CN219398731U - Therapeutic equipment - Google Patents

Abstract

The utility model relates to the technical field of medical equipment, and provides a therapeutic apparatus, which comprises: the device comprises a cylindrical shell, a light source assembly, a ranging sensor, a controller and a driving mechanism; one end of the cylindrical shell is provided with a bearing plate, the other end of the cylindrical shell is provided with a cover plate, the light source assembly and the distance measuring sensor are both arranged on the bearing plate, and the driving mechanism is movably connected with the cylindrical shell; the controller is used for controlling the opening and closing of the light source assembly, the light source assembly is used for emitting light beams to the treatment part, the distance measuring sensor is used for detecting the relative distance between the emitting surface of the light source assembly and the treatment part, and the driving mechanism is used for driving the light source assembly to move to a preset position. According to the therapeutic apparatus, the distance measuring sensor detects the relative distance between the light source assembly and the therapeutic part in real time, and the driving mechanism drives the cylindrical shell to move so as to drive the light source assembly to move to the preset position, so that the relative distance between the light source assembly and the therapeutic part is kept within the preset distance range, and the therapeutic effect is improved.

Description

Therapeutic equipment

Technical Field

The utility model relates to the technical field of medical instruments, in particular to a therapeutic apparatus.

Background

The phototherapy instrument is used as a physiotherapy auxiliary instrument and is widely applied to the medical field. Phototherapy treats patients through irradiation of red light, blue light or yellow light, and has good effects in tissue repair, wound healing, immunoregulation, chronic inflammation, allergic inflammation, pain relief, etc.

In the treatment process by using the phototherapy, the distance between the light beam emitted by the light source and the treatment part has an important influence on the treatment effect, the distance between the light source and the treatment part is too short, a patient is easy to scald, the distance between the light source and the treatment part is too far, and the illumination intensity is insufficient, so that the curative effect is influenced. In the prior art, the distance between the light source and the treatment part is manually adjusted, so that the distance between the light source and the treatment part is not easy to ensure, and the treatment effect is easy to be poor.

Disclosure of Invention

The utility model provides a therapeutic apparatus, which is used for solving the problem of poor therapeutic effect caused by inaccurate distance between a light source and a therapeutic part in the treatment process of the conventional therapeutic apparatus.

The present utility model provides a therapeutic apparatus comprising: the device comprises a cylindrical shell, a light source assembly, a ranging sensor, a controller and a driving mechanism;

one end of the cylindrical shell is provided with a bearing plate, the other end of the cylindrical shell is provided with a cover plate, the light source assembly and the distance measuring sensor are both arranged on the bearing plate, and the driving mechanism is movably connected with the cylindrical shell;

the controller is used for controlling the opening and closing of the light source assembly, the light source assembly is used for emitting light beams to the treatment part, the distance measuring sensor is used for detecting the relative distance between the emitting surface of the light source assembly and the treatment part, and the driving mechanism is used for driving the light source assembly to move to a preset position.

According to the therapeutic apparatus provided by the utility model, the therapeutic apparatus further comprises a temperature sensor, and the temperature sensor is arranged on the bearing plate and used for detecting the temperature of a therapeutic part.

According to the therapeutic apparatus provided by the utility model, the temperature sensor is connected with the controller, and the controller controls the light source assembly to be turned off under the condition that the temperature value detected by the temperature sensor is larger than the preset temperature threshold value.

According to the therapeutic apparatus provided by the utility model, the therapeutic apparatus further comprises a voice broadcasting device, and the voice broadcasting device is connected with the controller;

and the controller controls the voice broadcasting device to conduct voice broadcasting according to a comparison result of the temperature value detected by the temperature sensor and a preset temperature threshold value.

According to the therapeutic apparatus provided by the utility model, the distance measuring sensor is connected with the controller;

and the controller controls the voice broadcasting device to conduct voice broadcasting according to a comparison result of the distance value detected by the distance measuring sensor and a preset distance threshold value.

According to the therapeutic apparatus provided by the utility model, the driving mechanism comprises an arm support assembly;

the arm support assembly comprises a first arm section and a second arm section, one end of the first arm section is used for being movably connected with the base, the other end of the first arm section is movably connected with one end of the second arm section, and the other end of the second arm section is movably connected with the cylindrical shell.

According to the therapeutic apparatus provided by the utility model, the driving mechanism further comprises a connecting component;

the other end of the second arm section is movably connected with the cylindrical shell through the connecting component, and the connecting component can drive the cylindrical shell to rotate along a first direction and a second direction, wherein the first direction and the second direction are mutually perpendicular.

According to the therapeutic apparatus provided by the utility model, the therapeutic apparatus further comprises the holding part, and the holding part is arranged on one side of the cover plate, which is away from the bearing plate.

According to the therapeutic apparatus provided by the utility model, the therapeutic apparatus further comprises a conical shell, wherein the conical shell is provided with a small end and a large end, and the small end is connected with one end of the cylindrical shell.

