CN217611385U - Laser therapeutic instrument handle with infrared temperature measurement system - Google Patents

Abstract

The utility model relates to a laser therapeutic instrument handle with an infrared temperature measurement system, which is used for a laser therapeutic instrument and comprises a handle and a temperature control component; the handle is provided with a receiving end and a transmitting end, and the receiving end of the handle is connected with the laser therapeutic apparatus and used for receiving laser emitted by the laser therapeutic apparatus and transmitting the laser to a target area from the transmitting end; the temperature control assembly comprises an infrared temperature measuring probe and a controller, the infrared temperature measuring probe is arranged on the handle, a detection end of the infrared temperature measuring probe points to the emission end and is used for detecting the temperature of a target area, the infrared temperature measuring probe is electrically connected with the controller, and the controller is electrically connected with the laser therapeutic apparatus and is used for adjusting the power of the laser therapeutic apparatus according to the temperature detected by the infrared temperature measuring probe; the problem of inconvenient use because the treatment scheme of the host can not be dynamically corrected after being set and needs to be adjusted by a doctor in real time is solved.

Description

Laser therapeutic instrument handle with infrared temperature measurement system

Technical Field

The utility model relates to a laser treatment instrument technical field especially relates to a take laser treatment instrument handle of infrared temperature measurement system.

Background

The lattice laser therapeutic instrument is a beautifying instrument for removing acne scars, has the functions of super pulse and laser scanning output, can rapidly and accurately carry out various fine laser operations, and is suitable for human body plastic and facial beautifying operations. The high-speed graph scanner equipped in the dot matrix laser therapeutic apparatus system can scan and output graphs with different shapes, and can provide personalized therapeutic schemes according to the requirements of different patients.

For example, the utility model patent of application number CN215938807U provides a universal regulation formula medical laser therapeutic instrument, wherein, the rotation bracing piece is placed laser emitter in the connecting plate upper end, thereby rotates the fixed plate with the slide bar downstream, with the laser emitter centre gripping in the sponge piece inboard, will carry the inboard antiseptic solution of appearance to carry on the sponge piece through the conveyer pipe to disinfect laser emitter, be worth the power to push away.

However, the therapeutic scheme of the host cannot be dynamically corrected after being set, and needs to be adjusted by a doctor in real time, for example, the patient feels a burning sensation, the doctor stops outputting immediately, and the doctor starts the therapeutic scheme after reducing power, so that the therapeutic scheme is inconvenient to use.

SUMMERY OF THE UTILITY MODEL

In view of this, it is necessary to provide a laser treatment instrument handle with an infrared temperature measurement system, so as to solve the problem that the treatment scheme of the host cannot be dynamically corrected after being set, and needs to be adjusted by a doctor in real time, which is inconvenient to use.

The utility model provides a laser therapeutic instrument handle with an infrared temperature measurement system, which is used for a laser therapeutic instrument and comprises a handle and a temperature control component; the handle is provided with a receiving end and a transmitting end, and the receiving end of the handle is connected with the laser therapeutic apparatus and used for receiving laser emitted by the laser therapeutic apparatus and transmitting the laser to a target area from the transmitting end; the temperature control assembly comprises an infrared temperature measuring probe and a controller, the infrared temperature measuring probe is arranged on the handle, a detection end of the infrared temperature measuring probe points to the transmitting end and is used for detecting the temperature of a target area, the infrared temperature measuring probe is electrically connected with the controller, and the controller is electrically connected with the laser therapeutic apparatus and is used for adjusting the power of the laser therapeutic apparatus according to the temperature detected by the infrared temperature measuring probe.

Further, the handle includes casing, laser receiver and goes out light spare, laser receiver with go out light spare all with casing fixed connection, laser receiver's one end and laser treatment instrument are connected, laser receiver's the other end with the inside of casing is linked together for carry laser to the inside of casing, go out light spare one end with the inside of casing is linked together, it is regional to the directional target of the other end of light spare, be used for with the laser of the inside of casing is carried to the target area.

Further, the housing is detachably connected with the target area through a fixing part.

Furthermore, the laser receiver comprises an optical fiber and a connecting seat, one end of the optical fiber is connected with the laser therapeutic apparatus, and the other end of the optical fiber is communicated with the inside of the shell through the connecting seat.

