CN110960801A - Light treatment head assembly and physical therapy instrument - Google Patents

Abstract

The invention provides an optical treatment head component, which comprises a treatment head body, wherein the treatment head body comprises a handheld part, a light source component, a shell, a coating component and a light guide crystal, the light source component emits pulsed light under the driving of a pulse power supply, and the light guide crystal receives the pulsed light emitted by the light source component and acts on a treatment part of a patient; the light guide crystal is arranged on the therapeutic head body, the coating component is coated on the surface of the convex light guide crystal and comprises an adsorption surface extending outwards, and the adsorption surface is used for collecting the gel coated on the therapeutic part of the patient. The invention also relates to a light treatment head component and a physical therapy apparatus. The adsorption surface of the invention ensures that the treatment part has enough gel on one hand, and avoids the gel from flowing in a large area on the treatment part on the other hand; in addition, the cladding component is made of light absorption materials, so that light leaked from the light guide crystal can be fully absorbed, and the influence on a patient or an operator in the use process is avoided.

Description

Light treatment head assembly and physical therapy instrument

Technical Field

The invention relates to the technical field of medical treatment, cosmetology and physical therapy equipment, in particular to a light treatment head assembly.

Background

With the continuous improvement of living standard of people, more and more consumers pay attention to consumption items in health care, health preservation, beauty treatment and the like, for example, depilation, freckle removal and wrinkle removal are one of the most common items in the fields of beauty treatment and medical treatment at present, and in the items, a handle is used for acting on a treatment part and outputting light.

With the increase of consumers, doctors and consumers reflect dazzling of light leaking from the light guide crystal during the light extraction process of the handle during use, and psychological tension and discomfort are brought to the operators and the consumers even though the goggles or the eye shields are worn. In addition, in the using process, the gel is required to be coated on the treatment part, the gel is generally coated on a large number, and the existing treatment handle is not provided with a sucker, so that the gel is squeezed open once being contacted with the treatment part, on one hand, the effect is greatly reduced, and on the other hand, the gel flows on the non-treatment part and is inconvenient to clean.

Disclosure of Invention

In order to overcome the shortcomings of the prior art, the invention provides a light treatment head assembly.

The invention avoids the gel from flowing at the non-treatment part by coating the surface of the light guide crystal with the adsorption surface, thereby solving the technical problem.

The invention provides an optical treatment head component, which comprises a treatment head body, wherein the treatment head body comprises a handheld part, a light source component, a shell, a coating component and a light guide crystal; the light source assembly is driven by the pulse power supply to emit light pulses, and the light guide crystal receives the light pulses emitted by the light source assembly and acts on a treatment part of a patient;

cladding subassembly detachable install in the surface of leaded light crystal, the cladding subassembly is including cladding face and the outside adsorption surface that extends rather than, cladding face and adsorption surface fixed connection, the cladding face laminate in the surface of leaded light crystal, the adsorption surface is located leaded light crystal contact patient's treatment position one side, the gel that the adsorption surface will coat in the treatment position draws in to wherein.

Preferably, the cladding surface on the side contacting with the treatment part is a light-transmitting surface, and the light pulse emitted from the light guide crystal acts on the treatment part of the patient through the light-transmitting surface; and the other areas of the cladding component, which are removed from the light-transmitting surface, are light-absorbing areas.

Preferably, the adsorption surface is a sucker made of silicon rubber with a smooth surface.

Preferably, the light source assembly includes a condenser lens, a filter and a xenon lamp, the xenon lamp is installed between the filter and the condenser lens, the filter is installed between the xenon lamp and the light guide crystal, light emitted from the xenon lamp passes through the condenser lens and then enters the filter, and light with a set wavelength obtained after passing through the filter enters the light guide crystal.

Preferably, the edge of the cladding surface contacting the shell comprises an outwardly extending flange for shielding a gap between the light guide crystal and the shell.

