RU2140792C1 - Transformerless device for evaporation of liquid when heating - Google Patents

Abstract

FIELD: medicine, namely disinfection and sterilization. SUBSTANCE: device has heating assembly and reservoir filled with substance evaporating in heating. One end of central member for suction of evaporating substance upwards is inserted in reservoir and in heating assembly. heating assembly is ring-shaped. It is provided with transformless exothermic body. The latter is thermal resistor with positive temperature coefficient of resistance. Its volt-ampere characteristics includes section of at least 100-240 V of applied voltage which satisfies definite condition. Device makes it possible to maintain constant temperature of heat production and constant volume of liquid consumption. EFFECT: enhanced efficiency. 1 tbl, 8 dwg

Description

 The invention relates to a device for evaporating liquid during heating, in which the substance is evaporated using a thermistor with a positive temperature coefficient of resistance in the heater, in which the evaporation of liquid during heating occurs at a certain speed and the flow rate of the evaporating substance does not change, even if it is heated in the voltage range from 100 V to 240 V.

 The device for evaporating the liquid during heating has such a structure that the central element 8 (Fig. 8) for suction upward of the substance evaporated during heating is placed in the tank 6, which is filled with the evaporating substance. The heating unit 9 is located on the periphery of the central element 8, which protrudes from the reservoir 6. Electric power is applied to the heating unit 9, the heat received is transferred to the central element 8. The evaporated substance, sucked upward into the central element 8, evaporates and is discharged into the room in the form of steam.

 The heating units used in conventional liquid evaporation devices include a thermistor with a positive temperature coefficient of resistance, which changes the temperature in proportion to the applied voltage.

 In a device for evaporating liquid, the heating unit heats up when connected to a commercial electrical network. The voltage of a commercial electric network in Japan is a unified AC voltage of 100 V. In some countries of the world, the voltage of a commercial electric network is 220 V or 240 V. In some countries, the voltage of a electric network is 100 V and 220 V or 100 V and 240 V.

 It was indicated above that if a voltage of 220 V is applied to a thermistor with a positive temperature coefficient of resistance for a voltage of 100 V, the exothermic temperature rises by more than 7 degrees Celsius compared with the case when a thermistor with a positive temperature coefficient is heated at a voltage of 100 V.

 If the temperature rises by more than 7 degrees Celsius from the predetermined temperature, the amount of evaporated substance increases not proportionally and, therefore, it cannot satisfy the condition for the rate of consumption of the evaporated substance loaded into the tank. In a device for evaporating liquid exported to countries where a commercial electric network voltage of 220 V or 240 V is used, a heating unit can be used exclusively for use in such a device at a voltage of 220 V or 240 V. On the other hand, in those countries where the voltage of 100 V and 220 V or 100 V and 240 V is used (Fig. 8), the device contains a transformer 15 on the bottom cover 1, on which the tank is placed, and in addition, a switch is installed to change the voltage of the transforms torus (not shown) and use it when necessary.

 However, the transformer used in the above device has a rather large volume, for example, 40x26x30 mm. For this reason, it is necessary that the bottom cover has a size that would accommodate both the tank 6 and the transformer 15, this obliges to increase the weight and volume of the body of the device for evaporation.

 Japanese Utility Model Application Publication No. 1-40617 describes an electric iron used in Japan and the USA that uses a thermistor with a positive temperature coefficient of resistance. However, this iron does not cause high voltage breakdown, which is achieved by increasing the withstand voltage of a thermistor with a positive temperature coefficient of resistance, but it is not intended to reduce the temperature difference at exothermic temperatures at a voltage of 100 V and 220 V.

 The aim of the present invention is to provide a transformerless device for evaporating liquid during heating, which has a small difference in exothermic temperatures despite the magnitude of the applied voltage, so that the flow rate of the evaporating substance in accordance with the applied voltage does not change.

 In the transformerless device for evaporating liquid in accordance with the present invention, the device body and the heating unit are combined and an electric current is supplied to the heating unit for heating and subsequent evaporation of the substance in the tank located in the case of the transformerless device for evaporating liquid.

