RU108971U1 - ULTRASONIC INHALER - Google Patents

Abstract

 1. Ultrasonic inhaler, characterized in that it contains a power adapter connected to an interference filter, the outputs of which are connected to the power circuit of the control device, the input of the electronic key and the circuit of the display device, while the input of the electronic key is connected through the control device to the residual current device, and the output is with the power supply circuit of the pulse generator, the input of which is connected to the adjustment device, and the output with a power amplifier connected to the piezoelectric element. ! 2. The inhaler according to claim 1, characterized in that the power adapter is additionally connected to an alternating current network and is a pulse converter of alternating mains voltage to low constant voltage. ! 3. The inhaler according to claim 1, characterized in that the interference filter is made on capacitors and an inductor according to a typical U-shaped filter. ! 4. The inhaler according to claim 1, characterized in that the protective shutdown device is made on an optocoupler, a limiting resistor and thermal contact. ! 5. The inhaler according to claim 1, characterized in that the display device is made on LEDs and limiting resistors. ! 6. The inhaler according to claim 1, characterized in that the electronic key is made on a field effect transistor and limiting resistors. ! 7. The inhaler according to claim 1, characterized in that the pulse generator comprises a master oscillator on inverters, resistors, capacitors, an inductance element and a voltage stabilizer with filter capacitors. ! 8. The inhaler according to claim 1, characterized in that the adjustment device is made on a tuned resistor and a tuned capacitor. ! 9. The inhaler according to claim 1, x

Description

The utility model relates to medical equipment, in particular, to devices for converting a liquid drug substance into a fine aerosol using the energy of high-frequency oscillations of a piezocrystal, and is intended for the treatment and prevention of respiratory organs with drugs (essential oils (aromatherapy), antibiotics, herbal extracts, mineral water and etc.) both at home and in medical institutions.

An ultrasonic atomizer is known in the art which uses a frequency of 3 or 5 MHz as the oscillation frequency in order to produce submicron droplets. The atomizer may also use at least one piezoelectric ceramic oscillation to increase droplet volume. A supersonic atomizer includes an AC / DC converter, an inductive three-point generator, an amplification device, a spray chamber, and at least one piezoelectric ceramic generator (GB 2395131, 05/19/2004).

Known ultrasonic atomizer with a metal-coated ultrasonic generator containing a piezoelectric transducer, a bowl located above the transducer. Acoustic waves produced by the transducer propagate sequentially through the transmission medium of the first partition, the matching medium and the second partition, which is part of the bowl. The converter includes at least partially silver. Silver binds to the transmission medium to inhibit the growth of bacteria in the transmission medium (US 7779831, 08/24/20102).

The closest analogue in technical essence to the proposed utility model is an ultrasonic inhaler containing a high-frequency oscillation generator including a transformer with three windings, in which: the first output of the first winding is connected to the second output of the fourth capacitor; the second terminal of the first winding is connected to the emitter of the first transistor, the second terminal of the first capacitor, the first terminal of the third capacitor, the first terminal of the second resistor; the first terminal of the second winding is connected to the first terminal of the first resistor, to the first terminal of the first capacitor, to the first terminal of the second capacitor, the first terminal of the inductor and the first power rail; the second terminal of the second winding is connected to the second terminal of the second capacitor and the collector of the first transistor, in which the base is connected to the first terminal of the fourth capacitor and the second terminal of the first resistor; the first terminal of the third winding is connected to the emitter of the second transistor; the second terminal of the third winding is connected to the second terminal of the second resistor, the second terminal of the third capacitor, the second terminal of the load and the second power rail; - a power amplifier of high-frequency oscillations, including a second transistor, in which the base is connected to the power bus; the collector is connected to the second output of the inductor and the first output terminal for connecting the load, including the piezoceramic emitter; - a spray chamber in which a piezoceramic emitter is integrated, in which the first output is connected to the first terminal of the load connection and the second output to the second terminal of the load connection (RU 87916, 10.27.2009).

