RU2542508C2 - Ultraviolet bactericide unit - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: ultraviolet bactericide unit comprises an ultraviolet lamp, an operational life analyser, a start-control device, ambient temperature and/or humidity and/or supply voltage and/or lamp life analyser unit connected to a control unit setting effective exposure time by formula t_e=k_e×t_exp, wherein t_e is the effective exposure time, t_exp is the exposure time, and k_e=k_u×k_T×k_φ×k_t, wherein k_T is a coefficient of ambient temperature variations, k_φ is a coefficient of ambient humidity variations, k_u is a coefficient of supply voltage fluctuations, k_t is a coefficient of estimated exposure time.

EFFECT: invention provides automatic exposure time management.

1 dwg

Description

The invention relates to a device for disinfecting air in rooms with an increased risk of the spread of pathogens: in medical, pre-school, school, industrial and public organizations and other rooms with a large crowd of people, in order to reduce the level of bacterial contamination and create conditions to prevent the spread of pathogens infectious diseases.

Ultraviolet bactericidal devices are known, including either an ultraviolet bactericidal irradiator or a group of ultraviolet bactericidal irradiators. Ultraviolet bactericidal lamps are used for air disinfection [G. Sarychev. "Irradiation light-technical installations", Energoatomizdat, 1992]. Ultraviolet bactericidal lamps are powered from an alternating current electric network with a frequency of 50 Hz and a voltage of 220 V. The inclusion of bactericidal lamps in the network is carried out through ballasts, which are designed for conventional fluorescent lamps of the corresponding power. Ballasts provide the necessary modes of ignition, ignition and normal operation of the lamps and are a separate unit mounted inside a bactericidal irradiator.

Known medical bactericidal wall irradiator OBN-150UHL4.2 "Azov", antibacterial lamps OBR-15 and OBR-30 with an ultraviolet lamp counter (timer) and irradiator-recirculator "ARMED" SN-111 (1 * 30) [Medical bactericidal irradiator wall OBN-150UHL4.2 "Azov". Operation manual AB 70.00.00.00.00 RE]. The counter monitors the lamp life. When the set resource is reached, the counter signals to the personnel that the lamp needs to be replaced.

The design drawback is the inability to control the modes of exposure to bactericidal lamps in the workplace in duration and intensity.

The closest to implementation is an ultraviolet bactericidal installation, including an ultraviolet lamp, an intensity control sensor and a lamp hour counter (RF patent for utility model No. 104068, IPC A61L9 / 20, 2011).

The disadvantage of the installation is the ability to control only the intensity of the UV radiation of the lamp and the operating time of the lamp.

The technical result is the expansion of the arsenal of ultraviolet bactericidal plants.

The technical result is achieved by the fact that the ultraviolet bactericidal installation includes an ultraviolet lamp, a resource counter (timer), ballasts, a unit of analyzers of temperature and / or humidity, and / or voltage, and / or lamp time, connected to the control unit , while the block of the ambient temperature analyzer is connected to the control unit that sets the time of effective exposure t _e according to the formula

where t _e is the time of effective irradiation, t _reg is the time of the duration of irradiation, k _e = k _T is a coefficient that takes into account fluctuations in ambient temperature according to the calculated dependencies

Where

1,0 - the average value of the coefficient during fluctuations in ambient temperature from 10 to 40 ° C, at which the exposure time of the lamp remains unchanged,

1.1 - the average value of the coefficient during fluctuations in ambient temperature from 40 to 50 ° C, at which the time of irradiation of the lamp increases by 10%,

1.2 - the average value of the coefficient during fluctuations in ambient temperature from 5 to 10 ° C, at which the lamp exposure time increases by 20%;

the unit of the analyzer of humidity of ambient air is connected to a control unit that sets the time of effective exposure t _e according to the formula

where t _e is the time of effective exposure, t _reg is the time of exposure, k _e = k _φ is a coefficient that takes into account fluctuations in the humidity of the environment according to the calculated dependencies

Where

1,0 - coefficient taking into account fluctuations in the humidity of the ambient air from 30% to 80%, at which the exposure time of the lamp remains unchanged,

1.1 - coefficient taking into account fluctuations in ambient humidity of less than 30%, at which the lamp exposure time is increased by 10%,

1,3 - coefficient taking into account fluctuations in the humidity of the environment

air more than 80%, at which the lamp exposure time is increased by 30%;

the network voltage analyzer unit is connected to a control unit that sets the time of effective irradiation t _e according to the formula

where t _e is the time of effective irradiation, t _reg is the time of the duration of irradiation, k _e = k _u is a coefficient that takes into account fluctuations in the supply voltage according to the calculated dependencies

where U _nom - 220 V, U _c - the measured value of the network voltage,

1,0 - coefficient taking into account fluctuations in the supply voltage from 0.9 of the rated voltage to 1.1, at which the lamp exposure time remains unchanged,

1.15 - coefficient taking into account fluctuations in the supply voltage from 0.8 of the rated mains voltage to 0.9 of the rated mains voltage, at which the lamp exposure time is increased by 15%,

1,5 - coefficient taking into account fluctuations in the voltage of the supply network from 1.1 of the rated voltage of the network to 1.2 of the rated voltage of the network, at which the duration of the lamp increases by 50%;

the lamp operating time analyzer unit is connected to a control unit that sets the effective irradiation time t _e according to the formula

where t _e is the time of effective irradiation, t _reg is the time of the exposure time, k _e = k _t is the coefficient determined by the calculated dependencies

where t _pec is the irradiator resource (h),

1,0 - coefficient taking into account the estimated duration of exposure in the range from 0% to 33% of the specified lamp life, at which the lamp did not work one third of its life, and the lamp exposure time under normal conditions does not change,

