CN116943044B - Far infrared physiotherapy lamp based on electrophoresis control - Google Patents

Abstract

The invention discloses a far infrared physiotherapy lamp based on electrophoresis control, which comprises a supporting structure and an irradiation unit; the irradiation unit is provided with a liquid cavity and a containing cavity positioned above the liquid cavity, the inner top wall and the inner bottom wall of the liquid cavity are respectively provided with a transparent film electrode, the liquid cavity is filled with electrophoresis liquid, the electrophoresis liquid is formed by mixing solute particles capable of absorbing far infrared rays and colorless transparent medium liquid, the two opposite sides of the liquid cavity are provided with first polar plates, and the other two opposite sides of the liquid cavity are provided with second polar plates; the inner top wall of the accommodating cavity is provided with a far infrared lamp panel, a plurality of light guide shafts are arranged below the far infrared lamp panel, and the lower ends of the light guide shafts can movably extend into the liquid cavity; the irradiation unit is provided with a driving piece and a controller; the invention realizes the adjustment of the irradiation intensity of far infrared physiotherapy, can shield and irradiate a certain area, avoids adverse effect on tissues not needing the irradiation area of physiotherapy, avoids 'flood irrigation' physiotherapy, and further improves physiotherapy flexibility.

Description

Far infrared physiotherapy lamp based on electrophoresis control

Technical Field

The invention relates to the technical field of physiotherapy, in particular to a far infrared physiotherapy lamp based on electrophoretic control.

Background

After the human body is irradiated by the red light, the activity of the mitochondrial overgrowth hydrogen peroxide which is most strongly absorbed by the red light can be increased. Promoting metabolism of cells, increasing glycogen content, increasing protein synthesis and adenosine triphosphate decomposition, promoting cell synthesis, promoting wound and ulcer healing, accelerating regeneration of injured nerve, and increasing leukocyte chewing.

The irradiation range of the existing far infrared physiotherapy lamp is fixed, irradiation physiotherapy can only be carried out on the whole area when the physiotherapy lamp is used, a certain area cannot be selected and shielded, the irradiation intensity of a specific area cannot be adjusted, the physiotherapy mode of 'flood irrigation' is low in flexibility, and the normal metabolism of tissues which do not need the irradiation area can be adversely affected.

Disclosure of Invention

The invention aims to overcome the defects and provide a far infrared physiotherapy lamp based on electrophoresis control.

In order to achieve the above object, the present invention is specifically as follows:

a far infrared physiotherapy lamp based on electrophoresis control comprises a support structure and an irradiation unit hinged to the top of the support structure;

the irradiation unit is provided with a liquid cavity and a containing cavity positioned above the liquid cavity, the inner top wall and the inner bottom wall of the liquid cavity are respectively provided with a transparent film electrode, the liquid cavity is filled with electrophoresis liquid, the electrophoresis liquid is formed by mixing solute particles capable of absorbing far infrared rays and medium liquid which is well insulated and colorless and transparent, the two opposite sides of the liquid cavity are provided with first polar plates, and the two opposite sides of the liquid cavity are provided with second polar plates;

the inner top wall of the accommodating cavity is provided with a far infrared lamp panel, a plurality of light guide shafts are arranged below the far infrared lamp panel, and the lower ends of the light guide shafts can movably extend into the liquid cavity;

the irradiation unit is provided with a driving piece for driving each light guide shaft to synchronously move up and down, and a controller electrically connected with the transparent film electrode, the first polar plate, the second polar plate, the driving piece and the far infrared lamp panel.

The irradiation unit comprises a first shell, a baffle plate arranged at the top of the first shell and a second shell arranged at the top of the baffle plate, wherein the liquid cavity is formed between the first shell and the baffle plate, the accommodating cavity is formed between the second shell and the baffle plate, and the first shell and the baffle plate are both made of transparent materials.

According to the invention, the elastic liquid bag is arranged in the accommodating cavity and is communicated with the liquid cavity, and the electrophoresis liquid is filled in the elastic liquid bag.

