当增加诱饵盒 中的诱饵挥发物的挥发量, 又有利于延长诱饵盒的开口附近诱饵挥发物的 停留时间, 从而增大了诱饵盒的开口附近 (即, 进气口的上游附近) 的诱 饵挥发物的浓度。
此外, 根据本发明, 收集装置可拆卸地安装到壳体, 并且在安装到壳 体时和从壳体拆卸时自动地开启和关闭。 以这样的配置, 收集装置可以方 便地拆卸, 并且可以在拆卸时防止蚊虫逃逸。
此外, 根据本发明的昆虫诱捕器, 结构简单, 尺寸小, 成本低, 使用 的诱饵无毒性且不会污染环境, 有利于环保。 此外, 本发明的昆虫诱捕器 适用于室内使用。 附图说明
通过参照附图描述以下示例性实施例, 将更清楚地了解本发明的前述 的和另外的目的、 特征和优点, 在附图中, 相似的附图标记用来表示相似 的元件, 其中:
图 1是根据本发明的第一实施例的昆虫诱捕器的总体结构示意图; 图 2是根据本发明的第一实施例的昆虫诱捕器的分解结构示意图; 图 3是根据本发明的第一实施例的昆虫诱捕器的诱饵盒的安装结构示 意图;
图 4是示出根据本发明的第一实施例的收集装置从壳体拆卸和安装到 壳体的相关结构的示意图, 其中, 图 4的 A示出了收集装置从壳体拆卸的 状态, 图 4的 B示出了收集装置安装到壳体的状态;
图 5是根据本发明的第一实施例的昆虫诱捕器的工作状态示意图; 图 6的 A是根据本发明的第一实施例的昆虫诱捕器与诱饵盒放置位置 的示意图, 并且图 6的 B是根据本发明的第一实施例的昆虫诱捕器与诱饵 盒的不同有效放置位置示意图; 并且
图 7的 D是根据本发明的第二实施例的昆虫诱捕器与诱饵盒放置位置 的示意图, 并且图 7的 A、 B、 C是根据本发明的第二实施例的昆虫诱捕 器与诱饵盒的不同有效放置位置的示意图。 具体实施方式
下面, 将参考附图来描述本发明。 通过下面的详细描述可以更好地理 解本发明的各种元件的关系和功能。 但是, 本发明如下所述的实施例仅仅 作为示例, 本发明并不限于附图中所示的实施例。 此外, 在下面的说明 中, 以蚊虫为例来描述本发明的实施例的结构和功能。
第一实施例
图 1是示出了根据本发明第一实施例的昆虫诱捕器 10的总体结构示 意图。 图 2是示出了根据本发明第一实施例的昆虫诱捕器 10 的分解结构 示意图。 如图 1和图 2所示, 昆虫诱捕器 10包括诱饵盒 20、 发光装置 30、 壳体 40、 风扇装置 50以及收集装置 60。 诱饵盒 20用于放置诱饵并 通过散发诱饵挥发物来吸引蚊虫, 并且发光装置 30通过发光来吸引蚊 虫。 壳体 40形成为中空的筒体, 其横截面为大致圆形。 壳体 40包括设置 在其一个端部 (该端部在下文中被称为 "进气口端部" ) 的进气口 401和 设置在另一个端部的排气口 402, 进气口 401和排气口 402与筒体的中空 部分连通。 风扇装置 50布置在壳体 40的上述中空部分中, 用于产生从进 气口 401到排气口 402穿过壳体 40的气流, 以从进气口 401吸入蚊虫。 收 集装置 60连接到壳体 40的排气口 402, 用于收集被吸入到壳体 40的蚊虫 并且排出风扇装置 50所产生的气流。
再参考图 2, 昆虫诱捕器 10的壳体 40包括进气口罩 41和排气口罩 42, 其中进气口罩 41形成为进气口端部, 进气口罩 41在其端表面形成格 栅, 格栅之间的开口形成进气口 401。 进气口罩 41和排气口罩 42固定到 外圈 70, 外圈 70固定到底座 80, 从而构成壳体 40。