1,2 - coefficient taking into account the estimated duration of exposure in the range from 33% to 66%, at which the lamp worked more than one third of its life, and the exposure time automatically increases by 20%,

1.3 - coefficient taking into account the estimated duration of irradiation in the range from 66% to 100%, at which the lamp spent more than two-thirds of its life, and the time of irradiation of the lamp automatically increases by 30%;

the unit of analyzers of temperature, ambient humidity, network voltage and lamp operating time is connected to a control unit that sets the effective exposure time t _e according to the formula

t _e = k _e × t _reg ,

where t _e is the time of effective exposure, t _reg is the time duration of exposure,

k _e = k _u × k _t × k _φ × k _t ,

where all the coefficients have the above values.

The difference is the implementation of control units with the ability to set the time of effective exposure according to the above formulas.

The figure 1 shows a diagram of the proposed ultraviolet bactericidal installation, where 1 is a bactericidal lamp, 2 is a ballast, 3 is a capacitor to increase the power factor of the network and suppress radio interference, 4 is a block of analyzers of environmental parameters, which includes a 5-digital counter sensor working resource (timer), which allows you to measure the time from the moment the bactericidal lamp is first turned on, as well as the duration of each lamp cycle, 6 - digital sensor of the network voltage parameter analyzer, 7 - c front-end sensor of the analyzer of the parameter of temperature fluctuations, 8 - a digital sensor of the analyzer of the parameter of fluctuations in air humidity, 9 - a control unit that includes 10 - an integrated circuit (chip) of the counter of the service life, 11 - chip of the parameter of the voltage of the network, 12 - chip of the parameter of temperature fluctuations , 13 - chip fluctuations in air humidity, 14 - adder, 15 - LCD screen, 16 - switch.

In normal operation (at normal or documented normal values of the mains voltage, temperature, humidity and lamp life), an ultraviolet bactericidal installation works as follows.

When the device is turned on with the switch (16) through the ballast (2), power is supplied to the bactericidal lamp (1) and the lamp ignites. At the moment of switching on, the installation, using the analyzer block (4), receives information about the environment: changes in the network voltage through the digital sensor of the network voltage parameter analyzer (6), about temperature changes through the digital sensor of the temperature parameter analyzer (7), about changes in ambient humidity through the digital sensor of the analyzer of the parameter of fluctuation of air humidity (8). Then the information in digital form is transmitted to the control unit (9), which contains integrated circuits that process environmental information from the corresponding sensors of the analyzer unit. In each integrated circuit, calculations are made.

The lamp analyzer of the lamp life resource (10) calculates its operating life accordingly. The counter chip of the network voltage analyzer (11) receives information from the corresponding digital sensor and calculates the voltage fluctuations of the supply network k _u according to the calculated dependencies

The analyzer chip of the temperature fluctuation parameter (12) calculates the value of the coefficient taking into account the temperature fluctuations k _T using the calculated dependences

The counter chip of the parameter of fluctuations in air humidity (13) receives information about changes in humidity of the ambient air from the corresponding sensor, calculates the value of the coefficient k _φ , taking into account the influence of relative humidity of the air, according to the calculated dependences

Then the information on the calculated coefficients gets through the communication lines to the adder - integrated circuit. Depending on the specific conditions and duration of operation of the bactericidal lamp, the adder automatically sets the optimal values of the coefficient of radiation efficiency k _e according to the formula

In the most difficult version, when all the analyzed parameters exceed the standard, the lamp should work with k _e = 1.5 × 1.2 × 1.3 × 1.3 = 3.042. As can be seen, for effective disinfection of the environment with significant fluctuations in the mains voltage, temperature, humidity, and resource exhaustion, the device operates 3 times longer than a new lamp operating under standard conditions. This is provided by the control unit, which issues a command to turn off the lamp, after a period of time multiple of the coefficient k _e = k _u × k _T × k _φ × k _t , that is, much later than determined by the specified lamp life under normal conditions.

If the condition of equality between the operating time of the irradiator in this irradiation cycle obtained using the lamp timer and the effective irradiation time t _e calculated by the formula t _e = k _e × t _{reg is met} , the control unit issues a command for the ballast to open bactericidal lamp power supply circuit.

Thus, the installation allows you to automatically control the exposure time of the bactericidal lamp, eliminating the influence of the human factor.

Claims (1)

An ultraviolet bactericidal installation, characterized in that it includes an ultraviolet lamp, an operating life analyzer, a ballast, an analyzer unit for ambient temperature and / or humidity, and / or voltage, and / or lamp operating time, connected to a control unit that sets the effective time radiation according to the formula

where t _e is the time of effective exposure, t _reg is the time duration of exposure,

where k _T - coefficient taking into account the fluctuations in ambient temperature according to the calculated dependencies

k _φ - coefficient taking into account fluctuations in the humidity of the environment according to the calculated dependencies

k _u - coefficient taking into account voltage fluctuations of the supply network according to the calculated dependencies

where U _nom - 220 V,
U _c is the measured value of the network voltage,
k _t - coefficient determined by the calculated dependencies

where t _pec is the irradiator resource (h).

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