RU2598387C1 - System for monitoring and controlling medical-biological parameters of air in dental installation - Google Patents

Abstract

FIELD: medicine; hygiene.

SUBSTANCE: invention relates to methods and means of monitoring and controlling medical-biological parameters of air in dental plants and can be used independently, as well as in systems of air cleaning and sterilisation of medical facilities for various purposes. System comprises a unit of actuators, consisting of a source of ultraviolet radiation, system of corona electrodes and system of precipitation electrodes, fan with electric drive, input and output protective grids in air duct and a control unit consisting of circuit for switching on source of ultraviolet radiation, circuit for switching on device. Control unit includes electric drive control circuit of fan, channel for controlling operation of corona electrodes, channel for controlling operation of precipitation electrodes and channel for monitoring and controlling operation of ultraviolet radiation source. Structure of system includes a display unit, consisting of a first "Above normal" light indicator, second "Normal" light indicator, third "Low" light indicator, acoustic detector, inputs of which are first, second, third and fourth inputs of indication unit and are connected to fifth, sixth, seventh and eighth inputs of control unit respectively.

EFFECT: higher degree of efficiency of disinfection and filtration of dust from air.

1 cl, 1 dwg

Description

The invention relates to the field of measuring equipment and can be used to control and manage the medical and biological parameters of air in dental units, as well as as part of air purification and sterilization systems in medical facilities for various purposes.

The air environment is one of the main routes of transmission of infection and, in a significant part of diseases, pathogens such as measles, plague, anthrax, tuberculosis, influenza, etc., penetrate the human body through the airborne droplet. In the air, microorganisms are usually in a state of bacterial aerosol, which is a tiny droplet of a liquid or a particle of a solid suspended in the air with bacteria and viruses living in it. Dust particles with a size of 5 microns or less penetrate deep into the lungs (to the alveoli), particles of 5-10 microns are retained in the upper respiratory tract and bronchi, particles of 10 microns or more do not penetrate into the lungs, are retained in the upper respiratory tract and are rapidly deposited. Dust removal of air in the ducts of dental units allows you to remove from dust up to 90% of microorganisms and reduce its irritating effect on the eyes, skin and gastrointestinal tract.

Among the most famous technological processes of cleaning and sterilizing air in dental units and objects of other medical purposes, as shown in the work of Shtokman E.A. Air cleaning. Tutorial. - M .: DIA Publishing House. 1998 .-- 320 p. - [1], the principles of mechanical, chemical and radiation filtration and air purification are most often used, followed by electrostatic and ionization effects on the composition and properties of the air supplied through the dental gun to the patient’s oral cavity.

The group of analogues of the claimed technical solution includes devices for cleaning and disinfecting air, protected by RF patents for inventions No. 1824240, No. 2033272, No. 2121629.

Known electrostatic precipitator according to the patent of the Russian Federation No. 1824240, IPC B03C 3/14, publ. in bull. No. 24, 06/30/1993 - [2], containing an air duct in the form of a cylindrical body with an inlet for contaminated air, equipped with a swirl flow and an outlet for purified air, as well as cylindrical precipitation electrodes located inside the air duct, coaxially mounted to form ring channels, as well as corona electrodes installed in the annular channels and made of separate elements with points curved about its axis, a dust collecting bin and regenerating e device. In case of contamination of the precipitation electrodes, a regenerative device is switched on, under the influence of which, due to small-scale deformations, the dust aggregates are chipped into the dust collection bin located directly behind the precipitation electrodes. The rest due to centrifugal forces is pressed against the walls of the housing and is also poured into the dust bin.

Among the disadvantages of this technical solution, one can point out the reduced efficiency of air disinfection with increasing air humidity due to a decrease in the intensity of the corona discharge and the absence of deodorizing properties due to insufficient oxidation of gaseous waste products.

