CN117085259A - Scanning knee physiotherapy lamp - Google Patents

Abstract

The invention relates to the technical field of physiotherapy, in particular to a scanning knee physiotherapy lamp, which comprises a bracket, a guide rail and a rotating shaft; the rotating shaft is provided with a lamp panel; the guide rail is provided with a sliding block in a sliding manner; the bottom of the sliding block is provided with a valve plate; an accommodating cavity is arranged between the inside of the sliding block and the valve plate; a rotor is rotationally arranged in the accommodating cavity; the sliding block is provided with a first air passage and a second air passage; the valve plate is provided with an air inlet; the valve plate is provided with a valve core; the support is provided with a baffle. Compared with a far infrared physiotherapy lamp with fixed continuous irradiation, the scanning physiotherapy is reciprocating scanning irradiation, heat accumulation can not be generated on the surface of the skin, and the physiotherapy can be performed with higher intensity; in addition, after the compressed air is discharged from the accommodating cavity, the lamp panel can be cooled and blown out to the region corresponding to the far infrared light spot on the physiotherapy part, so that the heat of the physiotherapy part is further taken away, the skin tolerance is further improved, the physiotherapy strength is increased, and the physiotherapy effect is improved.

Description

Scanning knee physiotherapy lamp

Technical Field

The invention relates to the technical field of physiotherapy, in particular to a scanning knee physiotherapy lamp.

Background

The existing far infrared physiotherapy lamps continuously emit far infrared rays to the physiotherapy part of a patient through the far infrared LED lamp panel to carry out physiotherapy on the patient; the far infrared ray is continuously irradiated, and the distance between the skin surface and the far infrared LED lamp panel is smaller than the distance between the muscle layer at the bottom layer of the skin and the far infrared LED lamp panel, so that the thermal effect of the skin surface is obviously stronger than that of the muscle layer; the intensity of far infrared rays is relatively low due to the skin temperature tolerance, so that the physiotherapy effect of the muscle layer is limited.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide a scanning knee physiotherapy lamp which adopts reciprocating scanning irradiation scanning physiotherapy, does not generate heat accumulation on the skin surface and can carry out physiotherapy with higher intensity.

The aim of the invention is achieved by the following technical scheme: a scanning knee physiotherapy lamp comprises a bracket, a guide rail arranged on the bracket and a rotating shaft rotatably arranged on the bracket; the rotating shafts are arranged at the bottom of the guide rail in parallel; a lamp panel is arranged at the bottom of the rotating shaft;

the guide rail is provided with a sliding block in a sliding manner; the bottom of the sliding block is provided with a valve plate; an accommodating cavity is arranged between the inside of the sliding block and the valve plate; a rotor is rotationally arranged in the accommodating cavity; a linkage mechanism is arranged between the rotor and the guide rail; the sliding block is provided with a first air passage for driving the rotor to rotate positively and a second air passage for driving the rotor to rotate reversely; the valve plate is provided with an air inlet; the valve plate is movably provided with a valve core among the air inlet, the first air passage and the second air passage;

the support is provided with baffles matched with the valve core at two sides of the guide rail;

the scanning knee physiotherapy lamp also comprises an inflation device communicated with the air inlet.

The invention is further arranged that the linkage mechanism comprises a sliding rack and a sliding gear; the sliding rack is arranged in the guide rail along the length direction of the guide rail; the top of the rotor protrudes out of the accommodating cavity and is connected with the sliding gear; the sliding gear is meshed with the sliding rack.

The invention is further arranged that the two baffles are respectively arranged on the two sides of the guide rail in a sliding way; the baffle is provided with a blocking block; the resisting block is provided with an elastic locking piece; the elastic locking piece is abutted against the sliding rack.

