KR20120073476A - Apparatus for capturing vermin - Google Patents

Abstract

The disclosed pest trapping device includes a housing having an inlet through which a pest is introduced, a capture unit provided inside the housing for capturing pests, a light source emitting light in front of the housing to attract pests, and scattering light Stimulating pests, the scattering comprising a container disposed adjacent to the inlet, the upper side is open or the upper side is protected by a transparent window, the liquid contained in the container and scattering means for scattering the reflected light of the liquid surface Induction unit is provided.

Description

Pest trapping device {Apparatus for capturing vermin}

The present invention relates to a pest trapping device, and more particularly, to a pest trapping device having means for trapping pests and means for attracting the pests to the means for trapping the pests.

Pests are terms that refer to insects that damage humans, causing damage to food and textiles by damaging and contaminating them or transferring germs. Among these pests, in order to remove flying pests such as flies, mosquitoes, moths, etc., a device for capturing the pests by attracting the pests with light and electric shock or sticking to the sticky string is used. Such a pest trapping apparatus is also called a repeller or a repulsive impulse.

By the way, the conventional pest trapping apparatus uses only direct light emission using a fluorescent lamp as a means of attracting pests, and it is not enough as a motive for attracting pests. In addition, since the fluorescent lamp does not selectively irradiate light of a specific wavelength and emits light of a relatively wide wavelength band, it is difficult to respond to pest capture appropriately in a region or time when the frequency of occurrence of a particular pest is high.

The present invention provides a pest trapping apparatus that improves pest attraction by using light scattering as well as direct light emission using a light source.

The present invention provides a pest capture device that is easy to respond to the pest according to the region or time by increasing the wavelength band selectivity of the light source.

The present invention, the housing is formed with an inlet through which the pest is introduced, the capture unit provided inside the housing, the capture unit for capturing the pest, a light source for emitting light in front of the housing to attract the pest, and scattering the light to pests A scattering induction unit comprising a container disposed adjacent to the inlet and stimulated, the upper side being protected by a transparent window, the liquid contained in the container, and scattering means for scattering the reflected light of the liquid surface. It provides a pest capture device having a.

The light source may be configured to change the projection direction of the light.

The light source may include a light emitting diode (LED) that emits light of a wavelength preferred by the pest.

The light source may include a plurality of LED mounting terminals capable of mounting an LED detachably, and each LED mounting terminal may be configured to mount an LED having a predetermined wavelength.

The light source includes an LED chip on which at least one LED is mounted, and a plurality of LED chip mounting terminals on which the LED chip can be detachably mounted, and each LED chip mounting terminal is a predetermined type of LED chip. It can be configured to be mounted.

The capture unit may include a sticky tape coated with an adhesive substance to which pests are attached.

The pest trapping device may further include a mirror for reflecting the scattered light caused by the ripples of the liquid surface to the front of the housing.

The pest capture device may further include a fan that induces air flow to direct pests around the inlet to the capture unit.

The pest trapping device has a mesh smaller than the size of the pest in front of the fan to prevent pests introduced into the housing through the inlet from flowing out of the housing by air flow induced by the fan. The pest filter which has is further provided.

The pest trapping device has a mesh smaller than the size of the pest in front of the fan to prevent pests introduced into the housing through the inlet from flowing out of the housing by air flow induced by the fan. The pest filter which has is further provided.

The pest capture device may further include a TiO ₂ coating layer applied to the inner surface of the housing in which the capture unit is embedded, and a UV light source for irradiating ultraviolet light (UV) to the capture unit and the TiO ₂ coating layer.

The pest capture device may further include a sterilization filter including a sterilization filter including TiO ₂ disposed in the housing inner space in which the capture unit is embedded, and a UV light source for irradiating ultraviolet light (UV) to the sterilization filter. Can be.

The scattering means may be configured to induce ripple formation on the liquid surface.

The scattering means may be configured to vibrate the container.

The scattering means may be configured to vibrate on the surface of the liquid or while submerged in the liquid.

The scattering means may comprise at least one of a plurality of beads, a plurality of fly eye lenses, and a plurality of cube lenses, which cause scattering of light.