A device for cleaning and disinfecting air according to the patent of the Russian Federation No. 2033272, MKI B03C 3/12, A01K 1/01, A01K 1/00, A61L 9/015, published in bull. No. 11, 04/20/1995. - [3], comprising a housing, a high-voltage power supply, electrode systems: charging, accelerating, sedimentary and neutralizing, voltage divider, bactericidal lamp. The charging and precipitation electrode systems are made in the form of parallel plates, which are alternately connected with the negative and grounded terminals of the high-voltage power supply. The grounded output of the power supply is connected to the device. The neutralizing electrode system is made in the form of N sections, which are placed one after the other and are connected to the positive terminal of the power supply via a voltage divider. In this case, the use of several electrodes with different potentials, which is achieved by using a voltage divider, allows you to almost completely neutralize all air ions and decompose ozone. A bactericidal lamp installed in the output part of the housing allows for additional disinfection of the exhaust air, since microflora and bacteria are partially destroyed in the electrostatic field of the electrode system, which is characterized by a significant gradient of tension at the input and output of this system and the absence of a gradient of field strength inside it.

A disadvantage of the device for cleaning and disinfecting air is the need to use ozone to clean the electrodes, the content of which in the air of a dental unit is regulated by sanitary standards SanPiN 2.1.3.2524-09 “Sanitary and hygienic requirements for dental medical organizations” - [4]. In addition, the significant disadvantages of this solution include the low disinfection efficiency and limited productivity due to the high resistance of the duct in the dental gun under conditions of uncontrolled air supply to it.

A device for cleaning indoor air according to the patent of the Russian Federation No. 2121629, MKI F24F 003/16, published in bull. No. 32, 11/10/1998. - [5] containing the filtering means, ultraviolet radiation sources and ventilation means, the basic means, in which the filtering means, ultraviolet radiation sources and ventilation means are located, wherein the basic means is equipped with remote controlled means adapted to bring the basic means with the corresponding signal , on the one hand, to the position of full or partial passive filtering mode and harmless ultraviolet closed cleaning and exposure spirit passing through the base means, and, on the other hand, in the active mode position, in particular for ultraviolet open irradiation of objects and surfaces in the room and preferably in combination with filtering and purification of room air still passing through the base means. The basic tool consists of a housing containing one or more controlled covers, which, under the action of the corresponding signal, take a closed position for ultraviolet closed air cleaning and irradiation and an open position for combined ultraviolet open irradiation of objects and surfaces in the room and air purification, respectively.

The disadvantage of this technical solution is the low reliability of mechanically switched covers located in the base tool and providing regulation of the air supply to the device.

The closest in technical essence to the claimed technical solution, taken as a prototype, is a device for cleaning and disinfecting air according to the RF patent No. 2149704, IPC B03C 3/00, published in bull. No. 15, 05/27/2000 - [6], containing the executive body as part of the duct, fan and control unit. The executive body includes an ozone-free source of ultraviolet radiation with a total bactericidal flux of at least 10 W, protective gratings of the inlet and outlet of the duct, the first electrode fixed together with the ozone-free ultraviolet radiation inside the second electrostatic electrode-duct. The control unit contains a high voltage generator, a circuit for switching on a source of ultraviolet radiation and a unit for switching on a device. The executive outputs of the device enable node are connected, respectively, through the connection circuit of the ultraviolet radiation source to the ozone-free ultraviolet radiation source, to the fan inputs and to the inputs of the high voltage generator, the first and second outputs of which are connected respectively to the first and second inputs of the first electrode.

The disadvantage of this solution is the limited functionality when using the device for cleaning and disinfecting air as part of the dental unit due to the lack of control of the disinfection and air filtration process, as well as visual monitoring of the parameters of the disinfecting radiation in the duct of the dental gun.

The technical result, to which the claimed technical solution is directed, is to increase the efficiency of the process of disinfection and dust filtration of air in the dental gun, depending on its volume and degree of contamination by both mechanical particles and microorganisms.

