RU2812757C2 - Device for vaporizing volatile substances containing tampon and heat reflective element - Google Patents

Abstract

FIELD: evaporation equipment.

SUBSTANCE: device contains a tampon impregnated with volatile substances and a heating element configured to heat the tampon to evaporate the said volatile substances, as well as a reflective element for reflecting heat from the heating element to the said tampon. In this case, the said heating element is placed between the tampon and the reflective element. The heating and the reflective elements are cylindrical in shape, with the said heating element completely covering the tampon along the circumferential direction and partially covering the tampon along the axial direction. The heating element and the reflective element are placed inside one another such that the reflective element is external to the heating element. In this case, the reflective element completely covers the heating element along the circumferential direction and along the axial direction and covers the tampon along the axial direction beyond the region of partial coverage by the heating element.

EFFECT: improved efficiency and reliability of the design.

7 cl, 4 dwg

Description

This application is separated from application No. 2019121605 for the grant of a RF patent for an invention, filed on December 28, 2016, claiming priority based on the filing date of the said first application.

Field of technology to which the invention relates

The invention relates to a device designed for evaporating volatile substances and containing a tampon impregnated with volatile substances, as well as a heating element configured to heat the tampon to evaporate the volatile substances.

State of the art

Electric air fresheners have become a very common consumer product in recent decades. The most common of these devices are connected to electrical networks and contain a replaceable container with a liquid containing volatile substances and a tampon that transports the liquid from the internal volume of the container to the outer area of the tampon, where the volatile particles evaporate. This cylinder is placed in a device that enhances the evaporation of the volatile substance through an electric heater.

For the design of the heater, a standard technological technique is to supply the electric heater with a ceramic casing or insert an electrical resistor without insulation into the internal volume of the plastic housing. The function performed by this casing and housing is to provide electrical isolation between the resistor and the environment.

Known technical solutions associated with electrical devices that evaporate volatile substances have several disadvantages.

First, such devices are usually large in size, and each of their surfaces dissipates heat. As a result, only part of the heat is directed towards the tampon where it is needed, and this reduces the electrical efficiency of the device.

Second, heat directed away from the tampon results in overall heating of the device, which can significantly increase the surface temperature of the device. Therefore, to avoid a situation in which the surface temperature exceeds the limit set by electrical certification organizations, devices must be of significant size.

Accordingly, the object to which the invention is directed is to provide a device for evaporating volatile substances that allows substantially all of the heat emitted by the heating element to be directed towards the tampon, thereby preventing the surface temperature of the device from excessively increasing.

Disclosure of the invention

The device according to the invention eliminates the above disadvantages, while at the same time providing other advantages disclosed below.

A device for evaporating volatile substances according to the invention contains a tampon impregnated with volatile substances and a heating element configured to heat the tampon to evaporate these substances. This device is characterized in that it also contains a reflective element for reflecting heat from the heating element to the specified tampon.

Due to the presence of this feature, the reflective element reflects or redirects the thermal radiation emanating from the heater back towards the tampon impregnated with volatile substances, and the thermal energy emitted by the tampon itself is reflected back towards it, which allows the use of a heating element with the same evaporation efficiency consuming less energy.

Another advantage is that the reflected heat does not contribute to the overall heating of the outer surface of the device.

It is desirable to be able to use a resistor or a ceramic heater as a heating element, and it is preferable to make the reflective element with a metal surface.

In a preferred embodiment, a heating element is placed between the tampon and a reflective element, and according to a possible embodiment, said heating element and/or said reflective element are cylindrical in shape and placed one inside the other, namely, the reflective element is located outside the heating element.

If desired, the heating element and the reflective element can be connected via a base, and according to a possible embodiment, the reflective element is made of two layers and consists of a reflective layer and a base layer.

The device for evaporating volatile substances according to the invention may also include a thermal protection component connected to the reflective element, and a negative temperature coefficient element brought into contact with the reflective element for measuring the temperature of the reflective element and changing, through an electronic circuit, the power supply supplied to the device, according to the measured temperature.

It is desirable that the device for evaporating volatile substances made according to the invention further comprises a cover covering the tampon, a heating element and a reflective element.

The advantage of the device according to the invention is its very low thermal inertia. For example, while a standard heater using a rod (eg, metal oxide) resistor would reach operating temperature in 15-20 minutes, the device of the invention is capable of reaching operating temperature in seconds, specifically 10-20 seconds.

Brief description of drawings

For a better understanding of the above description, accompanying it are several drawings, which schematically and by way of non-limiting example only illustrate a practical embodiment of the invention.

In fig. 1 shows a schematic perspective view of a first embodiment of a device according to the invention for evaporating volatile substances.

In fig. 2 shows a schematic perspective view of a second embodiment of a device according to the invention for evaporating volatile substances.

In fig. 3 shows a schematic perspective view of a third embodiment of a device according to the invention for evaporating volatile substances.

In fig. 4 shows a schematic perspective view of a fourth embodiment of a device according to the invention for evaporating volatile substances.

Carrying out the invention

The proposed device for evaporating volatile substances contains a tampon 1, impregnated with volatile substances, and a heating element 2, which heats the tampon 1 to evaporate these substances. In addition, the device contains a reflective element 3 for reflecting heat from the heating element 2 to the specified tampon 1.

It should be borne in mind that for the sake of simplicity, only a portion of the device is shown in the accompanying drawings, since the rest of the device is common and obvious to one skilled in the art.

In fig. 1 illustrates a first embodiment of a device according to the invention.

In this first embodiment, the heating element 2 is a standard rod resistor (eg, a metal oxide resistor), and the reflective element 3 is a metal wall placed on the opposite side of the tampon.

