JPH0910330A - Phototherapic device - Google Patents

Abstract

PURPOSE: To eliminate any possibility of mistaking an intensity set member from the other members and prevent a person under a therapy from being stimulated more than necessity so as to make a device suited to domestic use by constituting, at least, a member for setting the emission intensity out of members for setting the contents of various therapy menus distinguished from the other set members. CONSTITUTION: A key for setting emission intensity of a flash emission part out of various kinds of set keys 6 which set the contents of treatment menus is surrounded with a wall 28 so as to be distinguished from the other set keys so that any possibility of mistaking the operation is eliminated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a phototherapy apparatus for irradiating a living body with a flash of flash light for treatment by physical therapy.

[0002]

2. Description of the Related Art Conventionally, as a phototherapy device of this type, a light source such as a xenon discharge tube is momentarily emitted to irradiate an affected area of the skin to apply pulsed photothermal stimulation to treat body pain. It has been known. In addition to such photothermal stimulation, there is also known a therapeutic device that applies a low frequency current by applying an electrode to an affected part to apply a low frequency current (for example, Japanese Patent Laid-Open No. 62-62,62).
-66867, JP-A-62-66872, etc.). This type of phototherapy device is composed of a treatment member (hereinafter referred to as a treatment probe) having a light emitting part mounted on an affected part, and a treatment device main body for setting and controlling treatment operation contents by the treatment probe. It

[0003]

By the way, in the above-mentioned conventional phototherapy device, a member for setting various operation contents is provided in the main body of the therapy device. It is arranged at a position apart from the setting member. This is to prevent the intensity setting member for treatment from being mistakenly operated with other members so as to prevent unnecessary stimulation of the subject. However, with this configuration, if a person who is familiar with the usage of a doctor or a nurse operates the treatment device, such a response is sufficient, but a person who does not do so, for example, an old man or a child, operates it. In some cases, it is easy to make an operation error. Furthermore, in order to put it into practical use as a household appliance, it is necessary to consider that the strength setting member will not be mistaken for other members even if anyone operates it. The present invention has been made to solve the above-mentioned problems, and a plurality of setting members are arranged in a fixed block, and at least a member that sets the emission intensity is distinguished from other setting members. By configuring as described above, it is possible to prevent the intensity setting member from being mistaken for other members, prevent the subject from being stimulated more than necessary, and provide a phototherapy device suitable as a household appliance. With the goal.

[0004]

In order to achieve the above-mentioned object, the invention of claim 1 is a phototherapy apparatus for irradiating an affected part of a living body with flash light for treatment by physical therapy. A treatment probe having a flash light emitting unit for irradiating the affected part of the living body, and a plurality of setting members for setting the contents of various treatment menus including light emission intensity by the flash light emitting unit, the plurality of setting members being arranged in a certain block In addition, at least the member that sets the emission intensity is configured to be distinguished from other setting members.

[0005]

In the phototherapy apparatus according to claim 1 having the above-mentioned structure, the contents of various treatment menus are set by operating the setting member arranged in a certain block, and the treatment probe is attached to the affected area to be set. By making the flash light emitting part emit light with the treatment menu, the affected area is photothermally stimulated for treatment. When setting the contents of various treatment menus by operating the setting member, the setting member for the emission intensity of the flash light emitting unit is configured to be distinguished from the other setting members, so that the operation is not mistaken. It is possible to prevent the thermal stimulus from being applied to the medical person with an intensity higher than necessary. In addition, regarding the intensity setting member of low frequency treatment,
The light emission intensity setting member may be configured to be distinguished from the others. In addition, as a configuration in which the emission intensity setting member is distinguished from other setting members, for example, the emission intensity setting member is surrounded by a raised wall, the color is changed, or the height is changed. Can be considered.