The disadvantages of these structures include the bulkiness and complexity of structures, inconvenience to use and low reliability in operation.

The problem to which the proposed utility model is directed is to create an ultrasonic inhaler that would eliminate the above disadvantages.

The technical result achieved by the implementation of this utility model is to increase the efficiency due to the use of a field effect transistor, to ensure high stability of the generator when changing the supply voltage and in a wide temperature range and to adjust the spraying performance without loss of power on the active elements, increasing manufacturability due to the use of standard winding products and a modern lead-free element base for mounting a circuit board on an automatic line and reliability by the use of small amounts of the active elements.

The specified technical result is achieved in an ultrasonic inhaler containing a power adapter connected to an interference filter, the outputs of which are connected to the power circuit of the control device, the input of the electronic key and the circuit of the display device, while the input of the electronic key is connected through the control device to the protective shutdown device, and the output is with the power supply circuit of the pulse generator, the input of which is connected to the adjustment device, and the output with a power amplifier connected to the piezoelectric element.

The power adapter is additionally connected to the AC mains and is a pulse converter of AC mains voltage to low DC voltage.

The interference filter is made on capacitors and an inductor according to the scheme of a typical U-shaped filter.

The protective shutdown device is made on an optocoupler, a limiting resistor and thermal contact.

The display device is made on LEDs and limiting resistors.

The electronic key is made on a field effect transistor and limiting resistors.

The pulse generator contains a master oscillator on inverters, resistors, capacitors, inductance element and voltage regulator with filter capacitors.

The adjustment device is made on a tuning resistor and a tuning capacitor.

The power amplifier contains a capacitor, filter capacitors, a diode, resistors, transistors, a key transistor, and an inductance element.

The control device includes a clock button, resistors, capacitors, a blocking capacitor, a limiting resistor, a D-flip-flop, and power filter capacitors.

An ultrasonic inhaler (nebulizer) is a device for converting a liquid medicinal substance into a fine aerosol using the energy of high-frequency oscillations of a piezoelectric element (piezoelectric crystal, piezoceramic emitter). It consists of a piezoelectric element of an ultrasonic transducer, a container for deionizing water and a cup for medicine (not shown). Aerosol formation occurs as follows: a high-frequency signal (1-4 MHz) deforms the piezoelectric element. Vibration from the piezoelectric element is transmitted to the surface of the solution, where the formation of "standing" waves. With a sufficient frequency of the ultrasonic signal at the intersection of these waves, a “microfront” (geyser) is formed, i.e. aerosol formation and release. As in the jet nebulizer, aerosol particles collide with a “damper”, larger ones come back into solution, and smaller ones are inhaled.

The aerosol is formed by spraying a liquid drug, placed in a spray chamber in a cup, by ultrasonic vibrations, with a frequency of 2.64 MHz, generated by a piezoelectric element, which is structurally part of the inhaler. The electronic circuit of the inhaler is powered by a direct current voltage of 12 V. This makes the device electrical safe. The power consumed by the device is 1.25A. The weight of the inhaler without a power supply is 170 g, the case is waterproof, made of durable plastic that does not contain substances harmful to humans and does not react with drugs or detergents. The device is easy to use, does not require special preparation before use. It can be disinfected at home. This allows you to use the device in everyday life, with a power supply network of 220V ± 22V.

The essence of the utility model is illustrated by drawings, where in Fig.1 shows a functional diagram of an ultrasonic inhaler; figure 2, 3 is a circuit diagram of an ultrasonic inhaler.

Figure 1 shows the power adapter 10, which is connected to an AC network and is a standard pulse converter of AC voltage to low DC voltage, from which all other devices of the inhaler are powered.

The input of the interference filter 9 is connected to the first “E1” and second “0V” outputs of the power adapter 10, and the output “E1-1” to the power supply circuit of the control device 7, the input of the electronic key 5 and the circuit of the indicating device 6. Output “0V” of the interference filter permanently connected to the common wire “⊥” of all devices of the device.