The invention also provides an optical treatment head component, wherein the treatment head body comprises a handheld part, a light source component, a shell, a coating component and a light guide crystal, the handheld part is fixedly connected with the shell, the light guide crystal is arranged on the treatment head body, and the light guide crystal protrudes out of the surface of the shell; the light source assembly is driven by the pulse power supply to emit pulsed light, and the light guide crystal receives the pulsed light emitted by the light source assembly and acts on a treatment part of a patient;

cladding subassembly detachable cladding in the surface of leaded light crystal and contact patient's treatment position, the cladding subassembly includes the cladding face that can absorb light, the cladding face laminate in the surface of leaded light crystal to block light from in the gap between leaded light crystal and the casing or from the side of leaded light crystal leaks.

Preferably, the edge of the cladding surface contacting the shell comprises an outwardly extending flange for shielding a gap between the light guide crystal and the shell.

A physical therapy apparatus comprises a therapy apparatus body, wherein the therapy apparatus body comprises a therapy head body, a pulse power supply and a main control assembly, and the pulse power supply is electrically connected with the main control assembly; the pulse power supply receives the instruction sent by the main control assembly and sends the received instruction to the xenon lamp so as to enable the xenon lamp to discharge to generate light pulses; the light guide crystal receives the pulse light emitted by the xenon lamp and acts on the treatment part of the patient.

Preferably, the therapeutic apparatus body further comprises an over-temperature protection assembly, the over-temperature protection assembly is electrically connected with the main control assembly, the over-temperature protection assembly comprises a temperature sampling circuit and an over-temperature protection circuit, and the temperature sampling circuit is connected with the over-temperature protection circuit; the temperature sampling circuit is connected with the therapeutic head body and the pulse power supply, the over-temperature protection circuit is electrically connected with the main control assembly, when the temperature collected by the temperature sampling circuit is larger than a set temperature threshold range, the main control assembly sends an instruction to the over-temperature protection circuit, and the over-temperature protection circuit stops the output of the therapeutic apparatus body.

Preferably, the therapeutic apparatus body further comprises a cooling assembly, the cooling assembly is electrically connected with the main control assembly, the cooling assembly comprises a semiconductor refrigerating part and a water cooling part, the semiconductor refrigerating part is connected with the light guide crystal, and the main control assembly adjusts the semiconductor refrigerating part to enable the light guide crystal to be kept within a set temperature threshold range; the water cooling part comprises a water cooling channel, and the water cooling channel is used for evacuating heat generated by the xenon lamp.

Compared with the prior art, the invention has the beneficial effects that:

the invention discloses an optical treatment head component which comprises a treatment head body, wherein a light guide crystal is arranged on the treatment head body, the light guide crystal protrudes out of the surface of a shell, a coating component is coated on the surface of the protruded light guide crystal and comprises an adsorption surface extending outwards, and the adsorption surface collects gel coated on a treatment part of a patient, so that on one hand, enough gel is ensured to be contained in the treatment part, and on the other hand, the gel is prevented from flowing in a large area at the treatment part. In addition, the cladding component is made of light absorption materials, so that light leaked from the light guide crystal can be fully absorbed, and the influence on a patient or an operator in the use process is avoided.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical solutions of the present invention more clearly understood and to implement them in accordance with the contents of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings. The detailed description of the present invention is given in detail by the following examples and the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

FIG. 1 is a perspective view of the overall construction of a light treatment head assembly of the present invention;

FIG. 2 is a perspective view of a sheathing assembly of a light treatment head assembly of the present invention;

FIG. 3 is a perspective view of a light source assembly of a light treatment head assembly of the present invention;

FIG. 4 is a cross-sectional view of the suction surface of a light treatment head assembly of the present invention;

FIG. 5 is a plan view of the cladding surface of a light treatment head assembly according to embodiment 2 of the present invention;

FIG. 6 is a schematic view of the overall structure of a physical therapy apparatus according to the present invention;

reference numerals: 10. the treatment head comprises a treatment head body, a 110, a handheld part, a 120, a shell, a 130, a light guide crystal, a 140, a light filter, a 150, a xenon lamp, a 160, a condenser lens, 170, a coating component, 171, a coating surface, 1711, a light transmission surface, 1712, a folded edge, 172 and an adsorption surface.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that any combination of the embodiments or technical features described below can be used to form a new embodiment without conflict.

