RU138858U1 - LASER MEDICAL DEVICE - Google Patents

Abstract

1. A laser medical device containing a housing with electrical elements located therein — laser emitters, backlight sources, a focusing unit, a video surveillance module, characterized in that the device body is made in the form of a thick-walled cylindrical shell, and Peltier thermoelectric elements are located on the outside of the cylindrical shell which are made curved, with a cylindrical inner surface and tightly pressed to the cylindrical shell of the housing from its outer side. 2. The laser medical device according to claim 1, characterized in that the focusing unit includes at least one lens. The laser medical device according to claim 1, characterized in that it further includes a power supply to which said electrical elements are connected. The laser medical device according to claim 1, characterized in that the power supply is located inside the housing. The laser medical device according to claim 1, characterized in that the outer side of each Peltier thermoelectric element is profiled, or a radiator is attached to the outer side of each Peltier thermoelectric element. The laser medical device according to claim 1, characterized in that the housing covers an additional cylindrical shell, while there is a gap between the housing and the additional cylindrical shell, the device additionally equipped with a forced cooling unit that allows the coolant to move in the gap between the housing and the additional cylindrical shell. 7. The laser medical device according to claim 6, characterized in that the forced cooling unit is

Description

The utility model relates to the field of medicine and is intended primarily for use in cosmetology, for laser hair removal procedures and skin exposure (for example, when resurfacing the skin).

The prior art apparatus for magneto-LED therapy containing a power supply, an LED, which includes at least two emitting crystals, a ring permanent magnet and a radiator for cooling the LED, the LED is located in the body of the radiator so that it radiating crystals are brought out to the end surface of the radiator, and a ring permanent magnet is fixed to the end surface of the radiator so that the radiating crystals output to it are located in the hole zone of the ring constant m agitation. An optical lens is additionally introduced into the LED, which is installed in the hole of the annular permanent magnet, a rigid plate is rigidly connected to the end surface of the radiator along its periphery, to which a strap is attached at its edges for attaching the device to the user's arm or leg, and an LED is used as an LED emitting electromagnetic radiation with a power of 120 ÷ 300 mW. (RU 48790 U1, A61N 5/06, 10.11.2005).

A device for influencing the body with optical radiation for physiotherapeutic purposes is known, which is a case inside which there is an autonomous power supply unit and a program control chip, in its front section there is a mirror reflector and an ultra-bright blue or red LED, and in the back section of the case there is a socket for plug of the charger for the battery, on the surface of the case there is a button to turn on the device and select a program for the phototherapy session, while on the front housing cases fastens one of three different light guide in the form of nozzles, selected from the following: a nozzle for irradiating natural cavities of the body, which is a circular cylinder with a rounded front edge; there is a restrictive ring in the back of the nozzle; nozzle for irradiating the back wall (RU 57124 U1, A61N 5/00, 10/10/2006).

A laser medical device is known that contains a power supply unit, a microprocessor control unit connected to it, connected to an optical unit including semiconductor laser sources, optical fibers, an optical alignment unit, and an adapter for connecting an interchangeable fiber-optic instrument, while it further includes functionally associated with the unit control unit for stabilizing the wavelength of laser radiation, a non-thermal monitoring unit for the irradiated zone, and a power indication and control unit provided with a unit sound and light signaling, while the stabilization unit for the wavelength of laser radiation includes a group of Peltier coolers connected to temperature sensors functionally connected to a microprocessor control unit (RU 46435 U1, A61N 5/067, 07/10/2005).

A device for contact irradiation with an electronic cooling system is known, including a laser radiation source, a light guide connected to it, a cooling unit including a sapphire window. The device includes a Peltier electronic element with a central hole, while a sapphire window equipped with a temperature sensor is connected to the “cold” side of the Peltier element, and the “hot” side of the Peltier element is equipped with a radiator with a developed surface and a hole for the passage of light, a fixture for attaching the fiber, and also an electronic unit consisting of a driver, a PID controller, an indication unit (RU 20008 U1, A61N 5/00, 09/10/2012).

The closest analogue of the technical solution is a laser medical device containing a housing with at least one laser emitter, a backlight and a radiation sensor, a focusing system, a video surveillance device and a power supply unit, characterized in that the video surveillance device is located on one axis with a body and a focusing system, and a laser emitter, a backlight, and a radiation sensor are placed along the generatrix, the coaxial axis of the focusing system (RU 2181572 C2, A61B 18/20, 04/27/2002).

The disadvantages of these technical solutions is the lack of efficiency of their cooling elements and the possibility of overheating of the components of the devices.

The task to which the technical solution is directed is to increase the durability and stability of the components of the device and the device as a whole.

The task is achieved due to the fact that the laser medical device contains a housing with electrical elements located in it - laser emitters, backlight sources, a focusing unit, a video surveillance module, the device housing being made in the form of a thick-walled cylindrical shell, and located on the outside of the cylindrical shell Peltier thermoelectric elements, which are made curved, with a cylindrical inner surface, and are tightly pressed to the cylindrical shell to mouth from its outer side.

