FI60344B - ANORDING FROM THE INSPECTOR - Google Patents

Description

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Ma ** (11) UTLÄGGNINGSSKRIFT 60 344 C ™ Patent granted 11 01 1982 '' Patent eeddelat ^ ^ (51) Kv.lk?/lnt.CI.3 A 01 N 25/08 FINLAND —FlN LAND (21) Patent application - Patenuiuöknlng 76 30 7 7 (22) Hakemlspilvl - Aiueknlngsdag 28.10.76 ^ '(23) Start date —Glk (| momKli | 28.10.76 (41) Become public —Bllvlt offentllg m ης 77

Patent and Registration Office

Patent-oeh Registerstyrelsen * ^ Ansöksn utto £ Tolh wUkrlfte ^ Wke »^ 30.09.81 (32) (33) (31) Pjrydetty Privilege — Begird prtoritet 31.10.75 USA (US) 627671 (71) A.H. Robins Company, Incorporated, IU07 Cvunming’s Drive, Richmond,

This invention relates to the control of insects, such as common houseflies, to the control of insects, such as common houseflies, to the control of insects such as common houseflies. Musca domestie), fruit flies (Drosophila melanogaster), mosquitoes (Culex pipiens) and other similar insects in the vicinity of the insecticide-containing device.

Hitherto, insect repellent devices such as pest strips and the like consisting of a PVC resin with a dispersion of an insecticide, dimethyl 2,2-dichlorovinyl phosphate, commonly known as DDVP or its trade name Vapona, have been widely used by flying insects such as , mosquitoes, etc. in the vicinity of the device. However, DDVPr has been reported to have an unpleasant paralytic effect on plasma and red blood cell cholinesterase, at least in animals, an effect that is particularly severe at high concentrations occurring in the first few days after first exposure of the pest strip to the open air. This is believed to be due to the fact that the release rate of DDVP from currently available DDVP-containing pest tapes is not uniform, but rather higher during the first few days after activation, i. after 2,60344 after the pest tape has been removed from the package and exposed to the outside air. There are also indications that DDVP may be harmful to humans. Pest tapes containing DDVP are banned in the Netherlands. Moreover, the aforementioned high release rate at the beginning implies an unreasonably rapid loss of insecticide and constitutes an upper limit to the period during which DDVP is released at a rate sufficient to effectively control blockages. DDVP has also been found to have a high degree of residual toxicity in the device area, apparently due to the adsorption of DDVP vapors on walls, floors, ceilings, curtains, carpets, etc. Even after several strips of DDVP have been removed from the room environment, residual DDV can be removed. days after.

It has also been proposed to use other insecticides such as naled (1,2-dibromo-2,2-dichloroethyldimethylphosphate) in an insect control device such as a pest tape.

The preparation of Naled is described in U.S. Patent 2,971,882. PVC resin-naled combinations have been proposed for use as a general insecticide in French Patent 1,568,198 and in U.S. Published Patent Application Serial No. 85,445, filed January 30, 1961, and similar in English. 350. Patent application 6610279, published in the Netherlands, discloses fly strips consisting of combinations of PVC-naled and PVC-DDVP which are shown to have insecticide release rates so high that they require an outer laminate layer to retard the release of the insecticide. U.S. Patent 3,344,021 discloses PVC naled combinations for use as an anthelmintic.

Many problems have been encountered in providing a commercially satisfactory PVC resin-naled combination for use in an insect control device. First, the released naled preparation must be in an amount sufficient to provide effective insect control in the vicinity of the device. Contrary to claims in previous publications in the art, it has been found that the release rates of naled are much lower than the release rates of DDVP. Naled * 4o has a low vapor pressure of about 2 x 10 mmHgs at 20 ° C compared to 1.2 x 10 of -2 DDVPs, thus being about 1.7% of the vapor pressure of DDVP.

3,60344

It has further been found that the incorporation of an insecticide such as naled into the synthetic resin matrix in sufficient amounts to control insects for a commercially acceptable time results in the sweat (or "expulsion") of the liquid insecticide on the surface of the device. These liquid droplets pose serious environmental and aesthetic problems and significantly shorten the effective life of the device.

Another unexpected problem observed with the PVC-naled blend was the tendency of the resin to disperse in the forming process. Unsatisfactory results were obtained, for example, in the first experiments in which DDVP was replaced by a naled compound in PVC combinations used in an extrusion device used to make PVC-DDVP pet collars known in the art. Burning and charring of the extrudate was found to occur during the heat treatment of the neckbands, and an unexplained decrease in naled concentration occurred in the final neckband compared to the naled concentration of the original mixture.

