KR20060034490A - Low power laser radiator with an approach sensor - Google Patents

Abstract

The present invention attaches a sensor made of a light receiving element to a commercially available low-power laser irradiator for the treatment of simple symptoms, thereby enabling the on-off operation according to the distance so that the laser light is irradiated only at a close distance. It starts.

According to the present invention, since the output of the home low power laser irradiator mainly uses the wavelength of the infrared region which is not detectable by humans, the laser is only applied at close range, which is the actual treatment range, to prevent accidents irradiated to the user's eyes. It is to provide a low power laser irradiator with a distance sensor to operate.

The present invention is to install a therapeutic infrared laser diode on the handpiece of the low power laser irradiator, the detector is installed in response to the wavelength of the laser beam around the laser diode to automatically operate when the irradiation distance of the therapeutic laser is far away. We propose a low power laser irradiator with a safety device to stop it.

Accordingly, in the present invention, since the laser operates only at close distances when treating various disease symptoms by the low power laser, it is possible to safely use the laser irradiator at the treatment site so as not to injure the eyes of the user or the neighbors due to carelessness. .

Description

Low Power Laser Radiator with an Approach Sensor {Low Power Laser Radiator with an Approach Sensor}

1 is an explanatory diagram of a main incision showing a conventional low-power laser irradiator for home.

Figure 2 is a circuit diagram showing the electrical configuration of a conventional low-power laser irradiator or hair growth laser treatment device.

Figure 3 is an explanatory view showing a conventional hair growth laser treatment device.

Figure 4 is a partial cutaway explanatory view showing the main portion of the handpiece of the laser irradiator according to the present invention.

5 is a circuit diagram showing an electrical configuration of a laser irradiator according to the present invention.

6 is an exemplary view showing a method of operating a laser irradiator according to the present invention.

Figure 7 is a partial cutaway explanatory view showing the main portion of the handpiece of the laser irradiator according to another embodiment of the present invention.

8 is a circuit diagram showing an electrical configuration of another embodiment according to the present invention.

9 is an exemplary view showing a method of operation according to another embodiment according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: laser diode 2: reset button

3: Nozzle 4: Gripping part

5: body 6: plug

7: Jack 8: Handpiece

9: power switch 10: time setting button

11: output button 12: photosensitive sensor

13: Control unit 14: Ultrasonic transmitter

15: ultrasonic receiving element

The present invention relates to a low power laser irradiator with a proximity sensor, and more particularly to a low power laser irradiator with a proximity sensor for enabling the safe use of a hospital or home or portable low power laser irradiator.

As is known, in recent years, low-power laser irradiators for treating tinnitus, rhinitis, and hair growth laser irradiators for treating baldness are widely used in hospitals. In addition, a low power laser irradiator used as a treatment aid for biostimulation, anti-edema, anti-inflammatory, and analgesia is widely used in homes. Most low-power laser irradiators used in hospitals and hospitals use semiconductor lasers that operate mainly in the infrared wavelength range. The risk of accidents is also increasing. As an example, the hair growth promoting laser uses an infrared wavelength of 890 nm, and since the home low power laser irradiator uses the same infrared wavelength, it cannot be confirmed with the naked eye. In addition, since the laser used in the laser irradiator is a semiconductor laser and operates at a very small power, the laser cannot be sensed at all even when directly irradiated to the living tissue. Accordingly, there is a risk of unconsciously looking into the eyes. On the other hand, since the laser has a very high straightness in one direction, even a weak output can be directly focused on the retina by the lens, and energy can be concentrated in the retina, a sensitive and fragile tissue, which can cause fatal damage. have.

The prior art that can overcome this disadvantage is to confirm the operation of the laser by simultaneously emitting the LED in the visible light region connected in series with the semiconductor laser to check the output, as shown in Figures 1 and 2 A low power laser irradiator (Korean Patent No. 0400272) capable of continuously checking operation has been proposed, which installs a laser diode 101 in the handpiece 100 of the low power laser irradiator, but is electrically connected in series with the laser diode 101. The light emitting diode 102 is provided, and the light emitted by the light emitting diode 102 is irradiated in the direction of the arrow as shown in FIG. 1 to allow the user to recognize that the output of the laser diode 101 is currently generated. It will be possible.

