RU2071785C1 - Apparatus for sterilizing medical instruments - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: apparatus comprises chamber with opening for receiving instruments to be sterilized, and cover attached hinged to axial-end surfaces of chamber. The latter houses ultraviolet radiation source and means for holding instruments to be sterilized. Internal side surface of chamber is cylindrically shaped, while axial-end surfaces are elliptically shaped. Means for holding instruments is formed as planar quartz glass piece whose plane passes through lower focal axis of chamber, and radiation source, suitable ultraviolet lamp, is aligned along upper focal axis of chamber. Optionally, chamber can accommodate halogen-filled incandescent lamps generating strong infrared radiation which represents additional sterilizing factor, while lamps themselves serve to stabilize voltage during voltage variations in power supply circuit. Above and below instruments-holding means, in side surface of chamber, openings are formed for air admission and outflow. EFFECT: structurally simple, cheap and highly efficient apparatus for simultaneous sterilization of great number of medical instruments. 3 cl, 3 dwg

Description

 The invention relates to medical equipment, in particular to devices for sterilizing medical instruments under the influence of ultraviolet radiation.

A device for sterilizing and storing medical instruments is known, which consists of a semi-cylindrical chamber with a lid, inside which an ultraviolet emitter with a timer is installed [1]
The disadvantage of this device is the low sterilization efficiency due to the fact that this design does not provide a complete and uniform irradiation of the entire surface of the instruments.

A device for sterilizing medical instruments is known, consisting of a chamber with an inlet for supplying oxygen-containing gas and an outlet for exhausting gaseous products, inside which a means for accommodating medical instruments, as well as two UV emitters equipped with mirrors and installed symmetrically relative to means for placement of medical instruments [2]
The disadvantages of this device also include insufficient efficiency due to incomplete irradiation of the surface of the sterilized instrument, as well as the mutual shading of the irradiated surfaces while sterilizing several instruments.

 Closest to the claimed is a device consisting of a camera, inside which is installed a means for placing medical instruments, on the inner surfaces of the chamber, four UV emitters equipped with mirrors are installed in pairs symmetrically with respect to the means for placing instruments.

 Means for placing tools is made in the form of a quartz tube, the axis of which coincides with the longitudinal axis of symmetry of the camera. A hole is made in the end wall of the chamber, the center of which lies at the intersection of the axis of symmetry of the chamber.

The device has a hinged cover [3]
The disadvantages of this device are the inefficiency of sterilization while simultaneously irradiating several medical instruments due to mutual shading of the surfaces.

 In addition, the use of four UV emitters and four mirrors complicates the design and makes it uneconomical to operate.

 The technical effect is the high sterilization efficiency, the possibility of simultaneous sterilization of a large number of instruments and the economy in operation.

 For this, in a device for sterilizing medical instruments, consisting of a chamber with an opening for placing medical instruments, inside which an ultraviolet emitter and means for accommodating medical instruments and a lid are installed, the inner side surface of the chamber is cylindrical, diffusely reflecting UV radiation, means for placing instruments made in the form of a plate of quartz glass, the plane of which passes through the lower focal axis of the camera, and the ultraviolet emitter copulating along the top focal chamber.

 The use of a camera having a cylindrical inner side surface that diffusely reflects UV radiation, when the emitter is placed along the upper focal axis of the camera, ensures full reflection of the rays from the chamber walls and the irradiation efficiency of instruments located on flat quartz glass.

 Inside the chamber, halogen incandescent lamps can be installed in a quartz case, connected in series with a UV emitter, which act as resistors and limit the discharge current in the emitter, working in the mode of discharge current barretters-stabilizers with current fluctuations in the power circuit. The combined use of a UV emitter and halogen lamps ensures metrological stability of the intensity of photochemically active radiation with a wavelength of 254 nm and additional heat treatment of the surface of sterilized instruments.

 Openings for air inlet and outlet made in the upper and lower parts of the side surfaces of the chamber provide convection air flows as well as air ozonation inside the chamber, which creates an additional sterilizing effect. The device cover is located on one of the end surfaces of the camera, attaching to it using hinges.

 Thus, using a single UV emitter provides shadowless irradiation of the entire surface of sterilized medical instruments.

 The device is illustrated by drawings, in which figure 1 shows the inner chamber of the device; figure 2 diagram of the path of the rays in the chamber; figure 3 is an electrical diagram of the inclusion of an ultraviolet emitter and halogen lamps.