The invention is further arranged that a third air passage and a fourth air passage are arranged in the valve plate; a fifth air passage and a sixth air passage are arranged in the valve core;

the third air passage is communicated with the first air passage; the fourth air passage is communicated with the second air passage; the air inlet is communicated with the third air passage through the fifth air passage; the air inlet is communicated with the fourth air passage through the sixth air passage;

the valve core is movably arranged in the valve plate, so that the air inlet and the fifth air passage are communicated with the third air passage or the air inlet and the sixth air passage are communicated with the fourth air passage.

The invention is further arranged that an exhaust air passage communicated with the accommodating cavity is arranged in the sliding block; the two sides of the sliding block are provided with spray pipes; the exhaust gas passage is communicated with the spray pipe.

The invention is further arranged that a shielding cover is sleeved outside the lamp panel; the bottom of the shielding cover is provided with a light-transmitting window along the length direction of the shielding cover; the top of the shielding cover is provided with guide plates towards two sides;

and a focusing lens is arranged between the shielding cover and the lamp panel.

The invention is further arranged that the outer wall of the rotating shaft is provided with a spiral groove along the length direction; the valve plate is provided with a bolt matched with the spiral groove in an extending mode; the bolt is movably arranged in the spiral groove;

the air inlet is arranged on the bolt.

The invention is further arranged that the rotating shaft is of a hollow structure; a telescopic connecting pipe is movably arranged in the rotating shaft; one end of the telescopic connecting pipe is communicated with the air inlet of the bolt; the other end of the telescopic connecting pipe is arranged on the bracket;

the inflation device is communicated with the other end of the telescopic connecting pipe.

The invention is further arranged that the scanning knee physiotherapy lamp further comprises a base; the air charging device is arranged at the bottom of the base; the support is arranged at the top of the base; a guide pipe is arranged between the air charging device and the other end of the telescopic connecting pipe;

the bottom of the base is rotatably provided with a transmission shaft; a one-way gear is sleeved on the transmission shaft; one end of the transmission shaft is connected with the air charging device; the bottom of the base is provided with a pedal; one end of the pedal is hinged with the base; the other end of the pedal is provided with an arc-shaped rack meshed with the unidirectional gear; a reset spring piece is arranged between the pedal and the base.

The invention is further arranged that a power generation device is arranged at the bottom of the base; the power generation device is connected with the other end of the transmission shaft.

The invention has the beneficial effects that: compared with a far infrared physiotherapy lamp with fixed continuous irradiation, the scanning physiotherapy is reciprocating scanning irradiation, heat accumulation can not be generated on the surface of the skin, and the physiotherapy can be performed with higher intensity; in addition, after the compressed air is discharged from the accommodating cavity, the lamp panel can be cooled and blown out to the region corresponding to the far infrared light spot on the physiotherapy part, so that the heat of the physiotherapy part is further taken away, the skin tolerance is further improved, the physiotherapy strength is increased, and the physiotherapy effect is improved.

Drawings

The invention will be further described with reference to the accompanying drawings, in which embodiments do not constitute any limitation of the invention, and other drawings can be obtained by one of ordinary skill in the art without inventive effort from the following drawings.

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

FIG. 2 is a schematic view of another view of the present invention;

FIG. 3 is a schematic view of the structure of the present invention after the base is hidden;

FIG. 4 is a schematic view of another view of the present invention after the base is hidden;

FIG. 5 is a schematic view of the slider, rail, and bracket assembly of the present invention;

FIG. 6 is an exploded view of the slider, rail, and bracket assembly of the present invention;

FIG. 7 is a schematic view of the slider, rotating shaft and lamp panel assembly of the present invention;

FIG. 8 is an exploded view of the slider, pivot shaft and light panel assembly of the present invention;

FIG. 9 is a cross-sectional view of the slider, swivel shaft, and light panel of the present invention mated;

FIG. 10 is a schematic view of the slider and valve plate of the present invention mated configuration;

FIG. 11 is an exploded view of the slider and valve plate of the present invention mated;