However, according to the low power laser irradiator that can continuously check the operation, it is helpful for the user to recognize the operation.However, since the laser is continuously output at the front end of the handpiece until the power switch is turned off, the user can handle the handpiece. Inadvertently there is a problem that you can not completely rule out the possibility that the laser of the handpiece is directly irradiated to the eye of the person or others.

3 shows a handset of the hair growth laser treatment device. This is a low power laser diode 200 is installed in the center, the high brightness LED 201 is installed on both sides to enable photodynamic therapy. On the other hand, this means that the handset of the laser treatment device is brought close to the scalp, and low level laser therapy is performed to obtain a biostimulation effect, thereby promoting hair growth. Frequently, there is a problem that the risk of injuring the retina remains frequent.

SUMMARY OF THE INVENTION An object of the present invention is to provide a low power laser irradiator with a proximity sensor to prevent the laser output when no object exists within a predetermined distance in front of the low power laser irradiator handpiece.

In order to achieve the above object, the present invention is connected to the output of the oscillation circuit and the oscillation circuit, in the known one having a handpiece equipped with one or more laser diodes for outputting a laser,

We propose a low-power laser irradiator with proximity sensor built-in distance sensor inside the handpiece.

Accordingly, the present invention is to stop the laser generation immediately when no object is present within a treatable distance within 3 cm from the front of the handpiece for example, so that the user actually starts the treatment before or after the treatment is completed. As soon as the piece is separated from the affected part, the laser operation is stopped to enable safe handling, thereby preventing inadvertent retinal injury, and the effect can be used with confidence.

Referring to the present invention in detail according to the accompanying drawings as follows.

3 and 4 show the overall configuration of the present invention. As can be seen from the above, the present invention provides a laser diode 1 for generating a laser, a nozzle 3 for guiding a laser beam, a gripping portion 4 for receiving them, and an electrical connection with the main body 5. A handpiece 8 having a plug 6 for the plug, a jack 7 into which the plug 6 of the handpiece 8 is inserted, and a power switch for controlling the power supply to the handpiece 8 9), a time setting button 10 for setting the operation time, an output button 11 for controlling the laser output and a control unit 13 built in the main body to control the overall operation,

On one side of the front end of the handpiece 8 is composed of at least one photosensitive sensor 12 for receiving the laser reflected wave as a proximity sensor, and a control unit 13 connected to the photosensitive sensor 12.

The present invention as described above first operates the power switch 9 for operation, and then press the time setting button 10 to set the time when the laser output is generated time setting button 10 consisting of time increasing and time decreasing buttons It is possible to set the optimum operating time by appropriately pressing the two buttons, and this setting data is stored by the control unit 13. Subsequently, when the user presses the output button 11 close to the skin of the handset 8 and presses the output button 11, as shown in Fig. 5, the operation of the control unit 13 causes the operation to be waited for a set time of, for example, 3 seconds. The control unit 13 supplies power to the laser diode 1 of the handpiece 8 so that the laser is output for a short time. Therefore, the infrared laser reaches the skin in a state where the nozzle 3 of the handpiece 8 is brought close to the application site of the body, thereby obtaining an adjuvant therapeutic effect as described above. In this state, the infrared laser outputted from the laser diode 1 of the handpiece 8 reaches the skin, and a large part of the infrared laser penetrates and serves as a treatment aid function as described above, and part of it is reflected and scattered. This reflected infrared laser reaches the photosensitive sensor 12 provided at the front end of the handpiece 8 when the front end of the handpiece 8 is at an effective distance to obtain an assisted therapeutic effect. An output signal is generated, which is applied to the control unit 13, and the control unit 13 is compared with a reference value by means of a comparison function implemented by hardware or software so that the front end of the handpiece 8 is normally applied. By touching the site, you can see whether the infrared laser is being irradiated normally. When it is determined that the infrared laser is normally applied by the signal level output from the photosensitive sensor 12 as described above, the control unit 13 normally supplies power to the laser diode 1 for a set time, thereby providing a treatment aid function. This should be done normally. In addition, after the set time has elapsed, it is determined whether the output signal of the infrared laser, which is the reflected light incident on the photosensitive sensor 12, is present, and when the reflected light is incident, the operating power is supplied to the laser diode 1 again. It is to repeat the above process.