In an alternative embodiment shown in FIG. 2, it is possible to change the geometry of the heating element 2. In this embodiment, it is made flat, and the reflective element 3 is a metal wall with a mirror polish. In this case, the heating element 2 is a metal-ceramic heater with a thickness of, for example, 1-2 mm. This type of heater exhibits very low thermal inertia and is able to heat up to the specified operating temperature very quickly.

In the next alternative embodiment, shown in FIG. 3, the geometry of the heating element 2 and the reflective element 3 is similar to the geometry of the tampon 1. The tampon 1 is a standard cylindrical tampon, and the heater has a tubular or cylindrical shape, preferably made of cermet. The reflective element 3 also has a tubular or cylindrical configuration.

In an alternative embodiment shown in FIG. 4, tampon 1 is not shown in the drawing, since it is located inside a cylinder formed by heating element 2. In this case, the diameter of tampon 1 can be selected in the range of 4-5 mm, and the heating element can be a metal-ceramic heater with a thickness of 2 mm, internal diameter 9 mm and height 12 mm.

For the reflective element 3, the preferred option is a metal element with a thickness of 1 mm and with a light reflection coefficient exceeding 30% in the spectral region from 400 nm including the infrared range. However, any type of reflective element 3 suitable for reflecting heat towards the tampon 1 can be used.

One of the preferred materials for this reflective surface is aluminum. Alternatives to it may be silver, copper, gold or other similar metals.

In addition, alternative materials may be considered, even those with lower performance and reduced reflectivity, such as plastic materials whose thermal conductivity is enhanced by the addition of boron nitride or carbon nitride or filler such as talc or fiberglass, or polymers. Using this type of material allows for simplified manufacturing (and also reduces costs); however, its technical characteristics are worse than those of the metal reflective element.

Alternatively, the reflective element 3 can be made of two layers, one of which is highly reflective and is located on the inside of the cylinder, and the other, located on the outside of the cylinder, has low thermal conductivity.

This two-layer structure can be produced simply by bringing two separate layers into contact and mechanically holding them together using the plastic base 4 of the device. Alternatively, the two layers may be joined to each other in any conventional and known manner.

Also, as an alternative, a highly reflective layer can be obtained by depositing a layer of thin metal film on the inside of a material having low thermal conductivity.

As an additional improvement, it is possible to attach a thermal protection component 5 to the reflective element 3. The function performed by this element is to ensure the safety of the device, and specifically to interrupt the power supply in the event of measuring an abnormally high temperature.

Another further improvement provides the possibility of attaching a negative temperature coefficient element to the outer surface of the reflective element 3. This element with a negative temperature coefficient is not shown in the drawings; however, it can be placed on the other side, opposite the thermal protection component 5, and used in addition to or instead of the thermal protection component 5.

The function performed by the NTC element is to measure the temperature of the reflective element 3 and, together with the electronic circuit, to change the power supply to adapt the temperature of the tampon 1 to compensate for possible voltage fluctuations. These voltage fluctuations can occur due to frequently detected changes in voltage at household outlets (more critical in a developing country), as well as due to the gradual decrease in voltage in a battery-powered device.

As shown in FIG. 4 and also applicable to other embodiments of the invention, for assembling the components of the device into a single whole, the device preferably comprises a base 4, preferably made of a plastic material. In addition, the device according to the invention may also contain a printed circuit board 7 with an electronic circuit that functions as an electronic control that controls the operation of the device.

For example, the electronic control may control the operation of the device to produce peaks of increased intensity and periods of decreased intensity, thereby counteracting the well-known olfactory habituation effect.

In a preferred embodiment, the device also has a case or housing (not shown in the drawings) equipped with a plug for connecting to the network.

One of the advantages of this design, especially when applied to a cermet heater, is its very low thermal inertia. Compared to a standard heater that uses a rod (eg metal oxide) resistor and reaches operating temperature in 15-20 minutes, the heater according to the invention is able to reach operating temperature in seconds, namely 10-20 seconds.

Although only specific embodiments of the invention are discussed, one skilled in the art will understand that, without going beyond the scope of legal protection defined by the appended claims, various variations and modifications can be made to the device discussed, and all parts described can be replaced by others, technically equivalent parts.

Claims (7)

1. A device for evaporating volatile substances, containing a tampon impregnated with volatile substances, and a heating element configured to heat the tampon to evaporate said volatile substances, and also containing a reflective element for reflecting heat from the heating element to said tampon, characterized in that said a heating element is placed between the tampon and the reflective element, and the heating element and the reflective element are cylindrical in shape, wherein the heating element completely covers the tampon along the circumferential direction and partially covers the tampon along the axial direction, and the heating element and the reflective element are placed one inside the other, so that the reflective element is external to the heating element, the reflective element completely covering the heating element along the circumferential direction and along the axial direction, and covering the tampon along the axial direction beyond the region of partial coverage by the heating element. 2. A device for evaporating volatile substances according to claim 1, in which the heating element is a ceramic heater. 3. A device for evaporating volatile substances according to claim 1 or 2, in which the reflective element has a metal surface. 4. A device for evaporating volatile substances according to any of the previous paragraphs, wherein said heating element and said reflective element are connected by a base. 5. A device for evaporating volatile substances according to any of the previous paragraphs, in which the reflective element is made of two layers: a reflective layer and a base layer. 6. The device for evaporating volatile substances according to any of the previous paragraphs, further comprising a thermal protection component connected to the reflective element. 7. The device for evaporating volatile substances according to any of the previous claims, further comprising a negative temperature coefficient element in contact with the reflective element for measuring the temperature of the reflective element and electronically changing the power supply supplied to the device in accordance with the measured temperature.

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