It is an object of the present invention to provide an insect control device which alleviates or avoids previous problems in the art.

Another object of the present invention is to provide an insect control device which can contain a relatively large amount of insecticide without the unpleasant formation of a drop of liquid insecticide on the surface of the device.

It is also an object of the present invention to provide an insect control device capable of fighting insects in the vicinity of the device with a long release of insecticide while minimizing unwanted absorption of the insecticide on adjacent solid objects.

It is a further object of the invention to provide a method of controlling insects by making a body of synthetic resin containing about 15-35% naled using a volatile additive released during the heat treatment step to form a structure having porous surface openings that allow naled gas to at an unexpectedly high growth rate of release, 60344 which is effective in controlling insects, thus providing a device containing a naled compound having a commercially effective effective age.

In one aspect, the present invention provides a device for controlling insects, the device comprising a shaped solid having a porous surface capable of gradually and continuously releasing a sufficient amount of naled insecticide from said naled compound to insects to provide active concentration for a long period of time. a resinous matrix material, about 15-35% by weight of a naled compound and a minor amount of finely divided silica and at least one saturated C 1 -C 10 aliphatic carboxylic acid or a salt or ester thereof, effective to slow the release of the insecticide from the device, of a mixture of a compound, finely divided silica particles, a saturated C 4 -C 4 aliphatic carboxylic acid or a salt or ester thereof and a surface porosity-adjusting component, the latter being unreacted in the mixture, and the boiling point is a heat treatment at a temperature below full temperature, producing surface openings in communication with the pores in said body by evaporation of said porosity adjusting component to maintain release of naled gas at an effective rate to control insects in the vicinity of said body.

In another aspect, the present invention provides a device for controlling insects, comprising: a separate body of flexible synthetic resin material containing about 20-30% by weight of a naled compound and an antiperspirant amount of about 15-25% by weight of fine silica particles, and n 0.5 to 1.5% by weight of at least one saturated C 1-4 C 20 Q aliphatic carboxylic acid or a salt or ester thereof; said discrete body being formed from a mixture of said synthetic resin, a naled compound, finely divided silica particles and an amount of a surface porosity adjusting component of about 1 to 3% by weight, which substance is unreacted in the mixture and has a boiling point at said temperature, 5 60344 to provide pores in said body by vaporizing said porosity control component to provide for the release of naled gas at a rate effective to repel insects in the vicinity of said body but insufficient to form droplets on the surface of the body.

In another aspect of the present invention there is provided a method of controlling insects, comprising: providing a separate body comprising a mixture of a synthetic resin, about 15-35% by weight of said strip of naled compound and an antiperspirant amount of finely divided silica particles and at least one a saturated C 1 -C 20 aliphatic carboxylic acid or a salt or ester thereof; said body is formed from a mixture of said synthetic resin, a naled compound, silica particles, a saturated aliphatic carboxylic acid and a minor surface porosity adjusting agent, which agent is unreacted in the mixture and the boiling point of which is at a temperature to vaporize and produce surface porosity in said body to provide for the release of the naled compound at a rate that effectively repels insects in the vicinity of said body but is insufficient to form droplets on the surface of the body; and placing and maintaining said body in an area where said insects are to be controlled.

The figure is a schematic representation of a preferred embodiment of an insect control device of the present invention.

Referring now to the drawings, Figure 1 shows a typical device suitable for fighting insects. As shown therein, such a device may be in the form of a shaped body 1 having a regular, symmetrical cavity matrix, generally indicated by the number 2, which cavities extend through one dimension of the whole body. The cavities have substantially parallel axes and walls 3 which form a substantially straight line along one dimension. The device designed in this way has good dimensional stability and ease of manufacture, as well as a relatively large surface area from which insecticide is released. Those skilled in the art will appreciate that other forms may be used.

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The components that make up a satisfactory insecticide-containing insecticidal device include a synthetic resin that is miscible with relatively large amounts of insecticide and strong enough to maintain the integrity of the shaped device throughout the time the insecticide is released to control effective amounts of insecticide. The shaped insect control device contains a synthetic resin in a sufficiently high concentration to give the device physical properties such as strength, flexibility and non-stickiness to make it suitable for use as an insect control device. In general, the shaped device contains about 20-80 and preferably about 25-50% by weight of synthetic resin.

