RU2098151C1 - Method for ionizing room air and device intended for its realization - Google Patents

Abstract

FIELD: medicine; agriculture. SUBSTANCE: method involves radiation of aeroions and provision for their concentration. Radiation of aeroions is performed with the aid of two groups of radiators spaced in room. In this case, one group of radiators is connected to negative pole of high-voltage source through high-voltage switch, while the other, is connected simultaneously with the first one to positive pole of high-voltage source. Preset concentration is ensured by change in polarity of connection of all or part of radiators included in both groups to high-voltage source. Device has power supply source, aeroion radiator, and control unit. In addition, device has high-voltage switch, high-voltage source, and at least one more radiator. Outputs of power supply source are connected to inputs of high-voltage source and control unit, and control unit outputs are connected to some inputs of high-voltage switch, which other inputs are connected to outputs of high-voltage source. These outputs are opposite poles of high-voltage source. High-voltage switch outputs are connected to radiators spaced in room, and high-voltage switch is made for connection of every radiator either to negative or positive pole of high-voltage source. EFFECT: higher efficiency.

Description

 The invention relates to aeroionization of air by the method of electroionization and can be used in medicine, agriculture, everyday life, etc.

 A known method for generating and moving ions (see ed. St. USSR N 1008830, publ. 30.03.83, MKI: H 01 T, 23/00). In the known method, air ions are generated, and then a directed flow of air ions is formed.

 A device for generating and moving ions (see ibid.), Comprising a power supply unit, a receiving electrode made in the form of a lattice with needles placed in the nodes of the lattice, and a corona electrode, also made in the form of a lattice with needles in the nodes of the lattice. The receiving and corona electrodes are connected to different poles of the power supply, which provides directional movement of aero ions.

 Using the known method and device, you can get only one form of distribution of aeroions in the room, and this distribution has the form. (See the book by A. L. Chizhevsky, “Aeronification in the National Economy,” 2nd ed., Abbr. M. Stroyizdat, 1989, p. 114, fig. 32, p. 115, fig. 33, p. 295, fig. 92). It should be noted that it is not possible to change this form of distribution of aeroions, since only one emitter is included in the design of the device.

 A known method for ionizing air. (See UK Pat. Nos. 2249878, publ. 05.20.92, MKI: H 01 T, 23/00). According to the known method, air ions are emitted by several emitters, and the number of emitted ions is controlled by changing the number of emitters in operation and by changing the voltage of their power sources.

 A device for ionizing air is known (see ibid.), Which contains several emitters included in one ionizer, rigidly fixed in one housing and connected to sources of different high voltage. In addition, the device includes a device for opening one or more emitters, made in one of the options in the form of a moving curtain.

However, although when implementing the known method and device, it is possible to control the number of emitted aeroions, it is not possible to obtain a predetermined (for example, uniform) distribution of aeroions over a room, since all emitters are located in one housing. In this case, the distribution will have the following form. (See the book of A. Chizhevsky)
The closest known (prototype) is a method for ionization of air (see US Pat. Russia N 2019207, publ. 15.09.94, MKI: A 61 N, 1/44), in which aeroions are emitted, and then maintain a given concentration of aeroions in point. So, if the concentration of aeroions exceeds a predetermined one, the voltage of the power source decreases, which reduces the number of generated ions, and vice versa, with a decrease in the concentration of aeroions, the voltage of the power source increases.

 The closest known (prototype) is a device for air ionization (see ibid.), Which contains an adjustable power source, control unit, aeroion emitter, aeroion concentration sensor, amplifier, information processing unit.

However, when implementing the known method and the known device, it is possible to obtain only one form of distribution of the concentration of aeroions in a room, namely: as you move away from the emitter, the number of aeroions will decrease (see the book by A. Chizhevsky)
In addition, it is not possible to change the shape of the distribution of air ions in the room, since the design of the device includes only one emitter of air ions.

 The purpose of the invention is the creation of a new method of ionization of air and a new technical means that, when implemented, allows to achieve the following technical results: providing the ability to create a given distribution of aero ions and making it possible to change the shape of this distribution by periodically changing the polarity of the connection of the emitters and by spacing the emitters around the room.