FIG. 12 is a perspective view of the slider of the present invention mated with a valve plate;

wherein: 1. a bracket; 11. a baffle; 12. a stopper; 13. an elastic locking piece; 14. a telescopic connecting pipe; 2. a rotating shaft; 21. a spiral groove; 31. a lamp panel; 32. a focusing lens; 33. a shielding cover; 34. a light-transmitting window; 35. a deflector; 4. a guide rail; 41. sliding racks; 5. a slide block; 51. a sliding gear; 52. a receiving chamber; 53. a rotor; 54. a first airway; 55. a second airway; 56. an exhaust gas passage; 57. a spray pipe; 6. a valve plate; 61. an air inlet; 62. a third airway; 63. a fourth airway; 64. a valve core; 65. a fifth air passage; 66. a sixth airway; 67. a plug pin; 71. an inflator; 72. a guide tube; 73. a power generation device; 8. a base; 81. a transmission shaft; 82. a one-way gear; 83. a pedal; 84. an arc-shaped rack; 85. and resetting the spring plate.

Detailed Description

The invention will be further described with reference to the following examples.

As can be seen from fig. 1 to 12, the scanning knee physiotherapy lamp according to the present embodiment includes a bracket 1, a guide rail 4 provided on the bracket 1, and a rotating shaft 2 rotatably provided on the bracket 1; the rotating shaft 2 is arranged at the bottom of the guide rail 4 in parallel; the bottom of the rotating shaft 2 is provided with a lamp panel 31;

the guide rail 4 is provided with a sliding block 5 in a sliding manner; the bottom of the sliding block 5 is provided with a valve plate 6; an accommodating cavity 52 is arranged between the inside of the sliding block 5 and the valve plate 6; a rotor 53 is rotatably arranged in the accommodating cavity 52; a linkage mechanism is arranged between the rotor 53 and the guide rail 4; the sliding block 5 is provided with a first air passage 54 for driving the rotor 53 to rotate positively and a second air passage 55 for driving the rotor 53 to rotate reversely; the valve plate 6 is provided with an air inlet 61; valve plate 6 is movably provided with valve core 64 between air inlet 61, first air passage 54 and second air passage 55;

the bracket 1 is provided with baffle plates 11 matched with the valve cores 64 at two sides of the guide rail 4;

the scanning knee physiotherapy lamp further comprises an inflator 71 in communication with the air inlet 61. Wherein the inflation device 71 may be an electric air pump or a manual air pump.

Specifically, when the user needs to perform infrared physiotherapy on the knee, the scanning knee physiotherapy lamp described in this embodiment sits at the scanning knee physiotherapy lamp in a sitting position, so that the knee part is just below the lamp panel 31, and then starts the lamp panel 31, so that the lamp panel 31 emits far infrared rays; meanwhile, during use, compressed air is generated by the inflator 71 and is delivered to the air inlet 61 of the valve plate 6;

when the valve core 64 is at the first position, the air inlet 61 is communicated with the first air channel 54, compressed air enters the accommodating cavity 52 through the air inlet 61 and the first air channel 54, so that the rotor 53 is driven to rotate positively, and the sliding block 5 is driven to slide along the first direction of the guide rail 4 under the action of the linkage mechanism;

when the slide block 5 moves to the contact of the valve core 64 and the baffle 11, the baffle 11 pushes the valve core 64 to slide to the second position, and at the moment, the air inlet 61 is communicated with the second air passage 55, so that the air passage direction is changed, the rotor 53 rotates reversely, and the slide block 5 is driven to slide along the second direction of the guide rail 4 under the action of the linkage mechanism, and the second direction is opposite to the first direction.

Compared with a far infrared physiotherapy lamp with fixed continuous irradiation, the scanning physiotherapy is reciprocating scanning irradiation, heat accumulation can not be generated on the surface of the skin, and physiotherapy can be performed with higher intensity; in addition, after the compressed air is discharged from the accommodating cavity 52, the lamp panel 31 can be cooled and blown out to the region corresponding to the far infrared light spot on the physiotherapy part, so that the heat of the physiotherapy part is further taken away, the skin tolerance is further improved, the physiotherapy strength is increased, and the physiotherapy effect is improved.