诱饵盒 20具有用于放置诱饵的一个或多个腔体和用于散发诱饵挥发 物的一个或多个开口, 其中不同的腔体可用于放置相同或不同种类的诱 饵。 诱饵盒 20可拆卸地安装到壳体 40, 使得诱饵盒 20的开口在进气口 401附近, 位于进气口 401的沿着气流的流动方向的上游, 并朝向壳体 40 的外侧。 具体地, 如图 1和图 2所示, 诱饵盒 20安装到进气口罩 41的端 表面 (即, 壳体 40 的进气口端部的端表面) 的中心, 并且该端表面的中 心与风扇装置 50的中心对准。 诱饵盒 20通过其开口散发诱饵挥发物将蚊 虫吸引到进气口 401 的附近, 以便于风扇装置 50所产生的气流通过进气 口 401将蚊虫吸入壳体 40。
图 3示出了根据本发明的第一实施例的诱饵盒与壳体之间的连接结构 的示意图。 诱饵盒 20通过图 3所示的连接结构可拆卸的安装到壳体 40。 如图 3所示, 诱饵盒 20形成为圆柱体形状, 开口设置在诱饵盒 20的朝向 壳体 40的外侧的端面上。 诱饵盒 20在其与开口侧端面相反的另一个端面 上设置有卡榫 201。 壳体 40的进气口罩 41在设置进气口 401—端的端表 面的中心处形成有凹槽, 凹槽的底部设置有榫槽 411, 该榫槽 411可以与 设置在诱饵盒 20上的卡榫 201相配合地连接。 通过将诱饵盒 20上的卡榫 201卡入壳体 40的进气口罩 41上的榫槽 411中并且旋转诱饵盒 20, 可将 诱饵盒 20固定到壳体 40的进气口罩 41上。 反向操作, 则可以将诱饵盒 20从壳体 40的进气口主体 41拆卸。 在本实施例中, 诱饵盒 20 中的诱饵可以包括能够引诱蚊虫的物质, 例如醇、 酸、 氨等。 例如, 诱饵可以以下各项中的一者或其组合: 信息 素、 乳酸、 辛烯醇、 能够裂解释放氨气的化合物 (例如碳酸氢氨等) 、 以 及能够裂解释放二氧化碳的化合物 (例如碳酸氢氨等) 。
下面, 将参考图 4详细地说明根据本发明的第一实施例的昆虫诱捕器
10的收集装置 60。 根据本发明的收集装置 60可拆卸地安装到壳体 40。 图 4的 A示出了根据本发明的第一实施例的昆虫诱捕器 10的收集装置 60从 壳体 40 (排气口罩 42) 拆卸的状态, 并且图 4的 B示出了根据本发明的 第一实施例的昆虫诱捕器 10 的收集装置 60安装到壳体 40 (排气口罩 42) 的状态。 收集装置 60包括阀门 61。 当收集装置 60安装到壳体 40 时, 阀门 61开启, 以使得通过进气口 401 吸入的蚊虫可以进入收集装置 60, 当收集装置 60从壳体 40拆卸时, 阀门 61关闭, 以防止收集装置 60 内的蚊虫从阀门 61 离开。 此外, 收集装置 60还包括盒体 62和透气网 63, 其中蚊虫被收集在盒体 62和透气网 63之内, 而风扇装置 50所产生的 气流穿过透气网 63的网目而排出。
以下具体说明收集装置 60安装到壳体 40和从壳体 40拆卸的相关结 构。 如图 4的 A所示, 收集装置 60在盒体 62的边缘上形成有卡口 621, 卡口 621能够与设置在壳体 40的排气口罩 42的边缘上的卡榫 421相配合 地连接。 通过如图 4的 A所示将壳体 40的排气口罩 42上的卡榫 421卡入 收集装置 60的卡口 621中并且如图 4的 B所示旋转收集装置 60, 可将收 集装置 60固定到壳体 40的排气口罩 42上。 反向操作, 则可以将收集装置 60从壳体 40的排气口罩 42拆除。