 The heating unit is mounted on the tank and heats the central element to suck the evaporating substance, which is drawn from the tank. The specified heating unit has a transformerless exothermic casing.

The transformerless exothermic case is a thermistor with a positive temperature coefficient of resistance and its current-voltage characteristic has a region higher than at least 100 V - 240 V of the applied voltage, which satisfies the conditions V _x + I _y = a, where a - is constant, in rectangular coordinates, where the x-axis indicates the voltage V _x , and the y-axis indicates the current I _y .

A thermistor with a positive temperature coefficient of resistance (manufactured by OHI-ZUMI MFG, CO, LTD, in Japan; product name: PGOD-202Y P5, hereinafter referred to as “transformerless exothermic object”) is sintered at a temperature of 1350 ^o C for two hours by adding 0 , 1 wt.% SiO ₂ and 0.20 wt.% Mn k (Ba ₀ , ₈₅₆ Pb _0.10 Sr _0.04 Y _0.004 ) Ti _1,000 O ₃ . In FIG. Figure 1 shows a sudden rise in the temperature-resistance characteristic after the Curie temperature (Tc). When a thermistor with a positive temperature coefficient of resistance is forced to heat above temperature Tc, the current value (Fig. 2) suddenly decreases inversely with the voltage value, even though the applied voltage increases and, thus, it can be assumed that the increase in electric power is suppressed, the ampere characteristic is therefore damped in extreme proximity to a straight line of 45 ^o in the region of 100 V - 240 V of the applied voltage. It was found that the damping characteristic satisfies the equation: V _x + I _y = a, where a - is constant, in rectangular coordinates, where the x axis indicates the voltage V _x , and the y axis indicates the current I _y . In FIG. 1 and 2, the characteristics of conventional thermistors for comparison are shown by dashed lines.

 When voltages of 100 V and 240 V are applied to the exothermic body, as shown in FIG. 2, the change in the electric power consumption P = VI is small and, therefore, there is almost no difference in exothermic temperatures in the range of 100 V - 240 V of the applied voltage. In other words, the heating temperature is constant and even when the heating unit is heated at a voltage of 220 V or 240 V or heated at a voltage of 100 V. The flow rate of all the evaporating material loaded into the tank does not change at different voltages applied to the heating unit.

 Therefore, there is no need to use a transformer and the device body can be made small in size and can be light in weight.

 As indicated above, the exothermic temperature of the heating unit can be maintained almost constant at 100 V, 220 V, or 240 V applied voltage. Therefore, there is no need to use a transformer to lower the voltage in the device case, in contrast to conventional devices. Thus, products for export and products used in Japan can be manufactured in the same way. In addition, they can be small in size and less weight. When the existing device case is used for export, the space in the lid from which the transformer is removed can be used as space for the casing of the electric current source.

 In addition, since there is no need to install a transformer, there is no need for the wiring diagrams themselves, which accompany the installation of the transformer, and therefore, the design can be simplified and the production steps and assembly steps can be reduced.

Further, the present invention is illustrated by a specific embodiment with reference to the accompanying drawings, in which:
FIG. 1 is a temperature-resistance diagram of a thermistor with a positive temperature coefficient of resistance according to the invention;
FIG. 2 shows a current-voltage characteristic of a positive temperature coefficient of resistance thermistor according to the invention;
FIG. 3 shows a device for evaporating a liquid (longitudinal section) according to the invention;
FIG. 4 shows a heating unit (top view in partial section) according to the invention;
FIG. 5 shows a second embodiment of a device for evaporating a liquid (longitudinal section) according to the invention;
FIG. 6 shows another embodiment of a device (longitudinal section) according to the invention;
FIG. 7 shows another embodiment of the invention (longitudinal section) according to the invention;
FIG. 8 shows a device for evaporating a liquid (longitudinal section) according to the invention.

 In FIG. 3 shows a transformerless device for evaporating a liquid in accordance with the present invention. Transformerless device for evaporating liquid has a housing and a heating unit 3.