The pest trapping apparatus according to the present invention attracts pests through light scattering of ripples as well as direct light emission using a light source, thereby improving insect attraction and trapping performance.

The pest capture device according to the present invention increases the wavelength band selectivity of the light source, and it is easy to respond to the pest according to the region or time.

In addition, the pest capture device using the LED as a light source can reduce the power use compared to the pest capture device using a fluorescent lamp as a light source.

1 is a cross-sectional view showing a pest capture device according to an embodiment of the present invention.
2 is a view for explaining the pest attraction effect using light scattering of the pest capture device of the present invention.
3 is a plan view showing a board for LED mounting, which is provided in the pest capture device according to an embodiment of the present invention.
4 and 5 are perspective views showing modifications of the scattering inducing unit, which can be mounted to the pest trapping apparatus of the present invention.
6 is a perspective view showing an example of a sterilization unit that can be mounted to the pest trapping apparatus of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a pest trapping apparatus according to an embodiment of the present invention.

1 is a cross-sectional view showing a pest capture device according to an embodiment of the present invention, Figure 2 is a view illustrating a pest attraction effect using light scattering of the pest capture device of the present invention, Figure 3 is an embodiment of the present invention It is a top view which shows the board | substrate for LED mounting provided with the pest trapping apparatus which concerns on this. Referring to FIG. 1, the pest capture device 10 includes a housing including an upper housing 11 and a lower housing 14, a capture unit 20 provided inside the lower housing, a light source attached to the upper housing 11, And a scattering induction unit 40 attached to an upper side of the lower housing 14. The lower housing 14 is disposed at a rear side adjacent to the scattering induction unit 40 and has an inlet 15 open upwardly so that the pest 5 can be introduced therein, and is disposed at the front lower side. A vent hole 17 is provided.

The capture unit 20 has a sticky tape 21 coated with an adhesive substance to which the pests 5 adhere. The surface of the sticky tape 21 may be further coated with a pesticide that causes the pest 5 to die upon contact or ingestion, and a surfactant that paralyzes the motor nerve of the pest 5 in addition to the adhesive material. The sticky tape 21 is previously wound on the feed roll 22 and the tip is connected to the recovery roll 23 through the first and second pulleys 24 and 25. The sticky tape between the first and second pulleys 24 and 25 is configured to stick the pests 5 to the upper side of the tape 21, and the sticky tape between the first and second pulleys 24 and 25 after a certain period of time. When the adhesive force of 21 is weakened, the recovery roll 23 is rotated to recover the wound, and at the same time, a new sticky tape having strong adhesive force is exposed between the first and second pulleys 24 and 25. Can be. On the other hand, the capture unit is not limited to the configuration provided with the sticky tape 21, as shown in Figure 1, for example, may be provided with a configuration that electrocuts and kills pests.

The upper housing 11 has a side facing the scattering induction unit 40 inclined diagonally, the light source is provided on the inclined surface of the upper housing 11. The light source includes a light emitting diode (LED) 30 that emits light of a wavelength preferred by a pest, and a mounting board 35 on which the LED 30 is mounted. A mirror 26 reflecting light is formed on an obliquely inclined surface of the upper housing 11. Therefore, when the LED 30 emits light, the light is irradiated to the front of the upper and lower housings 11 and 14. The mounting board 35 further includes a hinge 37 rotatably coupled to the upper housing 11 to change the light projection direction of the LED 30. Due to the configuration provided with the hinge 37, the rotation angle of the mounting board 35 can be adjusted so that the light of the LED 30 is irradiated in a direction more effective for controlling the pests 5.

On the other hand, the pest capture device 10 may further include an auxiliary light source for projecting light directly toward the front. The auxiliary light source may be installed in front of the upper housing 11 and may include an LED 38 that projects light forward.

The LEDs 30 and 38 can intensively irradiate light in a wavelength band preferred by a particular kind of pest 5, which is advantageous in attracting pests compared to fluorescent lamps irradiating light in a relatively wide range of wavelength bands. For example, ultraviolet light (UV) is easy to stimulate flies and mosquitoes, yellow visible light is easy to stimulate one type of moth, blue visible light is easy to stimulate another type of moth. Therefore, by selecting the type of the LED (30, 38) it is possible to intensively capture a particular kind of pest (5). In addition, the LED (30, 38) has the advantage that the power consumption is lower than the fluorescent lamp, the light emission time is long, the maintenance cost is low.