Example 1

The invention provides an optical treatment head assembly, as shown in fig. 1-3, comprising a treatment head body 10, wherein the treatment head body 10 comprises a handheld part 110, a light source assembly, a shell 120, a coating assembly 170 and a light guide crystal 130, the handheld part 110 is fixedly connected with the shell 120, the light guide crystal 130 is installed on the treatment head body 10, and the light guide crystal 130 protrudes out of the surface of the shell 120; the light source assembly emits pulsed light under the driving of the pulse power supply, and the light guide crystal 130 receives the pulsed light emitted by the light source assembly and acts on the treatment part of the patient; the cladding assembly 170 is detachably mounted on the surface of the light guide crystal 130, the cladding assembly 170 includes a cladding surface 171 and an adsorption surface 172 extending outward from the cladding surface 171, the cladding surface 171 and the adsorption surface 172 are integrally formed, the cladding surface 171 is attached to the surface of the light guide crystal 130, the adsorption surface 172 is located on one side of the light guide crystal 130 contacting with a treatment part of a patient, and the adsorption surface 172 collects gel coated on the treatment part into the adsorption surface. In one embodiment, the cladding surface is fixedly connected with the light guide crystal, the cladding surface and the adsorption surface are integrally formed, and the cladding surface is used for fixing the adsorption surface on one side of the light guide crystal, which is contacted with the treatment part; preferably, the cladding surface covers all or part of the side surface of the light guide crystal, which is to be understood as meaning that the cladding surface on the one hand fixes the adsorption surface on the light guide crystal and on the other hand prevents light leakage. The coating surface can coat the whole surface or partial surface of the side edge of the light guide crystal.

Generally, the handle 110 and the housing 120 are in a linear shape or form a U-shaped structure, the handle 110 may be in any structure that is convenient for a user to hold, and preferably, the handle 110 protrudes from the housing 120 to form an elongated linear structure, so that the handle is held by a hand. The light guide crystal 130 is arranged on the therapy head body 10, and the light guide crystal 130 has various models matched with the therapy head body so as to adapt to different types of therapy parts; the encapsulation component 170 mates with the light guide crystal 130, and different types of light guide crystals 130 mate with corresponding encapsulation components 170. The light source assembly emits pulsed light under the driving of the pulse power supply, and the pulsed light acts on the treatment part after passing through the light guide crystal 130. The suction surface 172 is similar to a suction cup, the suction surface 172 may be circular or square or any other shape, in this embodiment, it is preferably elliptical, and the force is uniformly applied to each point of the elliptical suction surface 172. Preferably, the surface of the absorption surface 172 is smooth, and when in use, a certain amount of gel needs to be coated on the treatment part of a patient, and the gel can provide effective cooling for the skin epidermis, help the skin to cool, protect the epidermis, and relieve pain and avoid scalding; in addition, the gel has high light transmittance, strong heat conductivity, no toxicity and no stimulation; in the treatment process, the gel is folded into the adsorption surface, so that the gel is prevented from flowing in a large area.

In a specific embodiment, the light source assembly includes a condenser 160, a filter 140, and a xenon lamp 150, the xenon lamp 150 is installed between the filter 140 and the condenser 160, the filter 140 is installed between the xenon lamp 150 and the light guide crystal 130, light emitted from the xenon lamp 150 passes through the condenser 160 and then enters the filter, and light with a specific wavelength obtained after passing through the filter 140 enters the light guide crystal 130. In this embodiment, krypton can be used as the xenon lamp 150, the xenon lamp 150 performs pulse discharge under the action of the pulse power supply, and the light emitted from the xenon lamp 150 passes through the condenser 160 and the filter 140 and finally acts on the treatment site of the patient through the light guide crystal 130.

