RU2149704C1 - Air cleaning and decontamination unit - Google Patents

Abstract

FIELD: cleaning of air in rooms and production systems. SUBSTANCE: unit has actuating member as part of air duct and fan control unit including high- voltage generator. Actuating member is provided with ultraviolet ozoneless radiation source at power of total bactericide flow no less than 10 W for obtaining required polarity of ion equilibrium of treated air medium, protective grids for air inlet and outlet ducts, electrodynamic catalyst as part of first electrode secured together with ultraviolet radiation source inside second electrostatic electrode - air duct. Control unit is provided with circuit for switching-on the ultraviolet radiation source and device for automatic switching-on of unit. EFFECT: enhanced efficiency of decontamination and control of this process depending on volume and degree of contamination. 2 dwg

Description

 The invention relates to sanitary-hygienic processing of air and can be used both independently and as part of air purity systems and technological systems.

 The devices used for sanitary-hygienic processing and air purification are based on the principles of filtration using special replaceable filters made on the basis of synthetic materials with the subsequent exposure to short-wave ultraviolet radiation or ozonation.

 Known devices for cleaning and disinfecting air in the housing with a receiver of contaminated air and an outlet with an exhaust device, an ionization chamber with two corona cathodes and a precipitation electrode in the form of a container located in the lower part of the housing (1).

 A disadvantage of the known solution is the low efficiency of disinfection, the formation of ozone due to corona discharges and the insufficient productivity associated with high resistance to air flow.

 The closest in technical essence is a device for electrofiltration of air, containing a cylindrical body with an inlet for dusty air, equipped with a swirl, and an outlet for cleaned, cylindrical precipitation electrodes, made in the form of a grid and installed coaxially with the formation of annular channels, a hopper for collecting dust and a corona electrode made of separate elements with points (2).

 A disadvantage of the known device is the dependence of the disinfecting efficiency on air humidity (the intensity of the corona discharge decreases with increasing humidity), the absence of a deodorizing property due to insufficient oxidation of gaseous waste products. In addition, the ionization of molecules of oxidation products and dust particles when exposed to a corona discharge can cause allergic reactions in people predisposed to such a disease.

 The technical essence of the utility model is to eliminate these shortcomings and increase the efficiency of disinfection and control of this process depending on the volume and contamination, as well as purification of air from organic compounds and normalization of the polarity of the ionic equilibrium of the treated air.

 This goal is achieved by the fact that in the device for cleaning and disinfecting air, containing an actuator comprising a duct, a fan and a control unit including a high voltage generator, an ozone-free ultraviolet radiation source with a total bactericidal flux of at least 10 W is introduced into the actuator, protective grilles of the inlet and outlet of the duct, electrodynamic catalyst in the first electrode, fixed together with a source of ultraviolet radiation one inside the second electrostatic electrode-duct, and the control unit includes a circuit for switching on a source of ultraviolet radiation and a unit for switching on a device as a part of a delay signal driver, a NOT element, an AND element, an OR element, a clock pulse generator, a divider counter, a switch, a switching circuit, and an electronic key, the executive outputs of which are connected through the outputs of the device’s switching unit through the connection circuit of the ultraviolet radiation source to the ultraviolet source, respectively of ozone-free summer radiation, with inputs of a fan and a high-voltage generator, the first and second outputs of which are connected respectively to the first and second inputs of the electrodynamic catalyst, and the control input of the electronic key is connected via the key switching circuit to the output of the OR element, the first input of which through the switch is connected to the outputs the counter-divider, and the second input is connected to the output of the element NOT and the first control input of the counter-divider, the second clock input of which is connected to the output of the element AND, vy input AND gate connected to the output of the clock and the second input - to the input of NOT circuit and the output of the delay generator.

 The device (Fig. 1) contains an actuator 1 consisting of an air duct 2, protective gratings 3 of the inlet and 4 of the outlet, a source of ultraviolet radiation 5 without ozone, an electrodynamic catalyst 6 containing a first 7 electrode and a second 8 electrostatic electrode, and a fan 9, as well as a unit 10 controls as part of a high voltage generator 11, a circuit 12 for turning on a source of ultraviolet radiation and a unit 13 for turning on a device.

 The unit 13 for turning on the device (Fig. 2) contains a delay driver 14, an element 15 NOT, an element 16 AND, an element 17 OR, a clock generator 18, a counter 19, a divider, a switch 20, a key switching circuit 21, an electronic key 22.

The actuator 1 of the device is made of a decorative duct 2, inside of which along its length a source of ultraviolet radiation 3 is free of ozone, which is an arc mercury-quartz lamp with a special coating that transmits radiation in the range 205-315 nm with a radiation maximum of 254-265 nm, excluding ozone formation. The total spectral density of the radiation flux of the source of ultraviolet radiation ( _{f LBK} ) should be at least 10 watts. For this purpose, for example, a DRB-40 quartz low-pressure lamp with a selectively transmitting coating, for example, made with a tetraethoxysilane-tetrabutoxy titanium composition, can be used. The source of ultraviolet radiation can also be made in the form of an arc gas discharge lamp with a quartz glass bulb coated with a mixture of silicon oxide and titanium oxide formed during the combustion of 4 silicon chloride and 4 titanium chloride in a directional oxygen-hydrogen burner during coating .