According to the invention, elastic liquid bags are arranged on two sides of the accommodating cavity.

In the invention, the driving part is a push rod, the accommodating cavity is provided with light guide plates, the upper ends of the light guide shafts are fixedly connected to the light guide plates, and the light guide plates are connected with the output end of the driving part.

The invention further provides a support structure comprising a base body, wherein the base body is fixedly connected with a first support rod, the top of the first support rod is hinged with a second support rod, and the top of the second support rod is hinged with the irradiation unit.

In the invention, the transparent film electrode is a graphene film.

The invention further provides that the solute particles are iron oxide or aluminum oxide.

The invention further provides that the medium liquid is glycerol or silicone oil.

In the invention, the lower end face of the light guide shaft is a light guide surface.

The beneficial effects of the invention are as follows: according to the invention, the liquid cavity is filled with the electrophoresis liquid formed by mixing solute particles capable of absorbing far infrared rays and medium liquid which is well insulated, colorless and transparent, and the first polar plate, the second polar plate and the transparent film electrode are arranged in the liquid cavity, so that far infrared rays emitted by the far infrared lamp plate are emitted through the light guide axis, thereby adjusting the irradiation intensity of far infrared physiotherapy, shielding and irradiating a certain area, avoiding adverse effects on tissues not needing the physiotherapy irradiation area, avoiding 'flood irrigation' physiotherapy, and further improving physiotherapy flexibility.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic view of the structure of the irradiation unit of the present invention;

FIG. 3 is an exploded schematic view of the illumination unit of the present invention;

FIG. 4 is a schematic cross-sectional view of an illumination unit of the present invention;

reference numerals illustrate: 100. a support structure; 101. a base; 102. a first support bar; 103. a second support bar; 200. an irradiation unit; 201. a first housing; 202. a partition plate; 203. a second housing; 204. a far infrared lamp panel; 205. a transparent thin film electrode; 206. a liquid chamber; 207. a receiving chamber; 208. a first plate; 209. a second polar plate; 210. a driving member; 211. a controller; 212. an elastic fluid cell; 213. a light guide plate; 214. an optically conductive axis.

Detailed Description

The invention will now be described in further detail with reference to the drawings and the specific embodiments, without limiting the scope of the invention.

As shown in fig. 1 to 4, the far infrared physiotherapy lamp based on electrophoresis control in this embodiment solves the problem of the existing physiotherapy mode of "flood irrigation" and improves the physiotherapy flexibility. The far infrared physiotherapy lamp includes a support structure 100 and an irradiation unit 200 hinged to the top of the support structure 100.

The irradiation unit 200 is provided with a liquid cavity 206 and a containing cavity 207 positioned above the liquid cavity 206, wherein transparent film electrodes 205 are respectively arranged on the inner top wall and the inner bottom wall of the liquid cavity 206, the liquid cavity 206 is filled with electrophoresis liquid, the electrophoresis liquid is formed by mixing solute particles capable of absorbing far infrared rays and medium liquid which is well insulated and colorless and transparent, first polar plates 208 are arranged on two opposite sides of the liquid cavity 206, and second polar plates 209 are arranged on two opposite sides of the liquid cavity 206;

the inner top wall of the accommodating cavity 207 is provided with a far infrared lamp panel 204, a plurality of light guide shafts 214 are arranged below the far infrared lamp panel 204, and the lower ends of the light guide shafts 214 can movably extend into the liquid cavity 206;

the irradiation unit 200 is provided with a driving member 210 for driving each light guide shaft 214 to move up and down synchronously, and a controller 211 electrically connected to the transparent thin film electrode 205, the first electrode plate 208, the second electrode plate 209, the driving member 210, and the far infrared lamp panel 204. Specifically, the first electrode plate 208 is disposed on the front and rear sidewalls of the liquid chamber 206, and the second electrode plate 209 is disposed on the left and right sidewalls of the liquid chamber 206; initially, solute particles are uniformly dispersed in a medium liquid, and the solute particles can be stably dispersed in the medium liquid and exhibit certain electrical property after being dispersed; preferably, the medium liquid is glycerol or silicone oil, the solute particles are metal oxides such as ferric oxide, aluminum oxide and the like, and the transparent film electrode 205 is a graphene electrode.

