RU104068U1 - UNIT FOR DISINFECTION WITH UV RADIATION - Google Patents

Abstract

 1. Installation for ultraviolet disinfection, containing at least one bactericidal lamp of ultraviolet radiation, connected to a power supply and a control unit equipped with a system for controlling the intensity of ultraviolet radiation, including a sensor for the intensity of ultraviolet radiation, a microprocessor configured to control the intensity of ultraviolet radiation, characterized in that the control unit contains a lamp hour meter, and the power supply contains a power factor corrector tee. ! 2. Installation according to claim 1, characterized in that the power supply is equipped with electronic ballasts made with the possibility of powering bactericidal ultraviolet lamps. ! 3. The installation according to claim 1, characterized in that the microprocessor is made non-volatile and is associated with an alarm device. ! 4. Installation according to claim 3, characterized in that the alarm device has a means for supplying an audio signal and an LED indicator.

Description

The utility model relates to installations for sterilization with ultraviolet radiation, in particular, to installations for the disinfection of drinking water, wastewater, air and open surfaces of domestic and specialized premises, in particular medical facilities, bacteriological laboratories, industrial premises of food or pharmaceutical industries .

Currently, widespread installation for disinfection with ultraviolet radiation, which use special bactericidal lamps. Often such installations are used in specialized rooms where the quality of disinfection plays a key role, for example, operating rooms, dressings, etc. Therefore, it is very important to effectively monitor the intensity of ultraviolet radiation, as well as an indication of any abnormal mode of operation of such an installation. Basically, for this purpose, ultraviolet radiation intensity control systems are used, made with the possibility of setting the minimum permissible value of ultraviolet radiation intensity, subsequent monitoring of ultraviolet radiation intensity, as well as ensuring the operation of signaling devices in the event of a critical decrease in the intensity of ultraviolet radiation or the failure of a bactericidal lamp. However, often such systems are not sufficiently informative and do not always allow to prevent the onset of a critical decrease in the intensity of ultraviolet radiation, which may entail negative consequences. In addition, an important characteristic of such installations is the quality of power consumption, which is characterized by a power factor, while the lower the power factor, the lower the quality of electricity consumption. The correction of the power factor allows to reduce the level of current consumption, which in turn can provide an increase in the economic efficiency of the introduction of such installations. Thus, the challenge remains to create installations for disinfection with ultraviolet radiation, which would allow for effective control of the intensity of ultraviolet radiation, and due to their design would reduce energy consumption, increase the life of lamps and the economic efficiency of the introduction of such installations.

The closest analogue of the claimed utility model is the installation for ultraviolet disinfection described in the patent of the Russian Federation for utility model No. 11068 and containing at least one bactericidal lamp of ultraviolet radiation, connected to a power supply and a control unit equipped with a system for controlling the intensity of ultraviolet radiation, including the setpoint of the minimum allowable value of the intensity of ultraviolet radiation, a microprocessor configured to control the intensity of ultraviolet radiation radiation and associated with the alarm device.

The disadvantages of the described device include the lack of information and installation efficiency when monitoring the intensity of ultraviolet radiation, as well as the inability to provide a rational consumption of the installed bactericidal lamps.

The utility model is based on the task of developing an installation for disinfection with ultraviolet radiation, which, due to the simplicity and optimal selection of structural elements, will ensure high efficiency of the installation, control the intensity of ultraviolet radiation, timely notification of the possibility of an emergency, and will also increase the life of used bactericidal lamps and increasing the economic efficiency of the installation as a whole.

The problem is solved in that the installation for ultraviolet disinfection is developed, comprising at least one bactericidal lamp of ultraviolet radiation, connected to a power supply unit and a control unit equipped with a system for controlling the intensity of ultraviolet radiation, including a UV intensity sensor, a microprocessor configured to measure the intensity ultraviolet radiation and associated with the alarm device, while the control unit with holding the lamp operation time count, and the power supply is provided with a power factor corrector.

Such an implementation of the utility model makes it possible to provide effective control of the intensity of ultraviolet radiation with timely notification of the possibility of an emergency due to the lamp operating time counter in the control unit, which allows you to record the duration of each bactericidal lamp and determine the need for warranty service. As the bactericidal lamp resource is depleted using the alarm device, the appropriate signals are sent about the need to replace the bactericidal lamp with the developed resource. The presence of a power factor corrector makes it possible to reduce the current consumed by the installation, since with a high value of the power factor (about 1), almost all the power consumption is transferred to the load, i.e. the practical absence of reactive power consumption, which significantly improves the quality of electricity consumption, since less harmonic distortion is fed back into the electric network, thereby reducing negative consequences for other consumers. Given that the power factor corrector is also a voltage stabilizer, the intensity of ultraviolet radiation does not depend on a wide variation in the supply voltage. This, in turn, ensures high efficiency of the implementation of the inventive installation.