The upper housing 11 is provided with a heat radiation fan 18 for preventing overheating of the LED (30, 38). When the heat radiating fan 18 rotates, air flows along the rear surface of the mounting board 35 to absorb heat and is discharged through the vent hole 12. In order to promote heat dissipation through the heat dissipation fan 18, a heat dissipation fin 38 may be formed on the rear surface of the mounting board 35.

Referring to FIG. 3, the mounting board 35 includes a plurality of LED mounting terminals 36 on which the LED 30 (see FIG. 1) can be mounted in a detachable manner. Each LED mounting terminal 36 may be designed to mount a predetermined type of LED. For example, 28 LED mounting terminals 36 may be arranged in four rows and seven columns on the LED mounting board 35, and ultraviolet light (UV) light may be applied to the LED mounting terminals 36 having odd columns L1, L3, L5, and L7. UV LED emitting light) may be mounted, and the LED mounting terminal 36 of even rows L2, L4, and L6 may be mounted with a BLUE LED emitting blue visible light. According to the user's choice, only a part of the LED mounting terminals 36 of odd-numbered columns (L1, L3, L5, L7) are equipped with UV LEDs to operate the pest trapping device 10, thereby making fly and mosquitoes the main targets. The moth may be set as the main target by operating the pest trapping device 10 by mounting the BLUE LED only in a part of the LED mounting terminals 36 of even rows L2, L4, and L6. Alternatively, some of the LED mounting terminals 36 in the odd rows L1, L3, L5, and L7 mount UV LEDs, and some of the LED mounting terminals 36 in the even rows L2, L4, L6 connect the BLUE LEDs. It can also be used to target all flies, mosquitoes and moths.

On the other hand, unlike FIG. 3, the mounting board 35 mounts an LED chip (not shown) on which at least one LED is mounted, instead of the LED mounting terminal 36 for directly mounting individual LEDs. A plurality of LED chip mounting terminals (not shown) may be provided. At this time, each LED chip mounting terminal may be configured to mount a predetermined type of LED chip. In addition, the light source is not limited to the structure provided with the LED 30 as shown in FIG. 1, For example, it may be provided with the structure provided with the fluorescent lamp.

Referring back to FIG. 1, the scattering induction unit 40 is attached to the upper side of the lower housing 14 facing the light source. The scattering induction unit 40 is to scatter light to stimulate the pest 5, the upper side of the container 41 is protected by a transparent window 43, the liquid 45 contained in the container 41 and And a diaphragm 47 for vibrating the container 41 to cause ripples 46 (see FIG. 2) on the surface of the liquid 45. The liquid 45 may be, for example, inexpensive and stable water (H ₂ O). The upper side of the container 41 may be opened without the transparent window 43. The diaphragm 47 is only one example of scattering means for supporting the container 41 and vibrating the container 41, and replaces the vibrator used in the mobile phone instead of the diaphragm 47. It may be attached to the outer surface of the to cause vibration. Alternatively, scattering means for forming the ripples 46 in the liquid 45 without vibrating the container 41 may be possible. For example, the stick may be moved on the surface of the liquid 45 or submerged in the liquid 45 to cause ripples on the surface of the liquid 45. Alternatively, the propeller may be rapidly rotated on the surface of the liquid 45 or submerged in the liquid 45 to cause ripples on the surface of the liquid 45. Alternatively, an ultrasonic vibrator may be used to cause ripples.

1 and 2 together, the container 41 vibrates due to the vibration caused by the diaphragm 47, which causes ripples 46 to occur on the surface of the liquid 45 inside the container 41. Light projected from the LED 30 and the surroundings to the liquid 45 side is scattered in the irregular direction by the ripples 46. Such scattered light S is projected toward the front of the upper housing 11 and the lower housing 14 directly or in the form of the reflected light R reflected by the mirror 26. The eye of the pest 5 has a hexagon shape, and is known to be greatly stimulated by rapid blinking of light or scattered light due to lattice or waves. Therefore, the scattered light S caused by the ripples 46 and projected forward of the upper and lower housings 11 and 14 may stimulate the pest 5 more than the direct light of the LEDs 30, Accordingly, the pest catching performance can be greatly improved.