 The housing contains a reservoir 6 in a predetermined position and filled with vaporizing substance 9. The housing has a bottom cover 1, a support frame 2 and a casing 4. The bottom cover 1 constitutes the base of the housing of the evaporation device and is equipped with a network switch 5. The support frame 2 is formed in one piece and is located in the Central part of the bottom cover 1.

 The supporting frame 2 is open on one side and a tank 6 is placed inside, which is in a predetermined position in the device body. The casing 4 controls the number of released vapors of the evaporating substance from the tank 6, and also has a decorative value. The casing 4 does not have a bottom and has an opening 14 in the upper part for the release of vapors of a substance evaporating during heating. The lower surface of the casing 4 is closed by the lower cover 1 so that it is freely clad on the cover.

 The tank 6 is a container that is loaded with the substance 9 evaporating during heating and into which the wick 8 is inserted for sucking up the vaporizing substance through the top cover 7. A part of the central element 8 is elongated on the top cover 7.

 The heating unit 3 (Fig. 4) is formed in such a way that a transformerless exothermic case 10 is installed inside the cylindrical shell 11. A through hole 12 is provided in the center of the shell 11. The flanges 13 provided on two parts of the periphery edge are screwed to the upper part of the support frame 2. Through the through hole 12 passes the Central element 8, elongated from the reservoir 6.

 In accordance with the position of the network switch 5, electric power is supplied to the heating unit 3. The transformerless exothermic body 10 in the heating unit 3 and the evaporating substance are heated. It is sucked up in the central element 8, evaporates and is released in the form of vapors to the outside of the device body through the hole 14. In this case, the air supplied through the hole 16 rises upward towards the hole 14 of the casing 4, which is heated.

 The table shows the consumption times of the total amount of evaporating substance in those cases when the heating unit 3 generates heat at a voltage of 100 V and 220 V. Below are transformerless devices for evaporating the liquid during heating, which were used in these tests.

1) Transformerless exothermic case:
thermistor with a positive temperature coefficient of resistance manufactured by OHIZUMI MFG. Co. LTD. Japan,
product name: "PGOD - 2002YP5".

This product is obtained by forming a blank of arc segments, each with an outer diameter of 1.34 cm, an inner diameter of 0.78 cm, a thickness of 0.36 cm and a central angle of 100 degrees. Sintering of the preforms was carried out at a temperature of more than 1330 ^o C for two hours. On both sides of the workpieces, electrodes and a pair of thermoresistive elements were provided, which are placed between the terminals and enclosed in the shell of the heating unit 3. Ten samples were selected from products that were produced in bulk as thermistors with a positive temperature coefficient of resistance (product name: PGOD-202YP5 ) These ten samples are indicated as AJ samples.

2) A substance that evaporates when heated:
mosquito repellent liquid (product name): Earth NO MAT (registered trademark) for 30 days (30 days when used 12 hours a day)
45 ml of this liquid was charged into the tank.

 The table shows the time of evaporation and diffusion (hours) of the evaporating substance, and the time at a voltage of 100 V and 220 V. is indicated. The difference is the difference in the time of evaporation of evaporating substances at 100 V and 200 V.

 In accordance with the results shown in table 1, the time for spending the evaporating substance in each sample was short in the case of a voltage of 220 V compared to a voltage of 100 V. However, the time difference was at most only 31 hours.

The evaporation time of the evaporating substance was changed by changing the type of evaporating substances, room temperature, the distance between the central element for sucking up the evaporating substance and the exothermic object. Measurements were carried out, if possible, under the same conditions. It was determined that if there is a difference of 1 ^o C at exothermic temperatures of applied voltages of 220 V and 100 V, this causes a difference of 12 hours in the time of consumption of the entire liquid 45 ml of the evaporating substance 9. Therefore, if the temperature difference is 7 ^o C, then the difference in the time of expenditure is 84 hours.

 Although the table shows data at a voltage of 100 V and a voltage of 220 V, the time spent for the entire liquid does not differ much in the case of a voltage of 240 V compared to a voltage of 100 V.