Various known synthetic resins that can be used in an insect control device include materials such as polyethylene, polypropylene, copolymers of ethylene and propylene, nylon, cellophane, polyacrylates such as methyl acrylate, ethyl acrylate, methyl methacrylate and ethyl methacrylate; polymers of vinyl compounds such as polystyrene, polymerized divinylbenzene; polyvinyl halides such as polyvinyl chloride; polyvinyl acetates such as polyvinyl butyral; polyvinylidene compounds such as polyvinylidene chloride; polyvinyl acetate; ethyl-vinyl acetate-vinyl acetate copolymers; copolymers of vinyl chloride and vinyl acetate; polyurethanes, polyaldehydes; and other thermoplastics.

Polyvinyl chloride (PVC) homopolymers and copolymers with other polymers such as vinyl acetate (PVA) are preferred synthetic resin materials. Suitable PVC resins are commercially available and include, for example, PVC homopolymer dispersion resin.

TM

Diamond PVC-7502 and PVC Homopolymer Extender Resin Diamond PVC

"TM

7-446, both available from The Diamond Shamrock Co., and mixtures thereof. Other suitable commercially available PVC resins are known in the art. Suitable PVC-PVA copolymers are also commercially available and include, for example, Geon 135 (Goodrich Corp.), PVC-74 (Diamond Alkali Co.) and XR-6338 (Exxon-Firestone). Other PVC-PVA copolymers are known in the art.

The improved insect control device of the present invention contains a sufficient amount of naled insecticide (1,2-dibromo-2,2-dichloroethyldimethyl phosphate) to provide an insecticide of active concentration against insects for a long period of time (e.g., about 120 days or more). , which amount is about 15-35 and preferably about.

20-30% by weight of insecticide. With insecticide concentrations in these areas, the insect repellent device releases about 0.2-0.8 mg of insecticide per square centimeter of surface area per day. Although the insect control device of the present invention can be used in any environment containing insects, maximum power can be achieved when the device is used in a confined space containing these insects.

In general, the use of naled insecticide in amounts of about 15-35% by weight in a synthetic resin matrix results in the formation of a liquid naled drop or "saliva" on the surface of an insect repellent device. Naled insecticide liquid droplets that form on the surface of a shaped device pose a significant health and safety hazard and reduce their insect repellent effect. The insect control device of the present invention contains a smaller amount of finely divided silica particles and at least one saturated C 1 -C 10 aliphatic carboxylic acid or a salt or ester thereof which effectively inhibits the perspiration of the insecticide and has a substantially reduced tendency to form a naledis.

Although silica, as well as many other minerals and glasses, is known in the art as a filler for various synthetic resins, it has surprisingly been found that fine silica particles, generally about 1-50 and preferably about 2-10 microns, have a high relative power in insecticidal sweating. it is used in sufficient amounts, the antiperspirant amounts generally being in the range of about 10-35 and preferably in the range of about 15-25% by weight of the insect control device. It has been found that the use of finely divided silica particles in an amount of less than about 10% by weight is generally ineffective in achieving any significant retardation of insecticide perspiration, while the use of finely divided silica particles in an amount greater than about 35% by weight does not result in any further reduction in sweat.

Although the addition of finely divided silica particles has a high relative effect in slowing down the sweating of naled insecticide, a small amount of naled insecticide can nonetheless sometimes 60344 sweat out of a device containing insecticide. It has further been found that the incorporation of a small amount of at least one saturated C 1-4 aliphatic carboxylic acid or a salt or ester thereof (e.g. magnesium stearate) into the device is not effective in slowing substantially all sweating of the naled insecticide that might otherwise occur. The saturated C 1-4-C 20 aliphatic carboxylic acid, which may be a mixture of such acids, is generally used in an amount of about 0.25-3 and preferably about 0.5-1.5% by weight in the device. Stearic acid and palmitic acid are preferred.

Although East German Patent 91,898 discloses the addition of a saturated C 1-4 aliphatic carboxylic acid together with a mixture of particular primary and secondary plasticizers to a mixture of polyvinyl chloride and DDVP, the addition of an acid-plasticizer mixture to detect CD The use of a -C 20 aliphatic carboxylic acid alone (i.e., without finely divided silica particles) with the resin and insecticide in the insect control device of this invention is insufficient to slow the sweating of the naled insecticide from the device. Similarly, the use of finely divided silica particles alone (i.e., without a saturated C14-C20 aliphatic carboxylic acid) is insufficient to effectively slow the perspiration of the insecticide from the device. However, the use of both fine silica particles and a smaller amount of saturated c4-C20 aliphatic carboxylic acid has been found to be of great effectiveness in slowing insecticide sweating and effectively keeping the surface of the device free of insecticide liquid droplets.