The control device 7 is designed to generate the electronic key control voltage “U on” and “U off” in various operating modes:

- When the supply voltage "E1-1" is supplied to the power supply circuit of the control device 7, from its output the voltage "U off" is supplied to the input of the electronic switch 5, which remains closed and the voltage "E1-2" is not connected to the pulse generator 1, power amplifier 3 and piezoelectric element 4. This ensures that the inhaler is in the off state when the power adapter is connected to the network.

- When a command is received to turn on / off the inhaler, the voltage “U on” (“U off”) is supplied to the input of the electronic key 5 from the control device 7 and the electronic key 5 closes (opens) the voltage input circuit “E1-1” and voltage output "E1-2". In this case, the voltage from the output of the electronic key "E1-2" is connected (disconnected) to the power circuits of the pulse generator 1, power amplifier 3, piezoelectric element 4 and the circuit of the indicating device 6. In this way, the power of these devices is turned on or off and the indicator is turned on work.

- If the piezoelectric element exceeds the critical temperature, the thermal contact 49 of the residual current circuit breaker 8 is closed and the voltage “Ut” is applied to the input of the control device 7. From the output of the control device 7, the voltage “U off” is applied to the input of the electronic key 5. The voltage "E1-2" is disconnected from the pulse generator 1, the power amplifier 3 and the piezoelectric element 4. The electronic key 5 is unlocked by switching the inhaler back on with the control element of the control device.

When voltage “E1-2” is applied to pulse generator 1, “U gene” appears at its output - a sequence of rectangular pulses with the working frequency of the piezoelectric element (piezoceramic emitter). The tuning elements of the adjustment device 2 “frequency control” and “power control” change the frequency and duration of the pulses at the output of the pulse generator 1. By adjusting the pulse duration, the power at the load, which is the piezoelectric element, is controlled.

The voltage "U gen." From the output of the pulse generator 1 is fed to the input of a power amplifier 3, the driver of which provides the voltage and current values necessary to switch the output transistor. The operation of the output transistor of the power amplifier 3 in key mode provides charge and discharge of the static capacitance of the piezoelectric element 4. When the static capacitance is discharged, the crystal of the emitter 4 undergoes deformation - vibrations with an ultrasonic frequency.

The electrical circuit of the ultrasonic inhaler is shown in figure 2, 3.

The interference filter 9 is made on the capacitors 60, 62 and the inductor 61 according to the scheme of a typical U-shaped filter. Capacitors 60.62 are connected between the “E1” wire and the “0V” wire before and after the inductor 61. The inductor 61 (notch) has two identical windings that are connected in series to the “E1” wire and the “0V” wire.

The supply voltage from the first output "E1-1" is supplied to the first output of the limiting resistor 57 of the control device 7, the first output of the limiting resistor 42 of the indicating device 6, the source of the transistor 39 and the first output of the resistor 41 of the electronic key 5.

The second output "0V" is connected to the common wire "_ | _".

From the second terminal of the limiting resistor 57, the voltage "E1-3" is supplied to the first terminals of the capacitors of the power filter 58.59, the other terminals of which are connected to the common wire "_ | _".

The output terminal of the supply voltage “V ss” of the D-flip-flop 55 is connected to the second terminal of the resistor 57, the common terminal “GND” to the common wire “_ | _”.

Translation of the D-flip-flop 55 into the counting mode is performed on an integrating RC circuit, in which the connection point of the second output of the resistor 56 and the first output of the capacitor 54 is connected to the input "D" of the D-flip-flop 55, and the output "Q inv." Is connected to the first output of the resistor 56. The second terminal of the capacitor 54 is connected to a common wire "_ | _".

The zeroing circuit of the D-flip-flop 55 when the power adapter is first turned on contains a differentiating R-C circuit in which, the connection point of the second output of the capacitor 52 and the first output of the resistor 53 is connected to the input "R" of the D-flip-flop 55; a first terminal of the capacitor 52 to a second terminal of the limiting resistor 57; the second output of the resistor 53 to the common wire "_ | _".