 Examples of the vaporizing substance used in the present invention are various types of substances that are used for deodorizing, emitting aroma, fungicides, repelling, preventing mold, regulating plant growth, as well as herbicides, insecticides, acaricides, anticides, borericides, which are listed below.

Insecticidal and acaricidal substance:
3-aryl-3-methylcyclopenta-2-ene-4-one-1-yl d1-cis / trans-chrysanthemate (generic name: allethrins, trade name: Pinamin forte, manufactured by Sumitomo Chemical Industries, Ltd, Japan (hereinafter referred to as " AA ");
3-aryl-2-methylcyclopenta-2-ene-4-one-1-yl d-cis / trans-chrysanthemate (commercial name: Pinamin forte, manufactured by Sumitomo Chemical Industries, Ltd., Japan (hereinafter referred to as "AB");
d-3-aryl-2-methylcyclopenta-2-ene-4-one-1-yl d-trans-chrysanthemum (commercial name: Exylin, manufactured by Sumitomo Chemical Industries, Ltd. Japan (hereinafter referred to as "AC");
3-aryl-2-methylcyclopenta-2-ene-4-one-yl 1-trans-chrysanthemate (generic name: bioarethrin, hereinafter referred to as "AD");
N- (3,4,5,6-tetrahydrophthalimide) methyl d1-cis / trans-chrysanthemate (generic name: phthalthrin, commercial name: Neopinamin, manufactured by Sumitomo Chemical Industries, Ltd, in Japan (hereinafter referred to as "AE");
5-benzyl-3-furylmethyl d-cis / trans-chrysanthemate (generic name: rethmetrin commercial name: Crislonforte, manufactured by Sumitomo Chemical Industries, Ltd (hereinafter referred to as "AA");
5- (2-propargyl) -3-furylmethyl chrysanthemate (generic name: flasmetrin hereinafter referred to as "AG");
3-phenoxybenzyl 2,2-dimethyl-3 (2 ', 2'-dichloro) vinyl cyclopropane carboxylate; (generic name; permetorin, commercial name: Exmin, manufactured by Sumitomo Chemical Industries, Ltd., hereinafter referred to as ("AH");
3-phenoxybenzyl d-cis / trans-chrysanthemate (generic: phenothrin), commercial name: Sumithrin, manufactured by Sumitomo Chemical Industries, Ltd.

hereinafter referred to as "Al");
alpha-cyanophenoxybenzyl isopropyl-4-chlorophenyl acetate (generic name: phenvalelat commercial name: Sumisaijin manufactured by Sumitomo Chemical Industries, Ltd, hereinafter referred to as "AJ");
(S) -alpha-cyano-3-phenocibenzyl (1R, cis) -3- (2,2-dichlorvinyl-2,2-dimethylcyclopropanecarboxylate (hereinafter referred to as "AL");
(R, S) -alpha-cyano-3-phenoxybenzyl (1R, 1S cis / trans-3- (2,2-dichlorvinyl-2,2-dimethylcyclopropanecarboxylate (hereinafter referred to as "AM");
alpha-cyano-3-phenoxybenzyl d-cis / trans-chrysanthemum (hereinafter referred to as "AN");
1-ethynyl-2-methyl-pentenyl cis / trans-chrysanthemate (hereinafter referred to as "AO");
1-ethynyl-2-methyl-2-pentenyl 2,2-dimethyl-3- (2-methyl-1-propenyl) cyclopropane-1-carboxylate (hereinafter referred to as "AP");
1-ethynyl-2-methyl-2-pentenyl 2,2,3,3-tetramethylcyclopropanecarboxylate (hereinafter referred to as "AQ");
1-ethynyl-2-methyl-2-pentenyl 2,2-dimethyl-3- (2,2-dichlorvinyl) cyclopropane-1-carboxylate (hereinafter referred to as "AR");
benfluslinplarestrin and isomers, their analogues and derivatives;
O, O-dimethyl O- (2,2-dichloro) vinyl phosphate (hereinafter referred to as "AS");
O-isopropoxyphenyl methyl carbamate (hereinafter referred to as “AT”);
O, O-dimethyl O- (3-methyl-4-nitrophenyl) thionophosphate (hereinafter referred to as the "AU code");
O, O-diethyl O-2-isopropyl-4-methyl-pyrimidine- (6) -thiophosphate;
O, O-dimethyl S- (1,2-dicarboethoxyethyl) -diotiphosphate.

