ES2893247A1 - Ozone generating light bulb (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

The invention describes a ozone-generating bulb (1) comprising a glass cylindrical tube (2) with a closed end (21) and an open end (22). The open end (22) is hermetically sealed by means of a bushing (3), and the glass tube (2) is filled with a mixture of noble gases. An interior electrode (4) that runs through the inside of the glass tube (2) is connected to the bushing (3), and an outer electrode (5) formed by a tubular metal mesh is arranged in an adjacent position outside the glass tube (two). In addition, the bulb (1) comprises separating elements between the glass tube (2) and the tubular metal mesh that constitutes the outer electrode (5). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Ozone generator bulb

OBJECT OF THE INVENTION

The present invention belongs to the field of ozone generation for hygiene and disinfection.

The object of the present invention is an ozone-generating bulb whose design allows its useful life to be greatly extended.

BACKGROUND OF THE INVENTION

The health crisis generated by the appearance of the Covid-19 virus has caused a growing demand for devices capable of disinfecting rooms and surfaces, mainly indoors. Currently, there are various technologies used for this purpose, among which we can mention the irradiation with ultraviolet light, the spraying of disinfecting agents, or the generation of ozone.

Ozone is an enormously powerful and highly efficient disinfectant biocide against all types of microorganisms, such as viruses, bacteria and fungi, as well as for the elimination of odors and environmental hygiene in interior spaces. The great instability of ozone molecules gives them a great capacity for oxidation, so that they react quickly with the organic molecules of microorganisms. As a consequence, microorganisms are destroyed or degraded into smaller molecules, often less toxic or biodegradable.

There are several mechanisms for the artificial generation of ozone, among which are the ozone-generating bulbs based on corona discharge. These types of light bulbs are basically made up of a glass tube whose end is closed by means of a metal cap and filled with a mixture of noble gases. Inside the glass tube there is an internal axial electrode connected to the metal cap, while an external electrode is located outside the tube. Under these conditions, when voltage is applied to the inner electrode through the bushing, electric arcs are produced between the inner electrode and the outer electrode that cross the dielectric layer formed by the glass tube itself. These electrical discharges, due to known effects that are not part of the invention, cause the dissociation of the oxygen present outside the bulb to form ozone molecules.

In the bulbs used today, the outer electrode takes the form of a metal mesh arranged around the glass tube. This configuration has the important drawback that the electrical discharges that run through the space between the inner electrode and the metal mesh that constitutes the outer electrode partially impact the glass tube itself. As a consequence of the multiple discharges that occur over time, the glass tube gradually wears out until it breaks, forcing the entire bulb to be replaced with a new one.

Ultimately, there is a need in this technical field for ozone-generating bulbs that have a longer useful life.

DESCRIPTION OF THE INVENTION

The present invention solves the above problems thanks to a new ozone-generating bulb where the metal mesh that constitutes the outer electrode is separated from the glass tube, so that there is no point of contact between the two. Thanks to this, the electrical discharges on the outer electrode do not affect the glass tube, thus extending its useful life.

The ozone generating bulb of the present invention basically comprises the following elements. First of all, a cylindrical glass tube with a closed end and an open end is provided, where the open end is hermetically closed by means of a cap, and the interior of this glass tube is filled with a mixture of noble gases. An inner electrode running inside the glass tube is connected to the ferrule, and an outer electrode formed of a tubular metal mesh is disposed adjacent the outside of the glass tube.

So far, the characteristics of the bulb of the invention are common with the bulbs conventionally used today. However, the bulb of the invention differs from those in that it also comprises separation elements between the glass tube and the tubular metal mesh that constitutes the external electrode. These separating elements prevent the tubular metal mesh from coming into contact with the glass, so that the discharges that affect the tubular metal mesh do not affect the glass tube in any way.

In principle, the separation elements can be of any type and number as long as they effectively separate the metal mesh from the glass tube, avoiding any point of contact between the two. Specifically, according to a particularly preferred embodiment of the invention, the separation elements comprise at least two O-rings arranged around the glass tube. In any case, the number of O-rings arranged in the bulb of the invention can vary, being chosen mainly based on the length and rigidity of the metal mesh.