It has been found that when the release rate drops to about 0 / 006-0.1 milligrams of naled compound per square centimeter of surface area per day, the effectiveness of the device for controlling insects is reduced to the point where it should be replaced. The use of Naled in the device in amounts of less than about 20% by weight results in a release rate that achieves an ineffective level for an unsatisfactorily short period of time (e.g., about 90 days or less). Use of Naled greater than n.

In amounts of 35% by weight, it causes sweating and the accumulation of droplets on the surface of the device.

The preparation of combinations of synthetic resin and insecticide is carried out by conventional methods. Due to the miscibility of the insecticide with the resin dispersions, the compositions can be prepared simply by mixing the pesticides with the mechanically ground resin. Dry blends, liquid pastes or plastisol dispersions can be prepared which, as is known, can be molded, extruded, cast or otherwise formed into a strip or strip. When the prepolymerized resin is in liquid form, as in the case of monomers such as styrene or methyl methacrylate, the insecticide may be incorporated into the liquid before being polymerized or cured. The term "dispersion" as used herein includes solid and liquid, liquid and liquid and mixtures of solid and solid.

In embodiments using polyvinyl resins, plasticizers and other additives commonly used to provide the flexibility, strength, and surface properties desirable in an insect control device are well known to those skilled in the art, and no further description is considered necessary herein. In addition, colorants and odor control agents can be used in the devices of this invention to improve consumer receptivity.

As mentioned above, the naled compound has a low vapor pressure. The release rate of the naled compound from the PVC naled device is relatively low and may be insufficient for a commercially acceptable insect control device. The use of an additive in the mixture can greatly increase the rate of release of the naled compound and allow for both effective insect control at lower initial concentrations of the naled compound and an extended effective life of the insect control device.

An additive, also referred to as a surface porosity adjusting component, is present in the final plastisol dispersion or mixture used to form the device and must therefore be unreactive with the other components of the dispersion or mixture. The main function of the additive is to provide a surface porosity which preferably contains pores which extend part of the way into the body of the device. The desired surface properties are achieved by evaporating the additive during the curing cycle. Thus, the additive should consist of one or more compounds having a boiling point at or below the curing temperature of the resin.

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Compounds suitable as surface porosity regulating components in PVC resins which are heat treated in the range of about 127-204 ° C include aldehydes and their lower alkyl acetates containing bromine or chlorine and generally having a boiling point between n.

77-204 ° C and preferably between about 85-177 ° C. The porosity adjusting component may thus include one or more of the following, the approximate boiling point temperature of which is given below:

Name Boiling point, ° C

chloroacetaldehyde 85 dichloroacetaldehyde 89 chloral 103 bromoacetaldehyde 80-105 dibromoacetaldehyde 174 bromodichloroacetaldehyde 126 chlorodibromoacetaldehyde 148 bromochloroacetaldehyde 112 2-bromopropanol 109

The surface porosity adjusting component is incorporated into the combination of the synthetic resin and the naled compound in an amount sufficient to provide sufficient surface porosity by evaporation thereof during heat treatment of the dispersion to effectively increase the release rate of the naled gas from the formed device. Although the amount of porosity adjusting component to be used depends on the desired density of surface openings and to some extent on the particular procedure used for heat treatment of the resin, it is generally about 0.8 to 5, and preferably about 1 to 3% by weight of the dispersion.

The invention is further described in connection with the following examples, which are to be construed as illustrative of the present invention. It is to be understood, however, that the invention is not limited to the specific details of the examples.

Example I

Mixture containing (by weight) 30 parts by weight of a polyvinyl chloride homopolymer dispersion resin 16 "di-2-ethylhexyl phthalate (DOP) 2" epoxidized octyl thallate (EPO) 1 "bentonium 27" naled compound (1,2-dibromo-2-dichloroethyl) phosphate) 3 "bromodichloroacetaldehyde 11 60344 20 parts by weight of amorphous silica particles, average particle size 2.35 microns 1" palmitic acid is triturated thoroughly to form a plastisol dispersion with a viscosity at 25 ° C of 16,000 cP measured at 12,000 cP at 20 ° Brookfield at 2 rpm. A portion of the plastisol is measured in a closed machined aluminum mold with the honeycomb cavity shown in the figure. The temperature of the mold at the time of filling, immediately indicated by the thermocouple, immediately below the surface of the cavity is 199 ° C. The mold temperature is maintained at 199 ° C for 2.5 minutes to keep the dispersion above the curing temperature, after which the mold temperature is rapidly lowered to ambient temperature. The color of the device is brownish bronze. A strong drug odor is observed to evaporate from the finished resin.