The on / off control is carried out by a clock button 45, one output of which is connected to the common wire "_ | _", and the other to the common point of the first output of the resistor 44 of the noise suppression circuit and the first output of the input capacitor 46 of the second differentiating R-C circuit. The connection point of the second output of the capacitor 46 and the first output of the resistor 47 of the second differentiating RC circuit is connected to the clock input “C” of the D-flip-flop 55. The first output of the blocking capacitor 48 is connected to the input “C”, the second output of which is connected to the common wire “_ | _ ".

The input "S", intended to set the trigger to a single state, is not used and is connected to the common wire "_ | _".

The residual current circuit breaker 8 is made on the optocoupler 51 and thermocontact 49. The anode of the control diode and the collector of the controlled transistor of the optocoupler 51 are connected to the second output of the limiting resistor 57. The cathode of the optocoupler 51 is connected through the resistor 50 to the first terminal of the thermal contact 49. The second terminal of the thermal contact 49 is connected to a common wire "_ | _". The emitter of the controlled transistor is connected to the input of the installation in the zero state of "R" D - trigger 55.

The electronic switch 5 is made on the field-effect transistor 39, the source of which is connected to the first output "E1-1" of the power filter 9, the drain is connected to the voltage output "E1-2", the gate is through a limiting resistor 40 with an inverting output "Q inv." D -trigger 55 of the control device 7. The first output of the resistor 41 is connected to the source, and its second output to the gate of the transistor 39.

The indicating device 6 is made on the LEDs 38,43. The power supply to the device is indicated by LED 43, the anode of which is connected to the E1-1 output of the interference filter 9 through the limiting resistor 42. The LED 38, the anode of which is connected via the limiting resistor 37 to the “E1-2” output, indicates the device is turned on electronic key 5. The cathodes of the LEDs 38, 43 are connected to a common wire "_ | _".

The pulse generator 1 contains a master oscillator on the inverter 14-1 of the chip 14. To start the generator, the input of the inverter 14-1 is connected to its output through the resistor 13. To feedback the phase of the signal by 180 degrees between the input and output of the inverter 14-1, a feedback circuit is introduced which: the first output of the capacitor 11 is connected to the input of the inverter 14-1; the first output of the capacitor 16 is connected to the output of the inverter 14-1; the second terminal of the capacitor 11 and the second terminal of the capacitor 16 are connected to a common point LC of the circuit - the first terminal of the capacitor 12, the first terminal of the inductance element 15 and the first terminal of the tuning capacitor 17 of the adjustment device 2. The second terminal of the capacitor 12, the second terminal of the inductance element 15 are connected to a common wire "_ | _" Schemas. By changing the capacitance of the tuning capacitor 17 of the adjustment device 2, in which the second terminal is connected to the common wire "_ | _", the frequency of the generated oscillations of the pulse generator 1 is regulated.

The output of the inverter 14-1 is connected to the input of the buffer amplifier - inverter 14-2.

The signal with digital logic levels from the output of the inverter 14-2 is fed to a differentiating RC circuit on the capacitor 18 and the tuning resistor 19, in which the first output of the capacitor 18 is connected to the output of the inverter 14-2, the common point of the second output of the capacitor 18 and the first output of the tuning resistor 19 adjustment device 2 is connected to the input of the inverter 14-3. Trimmer resistor 19, in which the second and third output are connected to a common wire "_ | _", regulates the duration and duty cycle of the pulses at the output of the pulse generator 1.

The buffer circuit is assembled on inverters 14-3, 14-4, 14-5, 14-6, in which the output of the inverter 14-3 is connected to the input of the inverter 14-4; the output of the inverter 14-4 is connected to the inputs of the inverters 14-5, 14-6. The signal from the output of the pulse generator 1 - the connection point of the outputs of the inverters 14-5, 14-6 is fed to the input of the power amplifier 3.

To convert the voltage from the output of the electronic switch 5 "E1-2" to the voltage of the microcircuit of the pulse generator 1, a voltage stabilizer is applied to element 22 with filter capacitors 20, 21.

