TH23694B - Targeting flying insects with enhanced pesticides and liquid recharging equipment - Google Patents

Abstract

DC60 Targeting flying insects with insecticides and liquid charge devices Improved Methods for killing flying insects This method consists of spraying it into the air where the insect is flying. Droplets of liquid aerosol mixtures Single-pole charge of which Will be split The liquid droplets as described above are carried out by the double charge and separation during spraying. A single-pole charge in the droplet scale as mentioned has a charge-to-mass ratio of at least +/- 1 x 10 to the -4 coulomb / kg power. A device for spraying liquid aerosol, which has the ability to dissociate into a single polar charge. Exit by the way Double charge And the separation of the charge to the droplets of the sprayed mixture, where there is a spray nozzle in the form of an actuator insert. The spray nozzle has a hole. Through which the fluid is excreted Which will have an exit destination The more popular it is to have a circumferential winding, which has an L / a ratio of at least 8, where L has a fixed circumference. In the destination bore into millimeters and a is in the cross-sectional area of the destination bore into Square millimeter And a device made so that the droplets are driven out of the head Spray at a flow rate of at least 0.5 g / s and have a charge to mass ratio of at least +/- 1x10 to the -4 power. Coulomb per kilogram Targeting flying insects with insecticides and liquid charge devices Improved Methods for killing flying insects This method consists of spraying it into the air where the insect is flying. Droplets of liquid aerosols of pesticide ingredients Single-pole charge of which It is separated from the droplets as described above by means of double charging and separation during spraying. A single-pole charge in the droplet level as mentioned has a charge-to-mass ratio of at least +/- 1 x 10-4 coulomb / kg. A device for spraying liquid aerosol, which has the ability to dissociate into a single polar charge. Exit by the way Double charge And the separation of the charge to the droplets of the sprayed mixture, where there is a spray nozzle in the form of an actuator. The spray nozzle has a hole. Through which the fluid is excreted Which will have an exit destination The more popular it is to have a circumferential winding, which has an L / a ratio of at least 8, where L has a fixed circumference. In the destination bore into millimeters and a is in the cross-sectional area of the destination bore into Square millimeter And a device that was made so that the droplets That will be driven from the head Spray at a flow rate of at least 0.5 gram per second. And will have a charge-to-mass ratio of at least +/- 1x10-4 coulomb per kilogram.

Claims (6)