[0006]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an external view of the phototherapy device according to the present embodiment, FIG. 2 is a cross-sectional view of a treatment probe that is connected to the device body and attached to an affected area, FIG. 3 is a cross-sectional view of a heat dissipation hole portion of the treatment probe, and FIG. FIG. 5 is a partial cross-sectional view of a therapeutic probe according to another example, FIG. 5 is a front view of the device body, and FIG. 6 is a diagram showing contents displayed on a display unit of the device body. In these figures, the phototherapy device 1 is for applying a photothermal stimulus to a living body with flash light, or for applying a low-frequency current together with this photothermal stimulus to treat an affected area with physical therapy. A device main body 2 for storing various settings and a treatment probe 4 (4A, 4A) connected to the device main body 2 via a connector cord 3 and attached to an affected part
B).

The apparatus main body 2 includes a main switch 5, various setting keys (switches) 6, a start switch 7, a stop switch 8, a memory switch 9, an LCD display unit 10,
It has an insertion slot 12 for a memory card (IC card, magnetic card, etc.) 11, an in-treatment indicator lamp 13, a terminal 14 to which the treatment probe 4 or the conductive adhesive pad 17 is connected. The treatment probe 4 is provided with a xenon discharge tube 15 facing the front side so as to emit a pulsed flash light to irradiate the human body, and further a low frequency current (several Hz to several Hz to the front surface of the light emission part). A transparent electrode pad 16 for applying a stimulus by flowing a few kHz, a dozen mA) to the human body is attached. The therapeutic probe 4 is usually used as a pair at the same time, and the transparent electrode pads 16 of both of them serve as electrodes for passing a low-frequency current to the human body, but only one therapeutic probe 4 is used. Alternatively, in that case, the conductive adhesive pad 17 is used in combination as the other electrode for passing the low frequency current.

As shown in FIG. 2, the treatment probe 4 has a flat case 18 whose exterior is made of a plastic material or the like.
In the inside, there are provided a reflection plate 19 that reflects the light emitted from the xenon discharge tube 15, a light receiving element 20 such as a photodiode that receives the reflected light, a circuit board 21, and a main capacitor 22 for light emission. Has been. A transparent glass 23 made of quartz glass or the like that transmits the light emitted from the xenon discharge tube 15 (ultraviolet rays, visible rays, infrared rays) is provided on the front surface of the case 18, and the transparent electrode pad 16 is mounted on the front surface thereof. . The transparent electrode pad 16 is formed by applying an adhesive layer 16b on the back surface of the transparent electrode 16a, and is detachably attached to the surface of the transparent glass 23 with the adhesive layer 16b. Thus, the transparent electrode pad 1
In the type in which 6 can be attached and detached, when the present apparatus 1 is shared by a large number of people, a plurality of transparent electrode pads 16 are prepared so as to be dedicated to each person. The transparent electrode 16a is electrically connected to a circuit inside the treatment probe 4 by a conductive member.

Further, since the electrode disposed on the front surface of the light emitting portion is made of a transparent member as described above, the electrode does not block the light irradiation and the flash light can be efficiently irradiated.
By providing the flatness, it is possible to improve the wearing stability on the body. Furthermore, the region where the heat treatment by light irradiation is performed and the region where the low frequency treatment is performed are the same affected area, and the treatment effect is improved. Further, a current of several hundred amperes flows when the xenon discharge tube 15 emits light, but since the main capacitor 22 for emitting light is provided on the treatment probe 4 side, the device main body 2
A large current does not flow in the connector cord 3 as compared with the case where it is provided on the side, and the cord may be thin, and therefore the treatment probe 4 can be easily handled.

At both longitudinal ends of the front of the case 18, mounting detection switches 24 for detecting that the therapeutic probe 4 is mounted on the body are provided. The actuation piece of the attachment detection switch 24 is biased by a spring so that it is retracted when it is properly attached to the body so that the switch is opened. Further, as shown in FIG. 3, the side wall of the case 18 of the treatment probe 4 is provided with a heat radiation hole 26 to which a visible light cut filter 25 is attached. In addition, as shown in FIG. 4, the therapeutic probe 4 is directly attached to the surface of the transparent glass 23 and directly attached to the xenon discharge tube 1.
Alternatively, the transparent electrode 16a that transmits the light emitted from No. 5 may be heat-treated and coated (a powder of tin, indium or the like is sprayed on the glass surface together with a liquid, and then heat-treated). By using quartz glass as the transparent glass 23,
Since the light in the ultraviolet range is also transmitted, the therapeutic effect can be enhanced.

