A flyswatter is disclosed which includes a handle split into a top part and a bottom part from a first end to a first predetermined location along an elongated direction of the handle, an elastic band wrapped around the handle at a second predetermined location between the first end and the first predetermined location of the handle, the elastic band urging the top part and the bottom part toward each other, and a perforated swatting panel removably inserted into the handle between the top part and the bottom part, the perforated swatting panel having a first and a second slot cut into an edge thereof accommodating two side portions of the elastic band, respectively.

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.

A fly swatter (10) with a hitting grid (16) and a stem (14), whereby the hitting grid (16) is joint to the stem (14) by means of a joint; the hitting grid (16) is rotatable against the force of a spring (36) from a relaxed position about an axis which lies in the plane of the hitting grid (16) and runs perpendicularly to the longitudinal axis of the stem (14); the hitting grid (16) is lockable in a pre-loaded position with a locking device, and the locking mechanism of the locking device (34) is releasable by way of a trigger (20), is characterized in that the joint with the turning axis of the hitting grid is assembled between the stem and the hitting grid (16); the locking device (34) is assembled remote to the trigger (20); and a string, a wire or different means of transmission (32) are provided, which transfer a triggering force from the trigger (20) onto the locking device (34).

A fly swatter (10) with a hitting grid (16) and a stem (14), whereby the hitting grid (16) is joint to the stem (14) by means of a joint; the hitting grid (16) is rotatable against the force of a spring (36) from a relaxed position about an axis which lies in the plane of the hitting grid (16) and runs perpendicularly to the longitudinal axis of the stem (14); the hitting grid (16) is lockable in a pre-loaded position with a locking device, and the locking mechanism of the locking device (34) is releasable by way of a trigger (20), is characterized in that the joint with the turning axis of the hitting grid is assembled between the stem and the hitting grid (16); the locking device (34) is assembled remote to the trigger (20); and a string, a wire or different means of transmission (32) are provided, which transfer a triggering force from the trigger (20) onto the locking device (34).

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.

A swatter that is available in four design configurations. All design configurations comprise a hand section with an upper section and a lower section, with an opening on the hand section created when the upper section is attached to the lower section, and four or five internal finger channels that allow a person to insert a hand through the opening into the hand section. A swatting section is attached to the hand section with a plurality of overlapping vanes that create an accordion structure. The swatting section's first end is attached to the second end of the hand section either permanently or non-permanently with the non-permanently attachment allowing the swatting section to be removed from the hand section. The longitudinal length of the swatting section's first end is less than the second end, which causes vanes to fan outward as the vaners extend from the hand section.

A swatter that is available in four design configurations. All design configurations comprise a hand section with an upper section and a lower section, with an opening on the hand section created when the upper section is attached to the lower section, and four or five internal finger channels that allow a person to insert a hand through the opening into the hand section. A swatting section is attached to the hand section with a plurality of overlapping vanes that create an accordion structure. The swatting section's first end is attached to the second end of the hand section either permanently or non-permanently with the non-permanently attachment allowing the swatting section to be removed from the hand section. The longitudinal length of the swatting section's first end is less than the second end, which causes vanes to fan outward as the vaners extend from the hand section.

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.

A compact improved bug killing gun includes a compressed gas source fluidly connected to a chamber connected to a barrel. A compressed gas release mechanism is connected to the compressed gas source. A projectile storage magazine stores particulate projectiles and is located adjacent the chamber. A projectile loading mechanism moves the projectiles into the chamber from the magazine. A cocking mechanism is mechanically connected to the compressed gas source, the compressed gas release mechanism, and the projectile loading mechanism. When the gun is cocked, the projectile loading mechanism loads a quantity of the particulate projectiles into the chamber. When the compressed gas release mechanism is activated the projectiles are ejected from the chamber into the barrel and expelled from the gun. The gun optionally includes a laser sighting mechanism. The battery operated laser sighting mechanism is removably attached to the barrel or permanently attached with an integral, trigger operated switch.