Furthermore, the handle further comprises a light guide part, the catheter part is arranged in the shell, the light guide part is provided with a light guide surface, and an extension line of light rays in the laser receiver and an extension line of light rays in the light emitting part are intersected on the light guide surface.

Furthermore, the light guide part comprises a lens barrel and a reflective lens, the lens barrel is fixedly arranged in the shell, the reflective lens is fixedly connected with the lens barrel, and one side of the reflective lens, which is far away from the lens barrel, forms the light guide surface.

Furthermore, the infrared temperature measuring probe is rotatably connected with the handle, and a detection area formed by rotating the detection end of the infrared temperature measuring probe covers the target area.

Further, the controller comprises a PCB circuit board, a nixie tube and a button, the PCB circuit board is fixedly arranged on the handle, the nixie tube and the button are installed on the PCB circuit board, the PCB circuit board is electrically connected with the infrared temperature measuring probe and used for receiving temperature signals, and the PCB circuit board is electrically connected with the laser therapeutic apparatus and used for controlling the power of the laser therapeutic apparatus.

Further, the controller still includes a membrane paper, the membrane paper lay in on the handle, the membrane paper with form a protection chamber between the handle, place in PCB circuit board, charactron and the button in the protection chamber.

Furthermore, the temperature control assembly further comprises an imaging probe, wherein the acquisition end of the imaging probe points to the emission end and is used for acquiring an image of a target area, and the imaging probe is electrically connected with the controller.

Compared with the prior art, the handle has a receiving end and a transmitting end, the receiving end of the handle is connected with the laser therapeutic apparatus, the laser therapeutic apparatus is used for receiving laser emitted by the laser therapeutic apparatus, the laser is transmitted to a target area from the transmitting end, the handle is matched with the laser therapeutic apparatus for use, the laser is conveniently transmitted to the target area, meanwhile, the temperature control assembly comprises an infrared temperature measuring probe and a controller through arrangement, the infrared temperature measuring probe is arranged on the handle, the detecting end of the infrared temperature measuring probe points to the transmitting end for detecting the temperature of the target area, the infrared temperature measuring probe is electrically connected with the controller, the controller is electrically connected with the laser therapeutic apparatus for adjusting the power of the laser therapeutic apparatus according to the temperature detected by the infrared temperature measuring probe, if the temperature is too high, the controller can reduce the laser emission power of the laser therapeutic apparatus, namely, the intensity of the laser is reduced, the temperature in the target area is ensured to be at a normal value, the handle of the laser therapeutic apparatus can automatically adjust the temperature, the manual adjustment process is replaced, and the use is more convenient.

Drawings

FIG. 1 is a schematic structural view of the whole embodiment of a laser therapeutic apparatus handle with an infrared temperature measurement system provided by the present invention;

FIG. 2 is an exploded view of the whole body of the laser therapeutic apparatus handle with an infrared temperature measuring system provided by the present invention;

FIG. 3 is a schematic diagram of the operation of the light guide member in this embodiment of the laser therapeutic apparatus handle with an infrared temperature measurement system according to the present invention;

fig. 4 is the utility model provides a pair of take infrared temperature measurement system's infrared temperature probe's in this embodiment of laser treatment instrument handle work schematic diagram.

Detailed Description

The following detailed description of the preferred embodiments of the invention, taken in conjunction with the accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention and not to limit the scope of the invention.

As shown in fig. 1-2, the laser therapeutic apparatus handle with an infrared temperature measurement system in the present embodiment is used for a laser therapeutic apparatus, and includes a handle 100 and a temperature control assembly 200; the handle 100 is provided with a receiving end and a transmitting end, wherein the receiving end of the handle 100 is connected with the laser therapeutic apparatus and is used for receiving laser emitted by the laser therapeutic apparatus and transmitting the laser to a target area from the transmitting end; the temperature control assembly 200 comprises an infrared temperature measuring probe 210 and a controller 220, the infrared temperature measuring probe 210 is arranged on the handle 100, a detection end of the infrared temperature measuring probe 210 is arranged towards a transmitting end and used for detecting the temperature of a target area, the infrared temperature measuring probe 210 is electrically connected with the controller 220, and the controller 220 is electrically connected with the laser therapeutic apparatus and used for adjusting the power of the laser therapeutic apparatus according to the temperature detected by the infrared temperature measuring probe 210.