On the other hand, when the front end of the handpiece 8 is outside the effective distance to obtain the auxiliary treatment effect, the infrared laser output reaching the photosensitive sensor 12 installed at the front end of the handpiece 8 is weak, and this state Is applied to the control unit 13, and the control unit 13 recognizes that this signal level is compared with the reference value and that the front end of the handpiece 8 is now normally isolated from the application site, and to the laser diode 1 It cuts off the power supply for a set time, determines whether the reset button 2 of the handset is pressed again, and if the reset button 2 is pressed, returns to the above-described process of returning to the standby state. When the reset button 2 is not pressed, the process of cutting off the power supplied to the laser diode 1 for a predetermined time is repeated.

4, the photosensitive sensor 12 as a proximity sensor is directly connected to the control unit 13, and the functions as described above are performed by hardware or software such as a comparator built in the control unit 13, If necessary, the comparator may be installed between the photosensitive sensor 12 and the control unit 13 to be practical.

In addition, another embodiment of the present invention is shown in Figures 6 and 7. As can be seen from this embodiment, the ultrasonic transmitting element 14 and the ultrasonic receiving element 15 are used as the proximity sensor, and these are installed in front of the handset, and the ultrasonic receiving element 15 is provided with a control unit ( 13). In this embodiment, as shown in FIG. 8, an external A / D converter for converting the intensity of the ultrasonic wave incident on the ultrasonic receiving element 15 into the digital signal after the ultrasonic wave emitted from the ultrasonic wave transmitting element 14 hits the applied skin. Or built into the control unit 13.

In the present invention according to this embodiment, since the ultrasonic wave is fired by first supplying power to the ultrasonic transmitting element 14 in a state where the power switch is turned on, when the user approaches the handset within a predetermined distance or less, ultrasonic waves are applied. Ultrasound reflected by the receiving element 15 is incident to a predetermined level or more. Accordingly, the control unit 13 in the present invention recognizes that the reflected ultrasonic wave of a predetermined level or more is input and immediately supplies the operating power to the laser diode for a set time.

In this way, after the set time has elapsed, the output level of the ultrasonic receiving element is again determined to determine whether to supply power to the laser diode, and as a result, when the output level of the ultrasonic receiving element is less than or equal to the setting level, the setting is performed. After elapse of time, the ultrasonic incidence level signal of the ultrasonic receiving element is again determined, and according to the result, it is determined whether or not the power is supplied to the laser diode.

In this way, the present invention can eliminate the risk of irradiating the laser to the eye of the user or people around because the low power laser irradiator operates normally only when it is in contact with or in proximity to the treatment target area and automatically shuts off when it moves away. There is a useful effect that can be used safely.

Claims (3)

A laser diode (1) for generating a laser, a nozzle (3) for guiding a laser beam, a gripping portion (4) for accommodating them, and a plug (6) for electrical connection with the main body (5) The handpiece 8, the jack 7 into which the plug 6 of the handpiece 8 is inserted, the power switch 9 for interrupting the power supply to the handpiece 8, and the time for setting the operation time In the well-known thing consisting of the setting button 10, the output button 11 which controls a laser output, and the control unit 13 built in the main body and controlling overall operation, A low power laser irradiator with a proximity sensor, characterized in that one side of the front end of the handpiece (8) has at least one proximity sensor for receiving a laser reflected wave as a proximity sensor, and a control unit (13) connected to the proximity sensor. The method of claim 1, The electrical proximity sensor is at least one photosensitive sensor (12) and has a reset button (2) attached to the handset (8). The method of claim 1, Low-power laser irradiator with proximity sensor, characterized in that the electrosensitive sensor is an ultrasonic transmitting element (14) and ultrasonic receiving element (15).

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