The voltage output "E1-2" is connected to the input "V in" of the stabilizer 22, the output "V out" is connected to the first terminals of the filter capacitors 20, 21 and the output "V ss" of the microcircuit 14. The second terminal of the capacitor 20, the second terminal of the capacitor 21, the output "GND" of the stabilizer 22 and the output "GND" of the chip 14 are connected to a common wire "_ | _".

The signal from the output of the generator "U gen." Is fed to the input of the driver of the transistor assembly 28 of the power amplifier 3, made on transistors 29, 30.

Pulses with a high logical level control the opening of the N-channel transistor 29, in which the gate output "3 1" is connected to the output circuit of the pulse generator "U gen."

Pulses with a low logical level control the opening of the P-channel transistor 30 through the transition capacitor 25, the first output of which is connected to the output circuit of the pulse generator "U gen.", And the gate terminal "3 2" of the transistor 30 is connected to the second output of the capacitor 25. The required level pulses on the gate provides a level fixing circuit, performed on the elements 23, 24, in which the second output of the resistor 24 and the anode of the diode 23 are connected to the second output of the capacitor 25.

The source terminal "And 2" of the transistor 30, the cathode of the diode 23 and the first output of the resistor 24 of the level fixing circuit, the first conclusions of the filter capacitors 26, 27, 36 are connected to the voltage output "E1-2. The second terminals of the filter capacitors 26, 27, 36 and the source terminal "And 1" of the transistor 29 are connected to a common wire "_ | _" The operation of the transistor 34 in the key mode is controlled by the voltage "E1-4" at the drain terminal "C 2" of the transistor 30 and voltage "0V" ("_ | _") at the drain terminal

“C 1” of the transistor 29. For this, the drain terminal “C 1” of the transistor 29 is connected to the first terminal of the resistor 31, and the drain terminal “C 2” of the transistor 30 is connected to the first terminal of the resistor 32.

The gate "3" of the key transistor 34 is connected to a common point of the second terminal of the resistor 31, the second terminal of the resistor 32 and the first terminal of the resistor 33. The source "AND" of the key transistor 34 and the second terminal of the resistor 33 are connected to the common wire "_ | _".

The load of the transistor 34 is a piezoelectric element 4: the drain of the transistor 34 is connected to a common point of the second output of the inductance element 35 and the first output of the piezoelectric element 4. The second output of the piezoelectric element 4 is connected to the common wire "_ | _" and the first output of the inductance element 35 is connected to the voltage output "E1 -2 ".

The proposed device operates as follows.

When the power adapter 10 is first connected to the network, the supply voltage is supplied to the interference filter 9. The filter is designed according to a typical U-shaped filter and suppresses high-frequency conductive interference, both from the power adapter 10 and from the inhaler. Capacitors 60, 62, connected between the "E1" wire and the "0" wire, are designed to filter the conductive noise of a symmetrical form with a frequency of up to hundreds of kilohertz. The notch choke 61 is made on a core with a sufficiently high magnetic permeability (ferrite) and has two identical windings. The windings are connected in series in the wire “E1” and wire “0”, and the polarity of the windings is such that they have a large inductance for unbalanced interference with a frequency of more than 1 MHz.

The voltage "E1-1" from the output of the interference filter 9 is supplied to the chip of the D-flip-flop 55 of the control unit 7, the LED 43 of the indicating device 6 and the source of the transistor 39 of the electronic key 5. The glow of the LED 43 indicates the power supply to the inhaler.

The electronic switch 5 is made on the field effect transistor 39 and the resistor 41. A resistor 41 connected between the source and the gate of the transistor 39 holds the transistor in the closed state when the supply voltage is applied until the operating control voltage is applied to the gate.