 The device has a camera, the inner side surface 1 of which is cylindrical, and the end surfaces 2 and 2 'in the form of ellipses. A UV emitter 3 located along the upper focal axis of the camera is placed inside the camera. In the lower part of the chamber there is a quartz table 4 for placing sterilized instruments, the glass plane passing through the lower focal axis of the chamber. Inside the case, halogen incandescent lamps 5 can also be installed, located on the upper and lower parts of the side surface 1. To ensure free convective air transport in the walls of the chamber 1, there are holes 6. The hole for placing medical instruments is made in one of the end walls of the chamber and is closed by a lid pivotally attached to the end wall of the chamber.

 The device operates as follows.

The device is included in the power supply with 220 V and 50 Hz using a power cord. Before turning on the device, you must ground it. The quartz table 4 is wiped with a swab to remove possible contaminants. Previously, a medical instrument is treated with an antiseptic solution. Then, through the opening for placement of medical instruments, made in one of the end faces of the chamber on quartz glass 4, all sterilized instruments are placed at a distance of more than 1.5 cm from each other, there are gaps between the inner surface of the chamber and the quartz glass that provide convection air flow. The height of the hole for placing tools does not exceed the distance between the two foci of the end base. The hole is closed by a lid pivotally attached to the end base. The emitter 3 (for example, type PRK) is included in the electric circuit, it provides an intensity of UV light emission of 10 ¹⁵ quantum / cm ² and operates in low current mode (about 0.3 A). Radiation with a wavelength of 254 nm has the highest bactericidal activity. The implementation of the inner side surface of the chamber is cylindrical, diffusely reflecting ultraviolet radiation, and the end surfaces 2 and 2 'in the form of ellipses when the emitter 3 is placed along the upper focal axis of the chamber, and the medical instrument is located on a flat quartz glass 4 passing through the lower focal axis of the chamber, to ensure complete diffuse reflection and effective irradiation with UV radiation of the instrument to be sterilized. Diffuse reflection refers to partial scattering of light by reflection from the inner surface of the camera. The surface material is selected so as to provide a diffuse reflection of UV radiation. Kersil can be used as such a material, the reflection coefficient of which is 0.8 in the ultraviolet region. In diffusion reflection, UV radiation is partially scattered by the surface. Halogen incandescent lamps in a quartz case 5, connected in series with the emitter 3, limit the discharge current in the UV emitter and provide stabilization of the discharge current in the electrical circuit during fluctuations in the supply voltage. The number of halogen lamps is determined by the discharge current of the emitter 3, necessary for the emission of radiation with a wavelength of 254 nm. Stabilization of the discharge current provides a constant UV radiation intensity and radiation dose necessary for effective sterilization. Halogen incandescent lamps provide intense infrared radiation, which provides additional heat treatment of the instrument being sterilized. As halogen lamps, lamps of the Narva type can be used. Through holes 6 cause the transfer of ozonation air. After sterilization, the instrument is removed from the chamber.

 Thus, the device provides complete shadowless irradiation of the entire surface of the sterilized instruments, and it is possible to simultaneously irradiate several instruments, the number of which is limited by the geometric dimensions of the chamber. This ensures high sterilization efficiency, and the device itself does not contain complex elements and scarce materials and is economical in production and operation.

 The device can be used to sterilize surgical, dental and other instruments both in a hospital and in an outpatient setting.

Claims (4)

 1. A device for sterilizing medical instruments, comprising a chamber with an opening for accommodating medical instruments, inside which a source of ultraviolet radiation and means for accommodating sterilized instruments are placed, and a lid, characterized in that the inner side surface of the chamber is cylindrical, the end surfaces of the chamber are ellipses , and the tool placement tool has the form of a flat quartz glass, the plane of which passes through the lower focal axis of the camera, and the source UV radiation is mounted along the top of the focal axis of the camera.  2. The device according to claim 1, characterized in that halogen incandescent lamps are installed inside the chamber.  3. The device according to paragraphs. 1 and 2, characterized in that in the lateral surface of the chamber above and below relative to the means for accommodating tools, holes are made for the inflow and exhaust of air.  4. The device according to claim 1, characterized in that the cover is pivotally attached to one of the end surfaces of the camera.

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