以下具体说明阀门 61的开关动作的相关结构。 阀门 61通过铰链可转 动地连接到盒体 62。 收集装置 60还包括弹簧装置 (未示出) , 该弹簧装 置向阀门 61施加使其关闭的力。 因此, 如图 4的 A所示, 当收集装置 60 从壳体 40拆卸时, 通过弹簧装置的力使阀门 61闭合。 此外, 壳体 40在排 气口罩 42的边缘内侧还设置有与阀门 61对应的顶针 422。 当收集装置 60 安装到壳体 40的排气口罩 42时, 顶针 422迫使相应的阀门 61沿着开启的 方向转动, 使阀门 61 打开, 从而使得从进气口 401 吸入的蚊虫可以通过 打开的阀门 61而进入收集装置 60。 当收集装置 60从壳体 40的排气口主 体 42拆卸时, 弹簧装置向阀门 61施加使阀门 61关闭的力, 使阀门 61关 闭, 从而防止被收集在收集装置 60内的蚊虫从阀门 61离开。
在本实施例中, 收集装置 60的盒体 62可以是塑胶的, 并且透气网 63 可以是金属丝网 (诸如不锈钢等) 和塑胶丝网等。 丝网的网目优选地为 250 目。 网目太小, 对气流的阻力太大, 从而导致气流的吸入力太弱, 并 且被捕获的蚊虫或灰尘等容易阻塞网目, 造成气流的吸入力下降。 网目太 大, 则蚊虫等容易逃出。 此外, 盒体 62和透气网 63的组合也可以用透气 的袋来代替。
根据本发明的第一实施例的昆虫诱捕器 10还包括发光装置 30。 发光 装置 30发射用于引诱蚊虫的光。 只要能够向昆虫诱捕器 10的外部发光, 发光装置 30 的设置位置和数量不受具体限制。 但是, 优选地, 使发光装 置 30朝向昆虫诱捕器 10的进气口端部的外侧发光, 并且更优选地, 使发 光装置 30设置在进气口附近, 或与进气口相邻地设置。 如图 1、 图 3和图 5所示, 在第一实施例中, 发光装置 30布置在壳体 40的进气口罩 41的端 表面上, 以将蚊虫吸引到进气口 401的附近。
发光装置 30可以是发光二极管、 荧光灯或冷阴极射线管以及其他适 合的发光装置。 优选地, 发光装置是发射紫外线的发光二极管; 更优选 地, 发光二极管所发射的紫外线波长为 385nm。 由于低功率光源对蚊虫有 足够吸引力, 又能降低对人眼球的伤害并且减少不期望的对其他益虫的诱 捕, 因此, 发光装置 30优选使用低功率光源。 例如, 发光装置 30可以是 功率可以在 0.01W到 0.1W之间的发光二极管, 更优选地, 发光二极管的 功率是 0.06W。 在本发明的第一实施例中, 发光装置 30包括四颗 0.06W、 发射波长 385nm的紫外线的发光二极管。
下面, 参考图 5详细的描述根据本发明的第一实施例的昆虫诱捕器 10 的工作原理。 图 5是根据本发明的第一实施例的昆虫诱捕器 10的工作状 态示意图。 在昆虫诱捕器 10幵始工作之前, 需要将诱饵放置到诱饵盒的 腔体中。
如图 5所示, 在将包含诱饵的诱饵盒安装到壳体并启动昆虫诱捕器 10 之后, 发光装置 30向外发射光线, 风扇装置 50运行并产生并且如虚线箭 头 b所示从进气口穿过壳体到排气口的气流, 并且如实线箭头 a所示, 诱 饵盒 20通过其开口向外散发诱饵挥发物。 由于诱饵盒 20的开口位于进气 口的附近, 且位于进气口的沿着气流 b方向的上游, 因此, 在诱饵盒 20 的开口附近 (即, 迸气口的上游附近) 产生了浓度足以吸引蚊虫的诱饵挥 发物。 诱饵挥发物的一部分随后会随着气流 b从进气口穿过壳体到排气 口, 由于气流 b对诱饵挥发物的稀释, 在进气口的下游直到排气口, 诱饵 挥发物的浓度显著降低。 因此, 蚊虫容易受诱饵挥发物和光线的吸引, 而 飞行到进气口 401附近。 风扇装置 50所产生的气流将被吸引到进气口 401 附近的蚊虫从进气口 401吸入到壳体 40中, 被吸入的蚊虫同气流一起经 过排气口 402, 并通过开启的阀门 61进入收集装置 60, 气流从收集装置 60的透气网 63排出, 而蚊虫则被收集在收集装置 60中。 同时, 由于风扇 装置 50所产生的气流, 蚊虫难以从收集装置 60逆气流飞出。