It is advisable to such an implementation of the utility model, in which the power supply is equipped with electronic ballasts, made with the possibility of powering bactericidal ultraviolet lamps. This embodiment of the utility model allows to ensure the optimal ignition mode of the lamps, and also allows not to limit the number of inclusions, which together allows you to significantly increase the life of bactericidal lamps while maintaining the required level of radiation, as well as reduce operating costs. The use of electronic ballasts allows you to eliminate the flashing of the lamps when turned on, to save energy, stabilize the operating modes of the installation, regardless of fluctuations in the electrical network. In addition, such ballasts heat up less during operation, thereby allowing to improve the temperature regime in the room, which is important due to the use of the inventive installation, among other things, for disinfection of specialized rooms, such as, for example, operating rooms and dressings.

Preferred is an implementation of a utility model in which the microprocessor is non-volatile. This allows you to ensure reliable operation of the installation and effective control of the intensity of ultraviolet radiation, as well as the operating time of the lamps with arbitrarily frequent removal of the supply voltage.

Also preferred is such an implementation of a utility model in which the alarm device has a means for supplying an audio signal and an LED indicator. This allows you to provide alerts at various stages of operation of the installation, in particular, an audio signal can be emitted when reaching 50% of the initial level of radiation intensity, and the achievement of the minimum acceptable level of radiation of bactericidal lamps can be accompanied by a blinking LED indicator. This implementation of the utility model allows to ensure high reliability of the installation and ease of operation.

When implementing the utility model, continuous-flow low-pressure mercury discharge lamps can be used. The lamps can be equipped with reflectors, as well as devices for regulating the position of the lamp in space.

The utility model is illustrated with the help of a figure, which shows a block diagram of an installation for ultraviolet disinfection.

The ultraviolet disinfection apparatus comprises a power factor corrector 1, to which a ballast 2 is connected, to which at least one bactericidal lamp 3 is connected. The apparatus also contains a microprocessor 4 for measuring ultraviolet radiation, a lamp operating hours counter 5, an ultraviolet radiation intensity sensor 6, alarm device 7.

Installation works as follows.

Germicidal lamps 3 of ultraviolet radiation are placed in a place where the disinfecting effect of the installation is necessary, for example, in a specialized room, industrial or medical purpose. When installing new bactericidal lamps 3, the so-called calibration of the installation is carried out, while the radiation level of the installed lamps 3 is adopted by the microprocessor 4, designed to control the intensity of ultraviolet radiation, for the maximum radiation intensity. After all preparatory operations are carried out using the control unit, the installation is brought into irradiation mode. When reducing the intensity of ultraviolet radiation by 50%, the alarm device 7 is activated, in particular, an audible signal is supplied. When the intensity of ultraviolet radiation decreases to the minimum acceptable value or if an emergency occurs, the sound signal may be accompanied by a flashing LED indicator.

Thus, the claimed utility model is an installation for disinfection with ultraviolet radiation, which, due to the simplicity and optimal selection of structural elements, allows for high operational efficiency, control of the intensity of ultraviolet radiation, timely notification of the possibility of an emergency, and also allows to increase the service life of used bactericidal lamps and increasing the economic efficiency of the installation as a whole.

Claims (4)

1. Installation for ultraviolet disinfection, containing at least one bactericidal lamp of ultraviolet radiation, connected to a power supply and a control unit equipped with a system for controlling the intensity of ultraviolet radiation, including a sensor for the intensity of ultraviolet radiation, a microprocessor configured to control the intensity of ultraviolet radiation, characterized in that the control unit contains a lamp hour meter, and the power supply contains a power factor corrector tee. 2. Installation according to claim 1, characterized in that the power supply is equipped with electronic ballasts made with the possibility of powering bactericidal ultraviolet lamps. 3. The installation according to claim 1, characterized in that the microprocessor is made non-volatile and is associated with an alarm device. 4. Installation according to claim 3, characterized in that the alarm device has a means for supplying an audio signal and an LED indicator.