When a supply voltage is applied to the D-trigger 55, a zeroing circuit is triggered on the differentiating R-C circuit - elements 52, 53 of the control unit 7, which provides a voltage of logical level “1” at the output “Q inv.” Of the D-trigger 55. The voltage from the output "Q inv." Through the resistor 40 is supplied to the gate of the transistor 39 of the electronic key 5, which will remain in the closed state, since it opens with a voltage with a logic level of "0". Thus, the supply voltage “E1-1” will not be supplied to the generator 1, amplifier 3 and piezoelectric element 4 and the inhaler will be turned off.

When you press the clock button 45 of the control unit 7, the D-flip-flop 55 is switched on and the voltage “Q inv.” Is set to the logic level “0”, which opens the transistor 39 of the electronic key 5. When the transistor of the electronic key is opened, the supply voltage is supplied to the LED 38 of indicating device 6, generator 1, amplifier 3, and piezoelectric element 4. LED glow 38 - an indication of the inclusion of the device in operation.

The pulse generator 1 for the piezoelectric element 4 is made on the CMOS inverter 14-1 of the chip 14. The resistor 13 provides a translation of the operating mode of the logic element from the limiting mode to the amplification mode. To generate the phase shift at the operating frequency should be 360 degrees and the gain of the generator circuit is greater than unity. The inverter 14-1 provides a phase shift of 180 degrees. At the resonant frequency, the feedback circuit on the capacitors 11, 12, 16, 17 and the inductance element 15 provides an additional phase shift of 180 degrees between the input and output of the inverter 14-1. The trimmer capacitor 17 of the control device 2 controls the value of the resonant frequency of the LC circuit, which determines the frequency of the generated oscillations.

Element 14-2 is a buffer amplifier designed to bring the level of the generated signal to digital logic levels.

From the output of the inverter 14-2, the pulses are fed to the differentiating circuit on the capacitor 18 and the resistor 19. By changing the time constant of the RC circuit using the trimming resistor 19 of the control device 2, it is possible to change the duration and duty cycle of the pulses at the output of the inverters 14-5, 14-6. Thus, the power supplied to the piezoelectric element 4 is regulated. Inverters 14-3, 14-4, 14-5, 14-6 are buffered. Elements 22, 20, 21 - voltage stabilizer 22 and capacitors of the power filter 20, 21 for the chip 14.

Power amplifier 3 is assembled on an element of transistor assembly 28 and a powerful MOSFET transistor 34. As a driver and a switching element, transistor assembly 28 is used, consisting of 2 field-effect transistors of different conductivity: n-channel 29 and p-channel 30. To control a powerful transistor 34 in the Key mode, the transistors 29, 30 are connected in a push-pull circuit.

The power parameters of the transistors at the selected supply voltage, provide a drain current sufficient to recharge the input capacitance of the transistor 34.

At a low logic level, the output of the pulse generator 1 opens the p-channel transistor 30 of the transistor assembly 28. The diode 23 and the resistor 24 provide the fixation of the required level of pulses. At the same time, a supply voltage is supplied to the gate of the transistor 34 through the resistor 32 and the transistor 34 opens.

At a high logical level, the n-channel transistor 29 of the element of the transistor assembly 28 opens at the output of the pulse generator 2. In this case, the gate of the transistor 34 is connected through a resistor 31 to the common output of the power source and the transistor 34 is closed.

When the transistor 34 is closed, the static capacitance of the piezoelectric element 4 is charged through the inductance element 35. When the transistor 34 is open, the static capacitance of the piezoelectric element 4 is discharged, while the emitter crystal is deformed — oscillations with an ultrasonic frequency.

The control device 7 is assembled on a chip D-flip-flop 55, which operates in counting mode. The transfer to the counting mode was carried out by connecting the inverse output “Q inv.” To the information input “D” through a resistor 56. When the supply voltage is initially applied to the D-flip-flop chip 55, the zeroing circuit is activated on the differentiating RC circuit - elements 52, 53 and provides a pulse to the input "R". At the same time, voltages with levels are set at the outputs: logical “0” at the output “Q” and logical “1” at the output “Q inv.” The voltage from the output of "Q Inv." D-flip-flop 55 through a resistor 40 is supplied to the gate of the transistor 39 of the electronic key 5, which will remain in the closed state.