4 and 5 are perspective views showing modifications of the scattering inducing unit, which can be mounted to the pest trapping apparatus of the present invention. The scattering inducing unit 50 of FIG. 4 may be mounted to the pest trapping device 10 in place of the scattering inducing unit 40 of FIG. 1. Referring to FIG. 4, the scattering induction unit 50 includes first to fourth containers 51, 53, 55, and 57 that are open and arranged in a row, and each container 51, 53, 55, and 57. The liquid 59 accommodated therein and means (not shown) for inducing the formation of ripples 60 on the surface of the liquid 59 are provided. As the liquid 45, water (H ₂ O) may be used as described with reference to FIG. 1. The containers 51, 53, 55, 57 may vibrate separately from each other. The means for inducing the formation of the ripples 60 may include, for example, a cam (not shown) connected to each of the containers 51, 53, 55, and 57 and a motor for driving the cam. The four containers 51, 53, 55, 57 connected to each other by the movement of the cam vibrate back and forth, thereby forming a ripple 60. Alternatively, the containers 51, 53, 55, 57 may be configured to vibrate up and down, respectively.

The scattering inducing unit 63 of FIG. 5 may be mounted to the pest trapping device 10 in place of the scattering inducing unit 40 of FIG. 1. Referring to FIG. 5, the scattering induction unit 63 may include a container 65 having an open upper side, a liquid 66 accommodated in the container 65, and a transparent window 67 covering the container 65. Equipped. As the liquid 66, water (H ₂ O) may be used as described with reference to FIG. 1. The transparent window 67 is attached with a plurality of beads 68, which cause scattering of light. Light directed toward the transparent window 67 may be irregularly scattered by being reflected by the beads 68, and may be irregularly and strangely scattered through the light beads 68 which are reflected from the surface of the liquid 66 and directed upward. . Meanwhile, a plurality of fly eye lenses or a plurality of cube lenses may be attached to the transparent window 67 in place of the beads 68.

Referring back to FIG. 1, the lower housing 14 is provided with a suction fan 19 which induces air flow to guide the pest 5 around the inlet 15 to the sticky tape 21 of the capture unit 20. do. The air inside the lower housing 14 is sucked toward the suction fan 19 by the rotation of the suction fan 19 and is discharged through the vent hole 17, and the atmospheric pressure inside and outside the lower housing 14. A difference occurs and air around the inlet 15 is introduced into the lower housing 14 through the inlet 15. Therefore, the pest 5 attracted to the scattering light S (see FIG. 2) of the LED 30 projection light and the scattering inducing unit 40 and moved around the LED 30 and the scattering inducing unit 40 is air. The flow is swept into the lower housing 14 through the inlet 15, and the strap is attached to and captured by the tape 21. In front of the suction fan 19 is provided with a pest filter 191 having a mesh smaller than the size of the pest (5) introduced into the interior through the inlet (15). The pest 5 introduced into the lower housing 14 through the inlet 15 is not attached to the tape 21 through the vent hole 17 along the air flow guided by the suction fan 19. Since the outer housing 14 can go out, the pest filter 191 prevents this.

As an example of a UV light source for irradiating ultraviolet light (UV) to the inner side of the lower tape 14 and the lower housing 14, the inner wall of the lower housing 14, UV LED 28 is installed. Since the inside of the lower housing 14 is a place where the pests 5 enter and die, the lower housing 14 may be contaminated by the dead pests 5 and germs may grow, but the lower housing may be caused by ultraviolet light (UV) projected from the UV LEDs 28. (14) The interior can be sterilized.

In addition, a TiO ₂ coating layer 16 is applied to the inner surface of the lower housing 14. When the TiO ₂ coating layer 16 is irradiated with ultraviolet light (UV) from the UV LED 28, the air purification power and sterilization power are further increased, so that even if many pests are collected and die inside the lower housing 14, the contamination thereof is suppressed. . Although not shown in FIG. 1, the TiO ₂ coating layer 16 may be replaced with a TiO ₂ component-coated film or thin plate to be detachably attached to the inner side of the lower housing 14. This configuration is possible with double sided tape or Velcro tape.