In actual use, the controller 211 controls the far infrared lamp panel 204 to work to generate far infrared rays, the far infrared rays are emitted through the light guide shafts 214, and far infrared physiotherapy is performed on the part to be treated; when the intensity of far infrared rays needs to be enhanced, the driving element 210 drives each light guide shaft 214 to synchronously descend to the lowest point, meanwhile, the controller 211 applies voltage to the transparent film electrodes 205 on the upper side and the lower side, so that the liquid cavity 206 forms a first electric field in the up-down direction, solute particles in the electrophoresis liquid move and gather in the upward direction of the transparent film electrodes 205 under the action of the first electric field, when all solute particles in the electrophoresis liquid move to the position above the lower end of the light guide shafts 214, the solute particles do not absorb far infrared rays in the liquid cavity 206 any more, far infrared rays emitted by the far infrared lamp panel 204 are fully emitted through the light guide shafts 214, and at the moment, the intensity of the far infrared rays output by the irradiation unit 200 is strongest;

when the direction and intensity of the first electric field are the largest, all solute particles are gathered upwards under the action of the electric field force, so that solute particles in the electrophoresis liquid near the transparent film electrode 205 above form a first liquid layer, at this time, the controller 211 makes the driving piece 210 drive the lower end of the light guide shaft 214 to move above the first liquid layer, so that after the far infrared rays emitted from the light guide shaft 214 are absorbed by the first liquid layer, the rest of the non-absorbed far infrared rays are emitted through the first liquid layer, the far infrared physiotherapy is performed on the part to be treated, and at this time, the intensity of the far infrared rays output by the irradiation unit 200 is the weakest;

in the electrophoresis process, the movement speed of solute particles in the electrophoresis liquid depends on the charge quantity of the solute particles and the shape of the solute particles, and the charge quantity and the shape difference necessarily exist among all the solute particles in the electrophoresis liquid, so that the movement speed of all the solute particles in the electrophoresis liquid is inconsistent under the same electric field condition; therefore, by utilizing the phenomenon that the movement speeds among solute particles are inconsistent, by controlling the voltages of the upper transparent film electrode 205 and the lower transparent film electrode 205 and enabling the transparent film electrode 205 to generate a second electric field with a periodic alternating change, solute particles can form a second liquid layer with a certain thickness in the electrophoresis liquid, thus the thickness of the second liquid layer can be controlled by controlling the intensity of the second electric field with the alternating change, and the concentration of solute particles in the second liquid layer is in direct proportion to the thickness of the second liquid layer, therefore, the second liquid layer with expected concentration can be obtained, the absorption amount of the second liquid layer to far infrared rays is controlled, and the adjustment of the far infrared physiotherapy intensity is realized;

when a certain part in the irradiation area needs to be shielded, the controller 211 forms a third electric field with alternating periods by controlling the first polar plate 208 and forms a fourth electric field with alternating periods by controlling the second polar plate 209, and controls the intensity of the third electric field and the fourth electric field, so that a third liquid layer with a certain thickness and an effective area smaller than that of the second liquid layer is formed in the electrophoresis liquid, thus controlling the concentration of solute particles by controlling the size of the electric field, controlling the concentration position of solute particles by controlling the alternating periods, so that the solute particles of the third liquid layer can be completely absorbed by far infrared rays emitted by the light guide shaft 214 opposite to the solute particles, so that the position corresponding to the third liquid layer is shielded to form irradiation shadows, the principle of which is similar to that of the shadow is formed by shielding sunlight, and the alternating frequency of the third electric field and the fourth electric field can be controlled, namely, the position of the third liquid layer in the horizontal direction can be controlled, namely the control of the shielding position is realized, so that the normal metabolism of tissues of the area which does not need to be irradiated is avoided; of course, by controlling the intensities of the third electric field and the fourth electric field, the density of solute particles in the third liquid layer can be controlled, so that the intensity of far infrared ray absorbed by the third liquid layer is different, and the irradiation intensity of the corresponding region can be controlled.

