An electrifiable projectile for an insect zapper gun is capable of killing a target insect at a distance from the user. The projectile includes a pattern of electric wires forming a front-facing conductive contact structure having a breadth sufficient to allow the projectile to intercept an insect when propelled in a forward trajectory toward an insect. When the projectile's pattern of electric wires comes into contact with the target insect, an electric charge on the projectile is transmitted to the insect rendering the insect deceased.

An insect zapper gun is capable of killing a target insect at a distance from the user. The zapper gun incudes an electrifiable projectile fired from a handheld base. When the projectile comes into contact with the target insect, an electric charge on the projectile is transmitted to the insect rendering the insect deceased.

An electric fly swatter housing comprising a front plate, a back plate, and interior vertical bars sized to house a fly swatter head and to align the fly swatter head to avoid snag. The housing may include thin brushes along a housing mouth to brush away any bug residue on the fly swatter. The housing may include a removable chamber at the bottom of the housing to dispose of any bug residue.

An insect trapping device traps, kills and facilitates disposal of an insect. The device includes a handle which is hollow defining a conduit extending between a first end and a second end. A fan coupled to the handle in the conduit such that the fan provides suction into the first end of the handle. A cup is coupled to the first end of the handle for directing an insect into the first end of the handle. A receptacle is coupled to the second end of the handle and vented end such that the fan urges air flow out through the receptacle wherein the receptacle receives and holds the insect sucked through the first end of the handle.

A method for manufacturing a flyswatter having a conductive plastic electrode net, and a flyswatter structure obtained thereby are provided. The method may include the following steps: (i) using an insulating plastic to perform injection molding, so as to obtain a flyswatter body; and (ii) using a conductive plastic to perform second injection molding on the flyswatter body to manufacture an electric net component, such that the electric net component and the flyswatter body are integrated with each other. The flyswatter structure includes the flyswatter body and the electric net component. The flyswatter body includes a shaft, a handle, and a frame. The handle has an inner chamber for installing a power control circuit and a battery therein. The electric net component consists of a positive electrode portion and a negative electrode portion. The positive electrode portion includes several strip-shaped positive electrode conductors and a positive electrode conductive connector, and the negative electrode portion includes several strip-shaped negative electrode conductors and a negative electrode conductive connector. The flyswatter structure does not require various manufacturing materials, and can achieve material saving during manufacturing.

An electromagnetic charge-sensitive electric mosquito swatter, comprising a charging-discharging circuit (1), a boost circuit (3) and a central control circuit (4). The charging-discharging circuit (1) provides required power to the boost circuit (3). Also comprised are an electromagnetic charge space scanning circuit (5) and a gate circuit (6); the gate circuit (6) is bridged between the electromagnetic charge space scanning circuit (5) and the central control circuit (4) so that when the electromagnetic charge space scanning circuit (5) senses a holding signal of a human hand holding the swatter, the holding signal is converted into a startup signal by means of the gate circuit (6) and is transmitted to the central control circuit (4); and the central control circuit (4) drives the charging-discharging circuit (1) to provide power to the boost circuit (3). The present mosquito swatter has the advantages of being convenient and safe to use and being effective in shocking mosquitos.

A battery-free electric mosquito swatter, comprising a flat swatting portion (1), a handle (2), a control circuit board (3), and a mechanical energy-based power generation device (5). The flat swatting portion (1) consists of a swatter frame and a swatter net. The flat swatting portion (1) is connected to the handle (2), the control circuit board (3) and the mechanical energy-based power generation device (5) are disposed within the handle (2), and the swatting net and the mechanical energy-based power generation device (5) are electrically connected to the control circuit board (3). The mechanical energy-based power generation device (5) comprises a hand squeeze member (51), a gear transmission mechanism, and a power generator (57). The hand squeeze member (51) is provided with a curved gear rack (511) meshing with an input gear of the gear transmission mechanism. An output gear of the gear transmission mechanism drives a rotating shaft of a rotor of the power generator (57) to rotate. The power generator (57) is electrically connected to the control circuit board (3). The handle (2) is provided with a discharge button switch (4) used to short a positive and negative electrode of the swatter net. The electric mosquito swatter of the present invention does not require a battery, lowers a use cost, and reduces environmental pollution caused by waste batteries. In addition, the present invention provides a reasonable and reliable overall design and safety during use, has a long service life and a low cost, and is easy to assemble and ready for use immediately after squeezing, thus providing convenience and fun during use.

A battery-free electric mosquito swatter, comprising a flat swatting portion (1), a handle (2), a control circuit board (3), and a mechanical energy-based power generation device (5). The flat swatting portion (1) consists of a swatter frame and a swatter net. The flat swatting portion (1) is connected to the handle (2), the control circuit board (3) and the mechanical energy-based power generation device (5) are disposed within the handle (2), and the swatting net and the mechanical energy-based power generation device (5) are electrically connected to the control circuit board (3). The mechanical energy-based power generation device (5) comprises a hand squeeze member (51), a gear transmission mechanism, and a power generator (57). The hand squeeze member (51) is provided with a curved gear rack (511) meshing with an input gear of the gear transmission mechanism. An output gear of the gear transmission mechanism drives a rotating shaft of a rotor of the power generator (57) to rotate. The power generator (57) is electrically connected to the control circuit board (3). The handle (2) is provided with a discharge button switch (4) used to short a positive and negative electrode of the swatter net. The electric mosquito swatter of the present invention does not require a battery, lowers a use cost, and reduces environmental pollution caused by waste batteries. In addition, the present invention provides a reasonable and reliable overall design and safety during use, has a long service life and a low cost, and is easy to assemble and ready for use immediately after squeezing, thus providing convenience and fun during use.

An apparatus, method and system for eradicating soil-borne pests in soil utilizing leading and trailing rows of shanks, a source of electricity and a mechanism to determine the condition of the soil being treated. The leading row has ripper shanks that open a path through the soil and the trailing row has specially configured electrically conductive stinger shanks, connected to the source of electricity, that discharge electricity into the soil to electrocute pests. The soil condition determination mechanism comprises one or more soil probes in a probe row disposed between the leading and trailing rows. The soil probe reads the condition of the soil in the path cut by the ripper shanks and transmits a signal to a voltage controller that is connected to the source of electricity to adjust the output thereof to the stinger shanks to automatically compensate for changing soil conditions to effectively and efficiently eradicate pests.

An insecticide device including a frame; a first electrically conductor element and a second electrically conductor element associated with said frame and reciprocally positioned so as to define between them a region of space; a power voltage generator circuit, to which are connected the first electrically conductor element and the second electrically conductor element, predisposed to generate in said region of space an electric field of intensity able to kill the insects that cross it. The first electrically conductor element and the second electrically conductor element include at least one respective portion made of electrically conductive polymer material.