The technical effect is achieved by the fact that in the monitoring and control system of medical and biological air parameters in a dental unit containing an actuator unit consisting of an ultraviolet radiation source, a corona electrode system and a precipitation electrode system, an electrically driven fan, input and output protective grilles located in the duct, and a control unit consisting of a circuit for switching on a source of ultraviolet radiation, a circuit for switching on a device,

new is that the control unit is additionally introduced

control circuit of the electric fan drive, the output of which is the first output of the control unit and is connected to the input of the electric fan drive,

the channel for controlling the operation of the corona electrodes, consisting of a series-connected high-voltage rectifier, a smoothing filter, a step-up transformer and a voltage multiplier, the output of which is the output of the channel for controlling the operation of the corona electrodes and is connected to the second output of the control unit connected to the input of the system of corona electrodes, and the input of the high-voltage the rectifier is the input of the channel for controlling the operation of the corona electrodes and is connected to the output of the device switching circuit ,

a control channel for the operation of the precipitation electrodes, consisting of a series-connected high-voltage rectifier, a smoothing filter, a step-up transformer and a voltage multiplier, the output of which is the first output of the control channel of the operation of the precipitation electrodes and is connected to the third output of the control unit connected to the input of the precipitation electrode system, and the second the output of the channel for controlling the operation of the precipitation electrodes is connected to the output of the smoothing filter of the channel for controlling the operation of the precipitate flax electrodes

wherein the input of the high-voltage rectifier is the first input of the channel for controlling the operation of the precipitation electrodes and is connected to the output of the device switching circuit, and the second input of this channel is connected to the second input of the step-up transformer,

a channel for monitoring and controlling the operation of an ultraviolet radiation source, consisting of a series-connected photodetector, a current-voltage converter, a digital potentiometer, a voltage amplifier, a comparator, and a precipitation electrode control circuit, the first, second, third, and fourth outputs of which are respectively the first, second, third and the fourth outputs of the channel for monitoring and controlling the operation of the ultraviolet radiation source, its fifth output is connected to the second output of the digital potential Etra,

the first input of the channel for monitoring and controlling the operation of the ultraviolet radiation source, connected with the second output of the channel for controlling the operation of the precipitation electrodes, is connected to the second input of the precipitation electrode control circuit, and the second input of this channel, which is the information input of the control unit, is optically through the light flux from the source ultraviolet radiation associated with the photodetector radiation,

in addition, the output of the inclusion circuit of the ultraviolet radiation source is the fourth output of the control unit,

and an indication unit has been introduced into the structure of the monitoring and control system for medical and biological air parameters in the dental unit, consisting of the first indicator light “Above the norm”, the second indicator light “Norm”, the third indicator light “Below the norm”, the electroacoustic detector, the inputs of which are the first, second, third and fourth inputs of the display unit and are connected to the fifth, sixth, seventh and eighth inputs of the control unit, respectively.

The invention is illustrated in FIG. 1, which shows a structural and functional diagram of a control system for medical and biological parameters of air in a dental unit.

Here:

1 - block executive bodies;

2 - source of ultraviolet (UV) radiation;

3 - a system of corona electrodes;

4 - a system of precipitation electrodes;

5 - fan;

6 - electric drive;

7 - input gratings;

8 - output gratings;

9 - duct of the dental gun;

10 - control unit;

11 is a diagram for including an ultraviolet radiation source;

12 is a diagram of the inclusion of the device;

13 is a control diagram of a fan electric drive;

14 - channel for controlling the operation of corona electrodes;

15 - high-voltage rectifier of the channel for controlling the operation of corona electrodes;

16 - smoothing filter of the control channel of the operation of the corona electrodes;

17 - step-up transformer channel control the operation of the corona electrodes;

18 - voltage multiplier of the channel for controlling the operation of the corona electrodes;

19 - channel control the operation of the precipitation electrodes;

20 - high-voltage rectifier channel control the operation of the precipitation electrodes;

21 - smoothing filter of the channel for controlling the operation of precipitation electrodes;

22 - step-up transformer channel control the operation of the precipitation electrodes;

23 - voltage multiplier channel control the operation of the precipitation electrodes;

24 - channel control and management of the source of ultraviolet radiation;

25 - radiation photodetector;

26 - current-voltage converter;

27 - digital potentiometer;

28 - voltage amplifier;

29 - a comparator;

30 is a control circuit of the precipitation electrodes;

31 - display unit;

32 - the first indicator light "Above the norm";

33 - the second indicator light "Norma";

34 - third indicator light "Below normal";

35 - electro-acoustic detector.