6 is a perspective view showing an example of a sterilization unit that can be mounted to the pest trapping apparatus of the present invention. The pest trapping apparatus 10 of the present invention may replace the TiO ₂ coating layer 16 and the UV LED 28 shown in FIG. 1 or may include the sterilization unit 70 of FIG. 5 together with them. The sterilization unit 70 includes a sterilizing filter 74 having a cylindrical shape disposed in an inner space of the lower housing 14, and a UV lamp 72 inserted into the sterilizing filter 74. The sterilizing filter 74 includes a TiO ₂ component and includes a plurality of fine pores that can transmit light. The UV lamp 72 is an example of a UV light source for irradiating ultraviolet light (UV). Ultraviolet light (UV) of the UV lamp 72 is projected out of the sterilizing filter 74 through the micro-pores of the sterilizing filter 74 to sterilize the inside of the lower housing 14, TiO ₂ component of the sterilizing filter 74 This further improves air purification and sterilization. On the other hand, although not shown, the sterilization unit may be configured with two parallel sterilization filters and a UV lamp interposed therein.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

5: Pest 10: Pest Capture Device
20: capture unit 21: sticky tape
26: mirror 30: LED
35: LED mounting board 40: scattering induction unit
41: container 45: liquid
46: ripple 47: diaphragm

Claims (15)

A housing having an inlet through which pests are introduced;
A capture unit provided inside the housing to capture pests;
A light source emitting light toward the front of the housing to attract pests; And,
Scattering means for scattering light to stimulate a pest, the container disposed adjacent to the inlet, the upper side of which is opened or the upper side of which is protected by a transparent window, the liquid contained within the container, and the scattering means for scattering the reflected light of the liquid surface. Scattering induction unit having a; pest capture device comprising a. The method according to claim 1,
And the light source is configured to change the projection direction of the light. The method according to claim 1,
The light source is a pest capture device, characterized in that it comprises a light emitting diode (LED) for emitting light of a wavelength preferred by the pest. The method of claim 3,
The light source includes a plurality of LED mounting terminals that can be mounted to the LED detachably, each LED mounting terminal is configured to mount a predetermined type of LED, characterized in that the pest capture device. The method of claim 3,
The light source includes an LED chip on which at least one LED is mounted, and a plurality of LED chip mounting terminals on which the LED chip can be detachably mounted, and each LED chip mounting terminal is a predetermined type of LED chip. The pest capture device, characterized in that configured to be mounted. The method according to claim 1,
The capture unit is a pest capture device, characterized in that it comprises a sticky tape coated with an adhesive substance to which the pest adheres. The method according to claim 1,
And a mirror for reflecting the scattered light caused by the ripples of the liquid surface to the front of the housing. The method according to claim 1,
And a fan for causing air flow to direct pests around the inlet to the capture unit. The method of claim 8,
A pest filter having a mesh smaller than the size of the pest in front of the pan so that pests introduced into the housing through the inlet are not allowed to flow out of the housing by air flow induced by the fan. A pest trapping apparatus comprising: The method according to claim 1,
And a TiO ₂ coating layer coated on the inner surface of the housing in which the capture unit is embedded, and a UV light source for irradiating ultraviolet light (UV) to the capture unit and the TiO ₂ coating layer. The method according to claim 1,
The pest further comprises a sterilization unit including a sterilization filter including TiO ₂ disposed in the interior space of the housing in which the capture unit is embedded, and a UV light source for irradiating ultraviolet light (UV) to the sterilization filter. Capture device. The method of claim 1, wherein the scattering means,
And capture the ripples on the surface of the liquid. The method of claim 12,
And the scattering means is configured to vibrate the container. The method of claim 12,
And the scattering means is configured to vibrate on the surface of the liquid or while submerged in the liquid. The method according to claim 1,
The scattering means comprises at least one of a plurality of beads, a plurality of fly eye lenses, and a plurality of cube lenses, which cause scattering of light. .

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