Vermin Repellent:
dimethyl phthalate, 2,3,4,5-bis (delta _2- butylene) -tetrahydrofuran; 2,3,4,5-bis- (delta _2- butylene) -tetrahydrofurfuryl alcohol; N, N-diethyl-m-triamide (DET); diethylamide caprylate; 2,3,4,5-bis- (delta _2- butylene) -tetrahydrofurfural; di-m-propyl-isocinchomeronate; secondary butylstyryl ketone; nonylstyryl ketone; N-propylacetoanilide; 2-ethyl-1,3-hexanedior; di-n-butyl succinate; 2-butoxyethyl-2-furfuridenene acetate; dibutyl phthalate; tetrahydrothiophene; beta naphthol; diaryl disulfide; bis (dimethylthiocarbamoyl) disulfide and so on.

Repellent Rodent:
tetramethylthiuramide sulfite; guanidine; cresolnaphthalene; cycloheximide; zinc dimethyldithiocarbamate; cyclohexylamine; N, N-dimethylsulfenyl dithiocarbamate and so on.

Repellent from cats and dogs:
2,6-dimethyl-octadiene- (2,6) -al (8) (citral);
O, O-diethyl S-2-ethylthioethyl dithiophosphate (ETP);
O, O-dimethyl S-2-isopropylthioethyl diophosphate (MIP); and so on.

Bird repellent:
gamma-chlorarose, 4- (methylthio) -3,5-xylyl-N-methylcarbamate, 4-aminopyridinanthraxinone, tetramethylthiuram disulfide, dialyldisulfide and so on.

Disinfector Rodent:
ANTU; monofluoroacetate soda; warfarin; coumachlor; fumarine; coumatetralylsilylosido; norvomide; N-3-pyridylmethyl-N'-nitrophenylurea;endoside;alpha-naphthylthiourea;thiosemicarbazide;diphenakm; a beer; chlorofazinone; scillatorene; calciferol and so on.

Substances to prevent the appearance of ants:
Belmetrin, Chlordane and so on.

Substance to prevent mold:
alpha-promocinnamicaldehyde, N, N-dimethyl-N-phenyl-N'-fluorodichloromethylthio) sulfonamide and so on.

Plant growth regulator:
4-chlorophenoxyacetate, gibberelin, N- (dimethylamino) succinamide, alpha-naphthylamido and so on.

Deodorant:
laurilic acid methacrylate (LMA) and so on.

Perfume:
citral, citronellal, and so on.

Of the substances described above that evaporate during heating, they form solutions. The solvent for the formulation of the solution of the evaporating substance is water and / or various types of organic solvents containing a surfactant, usually hydrocarbon solvents. It is particularly preferable to use a fatty hydrocarbon having a boiling point in the range of from 150 ^° C. to 350 ^° C. (paraffinic hydrocarbon and unsaturated fatty hydrocarbon). The most acceptable of these are n-paraffin and isoparaffin, as they are non-toxic to use, odorless and have very little risk of fire. In addition to the hydrocarbon mentioned above, other organic solvents are glycerin, propylene glycol, methanol, acetone, xylene, chlorosene, isopropanol, chloroform and so on.

 As indicated above, the solvent is used in accordance with the type of evaporating substance, there are no special restrictions. However, it is desirable to adjust the solvent content to a range of typically about 0.2 to 10% by weight, and preferably 0.3 to 8% by weight.