When you press the clock button 45 on the clock input "C" of the D-trigger 55 elements

44, 46, 47 form an exponential pulse, the leading edge of which (positive voltage drop) switches the outputs of the D-trigger to the opposite state. At the direct output “Q”, the logical level that was before the arrival of the clock at the input “D” will be established - the logical level “1”. The output "Q inv." Will establish a voltage with a logic level of "0", which is fed through a resistor 40 to the gate of the transistor 39 and ensures the opening of the electronic key 5 and the inclusion of the inhaler in operation. When the clock button 45 is pressed again at the output “Q inv.” Of the D-flip-flop 55, the voltage with the logic level “1” will be established, which will lead to the closure of the electronic key 5 and the inhaler to turn off.

The protective shutdown device 8 is designed to shut off the inhaler when the permissible temperature on the piezoelectric element 4 is exceeded and is assembled on an optocoupler 51, consisting of a control diode and a controlled transistor, and thermocontact 49. The voltage "E1-3" through the resistor 57 is constantly applied to the collector of the controlled transistor and the anode optocoupler control diode 51.

The voltage from the cathode of the control diode of the optocoupler 51 through a resistor 50 is applied to one of the terminals of the thermal contact 49, the other terminal of which is connected to the common wire "|". When exceeding the permissible temperature on the piezoelectric element 4, the thermocontact 49, with a normalized operating temperature and having thermal contact with the piezoelectric element, closes the circuit of the control diode of the optocoupler 51. The controlled transistor of the optocoupler 51 opens and the control voltage "U t" is applied to the input "R" of the installation D - trigger 55 to the zero state. The logical voltage “1” from the output “Q inv.” Of the D-flip-flop 55 through a resistor 40 is supplied to the gate of the transistor 39 and ensures the closure of the electronic key 5. Thus, the generator 1, amplifier 3 and piezoelectric element 4 will be disconnected from the power supply circuit “Е1-1 »- the inhaler is turned off.

The advantage of an ultrasonic inhaler is - noiseless operation, uniformity and constancy of particle size of the spray aerosol, as well as portability.

When using an ultrasonic inhaler, a therapeutic effect is achieved by inhaling the medications indicated by the doctor in the form of a fine aerosol.

Claims (10)

1. Ultrasonic inhaler, characterized in that it contains a power adapter connected to an interference filter, the outputs of which are connected to the power circuit of the control device, the input of the electronic key and the circuit of the display device, while the input of the electronic key is connected through the control device to the residual current device, and the output is with the power supply circuit of the pulse generator, the input of which is connected to the adjustment device, and the output with a power amplifier connected to the piezoelectric element. 2. The inhaler according to claim 1, characterized in that the power adapter is additionally connected to an alternating current network and is a pulse converter of alternating mains voltage to low constant voltage. 3. The inhaler according to claim 1, characterized in that the interference filter is made on capacitors and an inductor according to a typical U-shaped filter. 4. The inhaler according to claim 1, characterized in that the protective shutdown device is made on an optocoupler, a limiting resistor and thermal contact. 5. The inhaler according to claim 1, characterized in that the display device is made on LEDs and limiting resistors. 6. The inhaler according to claim 1, characterized in that the electronic key is made on a field effect transistor and limiting resistors. 7. The inhaler according to claim 1, characterized in that the pulse generator comprises a master oscillator on inverters, resistors, capacitors, an inductance element and a voltage stabilizer with filter capacitors. 8. The inhaler according to claim 1, characterized in that the adjustment device is made on a tuned resistor and a tuned capacitor. 9. The inhaler according to claim 1, characterized in that the power amplifier comprises a capacitor, filter capacitors, a diode, resistors, transistors, a key transistor and an inductance element. 10. The inhaler according to claim 1, characterized in that the control device comprises a clock button, resistors, capacitors, a blocking capacitor, a limiting resistor, a D-trigger and power filter capacitors.