According to the therapeutic apparatus provided by the utility model, the light source assembly comprises a red light unit, a blue light unit and a light supplementing unit, and the light supplementing unit is arranged in the circumferences of the red light unit and the blue light unit.

According to the therapeutic apparatus provided by the utility model, the bearing plate is arranged at one end of the cylindrical shell, the light source component and the distance measuring sensor are both arranged on the bearing plate, the driving mechanism is connected with the cylindrical shell, the distance measuring sensor detects the relative distance between the light source component and a therapeutic part in real time, the driving mechanism drives the cylindrical shell to move, and then the light source component is driven to move to a preset position, so that the relative distance between the light source component and the therapeutic part is kept within the preset distance range, and further the therapeutic effect is improved.

Drawings

In order to more clearly illustrate the utility model or the technical solutions of the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the utility model, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a front view of a therapeutic apparatus provided by the present utility model;

FIG. 2 is a bottom view of the therapeutic apparatus provided by the present utility model;

reference numerals: 1: a cylindrical housing; 2: a carrying plate; 3: a light source assembly; 301: a first light source; 302: a light supplementing lamp; 4: a ranging sensor; 5: a temperature sensor; 6: a driving mechanism; 601: arm support components; 6011: a first arm segment; 6012: a second arm segment; 602: a connection assembly; 6021: a first connector; 6022: a second connector; 7: a cover plate; 8: a grip portion; 9: a conical shell.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The therapeutic apparatus according to the embodiment of the present utility model is described below with reference to fig. 1 and 2.

As shown in fig. 1 and 2, a therapeutic apparatus provided in an embodiment of the present utility model includes: a cylindrical housing 1, a light source assembly 3, a distance measuring sensor 4, a controller, and a driving mechanism 6; one end of the cylindrical shell 1 is provided with a bearing plate 2, the other end of the cylindrical shell 1 is provided with a cover plate 7, the light source assembly 3 and the distance measuring sensor 4 are both arranged on the bearing plate 2, and the driving mechanism 6 is movably connected with the cylindrical shell 1; the controller is used for controlling the opening and closing of the light source assembly 3, the light source assembly 3 is used for emitting light beams to the treatment position, the ranging sensor 4 is used for detecting the relative distance between the emitting surface of the light source assembly 3 and the treatment position, and the driving mechanism 6 is used for driving the light source assembly 3 to move to a preset position.

Specifically, the cylindrical housing 1, the cover plate 7, and the carrier plate 2 enclose a hollow cavity in which electrical components and the like are mounted. The cylindrical housing 1 may be integrally formed, or the cylindrical housing 1 may be formed by splicing a plurality of arc-shaped housings, and the cover plate 7 and the carrier plate 2 are mounted at both ends of the cylindrical housing 1. The cover plate 7 is provided with a first hollowed-out part, the first hollowed-out part comprises a plurality of first through holes, the plurality of first through holes are distributed at intervals, and the first hollowed-out part is used for radiating heat. The cylindrical shell 1 is provided with a second hollow part, the second hollow part comprises a plurality of second through holes, the second through holes are distributed at intervals, and the second hollow part is also used for heat dissipation.

The light source assembly 3 and the ranging sensor 4 are installed on the bearing plate 2, the light source assembly 3 comprises a first light source 301 and a second light source, the first light source 301 comprises a red light unit and a blue light unit, the red light unit comprises a plurality of red light LED lamps, the blue light unit comprises a plurality of blue light LED lamps, and the plurality of red light LED lamps and the plurality of blue light LED lamps are installed in the middle area of the bearing plate 2 at intervals. The second light source includes a plurality of light compensating lamps 302, the plurality of light compensating lamps 302 form a light compensating unit, and the plurality of light compensating lamps 302 are arranged at intervals in the circumferential direction of the first light source 301 around the central axis of the carrier plate 2. The red light unit can emit red light with a wavelength of 625-740 nanometers, the blue light unit can emit blue light with a wavelength of 400-480 nanometers, and the light supplementing unit can emit near infrared light with a wavelength of 700-1100 nanometers. The red light unit, the blue light unit and the light supplementing unit are all connected with the controller, and the controller can respectively control the on and off of the red light unit, the on and off of the blue light unit and the on and off of the light supplementing unit, so that the light source assembly 3 has various working modes, irradiates the treatment part of a patient and carries out treatment.

The ranging sensor 4 is mounted on the carrier plate 2, the ranging sensor 4 may be a laser ranging sensor, an ultrasonic ranging sensor or an infrared ranging sensor, and the ranging sensor 4 is used for detecting a relative distance between the emitting surface of the light source assembly 3 and a treatment part of a patient. In the treatment process by using the phototherapy, the relative distance between the emitting surface of the light source assembly 3 and the treatment part of the patient has an important influence on the treatment effect, the relative distance between the emitting surface of the light source assembly 3 and the treatment part of the patient is too small, the patient is easy to scald, the relative distance between the emitting surface of the light source assembly and the treatment part is too large, and the treatment effect is poor, so the relative distance between the emitting surface of the light source assembly and the treatment part of the patient is required to be kept within the preset distance range, and the treatment effect can be ensured. The preset distance range is set according to practical situations, for example, the preset distance range is 100-200 mm.