The linkage mechanism comprises a sliding rack 41 and a sliding gear 51; the sliding rack 41 is arranged in the guide rail 4 along the length direction of the guide rail 4; the top of the rotor 53 protrudes out of the accommodating cavity 52 and is connected with the sliding gear 51; the slide gear 51 is engaged with the slide rack 41.

Specifically, when the rotor 53 rotates, the rotor 53 can drive the sliding gear 51 to rotate in the forward direction or in the reverse direction, so that the sliding gear 51 can drive the slider 5 to reciprocate along the sliding rack 41.

In the scanning knee physiotherapy lamp of the embodiment, two baffle plates 11 are respectively arranged on two sides of the guide rail 4 in a sliding manner; the baffle 11 is provided with a stop block 12; the resisting block 12 is provided with an elastic locking piece 13; the elastic locking piece 13 abuts against the slide rack 41.

Specifically, in this embodiment, by disposing the baffle plates 11 on both sides of the guide rail 4, when the valve core 64 contacts with the baffle plate 11 on one side of the guide rail 4, the baffle plate 11 can push the valve core 64 to change the position on the valve plate 6, so as to change different air passage communication, so as to realize forward rotation or reverse rotation of the rotor 53.

In addition, an elastic locking piece 13 is arranged between the baffle 11 and the sliding rack 41, so that the position of the baffle 11 can be adjusted, the sliding stroke of the sliding block 5 can be adjusted, and the scanning range of the scanning physiotherapy unit can be controlled.

In the scanning knee physiotherapy lamp according to the present embodiment, a third air passage 62 and a fourth air passage 63 are provided in the valve plate 6; a fifth air passage 65 and a sixth air passage 66 are arranged in the valve core 64;

the third air passage 62 communicates with the first air passage 54; the fourth air passage 63 communicates with the second air passage 55; the air inlet 61 is communicated with the third air passage 62 through a fifth air passage 65; the air inlet 61 is communicated with the fourth air passage 63 through a sixth air passage 66;

the valve core 64 is movably arranged in the valve plate 6, so that the air inlet 61 and the fifth air passage 65 are communicated with the third air passage 62 or the air inlet 61 and the sixth air passage 66 are communicated with the fourth air passage 63.

Specifically, when the valve spool 64 moves to the first position, the air intake port 61, the fifth air passage 65, the third air passage 62, and the first air passage 54 are sequentially communicated, so that the rotor 53 is rotated in the forward direction; when the valve spool 64 moves to the second position, the air inlet port 61, the sixth air passage 66, the fourth air passage 63, and the second air passage 55 are sequentially communicated, so that the rotor 53 is reversely rotated.

In the scanning knee physiotherapy lamp according to the embodiment, an exhaust air passage 56 is arranged in the slider 5 and is communicated with the accommodating cavity 52; the two sides of the sliding block 5 are provided with spray pipes 57; the exhaust gas passage 56 communicates with the nozzle 57.

Specifically, compressed gas enters the accommodating cavity 52, drives the rotor 53 to rotate, and then is discharged from the exhaust air passage 56 to the spray pipes 57 on two sides of the sliding block 5, so that the lamp panel 31 can be cooled and blown out to the region corresponding to the far infrared light spots on the physiotherapy part, and heat of the physiotherapy part is further taken away, so that the skin tolerance is further improved, the physiotherapy strength is increased, and the physiotherapy effect is improved.

In the scanning knee physiotherapy lamp according to the embodiment, a shielding cover 33 is sleeved outside the lamp panel 31; the bottom of the shielding cover 33 is provided with a light-transmitting window 34 along the length direction of the shielding cover 33; a deflector 35 is arranged at the top of the shielding cover 33 towards two sides;

a focusing lens 32 is arranged between the shielding cover 33 and the lamp panel 31.

