RU2144396C1 - Physiotherapeutic apparatus - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: operation of apparatus is based on optical radiation of visible and/or infrared range. The apparatus has power supply source, number of radiating diodes with different spectra from light and/or infrared radiation range which forms radiating diode matrix connected to power supply source. Part of diodes are connected in parallel. They form separate groups of parallel-connected radiating diodes connected in series. Within separate group of parallel-connected radiating diodes it is expedient to select diodes of identical nominal voltage. Diodes of different polarity are connected in pairs in groups of parallel-connected diodes so that unipolar diodes are connected in matrix column. Number of diodes in every group is selected proceeding from approximate equality of sum of operating currents of unipolar diodes in group to full of given direction through matrix. Number of groups is selected proceeding from approximate equality of sum of group nominal voltages to output voltage of power supply source. Surplus voltage is damped by means of damping resistor (resistors) connected in series to both separate diodes and matrix as a whole. The apparatus provides for electric safety and preserves therapeutic efficiency in case of failure of part of radiating diodes in matrix. EFFECT: higher reliability. 5 cl, 5 dwg

Description

 The invention relates to medical equipment, in particular to physiotherapeutic devices operating on the basis of irradiation of pathological foci or biologically active zones (points) with optical radiation of the visible and / or infrared range and is intended for physiotherapeutic procedures in the field of rheumatology, dermatology, surgery and other fields of medicine .

 Known laser physiotherapeutic apparatuses in which the radiation source is a gas or semiconductor laser or a laser matrix [1]. The devices are widely used, they allow for a large number of physiotherapeutic procedures in various branches of medicine, however, they have a relatively low durability, high price and often require high supply voltages, that is, they have an increased electrical hazard in operation.

 A simple and fairly cheap LED physiotherapeutic apparatus is known [2], in which semiconductor emitting diodes of the visible (mainly red) range are connected in series in one or more circuits, forming a matrix. Moreover, each of the circuits is connected to a power source, made, as a rule, according to the scheme of the current generator. The power source may include controls for radiation parameters (current regulator, modulator, timer, etc.).

 The disadvantages of the apparatus are limited therapeutic possibilities, due to the fact that it uses only radiation of a single wavelength.

 More advanced physiotherapeutic devices are known [3,4], using LEDs with different spectra from the light and infrared wavelength ranges as sources. Each of the devices contains a power supply, a series of emitting diodes with different spectra from the light and infrared ranges of radiation, forming a matrix of emitting diodes, which are interconnected in at least one serial circuit connected to the power supply. In specific devices built according to this scheme, the number of diodes connected in series in one circuit is several tens [4].

 The main disadvantages of the mentioned devices include the relatively low reliability of the serial circuits of the emitting diodes, since the failure of one diode or contact node (soldering, welding) in the event of an “open” failure, which is most common when the emitting diodes fail, leads to a catastrophic device failure , that is, incapacitates the apparatus as a whole.

 When several separate serial diode circuits are connected to the power source (current generator), the failure of one of the diodes of the serial circuit stops the operation of this circuit, sharply reduces the current (usually to zero) in the circuit and leads to an abrupt increase in current in 1 / M times in other consecutive circuits (M is the number of identical consecutive circuits in the apparatus). And this, in turn, can lead to an avalanche failure of the remaining diodes, since the increased operating current dramatically reduces the operating time of the emitting diodes.

 In addition, the failure of one of the series circuits reduces the output optical power of the apparatus by ≈1 / M times. A significant decrease in the output optical power of the apparatus essentially renders it unusable, as it violates the conditions for the effect of radiation on biological objects (the energy characteristics of radiation, doses, etc., change), and, therefore, the treatment result obtained can differ significantly from the results obtained using fully operational and usable devices.

 A very important disadvantage of this type of apparatus (see, for example, [4]) is the increased electrical hazard during its operation, due to the fact that the apparatus is powered directly from an alternating current network with a voltage of 220 V, which is inserted through the cord into the apparatus body and, therefore , current-carrying elements of the apparatus under the indicated voltage are located in close proximity to the patient’s body.