FIG. 5 shows the configuration of the LCD display section 10 and various setting keys 6. In the figure, the LCD display unit 1
0 is low frequency treatment A, B (alternately repeated)
Frequency, time, intensity, luminescence intensity of hyperthermia treatment by light
A menu consisting of a light emission interval and a set treatment time timer is displayed. The various setting keys 6 are arranged corresponding to the above-mentioned menus, and are used for UP / DOWN setting values. Among them, unlike other keys, the key to set the low-frequency treatment and the heat intensity by the flash light is uncomfortable when it is set by mistake due to an erroneous operation. A raised wall 28 is formed around the strength setting key so as to draw the user's attention. The key for setting the strength may have a different color to distinguish it from other keys, or may have a different height from other keys.

FIG. 6 shows the contents of each menu displayed on the LCD display section 10. In the figure, each row 6a-
6h is a content corresponding in order from the left side of the setting key 6, and corresponds to each menu displayed on the LCD display unit 10. The frequency of the treatment A is 1 kHz to 1 Hz, and the time 2.
0 to 0.1 seconds and continuous (CONT), frequency of treatment B is 25 Hz to 1 Hz and intermittent (INT), time 2.0 to 0
Second (at this time, treatment A is continuous), the intensity of treatments A and B is 30
0 to 20 V and OFF, the intensity of heat is 20 to 2 W / second and OFF, the interval is 0.2 to 5 seconds, and the timer can be adjusted within the range of 30 to 2 minutes. The value surrounded by a white frame is a preset initial value. The initial values of low frequency and heat intensity are the lowest levels. By setting the intensity of either low frequency or heat to OFF, OF
The low frequency or thermal treatment operation designated as F is not performed.

7 and 8 are views showing how to use the treatment probe 4 of the phototherapy apparatus 1. FIG. 7 shows a case of treating the lower back of a human body. A pair of treatment probes 4 are attached side by side on the inner surface of the waist of a vest 30 as elastic clothing, and the vest 30 is attached to the treatment probe 4 by the user. The transparent electrode pad 16 on the front side for irradiating the light is attached so as to directly contact the skin of the waist of the patient. The best 30
A hook-and-loop fastener on the inside of the case 18 of the treatment probe 4
It is sufficient to attach the surface fasteners to the back surface of each of the above and attach the treatment probe 4 to the vest 30 by combining the surface fasteners. FIG. 8 shows a case of treating the shoulder of a human body, and a pair of treatment probes 4 are attached side by side on the inner surface of the shoulder of the vest 30. When only one of the treatment probes 4 is used, the conductive adhesive pad 17 is used instead of the other treatment probe 4. Further, the treatment probe 4 may be attached to the human body by using a belt or a supporter, and other various methods may be adopted.

9 and 10 are circuit diagrams of the apparatus body 2 and the treatment probe 4 (4A, 4B) of the phototherapy apparatus 1. The device main body 2 includes a CPU 31 having a function of controlling the entire device such as light emission control for hyperthermia treatment and current control for low frequency treatment,
It has a card input section 32, an AC / DC converter 33 as a charging circuit for charging the light emitting main capacitor 22 provided in the power supply circuit and the treatment probe 4, and further, an operational amplifier circuit 34 for low frequency current and a pulse. It has a built-in transformer 35. The CPU 31 includes an operation signal from a switch block 36 including various setting switches 6 and the memory card 11 connected to the card input section 32.
Various data of is input. Also, the terminal H of the CPU 31
Signals corresponding to the mounting state of the treatment probe 4 by the mounting detection switch 24 and the amount of reflected light received by the light receiving element 20 are input to KA and HKB. The CPU 31 has a timer function that measures time based on various inputs. Also, C
From the gates HKGA and HKGB of the PU 31, the IGBT (Insulated Gate Bipolar Transis) in the treatment probe 4 is connected.
A signal for driving the tor) 41 to cause the xenon discharge tube 15 to emit light is output, and the pulse transformer 35 is output from the terminal TT according to the set frequency and time for low frequency treatment.
Is output, and the voltage is output from the terminal TTD / A to the input terminal of the operational amplifier circuit 34 according to the set intensity for low frequency treatment. Furthermore, CPU
Reference numeral 31 drives the LCD display unit 10, and drives the in-treatment display lamp 13 by the terminal LAMP.