The handle 100 is provided with a receiving end and a transmitting end, the receiving end of the handle 100 is connected with the laser therapeutic apparatus and used for receiving laser emitted by the laser therapeutic apparatus and transmitting the laser to a target area from the transmitting end, the handle 100 is matched with the laser therapeutic apparatus and used for conveniently transmitting the laser to the target area, meanwhile, the temperature control assembly 200 comprises an infrared temperature measuring probe 210 and a controller 220, the infrared temperature measuring probe 210 is arranged on the handle 100, a detecting end of the infrared temperature measuring probe 210 is arranged towards the transmitting end and used for detecting the temperature of the target area, the infrared temperature measuring probe 210 is electrically connected with the controller 220, the controller 220 is electrically connected with the laser therapeutic apparatus and used for adjusting the power of the laser therapeutic apparatus according to the temperature detected by the infrared temperature measuring probe 210, if the temperature is too high, the controller 220 can reduce the laser transmitting power of the laser therapeutic apparatus, namely, the intensity of the laser is reduced, so that the temperature in the target area is in a normal value, the handle 100 of the laser therapeutic apparatus can automatically adjust the temperature and replace a manual adjusting process, and the use is more convenient.

It should be noted that the target area described above refers to the skin portion of the human body with treatment.

The handle 100 in this embodiment is used with the laser therapy apparatus, and because the laser therapy apparatus is bulky, the laser can be delivered to a target area through the handle 100 so as to facilitate the treatment process.

In a preferred embodiment, the handle 100 includes a housing 110, a laser receiver 120 and a light emitting member 140, the laser receiver 120 and the light emitting member 140 are both fixedly connected to the housing 110, one end of the laser receiver 120 is connected to the laser treatment apparatus, the other end of the laser receiver 120 is communicated with the inside of the housing 110 for transmitting laser to the inside of the housing 110, one end of the light emitting member 140 is communicated with the inside of the housing 110, and the other end of the light emitting member 140 is directed to the target area for transmitting laser from the inside of the housing 110 to the target area.

In order to avoid the influence of external dust and the like on the laser conducting structure inside the handle 100, in a preferred embodiment, the inside of the housing 110 is a sealed cavity, and the laser receiver 120 is used for sending the laser therapeutic apparatus into the sealed cavity and leading out along with the light emitting element 140, that is, the whole structure for transmitting laser is a sealed structure, which effectively avoids the interference of external factors.

To facilitate manipulation of the handle 100, in a preferred embodiment, the housing 110 is removably attached to the target area via a fastening portion 111. The fixing portion 111 may be implemented by a fixing band, an elastic band, or the like, depending on the use position. For example, when treating skin areas of the hands and the head, the fixing work of the housing 110 may be performed using a fixing band.

Of course, the fixing portion 111 may also be replaced by other structures, and the embodiment of the present invention does not limit this structure, so that the fixing portion is preferable to be detached and connected stably.

In a preferred embodiment, a USB port 112 is mounted on the housing 110, and the temperature control assembly 200 can be connected to the laser treatment apparatus via the USB port 112 to obtain the power required for its operation.

In a preferred embodiment, the laser receiver 120 comprises an optical fiber 121 and a connection seat 122, one end of the optical fiber 121 is connected with the laser treatment apparatus, and the other end of the optical fiber 121 is communicated with the inside of the housing 110 via the connection seat 122. The connecting seat 122 is sleeved on the optical fiber 121, and the connecting seat 122 is in threaded connection with the housing 110. The length of the optical fiber 121 is determined by the particular application.

In order to adjust the traveling path of the laser in the housing 110, in a preferred embodiment, the handle 100 further includes a light guide 130, the light guide 130 is disposed in the housing 110, the light guide 130 has a light guide surface, and the extension line of the light in the laser receiver 120 and the extension line of the light in the light emitting member 140 intersect on the light guide surface.

The light guide member 130 includes a lens barrel 131 and a reflective lens 132, the lens barrel 131 is fixedly disposed inside the housing 110, the reflective lens 132 is fixedly connected with the lens barrel 131, and a light guide surface is formed on a side of the reflective lens 132 away from the lens barrel 131.

As shown in fig. 3, the position and direction of the reflective lens 132 can be used to change the traveling path of the laser inside the housing 110, so as to prevent the laser from going straight into and out of the housing 110. Meanwhile, the laser light entering the housing 110 is in a conical umbrella shape, and after being reflected by the reflective mirror 132, the laser light is totally emitted to the light emitting element 140.