The monitoring and control system for medical and biological air parameters contains a block 1 of executive bodies, consisting of a source of 2 ultraviolet radiation, a system of 3 corona electrodes and a system of 4 precipitation electrodes, a fan 5 with an electric drive 6, input 7 and output 8 protective grilles placed in the duct 9 and a control unit 10, consisting of a circuit 11 for switching on a source of ultraviolet radiation, a circuit 12 for turning on a device.

The control unit 10 further includes a fan drive control circuit 13, a corona electrode operation control channel 14, precipitation electrode operation control channel 19, and an ultraviolet light source control and control channel 24.

The output of the fan drive control circuit 13 is the first output of the control unit 10 and is connected to the input of the drive 6 of the fan 5.

The channel 14 for controlling the operation of the corona electrodes consists of series-connected high-voltage rectifier 15, a smoothing filter 16, a step-up transformer 17 and a voltage multiplier 18. The output of the voltage multiplier 18 is the output of the channel 14 for controlling the operation of the corona electrodes and is connected to the second output of the control unit 10 connected to the input systems of 3 corona electrodes. The input of the high-voltage rectifier 15 is the input of the channel 14 for controlling the operation of the corona electrodes and is connected to the output of the device switching circuit 12.

The precipitation electrode operation control channel 19 consists of a series-connected high-voltage rectifier 20, a smoothing filter 21, a step-up transformer 22, and a voltage multiplier 23. The output of the voltage multiplier 23 is the first output of the precipitation electrode operation channel 19 and is connected to the third output of the control unit 10 connected to the entrance of the system 4 precipitation electrodes. The second output of the precipitation electrode operation control channel 19 is connected to the output of the smoothing filter 21 of the precipitation electrode operation control channel. The input of the high-voltage rectifier 20 is the first input of the precipitation electrode operation control channel 19 and is connected to the output of the device switching circuit 12, and the second input of this channel is connected to the second input of the step-up transformer 22.

The channel 24 for monitoring and controlling the operation of the ultraviolet radiation source consists of series-connected photodetector 25 radiation, a current-voltage converter 26, a digital potentiometer 27, a voltage amplifier 28, a comparator 29 and precipitation electrode control circuit 30, the first, second, third and fourth outputs of which are respectively, the first, second, third and fourth outputs of the channel 24 for monitoring and controlling the operation of the ultraviolet radiation source, its fifth output is connected to the second digital output potentiometer 27. The first input of the channel 24 for monitoring and controlling the operation of the source of ultraviolet radiation associated with the second output of the channel 19 for controlling the operation of the precipitation electrodes is connected to the second input of the circuit 30 for controlling the precipitation electrodes, and the second input of this channel, which is the information input of the control unit 10, is optically through the light flux from the source 2 of ultraviolet radiation is connected with the photodetector 25 radiation. The first output of the channel 24 for monitoring and controlling the operation of the ultraviolet radiation source is connected to the second input of the precipitation electrode operation control channel 19 and to the control input of the ultraviolet radiation source switching circuit 11. The second, third, fourth and fifth outputs of the channel 24 for monitoring and controlling the operation of the ultraviolet radiation source are the fifth, sixth, seventh and eighth outputs of the control unit 10.

The output of the ultraviolet radiation source switching circuit 11 is the fourth output of the control unit 10.

An indication unit 31 is introduced into the structure of the monitoring and control system for medical and biological air parameters in the dental unit, consisting of the first light indicator 32 “Above the norm”, the second light indicator 33 “Norm”, the third light indicator 34 “Below the norm”, the electro-acoustic detector 35 the inputs of which are the first, second, third and fourth inputs of the display unit 31 and are connected to the fifth, sixth, seventh and eighth inputs of the control unit 10, respectively.

The system operates as follows. When the dental unit is turned on, the supply voltage of 220 V is supplied to the power inputs of the control unit 10. In the control unit 10, this voltage is simultaneously supplied to the device switching circuit 12, the ultraviolet radiation source switching circuit 11, the fan electric drive control circuit 13, and the channel 14 power input control the operation of the corona electrodes and the power input of the channel 19 control the operation of the precipitation electrodes.