 The goals are achieved by the fact that in the method of ionizing air in a room, which consists in emitting aeroions and providing a given concentration of aeroions, aeroions are emitted using two groups of emitters spaced around the room, while using a high-voltage switch one group of emitters is connected to the negative pole of a high source voltage (IVN), and the other simultaneously with the first is connected to the positive pole of the IVN, and the specified concentration is provided by changing the polarity connection to the IVN of all or part of the emitters included in both groups.

 The goals are also achieved by the fact that in the device for implementing this method, containing a power source, an aeroion emitter, a control unit, a high-voltage switch, a high voltage source (HVI), at least one other emitter are additionally introduced. The outputs of the power source are connected to the inputs of the IVN and the control unit, and the outputs of the control unit are connected to one of the inputs of the high-voltage switch, the other inputs of which are connected to the outputs of the IVN, which are opposite poles of the IVN. The outputs of the high-voltage switch are connected to the emitters, spaced across the room, and the high-voltage switch is configured to connect each emitter to either the negative or positive poles of the IVN.

 Analysis of publicly available sources of information shows that the proposed technical solution is unknown from the prior art, which proves the compliance of this solution with the novelty criterion.

 In addition, it should be noted that the distinctive features separately from each other can be found in other technical solutions. But the causal relationship between the claimed combination of distinctive features and the achieved technical results, according to the authors, is unknown from the prior art, which proves the conformity of the claimed technical solution to the criterion of inventive step.

 In FIG. 1 shows a functional diagram of a device; in FIG. 2 - curves of the distribution of aeroions depending on the distance from the emitter (generator of aeroions): “a” curve from one radiator located to the left, “b” curve from another radiator located to the right, “c” curve of the total distribution of aeroions resulting from alternating the work of two emitters of ions; in FIG. 3 is a circuit diagram of the device for the case of one emitter in each group; in FIG. 4 is a circuit diagram of a device for the case of "N" emitters.

 The proposed device (see Fig. 1) contains a power source 1, the outputs of which are connected to the input of the high voltage source 2 and to the input of the control unit 3, the outputs of which are connected to one of the inputs of the high-voltage switch 4, the other inputs of the high-voltage switch 4 are connected to the opposite poles of the source high voltage 2. The outputs of the high-voltage switch 4 are connected to the emitters 5. The emitters 5 are combined in two groups. One group of emitters 5 is connected through the switch 4 to the negative pole of the high voltage source 2, and another group of emitters 5 'is connected through the switch 4 to the positive pole of the high voltage source 2. Switch 4 is configured to alternately connect the emitters 5, 5' to the negative, then to the positive poles of the high voltage source 2.

 The proposed method is implemented as follows. For a better understanding of the essence of the processes, a description of the method is given on the example of a variant of the device having only one emitter in each group (see Fig. 3).

 When the device is turned on, the emitter 5, connected to the negative pole of the high voltage source 2, through the switch 4 generates negative air ions that propagate in the space of the room and move mainly in the direction of the second emitter 5 ', connected through the switch 4 to the positive pole of the high voltage source 2. When this distribution of the concentration of ions depending on the distance from the emitter 5 has the form (see Fig. 2, curve "a"). After some time, the polarity of the connection of the emitters is reversed. This operation is carried out by the high-voltage switch 4. Now the emitter 5 'begins to generate negative ions that are already moving in the direction of the emitter 5. The concentration distribution depending on the distance from the emitter 5' will have the form (see Fig. 2, curve "b"). The total distribution of the concentration in the room during alternate switching of the emitters will have the form (see Fig. 2, curve "c"). The graphs show that the distribution of the concentration of aeroions in the room (total) when using the proposed method will be more uniform than in the prototype. By increasing the number of emitters spaced in the room, you can get a given distribution of the concentration of ions in the room and change this distribution depending on specific conditions.

 A device for implementing the proposed method in the simplest embodiment may contain only two emitters 5 and 5 '(one in each group), as shown in FIG. 3, which shows a circuit diagram of this embodiment of the device. In accordance with this scheme, the power source 1 contains a transformer, a rectifier low voltage +12 V, +200 V and is made according to known rules. (See, for example, the book by Artamonov B.I. Bokunyaev A. A. Power sources for radio devices. Textbook for technical schools M. Energoizdat, 1982, fig. 1.7, p. 15, fig. 1.10, p. 19). One output of the power supply 1 +12 V is connected to the input of the control unit 3, and the other output of the power supply +200 V is connected to the input of the high voltage source 2. The control unit 3 is an infra-low frequency generator (timer) based on the chip 1006 VI 1 according to the multivibrator scheme with a variable frequency. (See, for example, the book Shilo VL Functional analog integrated circuits. M. Radio and communications, 1982, fig. 2.3a, p. 66, fig. 2.22b, p. 89). The output of the control unit 3 is connected to the input of the high-voltage switch 4, made by the type of relay. The high voltage source 2 is made according to well-known rules (see, for example, the book by B. A. Artamonov, A. A. Bokunyaev), and its opposite poles are connected to the contact groups of the high-voltage switch 4. In turn, the contact groups are connected to the emitters of aero ions 5 and 5'.