Specifically, the air discharged from the nozzle 57 flows to the lamp panel 31, specifically, the air discharged from the accommodating cavity 52 enters the nozzle 57 through the air discharge channel 56 and then is sprayed downwards, and enters the shielding cover 33 under the flow guide of the deflector 35, after the lamp panel 31 is cooled, the air is blown out from the light-transmitting window 34 to the region corresponding to the far infrared light spot on the physiotherapy part, so that the heat of the physiotherapy part is further taken away, the skin tolerance is further improved, the physiotherapy intensity is increased, and the physiotherapy effect is improved.

In the scanning knee physiotherapy lamp according to the embodiment, a spiral groove 21 is formed on the outer wall of the rotating shaft 2 along the length direction; the valve plate 6 is provided with a bolt 67 matched with the spiral groove 21 in an extending mode; the bolt 67 is movably arranged in the spiral groove 21; the air inlet 61 is provided on a plug 67.

Specifically, when the slider 5 reciprocates on the guide rail 4, the bolt 67 is movably inserted into the spiral groove 21 of the rotating shaft 2, so that when the slider 5 slides, the rotating shaft 2 can reciprocate along the shape of the spiral groove 21, and meanwhile, the lamp panel 31 is driven to reciprocate, so that heat accumulation of the infrared lamp on the skin surface is further prevented, and physiotherapy can be performed with higher strength.

The rotating shaft 2 of the scanning knee physiotherapy lamp is of a hollow structure; a telescopic connecting pipe 14 is movably arranged in the rotating shaft 2; one end of the telescopic connecting pipe 14 is communicated with the air inlet 61 of the bolt 67; the other end of the telescopic connecting pipe 14 is arranged on the bracket 1; the inflator 71 communicates with the other end of the telescopic connection pipe 14.

Specifically, the telescopic connection pipe 14 penetrates the rotation shaft 2 and is connected with the plug pin 67 at the position of the spiral groove 21, so that the telescopic connection pipe 14 communicates with the air inlet 61, and the inflator 71 can supply air to the air inlet 61.

The embodiment of the scanning knee physiotherapy lamp further comprises a base 8; the inflator 71 is arranged at the bottom of the base 8; the bracket 1 is arranged at the top of the base 8; a guide tube 72 is arranged between the inflator 71 and the other end of the telescopic connecting tube 14;

a transmission shaft 81 is rotatably arranged at the bottom of the base 8; a one-way gear 82 is sleeved on the transmission shaft 81; one end of the transmission shaft 81 is connected with the inflator 71; the bottom of the base 8 is provided with a pedal 83; one end of the pedal 83 is hinged with the base 8; the other end of the pedal 83 is provided with an arc-shaped rack 84 meshed with the unidirectional gear 82; a reset spring piece 85 is arranged between the pedal 83 and the base 8. In the scanning knee physiotherapy lamp according to the embodiment, a power generation device 73 is arranged at the bottom of the base 8; the power generation device 73 is connected to the other end of the transmission shaft 81.

Specifically, with the above arrangement, the user can drive the transmission shaft 81 to rotate by alternately stepping on the pedals 83 on both sides to drive the power generation device 73 to generate power, and supply the power to the lamp panel 31 to generate far infrared rays; meanwhile, when the transmission shaft 81 rotates, the inflator 71 can be driven to generate compressed air; the user can exercise, and simultaneously, the effects of saving electricity and saving cost are achieved.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention.