The connector cord 3 between the device body 2 and the treatment probe 4 includes a charging line 3a and a mounting detection line 3
b, a light emission trigger line 3c, a ground line 3d, and a low-frequency current code 3e. The low frequency output of the pulse transformer 35 is given between the transparent electrode pads 16 and 16 via the low frequency current cords 3e and 3e. A conductive adhesive pad 17 may be used instead of the transparent electrode pad 16. An IGBT that is connected in series with the xenon discharge tube 15 and controls light emission inside the treatment probe 4 (4A, 4B).
41, a light emitting main capacitor 22 connected to the charging line 3a, a trigger transformer 42 connected in parallel with the capacitor 22 for triggering the light emission of the xenon discharge tube 15, a resistor RT for triggering, and a capacitor CT.
Etc. The light receiving element 20 has two mounting detection switches 2
4 is connected in parallel and is connected between the mounting detection line 3b and the ground line 3d. Line 3c for light emission trigger
Is connected to the base of the IGBT 41 via a reversible fuse 43.

FIG. 11 shows the structure of the memory card 11. The memory card 11 has a built-in EEPROM 51,
The preset data is stored so that an appropriate operation can be obtained when the patient is treated by the phototherapy device 1. By inserting and connecting the memory card 11 to the card input section 32, the data is read by the CPU 31, and the phototherapy apparatus 1 automatically operates with the setting data. When the phototherapy device 1 is operated without using the memory card 11, the CPU 31
Works with initial values.

Next, the operation of the phototherapy apparatus 1 configured as described above will be described with reference to the flowcharts of FIGS. 12 to 22. FIG. 12 is a flowchart showing a main flow operation after the CPU 31 is reset by turning on the main switch 5. CPU 31 is a memory card 11
Check whether or not is inserted (# 1), if it is inserted, enter the card data, set the card data, LCD
It is displayed on the display unit 10 (# 2). If the memory card 11 is not inserted, the initial value is set and displayed (#
3). Next, key input processing is performed (# 4). Note that, as described above, the setting value at the time of previous use is automatically set only by inserting the memory card 11, which is convenient. FIG. 13 shows another example of the main flow, the details of which will be described later.

FIG. 14 shows a flowchart of the key input processing subroutine. In the key input process, the memory switch 9 is turned on (# 41), the stop switch 8 is turned on (# 42), and the treatment timer setting switch is turned on.
(# 43), OF of card mounting switch (not shown)
F to ON (# 44), flash intensity switch ON
(# 45) and ON of other switches (# 46) are sequentially checked. When each switch is turned on, memory switch processing (# 50), stop switch processing (# 60), treatment timer setting switch processing (# 70), card mounting switch processing (# 80), thermal strength switch processing (# 9)
0) and other mode settings, that is, setting of frequency, time and intensity of low frequency treatment (# 47).

In the memory switch process (# 50), as shown in FIG. 15, if the memory card 11 is inserted (YES in # 51), the current setting conditions are transferred to the card 11 (# 50). 52), the process returns.
As a result, the set value at that time is automatically stored, so that the data can be used next time.

In the stop switch process (# 60), as shown in FIG. 16, the low frequency output is turned off (# 6
1), stop the light emission interval timer (# 62), stop the wearing timer count (# 63), stop the treatment timer count (# 64), turn off the treatment lamp 13 (# 65), The flow moves to A, that is, # 5.

Treatment timer setting switch processing (# 70)
, The UP switch is turned on as shown in FIG.
Is checked (# 71), if it is ON, the current setting value is 2 minutes (time to increase by turning ON the UP switch once).
It is checked whether the value obtained by adding (the new setting value) does not exceed the value obtained by subtracting the count value of the mounting timer from 30 minutes up to that point (# 72).
O), the timer setting is increased by one step (# 73), the display of the treatment timer is changed (# 76), and the process returns. If the determination in # 72 is YES, no further UP setting is performed and the process returns. DO in # 71
If the WN switch is ON, check whether the timer setting is 2 minutes (minimum value) (# 74). If not, DOWN the timer setting by one step (# 75), # 76.
Proceed to. If the determination in # 74 is YES, the settings below are not performed and the process returns.