 The aim of the present invention is to provide a physiotherapeutic apparatus of increased reliability and electrical safety.

 To achieve this goal in a physiotherapeutic apparatus containing a power source, a series of emitting diodes with different spectra from the light and / or infrared ranges of radiation, forming a matrix of emitting diodes connected to a power source, some of the diodes are connected in parallel and form separate contracts in parallel connected emitting diodes, connected in series.

 For more stable operation of the apparatus and simplification of assembly, it is advisable to select diodes within a separate contract of parallel-connected emitting diodes identical in their rated voltage.

 If it is necessary to include emitting diodes in a row that differ in rated voltages and operating currents, it is advisable to provide at least a part of the diodes with separate quenching resistors in the series of diodes in parallel.

 Often, for technical or medical reasons, it becomes necessary to use an AC power source (for example, to modulate radiation). In this case, it is advisable to include diodes in pairs bipolar in the contracts of parallel connected diodes so that diodes of the same polarity are included in the rows of the matrix.

 Since emitting diodes of a different emission spectrum, as a rule, differ in the values of operating currents and voltages, for a balanced matrix operation it is necessary to set a certain number of diodes in each circuit (if damping resistances are included, they must be taken into account when determining the number of diodes). In the general case, the number of diodes in each contract is selected based on the approximate equality of the sum of the operating currents of unipolar contract diodes to the full current of a given direction through the matrix, and the number of contracts is selected based on the approximate equality of the sum of the nominal voltage of the contracts to the output voltage of the power source.

 The excess voltage can be repaid using a quenching resistor (s) connected in series with both individual diodes and the matrix as a whole.

 Nevertheless, in practice, it is preferable to combine diodes of the same radiation spectrum (luminescence colors) in parallel contracts.

 With such a combination of diodes in the matrix, the failure of one of the diodes leads to an insignificant (not more than a few percent) increase in the current flowing through the diodes of this contract; the current flowing through the diodes of other contracts remains unchanged and the performance of the device is not disturbed. Theoretical and experimental estimates show that failure of up to 30% of the diodes in the matrix does not lead to significant changes in the output power and a catastrophic failure of the device. Thus, the reliability of the device increases significantly.

 A reasonable number of diodes in the matrix columns does not exceed 3-6, and the optimal number of parallel-connected diodes in a row is 4-10 and is determined by the operating current of the diodes and the permissible (nominal) output current of the power source. The operating voltage of such a matrix of semiconductor emitting diodes is in the range 5.5-12.0 V, that is, the matrix can be powered from a low-voltage battery or power supply with a step-down transformer. Therefore, during operation, a device with a low supply voltage of a few volts is brought to the patient’s body, which ensures a high level of electrical safety for the operation of the device.

 Thus, the listed features provide the physiotherapeutic apparatus with high reliability and electrical safety while maintaining therapeutic efficacy in case of possible failure of part of the emitting diodes in the matrix.

 Further, the invention is illustrated by drawings.

 In FIG. 1 shows an electrical diagram of the proposed physiotherapeutic apparatus with a polar power source, an electrical circuit with washing an array of diodes with alternating current is shown in FIG. 2. Figure 3 shows a fragment of a matrix with a diode equipped with a quenching resistor. Figure 4 shows a diagram of the experimental tests of the matrix, and figure 5 illustrates the results of the experiment.

One of the possible versions of the apparatus (Fig. 1) contains a polar power source - 1, a matrix of emitting diodes - 2, sequentially connected contracts - 3 parallel unipolar emitting diodes. Diodes can be of any spectrum from the therapeutically active wavelength range of 400 - 1600 nm, and their number in contracts (m ₁ , m ₂ ..... m _n ) is selected based on the approximate equality of the sum of the operating currents of unipolar contract diodes to the full current in this direction through the matrix, and the number of contracts is selected based on the approximate equality of the sum of the nominal voltage of the contracts to the output voltage of the power source.

 In the general case, the excess voltage can be suppressed with the help of a quenching resistor both in the circuit of a separate diode (Fig. 3) and at the input of the matrix as a whole.

 When using an AC power source (Fig. 2), the matrix diodes - 2 are turned on in each contract - 3 in parallel, in different polarity, so that there are columns in the matrix with one direction of switching on the diodes.