Analysis of the device after curing and cooling shows that the naled content of the neckband is 26% by weight.

The polyvinyl chloride dispersion used is commercially available from Diamond Shamrock Company (PVC 7502) and is a high molecular weight homopolymer dispersion resin having a particle size of less than two microns; the intrinsic viscosity is 1.62-1.68 as measured from a 1% solution of the resin in cyclohexane at 30 ° C according to the ASTM procedure.

DOP is a plasticizer for PVC and EPO is a stabilizer. Bentone is added to adjust the viscosity of the plastisol.

The above dispersion and extender resins are as easy to handle in the manufacture of a satisfactory device as any used. However, as is well known to those skilled in the art, a large number of other materials described above may be used. Naled is not known to react chemically with any synthetic resin and significant changes in both ingredients and ratios can be made successfully.

Example II

The amounts and procedures of Example I are repeated except that an open surface mold is used. The top of the device is rounded due to the convexity formed when the mold is filled, while the shape is retained during i2 60344 curing. The resulting device is brownish bronze in color and contains 25% naled compound. Apparently, a small portion of the naled compound disappeared by evaporation or migrated with evaporation of the surface porosity regulating component during curing. The same drug odor was present.

Example III

The procedure of Example I is repeated using a plastisol dispersion containing by weight: 20 PVC homopolymer dispersion resins 10 PVC homopolymer extender resins 18 di-2-ethylhexyl phthalate (DOP) 2 epoxidized octyl thallate 22 naled (1,2-dibromo-2,2-dichloroethylate) tia) 2 surface porosity regulating components (eg bromodichloroacetaldehyde) 25 amorphous silica particles, average particle size microns 1 starchic acid

A bronze-colored resin body is obtained which is suitable as a pest strip and the analysis of which shows 22% by weight of naled compound after curing and cooling. Drug odor was present.

Example IV

Following the procedure of Example I and using a plastisol dispersion containing 20 parts by weight of PVC homopolymer dispersion resin 11 PVC homopolymer extender resin 9 di-2-ethylhexyl phthalate (DOP) 2.5 epoxidized octyl thallate 1 bentone 28 naled-2,2-dibromo dichloroethyl dimethyl phosphate) 2 surface porosity adjusting components (e.g. bromodichloroacetaldehyde) 25 amorphous silica particles, average particle size microns 1.5 palmitic acid 13 60344 printed weight after curing and cooling. The smell of medicine was present.

Example V

The mixture and procedure of Example I is repeated except that 30% by weight of the technical grade of naled (1,2-dibromo-2,2-dichloroethyldimethylphosphate) available from Chevron Chemical Company is used. This product is known to contain certain impurities such as bromodichloroacetaldehyde, chloral, carbon tetrachloride and various forms of phosphates. These impurities make up about 9% by weight of the product and are largely volatile enough to be released during or shortly after curing of the neckband and thus do not interfere with the operation of the neckband.

The device formed and cured as described in Example I is brownish bronze in color and contains about 20% by weight of naled compound.

Example VI

A uniform mixture of (by weight) 29.0 parts by weight of a polyvinyl chloride homopolymer general purpose resin 15.3 "di-2-ethylhexyl phthalate (DOP) 2.0" epoxidized octyl thallate (ΕΡ0) 25.7 "naled compound (1,2-dibromo) is formed. 2,2-dichloromethyldimethyl phosphate) 3.0 "bromodichloroacetaldehyde 20.0" amorphous silica particles, average particle size 2.35 microns 1.0 "stearic acid 4.0" heat stabilizer and lubricant.

The heat stabilizer and lubricant are a mixture containing 3.3 parts by weight of dibasic lead phosphate and 0.7 parts by weight of dibasic lead stearate. The mixture is fed to an injection molding machine and injection molded as shown in the figure at a temperature of 129 ° C and a pressure of about 70-150 MPa. The color of the device is brownish bronze and a strong odor of medicine is observed, which evaporates from the cast device.

14 60344

Analysis of the device after cooling shows a naled content of about 25% by weight.

Naled compound release rate

The release rate of the naled compound from the formulations useful in this invention per thickness and area of the device administered varies depending not only on the initial concentration of the naled compound, but more importantly whether or not the above volatile additive acting as a porosity adjusting component was used. . The device formed according to the present invention contains a sufficient amount to control insects for several months in the area of the device.