 The inlet of the duct is closed by a protective grill 3 of the inlet, which passes air into the duct, but does not allow direct short-wave ultraviolet radiation into the outer space. For this, the lattices of the grill are made, for example, at an angle of 45 degrees. The outlet in front of the fan is also covered by an exit grid 4 to protect it from ultraviolet radiation on the polymer parts of the fan and its destruction during prolonged exposure to high-power ultraviolet radiation.

 The electrodynamic catalyst 6 is fixed at the outlet of the duct and is positioned so as to accommodate at least a third of the volume of air processed in the installation. The first 7 electrode and the second 8 electrostatic electrode are made of copper, and the first electrode is made of cut strips of copper mesh with sharp edges. The interconnected strips of copper mesh are fixed around a source of ultraviolet radiation. The second 8 electrostatic electrode is a copper sheet duct placed on top of the first electrode. Moreover, the air after processing it with ultraviolet radiation should enter the electrode 8 of the electrostatic duct for catalytic processing of statically charged copper electrodes of the electrodynamic catalyst 6.

 The fan 9 serves for active pumping of air through the unit and is located at its outlet in such a way as to take already processed air directly from the electrodynamic catalyst 6.

 Unit 10 of the control device includes a node 13 on, which is a controllable timer for periodic activation and a given duration of work. The operating modes of the node 13 are set depending on the volume of air to be processed for a certain period of time, or the volume of the room in which it is necessary to constantly maintain a given air purity.

 The node 13 using the executive key as part of its circuit is connected to a fan 9, a high voltage generator 11 and a circuit 12 for turning on an ultraviolet radiation source 5, to which it supplies a power load to a predetermined time frequency.

 The generator 11 is a circuit for generating a high DC voltage of 2.5-5 kV, the first output of a voltage of negative polarity which is connected to the first 7 electro-effluvial electrode, and the second output of the voltage of positive polarity is connected to the second 8 electrostatic electrode.

 The circuit 12 for switching on the source of ultraviolet radiation 5 without ozone can be performed, for example, according to the scheme of the high-frequency generator and sufficient voltage to power the source 5 or using the known throttle-starter circuit for starting arc mercury-quartz lamps, which in this case does not matter.

 The inclusion node 13 (Fig. 2) contains a delay driver 14, made, for example, according to the scheme of a capacitive storage device, the output of which is connected to the input of a single-shot. The output of the one-shot in the shaper 14 of the delay signal is connected to the second control input of the element 16 AND and through the element 15 is NOT connected to the control input of the counter 19 of the divider and to the second input of the element 17 OR. The clock generator 18 through the first input of the element 16 And is connected to the counting input of the counter 19 of the divider. The outputs of the counter 19 of the divider are connected to the inputs of the switch 20 to select the duration of the period of operation of the device, the signal the end of work and the restart of which comes from the output of the switch 20. The signal of the duration of work is fed to the first input of the element 17 OR, and the second input of this circuit receives a signal from the output element 15 is NOT a delay delay, formed at the time of the first inclusion of the device. From the output of the element 17 OR control signals are fed to the input circuit 21 of the inclusion of the electronic key.

 The circuit 21 for switching on the electronic key is made, for example, according to the circuit of a composite transistor, which is connected to a trinistor included in the diagonal of the diode bridge of the electronic key 22. When the output of the element 17 OR level is a logical unit, the composite transistor is open, the trinistor is closed at this time and no load current flows through the diagonal of the bridge of the key 22. When the output of the element 17 OR signal changes to a logical zero, the composite transistor closes, and the trinistor opens by current through the load resistor according to the known scheme of a composite transistor. The trinistor is included in the diagonal of the rectifier bridge, so an alternating current flows through the load, supplying the main components of the device. Such a switching circuit is optimal in this case, since its main condition is protection against peak current values at the moment the device is turned on, which extends the service life of an ultraviolet radiation source by an average of two to three times.

 The device operates as follows. When you turn on the device, the voltage is supplied to the capacitive storage, and from it to the input of the shaper-one-shot as part of the shaper 14 delay. After the voltage on the capacitive storage reaches a certain level, for example, after 0.5-1 s, a logical unit is formed at the output of a single-vibrator made according to the waiting multivibrator scheme, which is fed to the second input of element 16 AND and through element 15 is NOT logical zero is fed to the control input of the counter 19 of the divider, zeroing it with an installation signal, and to the second input of the OR element, from the output of which a logical zero signal using the switching circuit 21 triggers an electronic key 22.