 The vaporizing substances mentioned above can be introduced with various types of additives, for example, with an anti-clogging substance, with a substance that enhances the effect, with a substance that improves the vapor release ratio, with deodorant, perfume and so on. Examples of substances to prevent clogging are BHT and BHA. Examples of a substance enhancing effect are piperonyl butoxide, N-propylisole, MGK-264, Sinepirin 222, Sinepirin 500, Recen 384, IBTA, S-421, and so on. Examples of substances for improving the vapor release ratio are phenethylisothiocyanate, dimethylchemical.

 As a central element for sucking up the evaporating substance used in the thermal evaporation apparatus according to the present invention, are felt, cotton, cellulose, non-woven textiles, asbestos, inorganic molded materials, organic molded materials. It is preferable to use felt, non-glazed material, cellulose and an element of an inorganic molded material, for example, obtained by curing an inorganic porous porcelain fiber, inorganic glass fiber or asbestos inorganic fiber, with a binder, gypsum or bentonite.

In addition, an element from an inorganic molded material can be obtained simply using kaolin, active porcelain clay, talc, diatomaceous earth, gypsum, clay, magnesium carbonate, perlite, bentonite, alumina, silicon oxide, titanium, vitreous sintered volcanic rock powder, sintered volcanic ash powder, etc., or using them together with wood powder, charcoal powder, activated carbon and so on, which are strengthened with textile glue, for example, dextrin starch, gum arabic, si SMS paste and so on. Particularly preferred for sucking up the evaporating substance is an element obtained by compounding 100 parts by weight of mineral powder and 10-300 parts by weight of wood powder or a mixture of wood powder and an equivalent weight of powder and / or activated carbon with a textile adhesive of 5-25% by weight in relation to the total amount of material, and in addition, the introduction of water to give plasticity and the ability to be molded by extrusion and drying. It is desirable that the rate of suction upward of the thermally evaporating substance is 1-40 hours, preferably 8-21 hours. The suction rate is a value determined by measuring the time when the element is immersed, with a diameter of 7 mm and a length of 70 mm, in n-paraffin at a temperature of 25 ^o C, from the position of 15 mm from the bottom of the element until the paraffin reaches the upper edge of the element. If necessary, wood powder and textile glue can be combined with a dye, for example maraquitic herbs and so on, sorbic acid and its salts, a fungicidal substance, for example dehydracetate acid and so on.

The method of releasing vapors (for example, an insecticidal substance) when using the composition in the claimed device can be carried out in conventional devices of this type. The evaporation temperature is selected in accordance with the type of vaporizing substance used and is not particularly limited, but as a rule, the surface temperature of the exothermic object is in the range of about 40-150 ^° C, preferably 85-145 ^° C, about 30-135 ^° C, preferably about 70-130 ^o C the surface temperature of the element for sucking up the evaporating substance.

 In FIG. 5 is a longitudinal sectional view showing another embodiment of the present invention. In FIG. 5, the heating unit 3 is supported by part 2a, and part of the surface of the casing 4 is closed by the lower cover 1. The upper surface of the lower cover is formed with a protrusion 15, part of the side surface of the casing has an opening for air flow, and between the outer peripheral surface of the element 8 for sucking up the evaporating substance and the inner peripheral surface of the heating unit 3 form a gap 17.

 In accordance with this example, the following advantages can be obtained. Since the gap 17 and the hole 16 are in communication with the atmosphere, the diffusion efficiency of the effective components can be improved. In addition, since the position of the reservoir 6 can be determined by the protrusion 15 on the upper surface of the lower cover 1, centering can be smoothly performed and the transformerless exothermic object can have high functioning efficiency.

 FIG. 6 is a longitudinal sectional view of yet another embodiment of the device. In FIG. 6, part 2a almost in the center has a sleeve 19 and the inside of the sleeve 18 is provided with an internal thread 18a. The tank 6 is threaded 6a connected to the internal thread 18a of the sleeve 18. The element for sucking up the evaporating substance of the tank 6 is inserted into the heating unit 3 so that the element 8 can move in the vertical direction. The lower surface of the casing 4 does not have a bottom, and a support 19 is provided on the open edge of the lower surface of the casing 4. The lower surface of the reservoir 6 is raised upward from the surface using the support 19. Accordingly, the air intake part is fixed on the lower surface of the casing 4. In addition, the lower surface of the supporting Details 2a is provided with elements for the inflow of air, which are located on the inner and outer periphery of the heating unit 3.