The xenon lamp 150 outputs incoherent pulsed light with a wavelength of 400nm to 1200nm under the action of the pulse power supply module, and the condenser 160 reflects a part of light to converge the light to the light guide crystal 130 because the light output by the xenon lamp 150 is transmitted in various directions. The light output by the xenon lamp 150 is selected by the optical filter 140, and then outputs the pulse light with specific wavelength, for example, the wavelength of the output light is 560nm to 1200nm by using the optical filter 140 with 560 nm; the light passing through the filter 140 enters the light guide crystal 130, the light guide crystal 130 functions to uniformly transmit the pulse light energy to the treatment site on one hand, and on the other hand, the light guide crystal 130 contacts with the treatment site, and the light guide crystal 130 is cooled by semiconductor refrigeration to make the patient feel comfortable. The light guide crystal 130 may be made of K9 glass, sapphire glass, or the like, and sapphire glass with good thermal conductivity is generally used.

Example 2

An optical treatment head component comprises a treatment head body 10, wherein the treatment head body 10 comprises a handheld part 110, a light source component, a shell 120, a coating component 170 and a light guide crystal 130, the handheld part 110 is fixedly connected with the shell 120, the light guide crystal 130 is arranged on the treatment head body 10, and the light guide crystal 130 protrudes out of the surface of the shell 120; the light source assembly emits pulsed light under the driving of the pulse power supply, and the light guide crystal 130 receives the pulsed light emitted by the light source assembly and acts on the treatment part of the patient; the cover assembly 170 is detachably covered on the surface of the light guide crystal 130 and contacts the treatment part of the patient, the cover assembly 170 includes a cover surface 171 capable of absorbing light, and the cover surface 171 is attached to the surface of the light guide crystal 130 to prevent light from leaking out of the gap between the light guide crystal 130 and the housing 120 or from the side surface of the light guide crystal. In one embodiment, the covering surface 171 is preferably made of an elastic material, so that the covering surface 171 can be easily and conveniently attached to the surface of the light guide crystal 130, and the covering surface 171 can be more closely attached to the surface of the light guide crystal 130.

The covering surface 171 has a certain thickness, and when the covering surface 171 covers the surface of the light guide crystal 130, the light-absorbing covering surface 171 can effectively block light leaking from the connecting seam between the light guide crystal 130 and the housing 120.

In a preferred embodiment, as shown in FIG. 5, the edge of the cladding surface 171 contacting the housing includes an outwardly extending flange 1712, the flange 1712 being configured to block the gap between the light directing crystal 130 and the housing 120; the edge 1712 and the cladding surface 171 are integrally formed, the edge 1712 is attached to the housing 120, and the edge 1712 attached to the housing 120 and the cladding surface 171 on the light guide crystal 130 form a certain angle. At the position where the light guide crystal 130 contacts the housing 120, the peripheral edge of the cladding surface 171 extends outward to form a folded edge 1712, which can more effectively block the light leaking from the gap between the light guide crystal 130 and the housing 120.

Example 3

The technical solution that can simultaneously solve the technical problems in the embodiments 1 and 2 is as follows: in embodiment 1, the cladding surface 171 completely covers the side edge of the light guide crystal 130, the cladding surface 171 is made of a light absorbing material, preferably, the absorption surface 172 is made of a light absorbing material, and the cladding surface 171 and the absorption surface 172 are integrally molded, so that the cost is reduced in the production process and the production efficiency is improved. When the absorption surface 172 and the cladding surface 171 are made of light absorbing materials, light leaking from a gap between the light guide crystal 130 and the housing 120 or from the side surface of the light guide crystal 130 can be shielded, and gel in the treatment process can be collected into the absorption surface 172, so that the gel is prevented from flowing in a large area.

The cladding surface on the side contacting with the treatment part is a light transmission surface 1711 through which the pulse emitted from the light guide crystal 130 acts on the treatment part of the patient; the other region of the cladding assembly 170 where the light-transmitting surface is removed is a light-absorbing region. In one embodiment, as shown in fig. 4, light is easily leaked from the joint between the light guide crystal 170 and the housing 120, a part of the side surface of the light guide crystal is wrapped with a metal sheet to prevent light leakage, and the side surface not wrapped with the metal sheet is easily leaked, the wrapping surface 171 is wrapped on the surface of the light guide crystal 130, and the wrapping surface 171 is set to be a dark light-absorbing color, preferably black; the cladding surface on the side contacting with the treatment part is a light transmission surface 1711, the pulse emitted from the light guide crystal 130 acts on the treatment part of the patient through the light transmission surface, and the light transmission surface 1711 is preferably hollow, that is, the side of the light guide crystal 130 acting on the treatment part directly contacts with the skin.