The air entering the duct inlet is preliminarily exposed to ultraviolet radiation by means of an ultraviolet radiation source 2 controlled by an ultraviolet radiation source switching circuit 11. Such radiation in the range 205-315 nm for an air flow rate of up to 4 m / s has a 100% sterilization effect and causes its quanta to be absorbed by nucleic acid molecules, proteins, lipids and a number of other biochemical components of microorganism cells and photochemical damage to virus molecules, which leads to their destruction.

As a result of supplying the supply voltage at the output of the high-voltage rectifier 15 of the channel 14 for controlling the operation of the corona electrodes and the high-voltage rectifier 20 of the channel 19 for controlling the operation of the precipitation electrodes, a high-level pulsating voltage is generated, which is supplied to the voltage multipliers through smoothing filters 16 and 21, increasing transformers 17 and 22 and 23, respectively, at the outputs of which a voltage is formed with a potential difference in the range of 2.5-5 kV. This voltage is supplied to the inputs of the system 3 of the corona electrodes and to the inputs of the system 4 of the precipitation electrodes.

The disinfected air washing the system of 3 corona electrodes undergoes polarization. Then, after interaction with the system 4 of precipitation electrodes, the process of electrostatic filtration from dust particles contained in the air occurs.

Simultaneously with the formation of a high voltage at the outputs of the channel 14 for controlling the operation of the corona and channel 19 for controlling the operation of the precipitation electrodes, a fan 5 is activated, controlled by pulses from the circuit 13 for controlling the electric drive 6 of the fan. Under the influence of the fan located at the outlet of the duct 9, the cleaned and dust-free air from the precipitation electrode system 4 through the protective outlet grill 8 enters the duct of the dental gun.

To protect against ultraviolet radiation from entering the polymer parts of fan 5 and its destruction during prolonged exposure to ultraviolet radiation, the outlet and inlet openings of the duct 9 containing the actuator unit 1 are covered by protective input 7 and output 8 gratings that do not allow short-wave ultraviolet radiation to enter the external space.

In the process, the source 2 of ultraviolet radiation requires control over the parameters of the modes of operation. The effectiveness of ultraviolet radiation on microorganisms is determined by the intensity of ultraviolet radiation, as well as the exposure time. The product of the radiation intensity at a time is called the radiation dose (mJ / cm ² ) and is a measure of the bactericidal energy received by microorganisms when passing through a source of ultraviolet radiation. The radiation dose is the most important parameter that determines the effectiveness of the monitoring and control system of medical and biological parameters of air, and should not be lower than the required value necessary for reliable disinfection of air during the operation of the system. Monitoring is carried out using the channel 24 for monitoring and controlling the operation of the ultraviolet radiation source.

The output signal of the photodetector 25 of the radiation located at the input of the channel 24 is proportional to the intensity of the light flux passing through the air stream. This signal is supplied to the current-voltage converter 26. The output voltage of the channel 24 for monitoring and controlling the operation of the ultraviolet radiation source and, accordingly, the gain is adjusted by a digital potentiometer 27, in the non-volatile memory of which the set gain is stored. From the digital potentiometer 27, the signal is supplied to a voltage amplifier 28, which amplifies the signal to the level necessary for the operation of the precipitation electrode control circuit 30. In this scheme, which has one control (first) and three threshold (second, third and fourth) outputs, the current value of the control signal from the output of the smoothing filter 21 of the precipitation electrode operation control channel 19 is compared with a reference level. As a result of the analysis, a signal is generated that serves to adjust the output voltage of the precipitation electrode operation control channel 19, for which it is connected to the second input of the step-up transformer 22 of this channel. Other outputs of the precipitation electrode control circuit 30 are used to control the operation of the indication unit 31.

If the radiation intensity is above the minimum acceptable by more than 40-50%, the first indicator light 32 “Above the norm” lights up. When the radiation intensity is above the minimum within 10-40%, the second indicator light 33 “Norma” lights up, which indicates the normal operation of the source of 2 ultraviolet radiation. In the event that the radiation intensity is below the minimum allowable, the third indicator light 34 “Below normal” lights up. With a significant reduction in the dose of the installed ultraviolet radiation, in addition to the light indication, an acoustic signal is generated using an electro-acoustic detector 35. In this case, a signal is applied to the input of the circuit 11 for switching on the ultraviolet radiation source, under the influence of which the correction of the operation of the ultraviolet radiation source 2 occurs, which leads to an increase in the intensity of ultraviolet radiation penetrating the air stream. At the same time, there is an increase in the voltage at the output of the precipitation electrode operation control channel 19, which allows the deposition of not only fine, but also large dust particles in the air, the appearance of which reduces the intensity of light radiation from the source of 4 ultraviolet radiation.