The focusing unit includes at least one lens.

The laser medical device may further include a power supply to which said electrical elements are connected.

The power supply can be placed inside the case.

The outer side of each Peltier thermoelectric element may be profiled, or a radiator may be attached to the outer side of each Peltier thermoelectric element.

The housing may cover an additional cylindrical shell, while there is a gap between the housing and the additional cylindrical shell, moreover, the device is additionally equipped with a forced cooling unit that allows the coolant to move in the gap between the housing and the additional cylindrical shell.

Preferably, the forced cooling unit is a fan.

The forced cooling unit may be a liquid cooling module.

From the inside of the thick-walled cylindrical shell in its end part from the location of the focusing unit, a thread can be made or fixing devices for fixing additional optical nozzles can be placed.

It is preferable that the video surveillance module is located on the same axis as the body and the focusing unit, while laser emitters and backlight sources are located around this axis in accordance with radial symmetry.

The technical result is to increase the cooling efficiency of system components, which in turn provides increased durability and stability of the components of the device and the device as a whole.

In FIG. 1 shows a longitudinal section of a device.

In FIG. 2 shows an end view.

In FIG. 3 shows a standard Peltier thermoelectric element.

In FIG. 4 shows the original Peltier thermoelectric element, made in accordance with the described technical solution.

In FIG. 5 shows the original Peltier thermoelectric element, made in accordance with the described technical solution with a profiled outer side (equipped with ribs).

In FIG. 6 shows a longitudinal section of a device equipped with an additional cylindrical shell and a cooling unit.

In FIG. 7 is an end view of a device equipped with an additional cylindrical shell and a cooling unit.

The laser medical device contains a housing 1 with electrical elements located therein - laser emitters 2, illumination sources 3, focusing unit 4, video surveillance module 5.

The device casing is made in the form of a thick-walled cylindrical shell, with Peltier thermoelectric elements 6 located on the outside of the cylindrical shell, which are made curved with a cylindrical inner surface 7 and are tightly pressed to the cylindrical shell of the casing from its outer side 8.

The focusing unit of the device includes at least one lens 9 for converging the beams of laser emitters 2.

The laser medical device may include a power supply 10 to which said electrical elements are connected. The power supply 10 can be placed inside the housing (FIG. 1-6), and can be taken out of it. Equipping the device with thermoelectric elements 6 Peltier with a curved configuration allows for efficient heat dissipation and place the power supply inside the space of the device.

The outer side 11 of each Peltier thermoelectric element can be profiled (FIG. 5) and have ribs 12. Or a radiator can be attached to the outer side of each Peltier thermoelectric element (not shown conditionally in the drawings).

To intensify the cooling process, the casing can be equipped with an additional cylindrical shell 13 (FIG. 6), moreover, there is a gap 14 between the casing and the additional cylindrical shell, and the device is equipped with a forced cooling unit that allows the coolant to move (by air traction or pumping liquid) in the aforementioned the gap 14 between the housing and the additional cylindrical shell 13, which provides heat removal from the outer sides 11 of the Peltier thermoelectric elements.

Preferably, the forced cooling unit is a fan 15, while the coolant is air.

The forced cooling unit may be a liquid cooling module (not shown conventionally), while the coolant is a liquid.

On the inner side of the thick-walled cylindrical shell in its end part from the location of the focusing unit 4, thread 16 is made or fixing devices for fixing additional optical nozzles are placed.

The CCTV module 5 is located on the same longitudinal axis with the housing 1 and the focusing unit 4, while the laser emitters 2 and the illumination sources 3 are compactly located around this axis in accordance with radial (circular) symmetry.

The standard Peltier thermoelectric elements currently manufactured by the industry are flat (FIG. 3) and consist of two flat plates 17 made of dielectric material, between which are semiconductor thermocouples connected in series by metal copper pads (not shown conventionally) 18. Usually, said plates 17 are made of ceramic based on aluminum oxide or nitride. Standard thermoelectric elements of a flat shape (FIG. 3) are not suitable for placement on the housing 1 of the device, which is made in the form of a thick-walled cylindrical shell, because between the flat elements and the cylindrical shell, only point contact is possible, or there is a need to use intermediate elements providing tight contact of the flat elements with the case, which in any case will lead to a significant decrease in the cooling efficiency of the case, an increase in the temperature inside the case and a possible failure of the electrical elements of the device.

The cylindrical shape of the housing is due to the compact radial arrangement of electrical elements in it, therefore it is most preferable for the device in the framework of the described technical solution. In addition, the device with a cylindrical body is more ergonomic. In order to ensure effective heat removal from the cylindrical shell within the framework of the described technical solution, the original Peltier thermoelectric elements of a curved shape with a cylindrical inner surface 7 (FIG. 4, 5) were used. These elements may include two curved plates 19 of a dielectric material (FIG. 2, 4). The most preferred option is when the Peltier thermoelectric element of curvilinear shape includes, on the side intended for fixing on the housing 1, a curved plate 19 with a cylindrical inner surface 7, and on the other a curved radiator 20, the inner side of which is cylindrical and the outer one is equipped with fins 12. semiconductor thermocouples 18 are placed between the curved plate 19 and the curved radiator 20. In the case when the device is equipped with a forced cooling unit, fins 12 times escheny in the gap 14 between the housing and the additional cylindrical shell 13 to form channels 21 (FIGS. 6, 7).