In the card mounting switch process (# 80), as shown in FIG. 18, the low frequency output is turned off (# 81), the light emission interval timer is stopped (# 82), and the mounting timer count is stopped. (# 83), the treatment timer stops counting (# 84), the treatment lamp 13 is turned off (# 85), card data is input, each mode is set, and the display is changed (# 86). A, that is, move to # 5.

In the heat intensity switch process (# 90), as shown in FIG. 19, it is checked whether or not the UP switch is ON (# 91), and if it is ON, the heat intensity maximum value described later in FIG. 21 is reached. (# 92). The maximum value of thermal intensity is set to 20 Ws at reset. If it is not the maximum setting (NO in # 92), set the strength setting to 1 level U
P (# 93), the intensity display is changed (# 98), and the process proceeds to # 99 and below. Strength setting UP and DOWN are I
This is performed by adding or subtracting a predetermined amount of gate on-time data TMG of the GBT 41. If the DOWN switch is ON in # 91, check whether the strength setting is OFF (# 9
4) If it is not OFF, the intensity setting is 2 watts / second (W
s) is checked (# 95), and if not, the strength setting is DOWN by one step (# 96), and the process proceeds to # 98. # 9
If the judgment of 5 is YES, the DOWN of the set value less than that
N is not performed, the intensity setting is turned off (# 97), and the process proceeds to # 98. If the determination at # 92 is YES, no further setting is made and the process proceeds to # 99 and below.

The processing after # 99 is to limit the setting of the thermal intensity, that is, the light emission amount and the light emission interval to a combination that does not cause low-temperature burns and high-temperature burns. First,
It is checked whether the intensity is 20 Ws or more (# 99), and if so, it is checked whether the light emission interval is 1.0 second or less in order to limit the light emission interval to the shortest 1.0 second (# 101). If so, since the interval is too short, the light emission interval is set to 1.0 second (# 102), and the light emission interval display is changed (# 1
03). If it is not 1.0 seconds or less in # 101, the process directly proceeds to # 103. Next, it is checked whether the intensity is 18 Ws or more (# 104), and the light emission interval is limited to the shortest 0.5 second (# 105). Further, the same process is performed when the strength is 16 Ws or more. FIG. 20 is a table showing the processes performed in the above steps # 99 and below, and the portions marked with “X” are too strong, so that the combination is prohibited. In addition, by appropriately adjusting the light emission amount and the light emission interval, for example, a person with dark skin color has a small light amount and a short interval, and a person with white skin color has a large light amount and a long interval. By that,
High-temperature burns and low-temperature burns are not caused, and effective treatment can be performed.

Referring back to FIG. 12, the flow after the key input process (# 4) will be described. In # 5, 2
Whether or not the individual treatment probes 4 (A, B) are attached to the body is checked by the attachment detection switch 24, and if they are attached, the start switch 7 is waited for being turned on (#
6). If not, reset the wearing timer that measures the wearing time, that is, the cumulative treatment time (# 7),
Return to # 4. When the start switch 7 is turned on (# 6
YES), the reflectance measurement / light amount limitation processing is performed (#
8). This process is performed in order to check the amount of reflected light and appropriately set the emission intensity, because the heat absorption by light irradiation differs depending on the color of the skin of the subject. Further, as described above, since it is possible to start the subsequent treatment operation only after it is confirmed that the treatment probe 4 is attached to the body, it is possible to directly see the flash light emission by an erroneous operation. Will disappear.