 The proposed device operates as follows.

 The mains voltage is supplied to power supply 1, where two voltages are generated: +12 V, +200 V. A voltage of +12 V powers the control unit 3, which generates a control signal for the relay of the high-voltage switch 4. A voltage of +200 V from power supply 1 is supplied to a high voltage source 2, where it is converted to a high constant voltage (in this case 30 kV), which is fed through two wires to the second input of the high-voltage switch 4. Switch 4, in accordance with the signal received from the control unit 3, switches spruce the aerons 5 and 5 'alternately to the opposite poles of the high voltage source 2. The emitters 5 and 5' are placed, for example, on opposite walls of the room. During operation of the emitters, the air ions are generated alternately from each emitter 5 or 5 ', and the direction of the flow of aerons alternately changes to the opposite.

It should be noted that the number of emitters included in each group can be selected by any. This is determined by the specific conditions of aeroionization, and an embodiment of a device with "N" emitters is shown in FIG. 4. All functional elements of the device can also be built from known elements according to known rules. (See, for example, the book "Automatic Switching", ed. By ON Ivanova. M. Radio and Communications, 1988)
The control unit 3 contains a control pulse generator 6 connected to a code setting counter 7, which is connected to the inputs of the decoder 8 with its outputs, and the outputs of the decoder 8 are connected via transistor switches to the relay coils of the high-voltage switch 4. The control pulse generator 6 is based on chip 1006VI1. The counter for setting code 7 is made on a K155IE7 or K155IE5 chip. Decoder 8 is based on the K155ID3 chip. The principles of construction of these devices are given, for example, in the book. Veniaminov et al. "Microcircuits and their application." Reference Guide, 3rd ed.

 M. Radio and Communications, 1989 pp. 102-103; Shilo V.L. "Popular digital circuits." M. Radio and Communications, 1987 pp. 89-90, 132.

 In the initial state, the power is off and all the relays of the switch are set to the position when all the emitters are connected to the positive pole of the high voltage source. When the power is turned on, the control pulse generator 6 gives out counting pulses to the counter 7 at a specified frequency, which are converted by the counter into a 4-digit digital code (in the general case, M-bit), which is supplied to the decoder 8. The decoder is in accordance with the digital code (word ) turns on one and simultaneously turns off the other relays of the high-voltage switch, connecting the emitters respectively to the negative or positive pole of the high voltage source. You can also submit a 4-bit digital code from an external source of the control signal (for example, microcomputers, etc.) using well-known principles for interfacing such systems (see the book Shevkoples BV "Microprocessor structures. Engineering solutions. Reference book, 2nd ed. M. Radio and Communications, 1990 pp. 477-478).

Claims (2)

 1. The method of ionizing air in a room, which consists in emitting aeroions and providing a given concentration of aeroions, characterized in that the aeroion is emitted using two groups of emitters spaced around the room, while using a high-voltage switch one group of emitters is connected to the negative pole of the high voltage source (IVN), and the other simultaneously connects to the positive pole of the IVN simultaneously with the first, and the specified concentration is provided by changing the polarity of the connection to the IVN all or part of the emitters included in both groups.  2. A device for ionizing indoor air, containing a power source, an aeroion emitter, a control unit, characterized in that it additionally includes a high-voltage switch, a high voltage source (IVN), at least one other emitter, while the outputs of the power source are connected with the inputs of the high voltage source and the control unit, the outputs of the control unit are connected to one of the inputs of the high-voltage switch, the other inputs of which are connected to the outputs of the IVN, which are opposite poles of the IVN, p When in use, the high voltage switch outputs are connected to the emitters, spaced throughout the room, and a high voltage switch arranged to connect each radiator to either the negative or the positive pole of high voltage source.

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