The following describes the operation of the device in accordance with its layout shown in FIG. 6.

Involve the electrical elements of the device, supplying them with electricity from the power supply, for example, through a control circuit board (not shown conventionally). Electrical elements can be switched on the control circuit board located inside the device, or made with the ability to connect to an external control device (computer). Laser emitters 2 synchronously generate low-power rays, which are reduced to a single beam or light spot on the object using the focusing unit 4. The illumination sources 3 illuminate the exposure area, which makes it possible to adjust the beam position using the video surveillance module 5 and also monitor the progress operations on the screen of the control device. After alignment and guidance of the beam in the desired area, an effect is made on the layers with a given depth, power and duration. Er: YAG lasers with a wavelength of 2940 nm can be used as laser emitters. Also in the housing of the device can be installed additional optical nozzles 22, which are screwed into the housing, for which it is equipped with a thread 16.

For example, a fractional nozzle can be installed, including an optical diffraction grating and a microlens for dividing the focused beam into many individual microbeams that focus on the skin surface with a diameter of 100-200 microns each, forming microthermal treatment zones.

In the process of operation of the electrical elements of the device, a significant amount of heat is generated inside the housing 1, which must be removed in order to avoid overheating of the said elements. For this purpose, thermoelectric Peltier elements 6 are arranged on the outside of the cylindrical shell, which are made curved with a cylindrical inner surface 7. The radius of curvature of the inner surface thermoelectric elements 6 Peltier equal to or slightly larger than the radius of the cylindrical shell of the housing. Thermoelectric elements 6 Peltier tightly pressed to the housing and mounted on it. Between the body and thermoelectric elements 6 Peltier placed a layer of thermal paste or hot melt. In the process of operation of the device, a cooling unit (fan) is constantly or temporarily activated, which creates air draft from the end to the end of the device in the gap between the housing and the additional cylindrical shell (the direction of air movement is shown by arrows in FIG. 6). The air flow in the gap removes heat from the ribs 12 of the thermoelectric elements 6 Peltier. To ensure the operation of the components of the device in automatic mode, it can also be equipped with temperature sensors, light sensors, and other sensors. 6 Peltier thermoelectric elements can be connected to the power supply through switching voltage regulators, which ensures their more efficient operation. The operation of the cooling unit and the voltage on the thermoelectric elements 6 Peltier are regulated by a control printed circuit board based on data from temperature sensors.

The described laser medical device has high stability, reliability, compactness, ergonomics and can operate continuously at maximum power.

Equipping the case with Peltier thermoelectric elements with a cylindrical inner surface made it possible to reduce the temperature inside the case by one and a half times, compared to the temperature with passive cooling, using the closest analogue circuit (using fins of the case), and in combination with the forced cooling unit, provided that the thermoelectric elements are present radiators 20, three times or more, depending on the type and power of the cooling unit, as well as the external surface area of the radiators.

Claims (10)

1. A laser medical device containing a housing with electrical elements located therein — laser emitters, backlight sources, a focusing unit, a video surveillance module, characterized in that the device body is made in the form of a thick-walled cylindrical shell, and Peltier thermoelectric elements are located on the outside of the cylindrical shell which are made curved, with a cylindrical inner surface and tightly pressed against the cylindrical shell of the housing from its outer side. 2. The laser medical device according to claim 1, characterized in that the focusing unit includes at least one lens. 3. The laser medical device according to claim 1, characterized in that it further includes a power supply to which the aforementioned electrical elements are connected. 4. The laser medical device according to claim 1, characterized in that the power supply is located inside the housing. 5. The laser medical device according to claim 1, characterized in that the outer side of each Peltier thermoelectric element is profiled, or a radiator is attached to the outer side of each Peltier thermoelectric element. 6. The laser medical device according to claim 1, characterized in that the housing covers an additional cylindrical shell, while there is a gap between the housing and the additional cylindrical shell, the device additionally equipped with a forced cooling unit that allows the coolant to move in the gap between the housing and the additional cylindrical shell. 7. The laser medical device according to claim 6, characterized in that the forced cooling unit is a fan. 8. The laser medical device according to claim 6, characterized in that the forced cooling unit is a liquid cooling module. 9. The laser medical device according to claim 1, characterized in that a thread is made on the inside of the thick-walled cylindrical shell in its end part from the location of the focusing unit or fixing devices are placed for fixing additional optical nozzles. 10. The laser medical device according to claim 1, characterized in that the video surveillance module is located on the same axis as the body and the focusing unit, while laser emitters and backlight sources are located around this axis in accordance with radial symmetry.

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