A significant advantage of the naled device of the present invention over the prior art DDVP device in commercial use is observed in the gaseous release form of the insecticide on the first few days of activation beginning when it is removed from the sealed container. The initial release rate of the Naled compound in the first few days is only a fraction of the devices corresponding to the initial release rate of DDVP, mainly due to vapor pressure differences. For a naled compound with a porosity adjusting additive, the release rate does not decrease significantly over about 10 weeks; thereafter, the release rate decreases to about 50% of the maximum after about 20 weeks. The shape of the release rate curve for a naled compound from a PVC device without a porosity control component is generally parallel. However, the total amount of naled released from a device made from a mixture containing a porosity adjusting component is significantly higher (e.g., 10% or more) than that released from a device made from a similar mixture without a porosity adjusting component, which indicates that more naled compound is released in any given period of time. 20 weeks from the previous device as the latter device.

Comparative Example A

Following the procedure of Example II and using a plastisol dispersion containing by weight 60 34 4 20 PVC homopolymer dispersive resin 12 PVC homopolymer extender resin 15 di-2-ethylhexyl phthalate 2 epoxidized octyl thallate 30 naled compound (1,2-dibroxine-2, 2-dichloroethyl dimethyl phosphate) 20 amorphous silica particles, average particle size microns 1 stearic acid

The cured strip contains about 25% by weight of naled compound, indicating that during the curing process more was lost from the naled compound originally present in this dispersion than was lost in Example II.

Example VII

The procedure and amount of Example I are repeated. The resulting device with a surface area of 2.45 cm is marked with the letter "A". Similar devices are prepared according to the procedure and amount of Example I except that 1% (w / w) stearic acid is used instead of palmitic acid (device "B"), 2% (w / w) stearic acid is used instead of palmitic acid (device "C"), palmitic acid is omitted (device "D "), the silica component is omitted (device" E ") and both the silica and palmitic acid component are omitted (device" F ").

Each of these devices is hung in a cell of about 0.6 cubic meters with dimensions of 61 x 61 x 153 cm. The cells consisted of a frame covered at the end and on three sides with kraft paper foil laminate and closed at the top with a glass plate to facilitate observations. The strips are hung from the top center of the cell so that they do not touch the sides or bottom of the cell. The experiment was performed for 16 weeks.

Visual inspections of the surfaces of each device are performed daily to determine the formation of liquid droplets of naled compound. Observations include the time at which the surface first becomes "slippery" or "wet" and the formation of spheres or droplets, the time at which signs of runoff are first observed, and the time at which droplets actually form at the bottom of the sample. These results are shown in Table I below.

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As can be seen from the table, in devices which did not contain both a silicic acid component and a saturated C 1 -C 20 aliphatic carboxylic acid component, the formation of liquid spheres occurs in a relatively short time. Both device E (acid but no silica) and device F (which did not contain silica or acid) have a slippery appearance in about 2 weeks and liquid ball formation in about 4 weeks, while device D (silica but no acid) has a slippery appearance in about 2 weeks. 6 weeks and droplet formation in about 10 weeks. All devices of the present invention (devices A, B and C) experience the formation of liquid spheres considerably later and no droplet formation at all.

The biological activity of devices B, C and D is measured against SRS-susceptible Musca domestica.

25 SRS-sensitive houseflies are added every day to each cell containing the device. LTvalue (in minutes) is measured. As is known in the art, LT ^ 0 has a lethal effect time in 50% of the introduced insects. Table II shows the values obtained with SRS-sensitive canine houseflies. Similar results are obtained with SRS-sensitive female houseflies, although the latter are generally more durable.

Table II

LT ^ Q minutes with SRS sensitivity = LT ^ 0, minutes

Device age - BCD

days 1 50 51 48 2 45 44 47 13 55 54 55 14 55 61 59 21 53 - 54 23 66 29 57 30 - 54 62 34 - 79 69 37 48 49 68 - 62 50 76 - 66 51 77 55 86 83 81

The values obtained show that the addition of the acid component does not affect the biological activity of the devices. Similar results are obtained when the experiments are repeated with CSMA (NAIDM) susceptible Musca domestica-18 60344 species and resistant species FC, Orlando DDT and Isolan-B Musca domestieä species. The latter are pure, hardy Musca domestie species, as one skilled in the art will realize.