需要注意的是, 在本实施例中, 诱饵盒 20安装到壳体 40的进气口罩 41的端表面的中心, 风扇装置 30的中心与壳体 40的进气口罩 41的端表 面的中心对准。 此外, 该端表面形成为环形的格栅, 从而形成用作进气口 401的多个开口。 在这种情形下, 在诱饵盒 20的正前方压强较小, 从而在 诱饵盒 20的周围产生了由风扇装置 50引起的气流所造成的负压。 这种压 强分布, 既有利于适当增加诱饵盒 20 中的诱饵挥发物的挥发量, 又有利 于延长诱饵盒 20 的开口附近诱饵挥发物的停留时间, 从而可增大诱饵盒 20的开口附近 (即, 进气口的上游附近) 的诱饵挥发物的浓度。 结果, 进 一步提高了诱捕蚊虫的效率。
此外, 可以根据各种诱饵挥发度的不同来设置诱饵盒 20 的开口的孔 径大小和数量, 以控制诱饵的挥发度。 诱饵的挥发度优选地控制在 0.1毫 克 /小时至 10毫克 /小时之间。 此外, 诱饵可以在室温中自然挥发, 也可以 使用加热装置等通过温度控制达到适当的挥发浓度。
此外, 在本实施例中, 适当地控制由风扇装置 50所产生的气流, 并 且根据对该气流的需求来确定风扇装置 50的规格。 风扇装置 50所产生的 气流应该足够大以使得被诱饵和光线吸引到进气口附近的蚊虫能够被吸入 到壳体中, 并且风扇装置 50所产生的气流应该足够小, 以使得被吸引到 进气口附近的蚊虫不会因感觉到乱流而飞离进气口。 此外, 风扇装置 50 所产生的气流还应该能够确保已经进入收集装置 60 中的蚊虫不会从收集 装置 60逆气流飞出。 根据这样的需求, 根据本发明的第一实施例的昆虫 诱捕器 10可以采用 12V、 200μΑ、 2000转 /分的六寸风扇。 昆虫诱捕器 10 也可以采用其他规格的风扇装置, 只要风扇装置所产生的气流能够满足上 述条件即可。
第二实施例
图 7示出了根据本发明的昆虫诱捕器的第二实施例。 第二实施例与第 一实施例的不同之处主要在于: 进气口的位置以及诱饵盒的位置。 如图 7 所示, 根据第二实施例的昆虫诱捕器为直立式布局, 其中壳体 400形成为 中空的筒体, 风扇装置 500设置在筒体的中空部分内。 壳体 400在一个端 部 (下文称为 "进气口端部" ) 处具有进气口, 在另一个端部处具有排气 口。 壳体 400在进气口端部处, 通过多个支柱 800支撑有端盖 900, 从而 使得多个支柱 800之间的间隙形成为进气口。 发光装置 300悬架于端盖 900的下方。
在图 7的 A-D中, 示出了诱饵盒 200的多种可行的布置方式。 例如, 如图 7的 Α所示, 诱饵盒布置在端盖 900的外侧, 并且诱饵盒的开口朝向 端盖 900的外侧。 如图 7的 B所示, 诱饵盒 200布置在端盖 900的底部。 如图 7的 C所示, 诱饵盒 200布置在壳体 400的与端盖 900相对的表面 上。 如图 7的 D所示, 诱饵盒 200布置在壳体 400的侧表面。 总之, 根据 本发明, 诱饵盒可以布置在壳体的各种位置处, 只要使得诱饵盒的开口在 壳体的进气口附近, 位于进气口的沿气流流动方向的上游, 并且朝向壳体 的外侧即可。
其他实施例
在以上描述中, 详细地说明了根据本发明的第一实施例和第二实施例 的昆虫捕捉器。 但是, 本发明还具有其他实施例。