1. Methods for killing flying insects. This method consists of spraying. Into the air Where the insect is flying Liquid droplets of the single-pole ionized insecticide mixture, which are separated from the droplets as mentioned above, by double charging and ionization during spraying. A single polarity at the drop drop level as mentioned above has a charge-to-mass ratio of at least +/- 1X 10 coulomb / kg. 2. Method as referred to in the claim. Article 1 where the pesticide mixture will be sprayed out From equipment for spraying liquid aerosols This will cause mechanical work under pressure 3. The method referred to in claim No. 2, where the aerosol spray device is Household Aerosol Spray Equipment 4. Method referred to in any of the above claims. Where the mixture The contents of the insecticide are either liquid or slurry. 5. Method referred to in any of the above-mentioned claims. Where the mixture of The pesticides are emulsion 6. The method referred to in one of the above claims, where the liquid droplets have an average diameter of between 5 and 100 micrometers. 7. The spraying device can be separated by a dual layer discharge. And separation of charges to Droplets of liquid droplets of the sprayed mixture From there, a single-pole charge is formed in the charge ratio. Per mass at least +/- 1 x 10-4 coulomb per kg The spraying device includes: i) a container for holding the liquid mixture, ii) a spray nozzle through which the liquid is expelled as a droplet spray, and iii) a guide system for feeding the mixture from a place. Contain to the spray nozzle where a) the nozzle will have a bore which allows the fluid driven from the device to flow through the bore to exit, which has a minimum L / a ratio. 10 where L is the circumferential length of the exit hole in mm and a is the cross-sectional area of the exit hole. Square millimeters and b) the device was made so that Those drops are ejected from the spray nozzle in A flow rate of at least 0.5 g / s. And will have the charge to Mass at at least +/- 1 x 10-4 Coulomb per kg 8. Spray equipment as referred to in Clause 7 where the spray nozzle is applied. 9. Spraying equipment as referred to in Clause 7 or Clause 8 where the L / a ratio is at least 12 1 0. Spraying equipment as specified in Article 7. It is referred to in one of the aforementioned claims in clauses 7 through 9 where the borehole end has a winding circumference. 1 1. Spraying device as referred to in the claim. Any of the above points 7 to 10 where the shape of the spray nozzle will have a bore hole, consisting of a bore hole that 1 2. The spraying equipment referred to in one of the aforementioned claims in clauses 7 to 10 where the bore end is supplemented with a bore. One or more holes in the center 3. Spraying equipment referred to in any of the aforementioned claims in clauses 7 to 10, where the nozzle shape is destined. Out of the borehole comprising many parts 1 4. Spraying equipment, as referred to in one of the above claims in clauses 7 to 10, where the shape of the nozzle There will be a destination out of the drilled holes including The grating or grating panels 1 5. The spraying equipment referred to in any of the aforementioned claims in clauses 7 to 10, where the shape of the spray nozzle has its destination. Hole punch Usually in the form of Cross hole hole 1 6. Spraying device as referred to in any of the aforementioned claims in clauses 7 to 10 where the shape of the nozzle has a hole end. The drill consists of a hole. In the form of a common ring 1 7. Spraying equipment referred to in any of the aforementioned claims in clauses 7 to 10, where the nozzle shape has Out-of-hole destination Will include a tongue similar to The protrusion into the hole. The protruding part of the bore can vibrate. 1 8. Spraying device which can be separated by double charge feeding. And separation of charges Into a liquid droplet of the mixture being sprayed out From there, a single-pole charge is formed in The charge-to-mass ratio at least +/- 1x10-4 coulomb per kg. Equipment for spraying is included; i) a container for storing the liquid mixture; ii) a spray nozzle through which the fluid is expelled as a drip spray; and iii) a guide system for feeding the mixture from the reservoir to the spray nozzle at Where a) The spray nozzle has a bore which allows fluid driven by the device to flow through the bore, there is an exit end where at least 8 L / a ratios should be used, i.e. 10 when L has the specified circumference length. The destination is drilled in millimeters, and a is the cross-sectional area of the tip. The outlet hole is drilled in millimeters, and b) the device is built so that Those drops are ejected from the spray nozzle in A flow rate of at least 0.4 grams per second. The most popular is at least 0.5 grams per second per second and will have a charge-to-mass ratio of at least +/- 1 x 10-4 coulomb per kilogram. As referred to in any of the claims 7 to 18, the liquid nebulization device includes: The valve assembly, which consists of i) the valve stem part, is located in an upright part that goes in line with the tail section, and ii) the actuator for the valve stem movement between the first closed position and the position. The second is open. Where the valve stem part is in contact with the tail, the spray nozzle is placed in the actuator adjacent to the valve stem and guide section, which consists of the valve stem part, the tail section and the immersion tube. Attached to the tail to the reservoir In which the navigation system contains fluid that is driven Exits from the reservoir to the nozzle by gas under pressure in the containment 2 0. The aerosol, referred to in claim 19, where the spray nozzle will include the expansion chamber. This will create a part of the navigation system 2 1. The aerosol, as referred to in claim 19 or 20, where the opening will be Provided in the valve stem for attaching to the tail section The open part, as mentioned above, will be in Two-way entrance form Each of which has a diameter that is between 0.51 mm and 0.61 mm 2. 2. The aerosol, referred to in one of the claims 19 to 21, where the tail includes an opening to allow gas in the containment to work directly on the fluid in the tail. The open part, as mentioned above, will be at least 0.76 mm at diameter 2. 3. Aerosol, as referred to in any of the claims 19 to 22 where the submersible pipe It will be attached to the opening in the tail. Which will have a diameter of 0.64 mm or less than 2 4. The aerosol, referred to in claim 19, continues to include the device. Mechanically split cut in the actuator Which will separate the liquid mixture obtained from the discharge of ions Additional of liquid droplets 2 5. Aerosol, as referred to in Clause 24, where the mechanical intersection device Will be assembled with a disc Which generally have radial-mounted holes. Which will work together with the surface Of the actuator In order to push the liquid mixture through those holes 2 6. The spraying equipment referred to in any of the Claims 8 to 25 where the overhang is formed from a polymer material such as acetate. Polyol, polyester, polyvinyl chloride, nylon or polypropylene