In a preferred embodiment, the light emitting member 140 includes a fixing base 141, a lower shell 142 and a protective lens 143, the fixing base 141 and the lower shell 142 are both fixedly connected to the housing 110, a clamping gap is formed between the fixing base 141 and the lower shell 142, the protective lens 143 is disposed in the clamping gap, wherein the protective lens 143 is clamped at an outer edge thereof, and the protective lens 143 is used for transmitting the laser beam in the housing 110 to a target area.

In a further preferred embodiment, the light emitting member 140 further includes an O-ring 144 and a tooth ring 145, and the upper edge and the lower edge of the protection lens 143 are abutted to the fixing seat 141 and the lower shell 142 via the O-ring 144 and the tooth ring 145, respectively, so that the protection lens 143 is fixed more stably.

In order to prevent the protection lens 143 from being damaged, in a preferred embodiment, the protection lens 143 is embedded in a groove formed on the housing 110, and a side of the protection lens 143 away from the inside of the housing 110 is an arc-shaped surface.

As shown in FIG. 4, the temperature control assembly 200 of the present embodiment is configured to detect the temperature of the target area and adjust the power of the laser treatment apparatus according to the temperature.

In a preferred embodiment, the infrared temperature measuring probe 210 is rotatably connected to the handle 100, and the detection end of the infrared temperature measuring probe 210 covers the target area through a detection area formed by rotation.

In a preferred embodiment, the controller 220 comprises a PCB 221, a nixie tube 222 and a button 223, the PCB 221 is fixed on the handle 100, the nixie tube 222 and the button 223 are both mounted on the PCB 221, the PCB 221 is electrically connected to the infrared temperature probe 210 for receiving the temperature signal, and the PCB 221 is electrically connected to the laser therapeutic apparatus for controlling the power of the laser therapeutic apparatus.

The PCB 221 is configured to collect a temperature of a target area detected by the infrared temperature measurement probe 210, and adjust a power of the laser therapeutic apparatus according to the temperature of the target area, where it should be noted that when the temperature of the target area is greater than a preset value, the power of the laser therapeutic apparatus is reduced until the temperature of the target area is not greater than the preset value. Specifically, according to the formula K = a × P + c, where K is temperature, P is power, a and c are correction coefficients, and the skin temperature of the human body is generally within 46 ℃ and is safe, that is, the preset value is that when the temperature detected by the infrared temperature measurement probe 210 is 46-60 ℃, a certain risk exists, and when the detected temperature is above 60 ℃, a serious risk exists. So when K is 60 ℃ or higher, P =0; when K is less than or equal to 46 ℃, P is set power and does not change. When the temperature is 46-60 ℃, the larger K is, the smaller P is, so that the dynamic equilibrium is achieved.

It is understood that the PCB 221 can control the power level by the temperature signal, and the structure that can be realized and thought by those skilled in the art will not be described in detail herein.

The nixie tube 222 is used for displaying temperature, and the button 223 is used for manually controlling the laser therapeutic apparatus.

In a preferred embodiment, the controller 220 further includes a film paper 224, the film paper 224 is laid on the handle 100, a protection cavity is formed between the film paper 224 and the handle 100, the PCB 221, the nixie tube 222 and the keys 223 are disposed in the protection cavity, and dust is effectively prevented from entering the protection cavity including the PCB 221, the nixie tube 222 and the keys 223.

In a preferred embodiment, the temperature control assembly 200 further includes a mapping probe 230, the acquisition end of the mapping probe 230 being disposed towards the transmission end for acquiring images of the target area, the mapping probe 230 being electrically connected to the controller 220. The imaging probe 230 can acquire images of the target area, so as to monitor the treatment condition of the target area in real time.