在前述实施例中, 壳体 40是横截面为大致圆形的筒体。 但是, 壳体 的横截面可以是其他形状, 例如方形、 多边形或其他不规则的形状。 在前述实施例中, 进气口形成在壳体的一个端部, 排气口形成在壳体 的另一个端部。 但是, 进气口和 /或排气口可以形成在壳体的其他位置, 例 如壳体的中部的侧表面等, 只要进气口和排气口的位置和朝向使得排气口 的排气不会在进气口附近造成乱流即可。 可预期的是, 由于本发明采用气 流从进气口穿过壳体到排气口的并流式设计, 只有在进气口和排气口正对 或紧密相邻时, 排气口的排气才会在进气口处造成影响昆虫的乱流。
在本发明的第一实施例的昆虫捕捉器 10中, 如图 6的 A所示, 诱饵 盒为单个, 并且布置在壳体的进气口端部的端表面的中心处。 但是, 只要 诱饵盒布置为, 使得诱饵盒的开口在进气口的附近, 位于进气口的沿气流 的流动方向的上游, 并朝向壳体的外侧, 则诱饵盒的位置和数量不受限 制。 例如, 如图 6的 B所示, 在本发明的第一实施例中, 诱饵盒也可以为 多个, 并且可以等间距地布置在壳体的进气口端部的端表面上。 在图 7所 示的实施例中, 也可以设置多个诱饵盒。
此外, 根据本发明的第一实施例, 壳体的进气口端部的端表面形成为 环形的格栅, 格栅之间的开口形成所述进气口。 但是, 壳体的进气口端部 的端表面也可以形成为其他适合的形状和结构。
此外, 根据本发明的第一实施例, 诱饵盒通过卡榫和榫槽的结构可拆 卸地安装到壳体, 但诱饵盒也可以通过其他适当的连接结构可拆卸地安装 到壳体, 例如搭扣、 磁性连接、 摩擦连接等。 此外, 诱饵盒也可以固定于 壳体, 通过开口或可打开的盖结构向其腔体添加诱饵。
此外, 根据本发明的第一实施例, 收集装置通过卡口和卡榫结构可拆 卸地安装到壳体, 但收集装置也可以通过其他适当的连接结构可拆卸地安 装到壳体, 例如搭扣、 磁性连接、 摩擦连接等。 此外, 收集装置通过顶针 和弹簧装置来实现阀门的自动开启和关闭, 但本发明也可以采用其他方式 来实现阀门的自动开启和关闭, 例如, 凸轮槽结构之类的机械结构或电磁 结构等。
此外, 在前述实施例中, 昆虫诱捕器包含发光装置。 但是根据需要, 也可以不包含发光装置, 或者为发光装置设置开关。
此外, 上文以蚊虫为例描述了本发明, 但是通过改变诱饵的种类, 发 光装置所发射光的波长和收集装置的网目大小等, 本发明的昆虫诱捕器也 可用于捕捉其他种类的飞虫, 例如果蝇等。 本领域内常用的果蝇诱饵包括 香蕉诱饵、 杨梅诱饵以及糖醋诱饵等。 例如, 中国专利申请公开
CN102805110A公开了一种果蝇诱饵及其制备方法。
效果
在上文中, 详细地说明了根据本发明的实施例的昆虫诱捕器的结构和 功能。 本发明的昆虫诱捕器具有如下优点。
根据本发明的实施例的昆虫诱捕器, 风扇装置产生将从进气口穿过壳 体到排气口的气流, 以从进气口吸入蚊虫。 与对流式昆虫捕捉器相比, 本 发明的昆虫诱捕器在进气口处仅产生单一方向的气流, 因此能够以更简单 的结构实现对蚊虫的捕捉并且避免乱流, 而且容易使诱饵挥发物的浓度达 到吸引蚊虫的要求。 此外, 本发明的昆虫诱捕器将诱饵盒的出口布置在壳 体的进气口的附近, 位于进气口的沿气流的流动方向的上游, 并朝向壳体 的外侧。 以这样的配置, 在进气口附近的诱饵挥发物的浓度最高。 虽然诱 饵挥发物的一部分随着气流进入进气口, 并向下游的排气口流动, 但是这 些诱饵挥发物被气流迅速地稀释。 结果, 相比排气口附近, 蚊虫更容易被 进气口附近的诱饵挥发物所吸引, 从而本发明的结构可以有效地提高蚊虫 的捕获效率。