According to the embodiment, through the arrangement of the liquid cavity 206, the liquid cavity 206 is filled with the electrophoresis liquid which is formed by mixing solute particles capable of absorbing far infrared rays and medium liquid which is well insulated and colorless and transparent, and the liquid cavity 206 is internally provided with the first polar plate 208, the second polar plate 209 and the transparent film electrode 205, so that far infrared rays emitted by the far infrared lamp plate 204 are emitted through the light guide axis 214, the adjustment of the irradiation intensity of far infrared physiotherapy can be realized, a certain area can be shielded and irradiated, adverse effects on tissues which do not need the physiotherapy irradiation area are avoided, the 'flood irrigation' physiotherapy is avoided, and the physiotherapy flexibility is further improved.

In this embodiment, as shown in fig. 1 to 4, the irradiation unit 200 includes a first housing 201, a partition 202 disposed on the top of the first housing 201, and a second housing 203 disposed on the top of the partition 202, where the first housing 201 and the second housing 203 are both in a groove structure, the partition 202 is sealed and fixed at an opening position of the first housing 201, and the second housing 203 is fixedly connected to the partition 202 in a position with an opening facing downward; the liquid cavity 206 is formed between the first housing 201 and the partition 202, the accommodating cavity 207 is formed between the second housing 203 and the partition 202, and the first housing 201 and the partition 202 are made of transparent materials, so that far infrared rays emitted from the far infrared lamp panel 204 can fully pass through the partition 202 and the first housing 201. The partition 202 and the transparent thin film electrode 205 located above are provided with through holes corresponding to each light guide shaft 214, and the light guide shafts 214 penetrate through the through holes and then extend into the liquid cavity 206.

In the far infrared physiotherapy lamp based on electrophoresis control according to this embodiment, in some embodiments, as shown in fig. 3 and 4, an elastic liquid bag 212 is disposed in the accommodating cavity 207, the elastic liquid bag 212 is communicated with the liquid cavity 206, and the electrophoresis liquid is filled in the elastic liquid bag 212. Specifically, the electrophoretic fluid in the elastic fluid bag 212 is the same as the electrophoretic fluid in the fluid chamber 206, and a certain pressure is provided for the electrophoretic fluid in the fluid chamber 206 by arranging the elastic fluid bag 212, so that the whole fluid chamber 206 can be filled with the electrophoretic fluid; meanwhile, solute particles in the electrophoresis liquid absorb far infrared rays and then generate heat, so that when the temperature of the electrophoresis liquid rises and expands, the expanded electrophoresis liquid can enter the elastic liquid bag 212, and the volume buffering effect is achieved on the liquid cavity 206.

In this embodiment, elastic liquid bags 212 are preferably disposed on both sides of the accommodating chamber 207, so that the volume buffering effect on the liquid chamber 206 is better.

As shown in fig. 3 and 4, in the far infrared physiotherapy lamp based on electrophoretic control according to this embodiment, in some embodiments, the driving piece 210 is a push rod, the accommodating cavity 207 is provided with a light guide plate 213, the upper end of each light guide shaft 214 is fixedly connected to the light guide plate 213, and the light guide plate 213 is connected to the output end of the driving piece 210. In this embodiment, the push rod pushes the light guide plate 213 to move, and the light guide plate 213 synchronously drives each light guide shaft 214 to move, so as to realize displacement adjustment of the light guide shafts 214, so as to adjust the irradiation intensity of the far infrared physiotherapy of the irradiation unit 200.