Thus, as a result of the sequential performance of technological operations during the dental procedure associated with the use of a dental gun, the air supplied to the oral cavity from pathogens, gaseous organic compounds and dust particles is continuously cleaned using a system without mechanical filters requiring periodic replacements. In this case, not only ionic equilibrium is achieved, but also the concentration of nitrogen oxides in the air decreases. At the same time, the design of the control and management system for medical and biological air parameters in a dental unit is easy to manufacture and reliable and safe in operation.

Claims (1)

A system for monitoring and controlling the medical and biological parameters of air, containing a block of executive bodies, consisting of a source of ultraviolet radiation, a system of corona electrodes and a system of precipitation electrodes, a fan with an electric drive, input and output protective grilles located in the duct, and also a control unit consisting of the inclusion circuit of the source of ultraviolet radiation, the inclusion circuit of the device, characterized in that
the control unit is additionally introduced
control circuit of the electric fan drive, the output of which is the first output of the control unit and is connected to the input of the electric fan drive,
the channel for controlling the operation of the corona electrodes, consisting of a series-connected high-voltage rectifier, a smoothing filter, a step-up transformer and a voltage multiplier, the output of which is the output of the channel for controlling the operation of the corona electrodes and is connected to the second output of the control unit connected to the input of the system of corona electrodes, and the input of the high-voltage the rectifier is the input of the channel for controlling the operation of the corona electrodes and is connected to the output of the device switching circuit ,
a control channel for the operation of the precipitation electrodes, consisting of a series-connected high-voltage rectifier, a smoothing filter, a step-up transformer and a voltage multiplier, the output of which is the first output of the control channel of the operation of the precipitation electrodes and is connected to the third output of the control unit connected to the input of the precipitation electrode system, and the second the output of the channel for controlling the operation of the precipitation electrodes is connected to the output of the smoothing filter of the channel for controlling the operation of the precipitating electrodes flax electrodes
wherein the input of the high-voltage rectifier is the first input of the channel for controlling the operation of the precipitation electrodes and is connected to the output of the device switching circuit, and the second input of this channel is connected to the second input of the step-up transformer,
a channel for monitoring and controlling the operation of an ultraviolet radiation source, consisting of a series-connected photodetector, a current-voltage converter, a digital potentiometer, a voltage amplifier, a comparator, and a precipitation electrode control circuit, the first, second, third, and fourth outputs of which are respectively the first, second, third and the fourth outputs of the channel for monitoring and controlling the operation of the ultraviolet radiation source, its fifth output is connected to the second output of the digital potential Etra,
the first input of the channel for monitoring and controlling the operation of the ultraviolet radiation source, connected with the second output of the channel for controlling the operation of the precipitation electrodes, is connected to the second input of the precipitation electrode control circuit, and the second input of this channel, which is the information input of the control unit, is optically through the light flux from the source ultraviolet radiation associated with the photodetector radiation,
wherein the first output of the channel for controlling and controlling the operation of the ultraviolet radiation source is connected to the second input of the channel for controlling the operation of the precipitation electrodes and to the control input of the circuit for switching on the source of ultraviolet radiation, the second, third, fourth and fifth outputs of the channel for controlling and controlling the operation of the ultraviolet radiation source are fifth, sixth, seventh and eighth outputs of the control unit,
in addition, the output of the inclusion circuit of the ultraviolet radiation source is the fourth output of the control unit,
an indication unit has been introduced into the structure of the monitoring and control system for medical and biological air parameters in the dental unit, consisting of the first indicator light “Above the norm”, the second indicator light “Norm”, the third indicator light “Below the norm”, the electroacoustic detector, the inputs of which are the first , the second, third and fourth inputs of the display unit and are connected to the fifth, sixth, seventh and eighth inputs of the control unit, respectively.

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