此外, 在本发明的优选实施例中, 将诱饵盒布置在壳体的进气口端部 的端表面处, 该端表面形成有格栅, 并且端表面的中心与风扇装置的中心 对准。 在这种情形下, 在诱饵盒的正前方压强较小, 从而在诱饵盒的周围 产生了由风扇装置引起的气流所造成的负压。 这种压强分布, 既有利于适 当增加诱饵盒中的诱饵挥发物的挥发量, 又有利于延长诱饵盒的开口附近 诱饵挥发物的停留时间, 从而增大了诱饵盒的开口附近 (即, 进气口的上 游附近) 的诱饵挥发物的浓度。
此外, 本发明的昆虫诱捕器的收集装置包括阀门, 当收集装置安装到 壳体时, 阀门开启, 以使得从进气口吸入的蚊虫可以进入收集装置, 并且 当收集装置从壳体拆卸时, 阀门关闭, 以防止收集装置内的蚊虫从阀门逃 逸。 因此, 根据本发明的实施例的昆虫诱捕器, 结构简单, 尺寸小, 成本 低, 使用的诱饵无毒性且不会污染环境, 有利于环保。 并且, 本发明的昆 虫诱捕器适用于室内使用。
下面, 将通过两组实验来说明本发明的昆虫诱捕器的捕蚊效果。
实验一
采用本发明的图 6的 A所示的根据本发明第一实施例的昆虫诱捕器与 作为对比例 1的昆虫诱捕器、 本发明图 7的 D所示的根据本发明的第二实 施例的昆虫诱捕器与作为对比例 2的昆虫诱捕器进行实验; 其中, 对比例 1是将图 6的 A所示的昆虫诱捕器去除诱饵盒之后的昆虫诱捕器, 并且对 比例 2是可从台湾环保之家商购获得的捕蚊达人第二代, 对比例 2不具有 本发明所示的诱饵盒。 此外, 图 6的 A所示的昆虫诱捕器和对比例 1采用 发光二极管作为光源装置, 并且图 7的 D所示的昆虫诱捕器和对比例 2采 用冷阴极射线管作为发光装置。 由于进行实验的两组昆虫诱捕器的发光装 置的功率不同, 为避免相互干扰影响, 将两组昆虫诱捕器放置在不同的地 点来进行实验。
在中国广东地区, 五月平均温度为 23°C至 30°C, 六月多雨平均温度 为 25 °C至 31 °C。 蚊子三月开始活动, 五月达到最高峰, 七八月高温在 35 °C以上, 蚊子活动力下降甚至不搔扰人类。 因此, 在一年的五月到六月 蚊虫活动频繁的时间, 在蚊虫较多的广东某工厂内做长时期 24小时连续 对比试验。 实验地点为工厂的 18平方米面积较小的电工房与 210平方米 面积较大的厂房, 两个实验地点的窗户均无防蚊纱窗。
在 5月 9日至 5月 31日的第一期实验中, 将一台图 6的 A所示的第 一实施例的昆虫诱捕器和一台作为对比例 1 的昆虫诱捕器同时放置于电工 房内, 并且将一台图 7的 A所示的第二实施例的昆虫诱捕器和一台作为对 比例 2的昆虫诱捕器同时放置于面积较大的厂房内。 同一组中的两台昆虫 诱捕器的距离为 1.5m。 在 6月 1日至 6月 27日为实验的第二期, 将两组 昆虫诱捕器的位置进行调换。
对两组昆虫诱捕器中每一台捕获的蚊虫数量进行统计, 结果如表 1所 表 1本发明的昆虫诱捕器与对比例所捕获的蚊虫数量 (只) 对比
Figure imgf000016_0001
从表 1中的实验结果可以看出, 在相同时间段内, 图 6的 Α所示的第 —实施例的昆虫诱捕器与对比例 1相比, 在面积较小的电工房内捕蚊效率 提高 53%, 而在面积较大的厂房内捕蚊效率提高 41%。 类似地, 图 7的 D 所示的第二实施例的昆虫诱捕器与对比例 2相比, 在面积较小的电工房内 捕蚊效率提高 45%, 而在面积较大的厂房内捕蚊效率提高 34%。
由此可知, 同时使用诱饵盒和发光装置来吸引蚊虫的昆虫诱捕器, 与 没有诱饵盒仅使用发光装置来吸引蚊虫的昆虫诱捕器捕蚊相比, 其捕蚊效 率要高得多。 需要注意的是, 相同的昆虫诱捕器在面积较小的电工房内比 在面积较大的厂房内捕蚊效率提高约 10%, 该差异主要与小空间内诱饵挥 发物的浓度较高有关。
实验二