Claims (10)

1. A scanning knee physiotherapy lamp, characterized in that: comprises a bracket, a guide rail arranged on the bracket and a rotating shaft rotatably arranged on the bracket; the rotating shafts are arranged at the bottom of the guide rail in parallel; a lamp panel is arranged at the bottom of the rotating shaft;

the guide rail is provided with a sliding block in a sliding manner; the bottom of the sliding block is provided with a valve plate; an accommodating cavity is arranged between the inside of the sliding block and the valve plate; a rotor is rotationally arranged in the accommodating cavity; a linkage mechanism is arranged between the rotor and the guide rail; the sliding block is provided with a first air passage for driving the rotor to rotate positively and a second air passage for driving the rotor to rotate reversely; the valve plate is provided with an air inlet; the valve plate is movably provided with a valve core among the air inlet, the first air passage and the second air passage;

the support is provided with baffles matched with the valve core at two sides of the guide rail;

the scanning knee physiotherapy lamp also comprises an inflation device communicated with the air inlet.

2. A scanning knee physiotherapy lamp as claimed in claim 1, characterized in that: the linkage mechanism comprises a sliding rack and a sliding gear; the sliding rack is arranged in the guide rail along the length direction of the guide rail; the top of the rotor protrudes out of the accommodating cavity and is connected with the sliding gear; the sliding gear is meshed with the sliding rack.

3. A scanning knee physiotherapy lamp as claimed in claim 2, characterized in that: the two baffles are respectively arranged on two sides of the guide rail in a sliding way; the baffle is provided with a blocking block; the resisting block is provided with an elastic locking piece; the elastic locking piece is abutted against the sliding rack.

4. A scanning knee physiotherapy lamp as claimed in claim 1, characterized in that: a third air passage and a fourth air passage are arranged in the valve plate; a fifth air passage and a sixth air passage are arranged in the valve core;

the third air passage is communicated with the first air passage; the fourth air passage is communicated with the second air passage; the air inlet is communicated with the third air passage through the fifth air passage; the air inlet is communicated with the fourth air passage through the sixth air passage;

the valve core is movably arranged in the valve plate, so that the air inlet and the fifth air passage are communicated with the third air passage or the air inlet and the sixth air passage are communicated with the fourth air passage.

5. A scanning knee physiotherapy lamp as claimed in claim 1, characterized in that: an exhaust air passage communicated with the accommodating cavity is arranged in the sliding block; the two sides of the sliding block are provided with spray pipes; the exhaust gas passage is communicated with the spray pipe.

6. The scanning knee physiotherapy lamp of claim 5, wherein: a shielding cover is sleeved outside the lamp panel; the bottom of the shielding cover is provided with a light-transmitting window along the length direction of the shielding cover; the top of the shielding cover is provided with guide plates towards two sides;

and a focusing lens is arranged between the shielding cover and the lamp panel.

7. A scanning knee physiotherapy lamp as claimed in claim 1, characterized in that: the outer wall of the rotating shaft is provided with a spiral groove along the length direction; the valve plate is provided with a bolt matched with the spiral groove in an extending mode; the bolt is movably arranged in the spiral groove;

the air inlet is arranged on the bolt.

8. A scanning knee physiotherapy lamp as claimed in claim 1, characterized in that: the rotating shaft is of a hollow structure; a telescopic connecting pipe is movably arranged in the rotating shaft; one end of the telescopic connecting pipe is communicated with the air inlet of the bolt; the other end of the telescopic connecting pipe is arranged on the bracket;

the inflation device is communicated with the other end of the telescopic connecting pipe.

9. The scanning knee physiotherapy lamp of claim 8, wherein: the scanning knee physiotherapy lamp also comprises a base; the air charging device is arranged at the bottom of the base; the support is arranged at the top of the base; a guide pipe is arranged between the air charging device and the other end of the telescopic connecting pipe;

the bottom of the base is rotatably provided with a transmission shaft; a one-way gear is sleeved on the transmission shaft; one end of the transmission shaft is connected with the air charging device; the bottom of the base is provided with a pedal; one end of the pedal is hinged with the base; the other end of the pedal is provided with an arc-shaped rack meshed with the unidirectional gear; a reset spring piece is arranged between the pedal and the base.

10. The scanning knee physiotherapy lamp of claim 9, wherein: the bottom of the base is provided with a power generation device; the power generation device is connected with the other end of the transmission shaft.