In this embodiment, when the cladding surface 171 completely covers the side surface of the light guide crystal 130, and the cladding surface 171 is made of a light absorbing material, light leaking from the gap between the light guide crystal 130 and the housing 120 can be blocked; in addition, the coating surface and the adsorption surface are integrally formed, the adsorption surface is contacted with a treatment part, and the gel is collected into the adsorption surface in the treatment process, so that the gel is prevented from flowing in a large area.

Example 4

A physical therapy apparatus, as shown in fig. 6, comprising a therapy apparatus body in embodiment 1 or embodiment 2 or embodiment 3, wherein the therapy apparatus body comprises a therapy head body, a pulse power supply and a main control assembly, and the pulse power supply is electrically connected with the main control assembly; the pulse power supply receives the instruction sent by the main control assembly and sends the received instruction to the xenon lamp so as to discharge the xenon lamp to generate pulse light; the light guide crystal receives the pulse light emitted by the xenon lamp and acts on the treatment part of the patient. In one embodiment, the physical therapy instrument comprises a therapy head body, instructions are sent to a pulse power supply through a main control assembly, the pulse power supply drives a xenon lamp in the therapy head body to discharge and generate pulse light, and a light guide crystal receives the pulse light emitted by the xenon lamp and acts on a therapy part of a patient.

The therapeutic instrument body also comprises an over-temperature protection assembly, the over-temperature protection assembly is electrically connected with the main control assembly, the over-temperature protection assembly comprises a temperature sampling circuit and an over-temperature protection circuit, and the temperature sampling circuit is connected with the over-temperature protection circuit; the temperature sampling circuit is connected with the therapeutic head body and the pulse power supply, the over-temperature protection circuit is electrically connected with the main control assembly, when the temperature collected by the temperature sampling circuit is larger than a set temperature threshold range, the main control assembly sends an instruction to the over-temperature protection circuit, and the over-temperature protection circuit stops outputting of the therapeutic apparatus body. In one embodiment, the temperature sampling circuit mainly collects the temperature of the optical cavity and a power device in the pulse power supply, when the temperature in the optical cavity, such as a xenon lamp or the pulse power supply, is greater than a set temperature threshold, the therapeutic apparatus body continues to work again to cause danger, therefore, when the temperature collected by the temperature sampling circuit is abnormal, the over-temperature protection circuit feeds back information to the main control assembly, and the main control assembly sends a stop instruction to the therapeutic apparatus, so that the safety protection effect is achieved.

The therapeutic instrument body further comprises a cooling assembly, the cooling assembly is electrically connected with the main control assembly, the cooling assembly comprises a semiconductor refrigerating part and a water cooling part, the semiconductor refrigerating part is connected with the light guide crystal, and the main control assembly adjusts the semiconductor refrigerating part to enable the light guide crystal to be kept within a set temperature threshold range; the water cooling part comprises a water cooling channel, and the heat generated by the xenon lamp is conducted through the circulating water cooling channel. In one embodiment, the semiconductor refrigerating part refrigerates the light guide crystal, and the light guide crystal is in contact with the skin of the treatment part to regulate the temperature of the surface layer of the skin; the heat generated when the xenon lamp emits light is taken away through the circulating water cooling channel, so that the xenon lamp is cooled.

In the physiotherapy apparatus of the present invention, the connection mode of the power supply line can be selected as the power supply line, and the charging mode or other power supply modes can be selected.

The foregoing is merely a preferred embodiment of the invention and is not intended to limit the invention in any manner; those skilled in the art can readily practice the invention as shown and described in the drawings and detailed description herein; however, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the scope of the invention as defined by the appended claims; meanwhile, any changes, modifications, and evolutions of the equivalent changes of the above embodiments according to the actual techniques of the present invention are still within the protection scope of the technical solution of the present invention.