采用本发明的图 6的 A所示的根据本发明第一实施例的昆虫诱捕器与 作为对比例 3和对比例 4的昆虫诱捕器进行实验; 其中, 对比例 3是将图 6的 A所示的昆虫诱捕器的诱饵盒放置到收集装置网内的昆虫诱捕器, 并 且对比例 4是将图 6的 A所示的昆虫诱捕器去除诱饵盒之后的昆虫诱捕 器, 除此之外, 昆虫诱捕器的其他配置均相同。 在 8月 30到 9月 19日, 在厂房内进行 24小时连续对比实验, 实验地点的窗户无防蚊纱窗。 此 时, 环境温度为 23°C到 33°C, 而且时间已经进入 9月, 蚊虫较少。
将一台图 6的 A所示的第一实施例的昆虫诱捕器、 一台作为对比例 3 的昆虫诱捕器和一台作为对比例 4的昆虫诱捕器同时放置于厂房内, 昆虫 诱捕器的距离为 1.5m
实验结束后, 对每台昆虫诱捕器捕获的蚊虫数量进行统计, 结果如表
2所示。 表 2本发明的昆虫诱捕器与对比例所捕获的蚊虫数量 (只) 对比
Figure imgf000017_0001
从表 2中的实验结果可以看出, 在相同时间段内, 图 6的 A所示的第 一实施例的昆虫诱捕器与对比例 3相比, 在相同的厂房内捕蚊效率提高 126%。 同时, 具有诱饵盒的第一实施例相对于没有诱饵盒的对比例 4捕蚊 效率也有显著提高。
由此可知, 将诱饵盒放置在进气口附近的昆虫诱捕器, 与将诱饵盒放 置成远离进气口 (例如更加靠近排气口) 的昆虫诱捕器相比, 其捕蚊效率 要高得多。 需要注意的是, 实验中的昆虫诱捕器的捕获蚊虫总数均不高, 这与实验期间 (9月) 蚊虫数量减少有关。
虽然在上文中已经详细描述了本发明的实施例, 但是本发明不限于上 述实施例或构造, 并且可以在上述实施例上进行各种修改和替换, 而不超 出本发明的范围。

Claims

权 利 要 求 书
1.一种昆虫诱捕器, 其包括:
壳体, 其具有进气口和排气口;
风扇装置, 其布置在所述壳体中, 并用于产生从所述进气口穿过所述 壳体到所述排气口的气流, 以从所述进气口吸入昆虫;
收集装置, 其连接到所述壳体的所述排气口, 以收集被吸入所述壳体 的昆虫; 以及
诱饵盒, 其具有用于放置诱饵的至少一个腔体和用于散发诱饵挥发物 的开口; 并且
其中, 所述诱饵盒布置为, 使得所述诱饵盒的所述开口在所述进气口 的附近, 位于所述进气口的沿所述气流的流动方向的上游, 并朝向所述壳 体的外侧。
2.根据权利要求 1所述的昆虫诱捕器, 其中
所述壳体是中空的筒体, 所述风扇装置设置在所述筒体的中空部分 内, 所述进气口和所述排气口与所述中空部分连通, 并且所述进气口和所 述排气口在所述筒体的位置和朝向被设定为使得所述排气口的排气不会引 起所述进气口附近的乱流。
3.根据权利要求 2所述的昆虫诱捕器, 其中
所述进气口位于所述筒体的一个端部处, 所述排气口位于所述筒体的 另一个端部处。
4.根据权利要求 3所述的昆虫诱捕器, 其中
在所述筒体的所述一个端部处的端表面上设置所述进气口。
5.根据权利要求 4所述的昆虫诱捕器, 其中
所述壳体还包括形成所述筒体的所述一个端部的进气口罩, 所述进气 口罩包括至少一个用于形成所述进气口的开口。
6.根据权利要求 3所述的昆虫诱捕器, 其中
在所述筒体的所述一个端部处的侧表面上设置所述进气口。
7.根据权利要求 1至 6中任一项所述的昆虫诱捕器, 其中 所述诱饵盒可拆卸地安装到所述壳体。
8.根据权利要求 1至 7中任一项所述的昆虫诱捕器, 其中
所述诱饵盒与所述进气口相邻地设置。
9.根据权利要求 1至 8中任一项所述的昆虫诱捕器, 其中
所述诱饵盒安装在所述壳体内。
10.根据权利要求 3至 9中任一项所述的昆虫诱捕器, 其中