The above-mentioned # 8 reflectance measurement / light amount limitation subroutine processing will be described with reference to FIG. The CPU 31 sets the terminals HKA and HKB as A / D conversion input terminals (# 111), and thereafter performs a process of causing light emission with the minimum light emission amount for reflectance measurement. That is, the gates HKGA and HKGB are set to high (Hi) to start light emission (# 112), and the minimum value TMGmin of the gate ON time data is set in the internal register A (# 113).
The value of register A is decremented by 1 (# 114), and # 114- #
The subtraction is repeated in the loop of 115, and the value of register A becomes 0.
Then, the gates HKGA and HKGB are set to low (Lo) to stop light emission (# 116). Next, the terminal HKA
, HKB input voltage is A / D converted (# 11
7) Check whether each input voltage of the terminals HKA, HKB is above a predetermined value (whether the integrated value of reflected light is below a predetermined value) (# 118,
# 119), and when the input voltage is not more than the predetermined value, (# 119)
No. 118, No. 119), there is a lot of reflected light, and it is considered that the person has a white skin color.
Set to Ws (# 120).

When any of the input voltages is equal to or higher than a predetermined value (YES in # 118 and # 119), the reflected light is small,
It is considered that the person with dark skin color has more heat absorption than the former, so the maximum heat intensity is limited to 14 Ws (# 121), and if the current set value is 16 Ws or more (in # 122, YES), set the heat intensity to 14 Ws,
The display is changed (# 123) and the process returns to the main flow. If it is not 16 Ws or more (NO in # 122), the process immediately returns to the main flow. By performing the above-described reflectance measurement / light amount limitation, the light amount can be suppressed when the skin color is dark, so that high-temperature burns are not caused by one light emission.

Returning to FIG. 12, description will be made again. # 8 above
After the reflectance measurement / light amount limitation processing of the
A treatment timer for measuring the treatment time and a light emission interval timer for measuring the light emission interval are started (# 9). Further, the treatment lamp 13 is turned on (# 10), the treatment timer display is set to subtract and displayed (# 11), and the low frequency treatment is started (# 12). Low frequency treatment is CPU31
The voltage corresponding to the setting is output from the terminal TT and the terminal TTD / A, and the pulse transformer 35 is driven. Output of pulse transformer 35, that is, treatment voltage Vout
Is provided between the transparent electrode pads 16 and 16 and the CPU 3
The output voltage V (TTD / A) of the first terminal TTD / A, the primary winding n0 of the pulse transformer 35, the secondary winding n1, the resistor R1,
From R2, it is expressed by the following equation. Vout = (n1 / n0) {(R2 / R1) V (TTD / A
) + V (TTD / A)}

Next, if the wearing time, that is, the treatment time exceeds a predetermined time, there is a risk of causing burns or the like due to excessive thermal action. Therefore, in order to limit the treatment time, the wearing time measured by the wearing timer is set. However, it is checked whether or not the time has exceeded a preset time (for example, 30 minutes) in the device (# 13). This determination may be made by detecting that the skin temperature, blood pressure, and heart rate of the subject have reached a certain level or higher, instead of the wearing time. The configuration for detecting these will be described later. If it is determined in # 13 that the wearing time does not exceed the predetermined time, then it is checked whether or not the treatment time set in the treatment timer has ended (# 14). If the treatment time has not ended (NO in # 14). , Check if the set firing interval timer has counted up (#
15) If you count up (YES in # 15),
A light emission control process is performed to perform heat treatment (# 16). Details of this light emission control will be described later.

When the light emission interval timer is not counting up (NO in # 15) or after the light emission control processing, the same key input processing as described above is performed (# 17), and the same as in # 5 above. , Whether or not the treatment probes 4 (A, B) are both attached to the body is checked by the attachment detection switch 24 (# 18). If the determination is YES, the process returns to # 12 and the above processing is repeated. Treatment is usually performed in this loop. On the other hand, if the determination is NO, then it is checked whether or not the treatment probes 4 (A, B) have both left the body for a predetermined time, for example, 5 seconds or more (# 19), and this determination is N.
If it is O, the process returns to # 12 and the above process is repeated, but if the determination is YES, the maximum value of the heat intensity is set to 20 Ws (# 195) and the mounting timer is reset (# 2).
0). In # 195, the time for determining that the treatment probes 4 (A, B) are both separated from the body is set to 5 seconds or more. If the time is shorter than that, the mounting position of the treatment probe 4 is slightly displaced. Since the treatment of almost the same region is performed, the mounting timer is not reset, but when the distance is more than 5 seconds, the mounting position of the treatment probe 4 is moved in most cases, Since the color of the skin changes when it is attached to a different part, the maximum value of thermal strength is set to 20 Ws and the attachment timer is reset.