The experimental circuit for checking the operability of the device in case of diode failures (Fig. 4) includes the same notation, as well as 4 - a meter for the total current through the matrix and 5 - a current meter in the circuit of a separate contract diode, in which the diodes “breaks” are simulated. A matrix of red LEDs of size m ₁ = m ₂ = ... = m _n = 10, n = 5 was tested. In a contract, in the circuit of one of the diodes of which the current meter through this separate diode is connected, 1, 2, .... 9 diodes are sequentially disconnected and the total current through the matrix (I ₀ ) and the current through the i-th diode (I _i ) are measured . The experimental dependence of I ₀ and I _i on the number of "failures" of diodes of the "open" type in this series is shown in Fig. 5.

Consider, for example, what the failure of one of the diodes of any series will lead to, for example:
1) in the case when the power supply unit of the device is designed according to the current generator circuit, a diode failure, with the most likely type of failure for LEDs is of the “open” type, in any of the rows - 3 will lead to a decrease in the output optical power of the row P _o by an amount close to P _o / m _i , where m _i is the number of diodes in the indicated series. At the same time, the current in each of the diodes of the indicated series will increase by the value I _i / m _i , where I _i is the operating current in the row of diodes under consideration, and the current flowing through the entire matrix will remain constant. An increase in the current flowing through the LED leads to a proportional increase in the output optical power of the LED. Consequently, the total output optical power of the device will practically remain unchanged and it is possible to use the established methods of exposure without any fear and obtain the expected treatment result;
2) in the case when the power supply is designed according to the voltage generator circuit, failure of the diode in a row with a failure of the “open” type will increase the row resistance to the value U _i / (m _i -1) I _i , where U _i and I _i - operating voltage and currents of the diodes of the series in question, and there will be a redistribution of voltage between the rows of diodes, in which the voltage increases on this series, and decreases on other "full" rows. In this case, the output optical power of the diodes and the apparatus as a whole will be proportional to changes in the currents flowing in the diodes. The output optical parameters of the device will change very slightly and there will be no reason to limit the use of previously developed methods of therapeutic phototherapeutic exposure.

 The results of an experiment conducted for a 10x5 red LED matrix for a different number of "failed" diodes in one of the rows confirm the analysis (Fig. 5).

 The proposed technical solution was tested in a conditional experiment and was used in the manufacture of laboratory samples of LED devices for phototherapy of the Geska series. During the operation of the samples, the return of failed devices was reduced several times.

Sources of information used in compiling the description
1. Illarionov V. Ye. Fundamentals of laser therapy. - M .: Respect of the association Inoteh-Progress, 1992, p. 71-80.

 2. Patent EPO N 0672435, A 61 N 5/06, 02.94.

 3. Patent GB N 22112010, A 61 N 5/06, 11.87.

 4. The device is a portable therapeutic LED matrix for phototherapy "Dune-T". Specifications 9444-001-44240337-97.

Claims (5)

 1. Physiotherapeutic apparatus containing a power source, a number of emitting diodes with different spectra from the light and / or infrared ranges of radiation, forming a matrix of emitting diodes connected to a power source, characterized in that in it part of the diodes is connected in parallel and forms separate contracts in parallel connected emitting diodes connected in series.  2. The apparatus according to claim 1, characterized in that it indicates the parallel-connected diodes within a separate contract of the parallel-connected emitting diodes are selected identical in their rated voltage.  3. The apparatus according to claim 1, characterized in that in it in a separate contract in parallel connected diodes, at least part of the diodes is equipped with separate quenching resistors.  4. The apparatus according to claim 1, characterized in that in it the diodes in parallel connected diodes are paired in different polarity so that the diodes of the same polarity are included in the rows of the matrix.  5. The apparatus according to claim 1, 2 and 4, characterized in that in it the number of diodes in each contract is selected based on the approximate equality of the sum of the operating currents of unipolar contract diodes to the full current of this direction through the matrix, and the number of contracts is selected based on approximately the equality of the sum rated voltage of the contracts to the output voltage of the power source.

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