 At this time, the clock pulses from the generator 18, the enabling signal of the logical unit at the second input of the And element 16, arrive at the counting input of the divider counter 19, gaining a certain number of pulses corresponding to the operating time of the device. After the number of pulses reaches a certain value corresponding to a given time, using a switch 20 connected to the corresponding output of the counter 19, the signal of the logical unit is supplied through the OR element 17 and the switching circuit 21, thereby turning off the electronic key 22 and stopping the operation of the device. After dialing the number of pulses of the corresponding time of "silence" of the device, the process of its inclusion is repeated, but only by the signal from the output of the counter 19 logical zero.

 By turning on the key 22, the load is allowed to be applied to the actuators of the installation: the fan 9 of the air flow passing through the duct 2 is turned on, the high-voltage generator 11 is started, and using the on-off circuit 12, the non-zoned ultraviolet radiation source 5 is started.

 Air enters the duct through the inlet protective grill 3 and enters the confined space of duct 2, irradiated with short-wave ultraviolet radiation of source 5. Under the action of ultraviolet radiation, chemical reactions occur that lead to the death and decay of microorganisms and viruses, as well as organic gaseous compounds.

 The air stream with the decay products of organic compounds and excited, under the influence of short-wave radiation, oxygen, enters the electrodynamic catalyst 6 and is already completely processed is discharged into the space using a fan 9.

 The electrodynamic catalyst 6 operates as follows. The first 7 electrode is made according to the principle of electro-effluvial construction in order to increase the area of contact of the air flow with the surface of a statically charged, negative polarity voltage, copper catalyst. The second 8 electrode-electrostatic duct directs the air flow that passes along the surface of a positively charged copper catalyst. The potential difference between the electrodes of 2.5-5 kV is not sufficient for the formation of a corona discharge, which in this case would change the course of photochemical reactions under the influence of ultraviolet radiation and lead to the formation of ozone and nitrogen oxides hazardous to health. The high voltage potential of this level acts as a neutralizer of the excess number of positively and negatively charged particles generated by ultraviolet radiation on impurities contained in the air stream. In this case, metallic copper electrodes acts as a catalyst in the decomposition of hydrocarbons in the processed air.

 The biological and physico-chemical meaning of air treatment is as follows.

 The bactericidal effectiveness of the device is associated with the specificity of the action of ultraviolet radiation in the range 205-315 nm and is determined by the absorption of its quanta 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.

 The processes of air purification from gaseous organic compounds depend on the specific properties of substances and their structure. For example, some hydrocarbon compounds, when the ultraviolet radiation power in the range of 205-315 nm is not less than 10 W, accompanied by the formation of electronically excited oxygen in the air stream, enter into photochemical processes leading to the formation of hydrocarbon oligomers.

 The formation of the direction of the photochemical process and the neutralization of charges of polymolecular products in the device are performed by a special electrodynamic catalyst, which normalizes the quantity and quality of ions in the treated air and promotes the formation of polyoligomers. The latter, together with dust particles of air, form suspended particles that precipitate from the air.

 Thus, the room air is purified from pathogens, gaseous organic compounds and dust particles using a device without filters that require replacement. At the same time, not only is the ionic balance normalized, but also the content of nitrogen oxides in the air is reduced, which makes it fresh and pleasant.

 This process takes place continuously and in the presence of people.

 The tests performed on the device showed its extremely high efficiency, and the product was recommended by the Committee on Medical Technology of the Ministry of Health of Russia for industrial production.

Sources of information taken into account
1. RF patent 1798024, M.cl. B 08 B 15/00, publ. Bull. 8, 1993

 2. RF patent 1824240, M.cl. B 03 C 3/14, publ. Bull. 24, 1993

Claims (1)

 A device for cleaning and disinfecting air, containing an actuator as part of the duct and fan and a control unit including a high voltage generator, characterized in that, in order to increase the efficiency of disinfecting and controlling this process depending on the volume and contamination, as well as air purification from organic compounds and the normalization of the polarity of the ionic equilibrium of the treated air, the source of ultraviolet radiation bezozona introduced into the executive body a new one with a total bactericidal flux of at least 10 W, protective gratings of the air inlet and outlet, an electrodynamic catalyst consisting of the first electrode fixed together with an ozone-free ultraviolet radiation source inside the second electrostatic air duct electrode, and a control circuit incorporating an ozone-free ultraviolet radiation source and a unit for switching on the device as part of the delay signal driver, the element NOT, the element AND, the element OR, the clock generator s, a set-divider, a switch, an electronic and electronic key switch on circuit, the executive outputs of which through the outputs of the device turn-on unit are connected respectively through a switch-on circuit of an ultraviolet radiation source to a non-zonal ultraviolet radiation source, to inputs of a fan and a high voltage generator, the first and second output which are connected respectively to the first and second inputs of the electrodynamic catalyst, and the control input of the electronic key is connected through circuits turn on the electronic key with the output of the OR element, the first input of which through the switch is connected to the outputs of the divider counter, and the second input is connected to the output of the element NOT and the first control input of the divider counter, the second clock input of which is connected to the output of the And element, the first input of the And element connected to the output of the clock generator, and the second input to the input of the element NOT and the output of the delay driver.

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