When the mounting timer is reset at # 20, the treatment lamp 13 is turned off (# 21), the treatment timer display is set to the set value (# 22), and the low frequency treatment is turned off (# 23). After stopping the wearing timer (# 24), #
Returning to step 4, the same processing is repeated thereafter. Also, # 13
In the case where the wearing time is 30 minutes or more, a warning is displayed by blinking the treatment lamp 13 or the like in order to prevent low temperature burns or the like from occurring (# 25), and
The light amount is set to half the set value (# 26), and then the process proceeds to # 18. As a result, it is possible to prevent treatment at the same site for a certain period of time or longer, and to prevent low-temperature burns. Therefore, non-specialists in general households can easily receive treatment. If the set treatment time ends in # 14, the process proceeds to # 21.
Proceed to.

The light amount restriction in # 26 may be performed by increasing the light emitting interval or controlling both the light amount and the interval. Further, even if the treatment time is set to a short time, for example, 10 minutes, if the treatment is repeatedly performed on the same site many times, a warning message is displayed when the wearing time exceeds 30 minutes. It has become so. That is,
When the first treatment time has passed 10 minutes, the determination in # 14 is Y.
When the ES becomes ES, the process proceeds to # 21, and after passing through # 22 to # 24, the mounting timer is stopped without being reset, and # 4
When the treatment time is set to 10 minutes again in the key input processing and the treatment operation is started again, the mounting timer accumulates the mounting time and measures the time. In this way, when the operation for 10 minutes for the treatment time is performed three times in total, # 1
In 3, the mounting time becomes 30 minutes or more, and a warning is displayed in # 25.

Next, regarding the light emission control processing of # 16,
This will be described with reference to FIG. When entering this process, first,
Check if the strength setting is OFF (# 161), then OFF
If not, the data T for the set gate ON time is set.
MG is set in register A (# 162) and gate HKG
A and HKGB are set to Hi (# 163), the value of the register A is decremented by 1 (# 164), the subtraction is repeated in the loop of # 164 to # 165, and when the value of the register A becomes 0, the gates HKGA and HKGB are set. It is set to Lo and the light emission is stopped (# 166). After that, the data of the light emission interval timer count is read (# 167), the light emission interval timer is started (# 168), and then the process returns. If the strength setting is OFF in # 161, immediately
Proceed to 67.

FIG. 13 shows a modification of the main flow of FIG. This modified example is different from the above example in that when the mounting time is 30 minutes or more in # 13, #
After displaying the warning message at 25, the procedure proceeds to # 22 and thereafter to stop the treatment operation.

FIGS. 23 (a), 23 (b) and 23 (c) are waveform charts showing various combinations of low frequency treatments A and B, respectively. (A) is a basic example in which treatment A and treatment B are alternately repeated, (b) is an example in which treatment A is continuous, and (c) is treatment B in intervals and treatment A is intermittent. It is an example that operates automatically.

FIG. 24 shows a circuit configuration for detecting the skin temperature. In # 13 of FIG. 12 above, when the wearing time is detected and a predetermined time is exceeded, a warning is issued, and the treatment is automatically limited to prevent low temperature burns, etc. It is also possible to detect the skin temperature of the site to which the hyperthermia treatment is given and judge that the skin temperature is abnormal when the skin temperature exceeds a predetermined value and stop the treatment. In this example, a microcomputer 50 (a microcomputer, which corresponds to the CPU 31 in FIG. 9) is provided in the main body 2, and a diode 51 for measuring an ambient temperature and infrared rays emitted from the skin are incident on the treatment probe 4. A thermocouple (thermopile) 52 that generates a voltage corresponding to the amount is provided, and the detection outputs of both are input to the microcomputer 50 through the amplifier 53, and the microcomputer 50 can detect the temperature of the skin. The thermocouple 52 is the light receiving element 20.
It should be placed at the same position as.