As shown in fig. 1, in the far infrared physiotherapy lamp based on electrophoresis control according to the present embodiment, in some embodiments, the support structure 100 includes a base 101, the base 101 is fixedly connected with a first support rod 102, a second support rod 103 is hinged to the top of the first support rod 102, and the top of the second support rod 103 is hinged to the irradiation unit 200; specifically, one side of the second housing 203 is hinged to the second support bar 103. In this embodiment, the second support rod 103 is hinged to the first support rod 102, and the irradiation unit 200 is hinged to the second support rod 103, so as to adjust the position and irradiation direction of the irradiation unit 200, and the structure is more flexible.

In the far infrared physiotherapy lamp based on electrophoresis control according to this embodiment, in some embodiments, the lower end surface of the light guide shaft 214 is a light guide surface; the irradiation intensity is adjusted by disposing the light guide surface on the lower end surface of the light guide shaft 214.

The foregoing description is only one preferred embodiment of the invention, and therefore all changes and modifications that come within the meaning and range of equivalency of the structures, features and principles of the invention are intended to be embraced therein.

Claims (10)

1. The far infrared physiotherapy lamp based on electrophoresis control is characterized by comprising a supporting structure and an irradiation unit hinged to the top of the supporting structure;

the irradiation unit is provided with a liquid cavity and a containing cavity, the liquid cavity is provided with a transparent film electrode, the liquid cavity is filled with electrophoresis liquid, the electrophoresis liquid is formed by mixing solute particles capable of absorbing far infrared rays and medium liquid which is well insulated and colorless and transparent, two opposite sides of the liquid cavity are provided with first polar plates, and two opposite sides of the liquid cavity are provided with second polar plates;

the inner top wall of the accommodating cavity is provided with a far infrared lamp panel, a plurality of light guide shafts are arranged below the far infrared lamp panel, and the lower ends of the light guide shafts can movably extend into the liquid cavity;

the irradiation unit is provided with a driving piece for driving each light guide shaft to synchronously move up and down, and a controller electrically connected with the transparent film electrode, the first polar plate, the second polar plate, the driving piece and the far infrared lamp panel.

2. The electrophoresis control-based far infrared physiotherapy lamp according to claim 1, wherein the irradiation unit comprises a first shell, a partition plate arranged at the top of the first shell, and a second shell arranged at the top of the partition plate, the liquid cavity is formed between the first shell and the partition plate, the accommodating cavity is formed between the second shell and the partition plate, and the first shell and the partition plate are made of transparent materials.

3. The far infrared physiotherapy lamp based on electrophoresis control of claim 1, wherein an elastic liquid bag is arranged in the accommodating cavity, the elastic liquid bag is communicated with the liquid cavity, and the electrophoresis liquid is filled in the elastic liquid bag.

4. A far infrared physiotherapy lamp based on electrophoretic control according to claim 3, wherein the two sides of the accommodation chamber are provided with elastic liquid bags.

5. The far infrared physiotherapy lamp based on electrophoresis control according to claim 1, wherein the driving piece is a push rod, the accommodating cavity is provided with light guide plates, the upper ends of the light guide shafts are fixedly connected to the light guide plates, and the light guide plates are connected with the output ends of the driving piece.

6. The electrophoresis control-based far infrared physiotherapy lamp according to claim 1, wherein the support structure comprises a base body fixedly connected with a first support rod, a second support rod is hinged to the top of the first support rod, and the top of the second support rod is hinged to the irradiation unit.

7. The electrophoresis control-based far infrared physiotherapy lamp of claim 1, wherein the transparent thin film electrode is a graphene thin film.

8. The electrophoresis-control-based far infrared physiotherapy lamp according to claim 1, wherein the solute particles are iron oxide or aluminum oxide.

9. The electrophoresis-control-based far infrared physiotherapy lamp according to claim 1, wherein the medium liquid is glycerol or silicone oil.

10. The electrophoresis control-based far infrared physiotherapy lamp according to claim 1, wherein the lower end face of the light guide shaft is a light guide surface.