Example VIII

Biological activity experiments with houseflies (Musca domestica), both hardy and susceptible species and mosquitoes (Culex pipiens) are performed in the cell used in Example VI. The insects are transferred to a cell containing a device prepared according to Example I containing 25% by weight of naled compound. Both LT ^ q and LTg ^ values are measured. The results are shown in Table III.

19 60344

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J * K

20 6 0 3 4 4

The results show that naled-containing devices secreted naled insecticide slowly and evenly over 20 weeks. The devices effectively killed both durable and sensitive houseflies as well as less hardened mosquitoes. Similar experiments with Drosophilia melanogaster show that these insects also die faster than houseflies.

Similar devices containing 25% by weight of naled compound are hung in the hallway of the building for 20 weeks and exposed to ambient temperatures. The percentage of naled remaining in the devices (average of 5 devices) is shown in Table IV.

Table IV

Conditioning time Amount of naled remaining in ventilated equipment (weeks),% by weight 0 25.25 1 24.66 2 23.22 4 21.22 8 17.38 12 15.98 16 13.28 20 12.34 This experiment still shows that the devices release naled insecticide evenly over a long period of time. Although some formation of naled insecticide liquid spheres is observed at about 16 weeks of aeration, no droplets or traces of runoff are observed at the end of the 20 week experiment.

Example IX

Samples of various household surfaces (aluminum foil, synthetic fiber mat, particle board, wood, semi-gloss enamel-treated wood, vinyl wall paper, glossy enamel-treated wood for 6 days) device. The devices are used in quantities of one device per approx. 0.6 cubic meters (run G) and two devices approx.

21 60344 0.6 per cubic meter (run H). Identical samples are exposed at the same time to a commercially available pest strip containing 20% by weight of DDVP (dimethyl-2,2-dichlorovinyl phosphate) in an amount of one device per about 0.6 cubic meters (run I). The adsorption of naled or DDVP venom was determined from the biological activity of the exposed material when placed in a closed container of about 3.9 liters into which houseflies are transferred. The LT The results are shown in Table V below.

Table V

LT ^ q minutes Estimated ventilation days to reach GUI LT ^ 0 ~ 300 min

G H I

Aluminum foil No No No effect

Carpet synthetic fibers 185 125 40 <5> 1 <5> 1 13

Particleboard vinyl 135 86 37 6 12 16

Tree 104 76 38 5 15 20

Wood semi-gloss enamel 125 109 50 9 12 28

Wallpaper vinyl 110 78 34 11 13 36

Wood - glossy enamel 125 79 40 24 30 40

Vinyl floor tile 128 98 35 9 13 42 Heat-treated hardboard 135 102 50 7 15 46

The results show that significantly less naled compound is adsorbed on surfaces than DDVP (as evidenced by much longer LTβ-Q times for naled). With ventilation, the naled compound was desorbed much faster than DDVP. Similar experiments are performed with different foods (potato, apple, bread, salad, tomato, orange, and burger) with a 24-hour exposure time. DDVP adsorption (compared to naled) was even higher. DDVP is adsorbed on all test nutrients with LT 1 values ranging from 12 minutes (potato) to 51 minutes (burger). The naled compound is not adsorbed to many of the foods tested at the same concentration and, when adsorbed, has LT ^ Q values ranging from 155 minutes (potato) to 380 minutes (sliced apple).

60344

Comparative Example B

A study is being performed to determine the effects of different materials on the release rates and efficacy of polyvinyl chloride blends containing about 25 weight percent naled compound, about 3 weight percent porosity adjusting component, and smaller amounts of PVC plasticizers and stabilizers.

Based on the initial screening, calcium carbonate, medium alumina and various silicone fluids and resins are found to be unsuitable either due to their reactivity with naled compound or porosity adjusting component or due to strong incompatibility with PVC mixtures even at relatively low load levels of the order of 5-15% by weight. Several types of powdered polyethylene and ethylene vinyl acetate resins are also tested and determined to be unsuitable due to their high plasticizer absorption as well as their cost.

Several species of dense glass microspheres (average particle sizes range from about 6 to 50 microns) are also being tested. All species of dense glass microspheres have relatively severe settling problems (larger as particle size increases). In addition, devices made according to Example I and containing 25% by weight of naled compound and 45% by weight of dense glass microspheres show surface slipperiness (or sweating) after only 2-3 weeks. Similar samples prepared to contain 45% by weight silica particles (in one case all particles pass through a 325 mesh screen and 95% of the particles are less than 40 microns and in another case all pass through a 200 mesh screen and 95% are less than 75 microns) show sweating in 5-6 weeks.