FIGS. 25 (a) and 25 (b) show the configuration of the heart rate detecting circuit and its external configuration. Instead of detecting the wearing time as described above, the heart rate may be detected, and when the heart rate exceeds a certain value, it may be determined that the physical condition is abnormal and the treatment may be stopped. In this example, the member 54 attached to the wrist has elasticity, a pressure sensor 55 and an amplifier 56 are provided in the member 54, and the member 54 is connected to the microcomputer 50 of the main body 2 via a cord 57. The heart rate is detected by the pressure sensor 55, and the detection output is counted by the microcomputer 50.

The present invention is not limited to the configuration of the above embodiment, and various modifications can be made. For example, in the above embodiment, the xenon discharge tube 15 is used as the flash light for performing the thermal treatment.
Xenon light is used, which is desirable in terms of its good transparency to living bodies, but is not limited to this, and an infrared lamp or the like may be used. The circuit for charging the main capacitor 22 for light emission may be provided on the treatment probe 4 side or may be driven by a battery. Further, for low-frequency treatment, treatment with high-frequency current is also possible, and in the above-mentioned embodiment, the one provided with both hyperthermia treatment and low-frequency treatment was shown, but the present invention can perform only hyperthermia treatment. It is applicable to devices.

[0039]

As described above, according to the phototherapy device according to the invention of claim 1, a plurality of setting members for setting the contents of the treatment menu are arranged in a certain block, and at least the light emission intensity among them is set. Since the member to be set is configured to be distinguished from the other setting members, the strength setting member is not mistaken for other members, and it is possible to prevent the user from being stimulated more than necessary. It is suitable as a device for use.

[Brief description of the drawings]

FIG. 1 is an external view of a phototherapy device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a treatment probe connected to the apparatus body and attached to the affected area.

FIG. 3 is a sectional view of a heat dissipation hole portion of the treatment probe.

FIG. 4 is a partial cross-sectional view of a therapeutic probe according to another example.

FIG. 5 is a front view of the apparatus main body.

FIG. 6 is a diagram showing contents displayed on a display unit of the apparatus body.

FIG. 7 is a view showing a method of using the treatment probe of the phototherapy device.

FIG. 8 is a diagram showing a method of using the treatment probe of the phototherapy device.

FIG. 9 is a circuit diagram of a device body of the phototherapy device and a treatment probe.

FIG. 10 is a circuit diagram of a device body of the phototherapy device and a treatment probe.

FIG. 11 is a diagram showing a configuration of a memory card.

FIG. 12 is a main flowchart showing the operation of the phototherapy device.

FIG. 13 is a flowchart showing another example of the main flow.

FIG. 14 is a flowchart of key input processing.

FIG. 15 is a flowchart of a memory switch process.

FIG. 16 is a flowchart of a stop switch process.

FIG. 17 is a flowchart of a treatment timer setting switch process.

FIG. 18 is a flowchart of a card mounting switch process.

FIG. 19 is a flowchart of a heat intensity switch process.

FIG. 20 is a diagram showing a content of limiting a combination of a light emission amount and a light emission interval.

FIG. 21 is a flowchart of reflectance measurement / light amount limiting processing.

FIG. 22 is a flowchart of a light emission control process.

23 (a), (b) and (c) are waveform charts of various combinations of low frequency treatments A and B, respectively.

FIG. 24 is a configuration diagram of a skin temperature detection circuit.

25 (a) and 25 (b) are a configuration of a heart rate detection circuit and an external configuration diagram thereof.

[Explanation of symbols]

 1 Phototherapy device 2 Device body 4 (4A, 4B) Treatment probe 6 Various setting keys (setting member) 15 Xenon discharge tube (flash light emitting part) 28 Wall

Claims (1)

[Claims] 1. A phototherapy device for irradiating an affected part of a living body with flash light for treatment by physiotherapy, a therapeutic probe which is attached to the affected part and has a flash emitting part for irradiating the affected part of the living body with flash light; With a plurality of setting members for setting the contents of various treatment menus including the light emission intensity by the section, the plurality of setting members are arranged in a certain block, and at least the member for setting the light emission intensity is A phototherapy device characterized in that it is configured to be distinguished from the setting member.