RU18055U1 - QUARTZ LAMPS BACZONE-FREE BACTERICIDAL - Google Patents

Abstract

Ozone-free bactericidal quartz lamp, the bulb of which is made of quartz glass and filled with an inert gas with a metered amount of mercury, with two electrode assemblies consisting of an oxide-coated electrode that reduces the electron work function fixed between two electrode legs, each of which is connected to the contact electrode foil and electrode contact, stamped into the flask from opposite ends on the contact electrode foil, characterized in that the electrode assemblies are made of m a stepwise spiral, and on the outer surface of the lamp bulb is selectively transmitting a silicon titanium coating made with a solution of tetraethoxysilane and tetrabutoxy titanium, followed by drying and heating of the lamp bulb.

Description

The utility model relates to the field of medicine, in particular, for ultraviolet quartz lamps for hygiene and hygiene treatment devices, it can be used as part of cleanroom systems for rooms and rooms, as well as in technological disinfection systems.

Lamps for ultraviolet disinfection are known, containing a flask and a blue glass stack, inside of which an electrotCC is fixed and the flask is filled with argon with a metered amount of mercury. When a sufficient hardener is supplied to the electrode, a nymn, a low-current, Д ГЕОЙ ра; fad Е argon arises, which, as the mercury evaporates, goes into the najjax mercury discharge, from its t / tea its spectrum (1).

A disadvantage of the known solution is the difficulty of standardizing the quality of uvolev glass during its preparation and the low transmission ability of the short-wavelength ngt1} 1enny in the range of 205-280 nm. In addition, the short term of lye service to the loss of its basic properties is due to the low stability of the z-viola stack to addecic and oxide products evaporating from the electrodes during the combustion of the lamp, which settle on the back of the bulb and reduce the radiation power.

A closer solution, but of a technical nature, is a lamp whose bulb is made of quartz glass, filled with an inert gas argon with a metered amount of mercury, and the electrodes are coated with an oxide composition, which reduces the work of all electrons, and the emission of these ions is in a blown vapor discharge mercury (2).

The disadvantage of this solution is the formation of ozone during lamp operation due to a wide spectrum of ultrafiltration radiation., With maximization of radiation at resonant wavelengths, not only 257.7 em bactericidal, but also 184.9 ozone-forming them. When ozone interacts with alotnous bases present in air, doxy form. The indicated compounds are poisons and benefits.

bactericidal SOURCE of ultraviolet with the same properties is unacceptable. In addition, ozone has been observed for many centuries to be a blue oxidizing agent in its content in vol. no other rules are allowed.

The technical validity of the utility model is to eliminate the indicated drawbacks, increase the power of the bactericidal nsjiyqeHHfl and eliminate the formation of ozone during LALSHA operation.

The set circuit is achieved by the fact that in a lamp whose bulb is made of quartz glass and filled with an inert metered amount of mercury, with electrode assemblies, an oxide electrode coated with an oxide coating that lowers the electron work function is closed by two electrode skin, each junction of which is connected to a foil with a contact electrodes and an electrode contact, stamped into a flask from opposite ends on a contact electrode foil, electrodes; the electrode assemblies are made using a multi-step spiral, and The outer surface of the lamp bulb is coated with a selectively transmitting silica-tinting coating, made with a solution of tetraethoxysilane and tetrabox to titanium, followed by drying and heating of the lamp bulb.

In FIG. 1 is a lamp diagram showing 1 quartz bulb, with selectively transmitting i-coating 2 silicon-titanium, with the first 3 and second 4 electrode assemblies consisting of an electrode 5 made from a multi-step spiral with a coating, electrode legs, 8 contact electrode foil and contacts 9 electrodes.

The lamp is made in the following manner. Os; |, preparation of the electrode assembly 3 and 4 is made. A spiral of 6 electrodes 5 and: 5 is prepared and, with EO.ta. of the frame thread, twist it into a spiral with the smallest possible pitch. From yao.puchennoy S11ira. the next spiral is twisted, it is even larger in pitch than the previous one. Then the next spiral is hidden / hidden from the river of the obtained double helix. A complete multi-step pyramidal spiral of 6 electrodes 5 is accreted between the legs of the 7th electrode and is coated with Be1Cestaom, which reduces the work function of electrons, for example, barium oxide, according to known technology. As a result of the fact that spiral b has a complex multi-step design, it possesses sufficient resistance for a given temperature of heating, and it bears a coating of oxide that reduces the electron work function much more ... better than in the manufacture of an electrode and, with a one-word

 Coated. This design of the spirles electrode, makes the allia lamp process easier and lowers the current required for the day the gas-discharge process is formed.