所述诱饵盒安装到所述筒体的位于所述一个端部处的所述端表面。
11.根据权利要求 10所述的昆虫诱捕器, 其中
所述诱饵盒安装到所述筒体的位于所述一个端部处的所述端表面的中 心。
12.根据权利要求 11所述的昆虫诱捕器, 其中
所述诱饵盒包括多个。
13.根据权利要求 12所述的昆虫诱捕器, 其中
多个所述诱饵盒等间距地布置。
14.根据权利要求 5所述的昆虫诱捕器, 其中
所述进气口罩的端表面形成有格栅, 从而形成进气口, 所述诱饵盒安 装到所述端表面的中心, 并且所述端表面的中心与所述风扇装置的中心对 准。
15.根据权利要求 1至 14中任一项所述的昆虫诱捕器, 其中
所述收集装置是透气的袋或包括透气网的盒。
16.根据权利要求 1至 15中任一项所述的昆虫诱捕器, 其中
所述收集装置可拆卸地安装到所述壳体。
17.根据权利要求 16所述的昆虫诱捕器, 其中
所述收集装置包括阀门, 当所述收集装置安装到所述壳体时, 所述阀 门开启, 使得通过进气口吸入的昆虫可以穿过所述阀门进入所述收集装 置, 并且当所述收集装置从所述壳体拆卸时, 所述阀门关闭, 使得所述收 集装置内的昆虫不能从所述阀门离开所述收集装置。
18.根据权利要求 17所述的昆虫诱捕器, 其中
所述壳体包括顶针, 所述收集装置还包括弹簧装置, 所述阀门通过铰链可转动地连接到所 述收集装置, 所述弹簧装置向所述阀门施加使所述阀门关闭的力,
当所述收集装置安装到所述壳体时, 所述顶针迫使所述阀门沿着开启 的方向转动。
19.根据权利要求 1至 18中任一项所述的昆虫诱捕器, 其中
所述诱饵是以下各项中的一者或其组合: 信息素、 乳酸、 辛烯醇、 能 够裂解释放氨气的化合物、 以及能够裂解释放二氧化碳的化合物。
20.根据权利要求 19所述的昆虫诱捕器, 其中
所述可裂解氨气的化合物是碳酸氢氨。
21.根据权利要求 19所述的昆虫诱捕器, 其中
所述可裂解二氧化碳的化合物是碳酸氢氨。
22.根据权利要求 19至 21中任一项所述的昆虫诱捕器, 其中
所述诱饵盒的所述开口的孔径被配置为使得所述诱饵的挥发度在 0.1 毫克 /小时到 10毫克 /小时之间。
23.根据权利要求 1至 22中任一项所述的昆虫诱捕器, 还包括 发光装置, 其用于发射引诱昆虫的光。
24.根据权利要求 23所述的昆虫诱捕器, 其中
所述发光装置是以下各项中的至少一者: 发光二极管、 荧光灯或冷阴 极射线管。
25.根据权利要求 23所述的昆虫诱捕器, 其中
所述发光装置是发射紫外线的发光二极管。
26.根据权利要求 25所述的昆虫诱捕器, 其中
所述发光二极管的功率在 0.01W-1W的范围内。
27.根据权利要求 26所述的昆虫诱捕器, 其中
所述发光二极管的功率是 0.06w。
28.根据权利要求 23至 27中任一项所述的昆虫诱捕器, 其中
所述发光二极管包括多个。
29.根据权利要求 14所述的昆虫诱捕器, 其中
所述发光装置包括安装到所述进气口罩的多个发光二极管, 所述发光
30.根据权利要求 1至 29中任一项所述的昆虫诱捕器, 其中 所述昆虫是蚊子或果蝇。
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US20160212984A1 (en) 2016-07-28
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JP5941932B2 (ja) 2016-06-29
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