RU46433U1 - NEW ADAPTIVE PHYSIOTHERAPEUTIC APPARATUS - Google Patents

Abstract

The invention relates to medical equipment, namely to devices for irradiation with light and infrared rays and can be used to carry out physiotherapeutic procedures in the field of reflexology, rheumatology, dermatology and in other fields of medicine. The objective of the invention is the creation of a physiotherapeutic apparatus that generates pulsed light from the infrared and light ranges with adaptation according to the heart rate, with a device for controlling the heart rate, and also having an additional several operating modes of the device, in addition to the adaptive mode, for example, with a pulsation frequency of 60 pulses per minute and s frequency of 40 Hz. In accordance with the task, the claimed device comprising a first power supply 1, a capacitor 2. an optocoupler 4, a matrix of emitting diodes 3, a second power supply 5, introduced two electrodes 6 E1 and E2, a cardiac signal amplifier 7, a low-pass filter 8, a detector R-pulse 9, the information processing and control unit 10, the mode selection unit 11 and the indication unit 12.

Description

The alleged invention relates to medical equipment, namely, devices for irradiation with light and infrared rays and can be used for physiotherapeutic procedures in the field of reflexology, rheumatology, dermatology and other fields of medicine, where the treatment is carried out by exposure to low-energy radiation in the optical and infrared ranges of lengths waves and is additional to the invention "Adaptive physiotherapy apparatus" (RF Patent No. 2192292, A 61 5/06, 10.11.02).

The disadvantage of this device is the insufficient accuracy of the optical heart rate sensor, inconvenience to use, since one finger should always be on the optical sensor, there is no control over the patient’s heartbeat, which is desirable during physiotherapy procedures for patients with heart diseases.

The objective of the invention is to provide a physiotherapeutic apparatus powered by a household electrical network that generates pulsed radiation of light and infrared radiation ranges with adaptation according to the heartbeat frequency, with a device for controlling the heartbeat frequency, and also having an additional several operating modes of the apparatus, in addition to the adaptive mode, for example, with a pulsation frequency of 60 pulses per minute and with a frequency of 40 Hz.

In accordance with the task, the proposed new adaptive physiotherapeutic apparatus containing a first power supply, to the outputs of which a capacitor is connected in parallel, and through an optocoupler key, a matrix of emitting diodes, a second power supply, characterized in that two electrodes E1 and E2 are additionally introduced. cardioamplifier, low-pass filter, low-pass detector, pulse detector, information processing and control unit, mode selection unit and unit

indications, electrodes E1 and E2 are connected to the input of the cardiac signal amplifier, the output of which is connected to the low-pass filter, the output of which is connected to the input of the R-pulse detector, the output of which is connected to the first input of the information processing and control unit, to the second input of which the output of the selection unit is connected mode, the first output of the information processing and control unit is connected to the control input of the optocoupler key, the information output is connected to the display unit, the outputs of the second power supply are connected to power circuits.

Figure 1 shows a functional electrical diagram of a new adaptive physiotherapeutic apparatus.

The new adaptive therapeutic apparatus (Fig. 1) contains a first power supply unit 1, a capacitor 2, a matrix of emitting diodes 3 with different emission spectra from the light and infrared wavelength ranges, an optocoupler 4, a second power supply 5, to the inputs of power supplies 1 and 5 a household electrical network is connected, a capacitor 2 is connected in parallel to the outputs of the first power supply unit 1 and through an optocoupler 4, a matrix of emitting diodes 3, electrodes (E1, E2) 6, a cardio signal amplifier 7, an low-pass filter 8, an R-pulse detector 9, an information processing unit and management 10, mode selection block 11, display unit 12, electrodes (A1, A2) are connected to the input of the cardio signal amplifier 7, the output of which is connected to the low-pass filter 8, the output of which is connected to the input of the R-pulse detector 9, the output of which is connected to the first input the information processing and control unit 10, to the second input of which the output of the mode selection unit 11 is connected, the first output of the information processing and control unit is connected to the control input of the optocoupler 4, the information output of the information processing and control unit 10 is connected to the indicator unit 12.

The work of the proposed new adaptive therapeutic apparatus is as follows. After connecting to a household power supply, the device is in adaptation mode, i.e. pulse frequency

control the patient's cardiac signals. In this case, the voltage from the first power supply unit 1 is supplied to the capacitor 2 and through the optocoupler switch 4 to the serial circuit of the matrix of LEDs 3, but the current does not pass through the diodes, because the key 4 is open, the capacitor 2 is charged to a voltage higher than optimal, because the series circuit of the diodes forming the resistive voltage divider is open.

Since stabilized low-voltage voltage is necessary for the operation of the remaining units of the apparatus, a second power supply unit 5 serves for these purposes.

When taking the device in hand, place the index finger on the electrode 31, and the middle finger on the E2 electrode, while the thumb on the back of the device will be located on a common substrate. The electrodes (6) E1 and E2 are located on one side of the handle body in the form of metal plates large enough, which increases the usability of the device. Using electrodes E1, E2, the cardiac signal is removed from the fingers that are attached to the electrodes, amplified by the cardioamplifier 7, the amplified cardio signal is filtered out from interference and interference through the low-pass filter (8), and the filtered cardio signal is fed to the R-pulse detector 9, which emits R- pulses from a cardiosignal, R-pulses are pulsations of a cardiosignal that have a maximum amplitude, the output signal of the detector is fed to the input of the information processing and control unit 10. As the information processing and control unit, A single-chip microcontroller is used, which measures the period of the pulse of the cardiosignal and calculates the pulse rate, the value of which is transferred from block 10 to the display unit 12. At the same time, when the trailing edge of the cardio pulse drops, the control signal is generated at the first output of the information processing and control unit, which is fed to the control input of the optocoupler key 4 and opens it, the LED circuit closes, and the LEDs of the matrix 3 begin to emit, when a new pulse of a cardiosignal arrives, the control signal

the LED matrix turns on and off. Thus, the luminescence of the LEDs falls on the period when the blood supply in the vessels is minimal, which ensures a deeper penetration of radiation into the patient’s muscle tissue, thereby increasing the therapeutic effect of radiation. Thus, a pulsed glow of the LEDs of the matrix 3 with a pulse rate, i.e. the device adapts to the patient’s heart rate.

However, in the case of a weak cardiac signal in the patient or for medical reasons, it is recommended to irradiate with a constant frequency of 60 pulses / min. or with a frequency of 40Hz. To do this, use the mode selection block 11, with which you can set the desired mode of operation of the new therapeutic apparatus.

Claims (1)

An adaptive physiotherapeutic apparatus containing a first power supply, to the outputs of which a capacitor is connected in parallel, and through an optocoupler, a matrix of emitting diodes, a second power supply, characterized in that two electrodes, E1 and E2, a cardio signal amplifier, a low-pass filter, a low-pass filter, are introduced R-pulse, information processing and control unit, mode selection unit and display unit, electrodes E1 and E2 are connected to the input of the cardio signal amplifier, the output of which is connected to a low-pass filter of low pass, the output of which connected to the input of the R-pulse detector, the output of which is connected to the first input of the information processing and control unit, the output of the mode selection unit is connected to the second input, the first output of the information processing and control unit is connected to the control input of the optocoupler, the information output is connected to the display unit , the outputs of the second power supply are connected to power circuits.