An emanating device includes a substrate with a body having a first portion and a second portion, a foldable member, and first and second hinges along a longitudinal axis of the body and connected to the foldable member. The foldable member is movable between a first state, such that the member is co-planar with the first portion and second portion, and a second state, such that the foldable member is not co-planar with the first portion and the second portion.

Disclosed is a pet insect repeller, tied to the neck of a pet by a strap, comprising a housing, and a battery, a circuit board and a heating portion mounted inside the housing. The battery and a heating plate are respectively connected to the circuit board. One side of the housing is provided with a plurality of through volatilization holes. The heating portion is provided with a drug carrying member that is loaded with a biological active component. The battery is used to provide an operating current for the heating portion. After the battery is turned on, the heating portion generates heat to heat the drug carrying member. After the temperature of the drug carrying member rises, the biological active component is volatilized and diffused to the body surface of a pet through the volatilization holes. By adopting the above technical solution, there will no harm to the pet.

A device for continuous release of a fluid at a near-optimum rate, the device including: a reservoir, having dimensions such that the fluid disposed in the reservoir is held in a shape having a height to a width ratio whereby the width is greater than the height; a flow-rate regulator adapted to regulate fluid release rate of the fluid exiting the reservoir via the flow-rate regulator.

A method of generating a low-CFM fog with a portable, battery-powered fogging apparatus is provided. Airflow is initiated through at least one passageway of fogging apparatus with a DC powered blower motor receiving power from at least one battery. A quantity of pressurized fogging liquid is expelled through a nozzle positioned proximate to an opening within a mixing chamber, wherein the quantity of pressurized fogging liquid exits the nozzle with at least 90% of an atomized micron particulate size between 5 and 60 microns. The expelled quantity of pressurized fogging liquid is atomized with the airflow to produce a fog at 190 CFM and at a velocity of less than 190 MPH.

A portable fogger apparatus includes a portable fogger body having at least one airflow passageway. A DC blower motor is connected to the fogger body proximate to the airflow passageway and receives power from a battery, wherein the DC blower motor produces an airflow through the passageway. A mixing chamber is positioned along the at least one passageway, wherein at least a portion of the airflow is movable through the mixing chamber. A quantity of pressurized fogging liquid is housed within a container connected to the fogger body. The pressurized fogging liquid is dispensable from the container into the mixing chamber where it is expelled through a nozzle and mixed with the airflow to produce a fog. The fog has an atomized micron particulate size between 5 and 60 microns. An activation switch controls activation of the DC blower motor and/or dispensing of the pressurized fogging liquid.

Oxalic acid vaporizer with integral body tube, detachable proximal end air nozzle, and floating heating element is a pest control vaporizer or pesticide vaporizer that is used to protect bees from certain pests, mites, and insects where the pesticide vaporizer expels a vapor that kills harmful pests, mites, and insects but does not harm or affect bees in the colony. Oxalic acid vaporizer with integral body tube, detachable proximal end air nozzle, and floating heating element includes an integral body tube that is without any holes, perforations, punctures, gaps, vents, or discontinuities. Oxalic acid vaporizer with integral body tube, detachable proximal end air nozzle, and floating heating element includes a detachable proximal end air nozzle. Oxalic acid vaporizer with integral body tube, detachable proximal end air nozzle, and floating heating element includes a floating heating element with a floating electrical connection.

The present invention relates to a formula or composition for use in reducing a honey bee parasitic mite infestation that may comprise, for example, a liquid, solid, or paste composition, comprising about 5-20% beta acids (about 5-75% by weight), about 5-75% by weight propylene glycol, about 5-75% by weight polysorbate 60, about 0.5- 35% of a thixotropic material, such as fumed silica, and/or about 0.5-5% pf an antioxidant, such as ascorbic acid, the composition is active against parasitic mites for more than about 14 days in the bee hives. Compositions of the present invention provide effective control, treatment, or prevention of honey bee parasitic mite infestation by inclusion of, for example, certain excipients that retard beta acid oxidation, prolong availability of active ingredient for bee uptake, improve convenience for beekeepers, or both retard beta acid oxidation and prolong the availability of active ingredient for bee uptake.

The current subject matter relates to controlling insects and includes a trap that can vary operation based at least on a target insect. For example, different insects are attracted to and/or repelled by different things, such as gases, orders, lights, and sounds. In general, things that attract a given insect are referred to as attractants and things that repel a given insect are referred to as repellents. By varying the operation of the trap, different attractants and repellants can be used to attract and/or repel specific insects. In addition, these attractants and repellants and/or characteristics thereof can these be varied dynamically based on, for example, time of day, proximity of individuals to the trap, proximity of insects to the trap, geographic location, and the like. Related apparatus, system, articles, and techniques are also described.

The present disclosure relates to methods and devices for controlling arthropods, including insects and arachnids in an environment. The methods generally comprise: generating a near-ideal gas Purified Hydrogen Peroxide Gas (PHPG) that is substantially non-hydrated (e.g., in the form of water in solution or water in solution or water molecules bonded by covalence, van der Waals forces, or London forces) and substantially free of, e.g., ozone, plasma species, and/or organic species; and directing the gas comprising primarily PHPG into the environment such that the PHPG acts to control arachnids in the environment. In certain aspects, the arachnids may be totally or partially killed.

Disclosed is a light-material coupling and emitting apparatus for coupling and emitting light and a material. The present disclosure is to utilize light coupled with a gaseous material or a certain state of material. According to the present disclosure, light is coupled with a gas, a liquid, or any state (plasma state) of material, and the coupled light and the material are emitted toward a target object or a predetermined region. When reaching the target object or the predetermined region, the material reacts with another material existing around the target object or the predetermined region. According to one embodiment, when light coupled with a first material is emitted from the light-material coupling and emitting apparatus, the first material coupled with the light falls away from the light and then chemically reacts with a second material. The apparatus uses a specific effect caused by this chemical reaction.