Claims (10)

1. An optical treatment head component is characterized by comprising a treatment head body, wherein the treatment head body comprises a handheld part, a light source component, a shell, a coating component and a light guide crystal; the light source assembly is driven by the pulse power supply to emit light pulses, and the light guide crystal receives the light pulses emitted by the light source assembly and acts on a treatment part of a patient;

cladding subassembly detachable install in the surface of leaded light crystal, the cladding subassembly is including cladding face and the outside adsorption surface that extends rather than, cladding face and adsorption surface fixed connection, the cladding face laminate in the surface of leaded light crystal, the adsorption surface is located leaded light crystal contact patient's treatment position one side, the gel that the adsorption surface will coat in the treatment position draws in to wherein.

2. The optical treatment head assembly as claimed in claim 1, wherein the cladding surface on a side contacting the treatment site is an optically transparent surface through which the light pulse emitted from the light guide crystal is applied to the treatment site of the patient; and the other areas of the cladding component, which are removed from the light-transmitting surface, are light-absorbing areas.

3. The optical treatment head assembly of claim 2, wherein the suction surface is a smooth surfaced silicone rubber suction cup.

4. The optical treatment head assembly of claim 1, wherein the light source assembly comprises a condenser lens, an optical filter and a xenon lamp, the xenon lamp is installed between the optical filter and the condenser lens, the optical filter is installed between the xenon lamp and the light guide crystal, light emitted from the xenon lamp passes through the condenser lens and then enters the optical filter, and light with a set wavelength passes through the optical filter and then enters the light guide crystal.

5. The optical treatment head assembly of claim 2, wherein the edge of the cladding surface contacting the housing includes an outwardly extending flange for shielding a gap between the light guiding crystal and the housing.

6. An optical treatment head component is characterized by comprising a treatment head body, wherein the treatment head body comprises a handheld part, a light source component, a shell, a coating component and a light guide crystal; the light source assembly is driven by the pulse power supply to emit pulsed light, and the light guide crystal receives the pulsed light emitted by the light source assembly and acts on a treatment part of a patient;

cladding subassembly detachable cladding in the surface of leaded light crystal and contact patient's treatment position, the cladding subassembly includes the cladding face that can absorb light, the cladding face laminate in the surface of leaded light crystal to block light from in the gap between leaded light crystal and the casing or from the side of leaded light crystal leaks.

7. The optical treatment head assembly of claim 6, wherein the edge of the cladding surface contacting the housing includes an outwardly extending flange for shielding a gap between the light guiding crystal and the housing.

8. A physical therapy apparatus, which is characterized by comprising a therapy apparatus body, wherein the therapy apparatus body comprises the therapy head body as claimed in claim 1 or 6, a pulse power supply and a main control component, and the pulse power supply is electrically connected with the main control component; the pulse power supply receives the instruction sent by the main control assembly and sends the received instruction to the xenon lamp so as to enable the xenon lamp to discharge to generate light pulses; the light guide crystal receives the pulse light emitted by the xenon lamp and acts on the treatment part of the patient.

9. The physical therapy apparatus according to claim 8, wherein the therapy apparatus body further comprises an over-temperature protection component, the over-temperature protection component is electrically connected to the main control component, the over-temperature protection component comprises a temperature sampling circuit and an over-temperature protection circuit, and the temperature sampling circuit is connected to the over-temperature protection circuit; the temperature sampling circuit is connected with the therapeutic head body and the pulse power supply, the over-temperature protection circuit is electrically connected with the main control assembly, when the temperature collected by the temperature sampling circuit is larger than a set temperature threshold range, the main control assembly sends an instruction to the over-temperature protection circuit, and the over-temperature protection circuit stops the output of the therapeutic apparatus body.

10. The physical therapy apparatus according to claim 8, wherein the therapeutic apparatus body further comprises a cooling assembly electrically connected to the main control assembly, the cooling assembly comprises a semiconductor refrigerating portion and a water cooling portion, the semiconductor refrigerating portion is connected to the light guide crystal, and the main control assembly adjusts the semiconductor refrigerating portion to keep the light guide crystal within a set temperature threshold range; the water cooling part comprises a water cooling channel, and the water cooling channel is used for evacuating heat generated by the xenon lamp.

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