Summary of Advantages The insect control device of the present invention contains relatively large amounts of a naled compound that is released steadily over a long period of time. Naled has reduced toxicity compared to previous devices containing DDVP in the art and shows a significantly lower tendency to adsorb to surfaces close to the device.

Although the naled compound has been known and commercially available for several years prior to this invention and considerable research has been done 23 6 0 3 4 4 using the naled compound as an insecticide, it has not been considered possible to replace DDVP in an insect control device. Attempts to form a lanyard containing naled as an insecticide were unsuccessful in the initial studies, so that the actual testing of naled in the control of flies became quite difficult. In addition, naled was not considered a likely candidate for substitution of DDVP because its vapor pressure is known to be less than 2% of the vapor pressure of DDVP. Besides, the problem of sweating over n.

With naled concentrations of 25%, sets upper limits on the amount of naled that can be used in the product. The device of the present invention containing antiperspirant amounts of finely divided silica and at least one saturated C 1 -C 20 aliphatic carboxylic acid or a salt or ester thereof allows the use of the naled compound in amounts of up to about 25% without the formation of sweat on the surface of the device.

By incorporating volatile additives into the mixture used to form the device, it has been possible to increase the release rate of the naled compound to a level that allows for mass production of a suitable insecticidal device.

The device of the present invention is made to have a porous outer surface not only to release the naled compound at a higher rate than otherwise possible and in a larger total amount, but also to release the naled compound at a rate effective to control insects for a substantially longer time than otherwise possible.

The principles, preferred embodiments, and modes of operation of this invention are described in the above specification. However, the invention contemplated herein is not to be construed as limited to the forms specifically set forth, as these are to be construed as illustrative rather than restrictive. Variations and changes may be made by those skilled in the art without departing from the spirit of the invention.

Claims (7)

60344 24 An insect control device comprising a shaped dense body having a porous surface capable of gradually and continuously releasing a sufficient amount of insecticide to provide an active concentration of insecticide against insects over a long period of time, characterized in that the device comprises a synthetic resinous matrix material. 15-35% by weight of 1,2-dibromo-2,2-dichloroethyldimethylphosphate, about 10-35% by weight of finely divided silica particles, which amount is effective in slowing down the perspiration of the insecticide and about 0.25-3% by weight of at least one saturated C 1 -C 20 carboxylate. -yl acid or a salt or ester thereof, the device being formed from a mixture of a synthetic resin, 1,2-dibromo-2,2-dichloroethyl dimethyl phosphate, finely divided silica particles, a saturated C 1-4 aliphatic carboxylic acid and a salt or ester thereof. 1-3% by weight of a surface porosity regulating component which does not react in the mixture and has a boiling point at or below the resin curing temperature to provide surface openings in communication with the pores in the body by evaporating the porosity regulating component to maintain gaseous insect in the vicinity of the device, but r unwilling to form sweating on the surface of the device. Device according to claim 1, characterized in that 1,2-dibromo-2,2-dichloroethyl dimethyl phosphate is present in an amount of about 20-30% by weight, silica particles are present in an amount of about 15-25% by weight and the acid is present in an amount of about 0.5-% by weight. 1.5% by weight of the device. Device according to Claim 2, characterized in that the synthetic resinous material is polyvinyl chloride. Device according to claim 1, characterized in that the boiling point of the surface porosity control component is from about 77 ° C to the curing temperature of the synthetic resinous material made of polyvinyl chloride. Device according to claim 4, characterized in that the surface porosity regulating component is selected from the group consisting of chloroacetaldehyde, dichloroacetaldehyde, chloral, bromoacetaldehyde, dibromoacetaldehyde, bromal, bromo-dichloroacetaldehyde, 2-dichloroacetaldehyde, chlorodibride -bromopropanol and mixtures thereof. Device according to claim 1, characterized in that the synthetic resin is a polyvinyl chloride resin, the fine silica particles are less than 200 mesh in size, 90% of the particles are less than 75 microns in size, the saturated C 1 -C 2 aliphatic carboxylic acid is palmitic acid or palmitic acid , the polyvinyl chloride resin is intended to be formed into a body from a liquid plastisol dispersion containing a surface porosity adjusting component by filling a mold which is preheated to a temperature of about 143 ° C, which is then intended to be raised to about 182 ° C and then cooled, and to be removed from the mold. Device according to Claim 6, characterized in that the mixture is intended to form a body by injection molding the mixture. 60344 26