Compared with the prior art: the handle 100 is provided with a receiving end and a transmitting end, the receiving end of the handle 100 is connected with the laser therapeutic apparatus and used for receiving laser emitted by the laser therapeutic apparatus and transmitting the laser to a target area from the transmitting end, the handle 100 is matched with the laser therapeutic apparatus and used for conveniently transmitting the laser to the target area, meanwhile, the temperature control assembly 200 is arranged to comprise an infrared temperature measuring probe 210 and a controller 220, the infrared temperature measuring probe 210 is arranged on the handle 100, a detecting end of the infrared temperature measuring probe 210 is arranged towards the transmitting end and used for detecting the temperature of the target area, the infrared temperature measuring probe 210 is electrically connected with the controller 220, the controller 220 is electrically connected with the laser therapeutic apparatus and used for adjusting the power of the laser therapeutic apparatus according to the temperature detected by the infrared temperature measuring probe 210, if the temperature is too high, the controller 220 can reduce the laser emission power of the laser therapeutic apparatus, namely, the intensity of the laser is reduced, so that the temperature in the target area is in a normal value, the handle 100 of the laser therapeutic apparatus can automatically adjust the temperature and replace a manual adjusting process, and the use is more convenient.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the present invention.

Claims (10)

1. A laser therapeutic apparatus handle with an infrared temperature measurement system is used for a laser therapeutic apparatus and is characterized by comprising a handle and a temperature control assembly;

the handle is provided with a receiving end and a transmitting end, and the receiving end of the handle is connected with the laser therapeutic apparatus and used for receiving laser emitted by the laser therapeutic apparatus and transmitting the laser to a target area from the transmitting end;

the temperature control assembly comprises an infrared temperature measuring probe and a controller, the infrared temperature measuring probe is arranged on the handle, a detection end of the infrared temperature measuring probe points to the transmitting end and is used for detecting the temperature of a target area, the infrared temperature measuring probe is electrically connected with the controller, and the controller is electrically connected with the laser therapeutic apparatus and is used for adjusting the power of the laser therapeutic apparatus according to the temperature detected by the infrared temperature measuring probe.

2. The laser therapeutic apparatus handle with the infrared temperature measuring system according to claim 1, wherein the handle comprises a shell, a laser receiver and a light emitting piece, the laser receiver and the light emitting piece are both fixedly connected with the shell, one end of the laser receiver is connected with the laser therapeutic apparatus, the other end of the laser receiver is communicated with the inside of the shell to convey laser to the inside of the shell, one end of the light emitting piece is communicated with the inside of the shell, and the other end of the light emitting piece points to a target area to convey laser in the inside of the shell to the target area.

3. The handpiece of claim 2, wherein the housing is removably attached to the target area via a mounting portion.

4. The laser therapeutic apparatus handle with the infrared temperature measuring system according to claim 2, wherein the laser receiver comprises an optical fiber and a connecting seat, one end of the optical fiber is connected with the laser therapeutic apparatus, and the other end of the optical fiber is communicated with the inside of the shell through the connecting seat.

5. The laser therapeutic apparatus handle with the infrared temperature measuring system according to claim 2, wherein the handle further comprises a light guide member, the light guide member is arranged in the housing, the light guide member has a light guide surface, and an extension line of the light in the laser receiver and an extension line of the light in the light emitting member intersect on the light guide surface.

6. The laser therapeutic apparatus handle with the infrared temperature measuring system according to claim 5, wherein the light guide member comprises a lens barrel and a reflective lens, the lens barrel is fixedly arranged in the shell, the reflective lens is fixedly connected with the lens barrel, and one side of the reflective lens, which is far away from the lens barrel, forms the light guide surface.

7. The laser therapeutic apparatus handle with the infrared temperature measuring system according to claim 1, wherein the infrared temperature measuring probe is rotatably connected with the handle, and a detection area formed by rotating a detection end of the infrared temperature measuring probe covers a target area.

8. The laser therapeutic apparatus handle with the infrared temperature measuring system according to claim 1, wherein the controller comprises a PCB circuit board, a nixie tube and a button, the PCB circuit board is fixedly arranged on the handle, the nixie tube and the button are both arranged on the PCB circuit board, the PCB circuit board is electrically connected with the infrared temperature measuring probe and used for receiving a temperature signal, and the PCB circuit board is electrically connected with the laser therapeutic apparatus and used for controlling the power of the laser therapeutic apparatus.

9. The laser therapeutic apparatus handle with the infrared temperature measuring system according to claim 8, wherein the controller further comprises a piece of membrane paper, the membrane paper is laid on the handle, a protection cavity is formed between the membrane paper and the handle, and the PCB, the nixie tube and the keys are arranged in the protection cavity.

10. The handpiece of claim 1, wherein the temperature control assembly further comprises an imaging probe, wherein the imaging probe has a collection end pointing to the emission end for collecting images of the target area, and the imaging probe is electrically connected to the controller.

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