On the other hand, the O-rings must be capable of withstanding the operating conditions of the bulb of the invention, mainly with regard to high temperature. Thus, in a preferred embodiment of the invention, the O-rings may be made of a fluorinated rubber material, more preferably hexafluoropropylene thermopolymer, with vinylidene fluoride, tetrafluoroethylene and vinyl ether perfluoro-methyl.

Fluorinated rubber, conventionally known as FKM or FPM, is a synthetic rubber from the group of thermosetting elastomers. Its best-known trade name is Viton®, developed by DuPont, although other companies have developed their own versions marketed under names such as Dyneon®, DaiEl ®, Fluorel®, Noxtite® or Tecnoflon®. Fluorinated rubber has excellent thermal resistance, maintaining its mechanical properties even at temperatures of 250°C or higher. It is also highly resistant to fuels and aggressive chemicals.

Finally, it should be noted that the location of the O-rings can also be any, as long as they firmly support the metal mesh and ensure an essentially uniform separation along its entire length. For example, in a particularly preferred embodiment of the invention, the two O-rings are provided at respective end portions of the glass tube.

BRIEF DESCRIPTION OF THE FIGURES

Fig. 1 shows a schematic view of an ozone generating bulb according to the present invention.

PREFERRED EMBODIMENT OF THE INVENTION

An example of an ozone generating bulb (1) according to the present invention is described below.

The bulb (1) is made up of a cylindrical glass tube (2) having a closed end (21) and an open end (22). The closed end (21) is completely hermetic, since it is constituted by a bulb of the glass itself that constitutes the tube (2). The open end (22), in turn, is also hermetically sealed by means of a bushing (3) of essentially circular shape and provided with a terminal (31) that protrudes externally in the axial direction. An inner electrode (4) having an end fixed to the socket (3) is disposed along the axial direction inside the glass tube (2). For its part, an external electrode (5) in the form of a cylindrical metal mesh is arranged in an external position adjacent to the glass tube (2), in parallel with it.

To ensure an essentially uniform separation between the glass tube (2) and the metallic mesh that constitutes the external electrode (5), two O-rings (6) made of fluorinated rubber, specifically a thermopolymer of hexafluoropropylene, with fluoride, have been provided. of vinylidene, tetrafluoroethylene and ethereperfluoro-methyl vinyl known commercially as Viton®. The great thermal and chemical stability of this material ensures adequate maintenance of the mechanical properties of the O-rings (6) throughout the useful life of the bulb (1). One of these O-rings (6) is installed near the end of the glass tube (2) closed by the bushing (3), while the other is installed near the opposite end (2) of the glass tube (2).

Thus, as the metal mesh (5) rests on the two O-rings (2), there is a uniform space between said metal mesh (5) and the glass tube (2). This space can be, for example, a few millimeters, avoiding any contact between the metal mesh (5) and the glass tube (2). In this way, the glass tube (2) of this novel light bulb (1) does not deteriorate due to the repeated electrical discharges that occur during its operation, and consequently its useful life is much longer than that of conventional light bulbs. .

Claims (5)

1. Ozone generator bulb (1), comprising a cylindrical glass tube (2) with a closed end (21) and an open end (22), where the open end (22) is hermetically sealed by means of a cap (3), where the glass tube (2) is filled with a mixture of noble gases, where an internal electrode (4) that runs inside the glass tube (2) is connected to the socket (3), and where a outer electrode (5) formed by a tubular metal mesh is arranged in a position adjacent to the outside of the glass tube (2), characterized in that it also comprises separation elements between the glass tube (2) and the tubular metal mesh that constitutes the external electrode (5). 2. Ozone generator bulb (1) according to claim 1, wherein the separation elements comprise at least two O-rings (6) arranged around the glass tube (2). 3. Ozone generating bulb (1) according to claim 2, wherein the O-rings (6) are made of a fluorinated rubber material. 4. Ozone generator bulb (1) according to claim 3, where the fluorinated rubber is a thermopolymer of hexafluoropropylene, with vinylidene fluoride, tetrafluoroethylene and ethereperfluoro-methyl vinyl. 5. Ozone generating bulb (1) according to any of claims 2-4, wherein the two O-rings (6) are arranged in respective end portions of the glass tube (2).