 According to this example, since the sleeve 18 is provided almost in the middle of the part 2a, a protrusion is made in the middle of the fluid supply element 8. In addition, by rotating the tank 6 to vertically move the element 8, the number of released vapors can be adjusted using the pitch of the external thread 6a.

 FIG. 7 is a longitudinal sectional view showing yet another embodiment of the invention. The examples shown in FIG. 1 to 6 represent such a device in which the housing of the device comprises a permanently held reservoir 6. In the example shown in FIG. 7, the reservoir 6 is connected to the sleeve 18 by a thread 6a and a thread 18a provided in the sleeve 18 of the part 2a. The tank 6 is open to the lower part of the housing and suspended from it in a stationary position. The plug of the power source 20, with which voltage is supplied to the transformerless exothermic casing of the heating unit 3, is freely inserted into the casing of the device. The inclusion is carried out by inserting the plug of the power source 20. This can be done without coding.

 In accordance with the foregoing, a very compact, non-encoded device can be obtained. In addition, the sleeve 18 may be provided with supporting flexible parts in the portion of the internal thread 18a so that the external thread 6a is pressed against the thread 18a.

 In the examples shown in FIG. 3 and 6, a mechanism may be provided such that electrical code communication is established between the heating unit and the electric power source. This code mechanism can be either manual or automatic. In each example shown in FIG. 3-6, instead of a device placed on the floor, a device mounted on a wall can be used. In addition, in each example shown in FIG. 3-6, a timer may be provided in the device to arbitrarily set the time for the release of the vapor of the substance evaporating when heated. In the tank, means may be provided for identifying the remaining amount of vaporized material by installing an optical sensor, a weight sensor, and so on.

 In the examples of FIG. 3 to 7, it is shown that the transformerless exothermic casing has an annular shape, but the present invention is not limited to this. Transformerless exothermic device may have a U-shape and a cylindrical shape. In the case of using a transformerless exothermic U-shaped device, there is the advantage that the element for sucking up the evaporating substance can be inserted into the tank from the side. In the case where a cylindrical shape is used, the amount of emitted vapor of the evaporating substance can be adjusted by changing the length of the element to suck up the evaporating substance, while the heating section of the central element changes.

 As indicated above, a transformerless device for evaporating liquid during heating in accordance with the present invention can be used to release vapors of deodorant, flavoring agent, fungicide, repellent, substance to prevent the formation of mold and substances to regulate plant growth and other medicines for home use and for use in business.

Note
The inscriptions of FIG. 1:
1 - ratio of resistance,
2 - (comparative example) a conventional product with a positive temperature coefficient of resistance,
3 - (the present invention) the product PGOD-202YP5,
4 - temperature.

The inscriptions of FIG. 2:
1 - a straight line at an angle of 45 degrees,
2 - a conventional product with a positive temperature coefficient of resistance (V _b = more than 1000 V),
3 - product of the present invention PGOD-202YP5 (V _b = 1500 V).

Claims (1)

A transformerless device for evaporating liquid during heating, comprising a housing and a heating unit that vaporizes an evaporating substance in a reservoir located in the device housing by heating a heating unit by passing an electric current, characterized in that the device housing comprises a reservoir filled with the evaporating substance in a predetermined position , the heating unit is mounted on the tank and is designed to heat the central element for sucking up things that evaporate when heated material drawn from the cavity of the tank and is equipped with a transformerless exothermic case, while the transformerless exothermic case is a thermistor with a positive temperature coefficient of resistance and its current-voltage characteristic has a range in the range from at least 100 to 240 V of the applied voltage, which satisfies the condition
V _x + J _y = a,
where a is a value in rectangular coordinates, where the voltage V _{x is} plotted along the x axis and the current J _{y is} plotted along the y axis.

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