A spiral of electrodes 5 is attached to the molybdenum legs 7. “An electrode that is attached to the molybdenum foil 8 of the contrast electrode, a. already on the molybdenum foil, 9 electrode contacts are welded.

Made in this way: 50AL first 3 and second 4 electrode coopKSi are soldered into a bulb 1 of a lamp made of quartz glass from the ends in such a way, whose spiral 5 of the electrode is multi-step, fixed on. legs 6 are sealed inside the flask, and stamping of the electrode assembly into a quartz flask is carried out on a 7-contact foil. Such a solution prevents the VEOD lamp from failing due to the possibility of the so-called leakage of atmospheric air through the place of the ta-vdpovkn electrode assembly into the VARSA flask.

After technological heating of the electrodes 5 with a high-frequency current, additional pumping of the lamp and filling with an inert gas with a metered amount of mercury and welding of the technological channel., The location of which is connected with an ignition principle of fundamental value on. FIG. 1 not shown. Ko.iiH4ecTBO mercury in the Lalsche, as well as the inert gas used and its pressure, is determined by the power of the lam.py.

Next; At this stage, the technical training of the lamp at the switch-on stand and verification of its electrical parameters is carried out.

After the iaroness of monitoring the lamp’s operability and its electric power for five points, the process of coating is excluded, excluding the study of the ultraviolet spectrum in the short-wave ozone-forming part.

To do this, a special solution of selectively transmissive coating is prepared consisting of the main components containing crem. Tetra ethoxysnlan and titanium tetrabutoxy titanium, diluted in zytol alcohol with the addition of hydrochloric acid. When this content is contained in the main components of a solution of a selectively transmissive coating, it does not exceed 5%. After the process of ripening the solution, after 24 hours, they begin to apply the coating on the surface of the bulb of the lamp by pouring and dipping.

After coating, the creep is slightly dried with turning around its axis in order to avoid the formation of sagging and heat up the hardening / fixing and fixing in the furnace.

The heating of the bulb of the lamps allows the formation of a film on the surface of LaAsha cobla containing titanium in silicon oxide, i.e. half a quartz film on the surface of the flask alloyed with titanium. Such a film is resistant to external interactions and is stored on the surface of the la-mpa flask for the entire period of its c.;: SvT c6bi.

The crystallization of titanium inclusions during heating allows the creation of a protective crystalline reagent} titanium molecule in the coating, which KopoTKOso.rjHOBoe cuts off the ozone image: a breathable ultraviolet coolant up to 205 FsM. At the same time, such a coating practically does not affect the bactericidal flux, i.e., the total value of 5nen in the range 205-315 nm.

After the operation, the coating is applied to control the light and speckle parameters of the lamp and, if necessary, 1, the electrode contacts 9 are fixed in the corresponding base.

The tests performed showed high technical parameters that met the medical requirements of the product. Ozone-free bactericidal quartz lamp “LBK recommended by the committee on new medical equipment of the Ministry of Health of Russia for production and practical use.

The information bullets taken into account.

1. Lamp bactericidal arc DB 30-1, technical specifications TU 16-535.273-75.

2. Lamp arc mercury-quartz bactericidal DRB-40, specifications A1Sh1K.433220.038 TU.

Claims (1)

Ozone-free bactericidal quartz lamp, the bulb of which is made of quartz glass and filled with an inert gas with a metered amount of mercury, with two electrode assemblies comprising an oxide coated electrode, which reduces the electron work function, fixed between two electrode legs, each of which is connected to a contact electrode foil and electrode contact, stamped into the flask from opposite ends on the contact electrode foil, characterized in that the electrode assemblies are made of m a stepwise spiral, and on the outer surface of the lamp bulb is selectively transmitting a silicon titanium coating made with a solution of tetraethoxysilane and tetrabutoxy titanium, followed by drying and heating of the lamp bulb.