The distance value detected by the distance measuring sensor 4 can be displayed through a display screen, and can also be played through a voice playing mode. The distance measuring sensor 4 is convenient for a worker to move the light source assembly 3 to a preset position through the driving mechanism 6, the light source assembly 3 is moved to the preset position, and the relative distance between the emitting surface of the light source assembly 3 and the treatment part of the patient is within a preset distance range.

Depending on the position of the treatment site of the patient, the patient is treated in a sitting posture, a supine posture, a prone posture, or a lateral posture. The driving mechanism 6 is connected with the cylindrical shell 1, and the driving mechanism 6 can drive the cylindrical shell 1 to translate and rotate in a vertical plane and translate and rotate in a horizontal plane, so that the light source assembly 3 is opposite to a treatment part of a patient. The driving mechanism 6 may be driven manually or electrically, and the relative distance between the light source module 3 and the treatment site is adjusted by the driving mechanism 6. In the process of moving the light source assembly 3 by the driving mechanism 6, the distance sensor detects the relative distance between the light source assembly 3 and the treatment part in real time, so that the light source assembly 3 can accurately reach the preset position.

The distance measuring sensor 4 and the light source component 3 are all installed on the bearing plate 2, and the driving mechanism 6 drives the in-process that the tubular shell 1 moved, and the distance measuring sensor 4 and the light source component 3 move synchronously, and the relative distance between the light source component 3 and the treatment part is detected in real time through the distance measuring sensor 4, so that the relative distance between the light source component 3 and the treatment part is ensured to be within a preset distance range, and the treatment effect is further improved.

In the embodiment of the utility model, one end of the cylindrical shell 1 is provided with the bearing plate 2, the light source component 3 and the ranging sensor 4 are both arranged on the bearing plate 2, the driving mechanism 6 is connected with the cylindrical shell 1, the ranging sensor 4 detects the relative distance between the light source component 3 and the treatment part in real time, the driving mechanism 6 drives the cylindrical shell 1 to move so as to drive the light source component 3 to move to a preset position, so that the relative distance between the light source component 3 and the treatment part is kept within the preset distance range, and the treatment effect is further improved.

In an alternative embodiment, as shown in fig. 2, the therapeutic apparatus further comprises a temperature sensor 5, and the temperature sensor 5 is provided on the carrier plate 2 and is used for detecting the temperature of the therapeutic site.

Specifically, the therapeutic apparatus further comprises a temperature sensor 5, the temperature sensor 5 is mounted on the bearing plate 2, the temperature of a therapeutic part can be detected in real time by the temperature sensor 5 in the therapeutic process, and the temperature value detected by the temperature sensor 5 can be displayed through a display screen or played through a voice playing mode. The temperature sensor 5 is convenient for medical staff to master the temperature of the treatment part at any time, so that the temperature of the treatment part is ensured to be kept within a preset temperature range, and the preset temperature range can be 40-60 ℃. The temperature value detected by the temperature sensor 5 is larger than 60 ℃, so that scalding is possibly caused, and the light source assembly 3 is turned off at the moment, so that a patient is prevented from being scalded. The temperature value detected by the temperature sensor 5 is smaller than 40 ℃, which indicates that part of lamps of the light source assembly 3 may be damaged, and can remind workers to overhaul the light source assembly 3 in time.

The temperature sensor 5 is arranged on the bearing plate 2, and when the light source assembly 3 is started, the temperature of a treatment part is detected in real time through the temperature sensor 5, so that the temperature of the treatment part is ensured to be kept within a preset temperature range, and the use safety of the therapeutic instrument is further ensured.

In the embodiment of the utility model, the temperature sensor 5 is arranged on the bearing plate 2, so that the temperature of a treatment part can be detected in real time, the temperature of the treatment part can be ensured to be kept within a preset temperature range, and the use safety of a therapeutic instrument is further ensured.

In an alternative embodiment, the temperature sensor 5 is connected to a controller, and the controller controls the light source assembly 3 to be turned off when the temperature value detected by the temperature sensor 5 is greater than a preset temperature threshold value.

Specifically, the temperature sensor 5 and the light source assembly 3 are both connected with a controller, the temperature sensor 5 detects the temperature of the treatment part in real time in the state that the light source assembly 3 is turned on, and the controller controls the on and off states of the light source assembly 3 according to the comparison result of the temperature value detected by the temperature sensor 5 and the preset temperature threshold value. For example, the preset temperature threshold is 60 ℃, and in the treatment process, if the temperature value detected by the temperature sensor 5 is greater than 60 ℃, the controller controls the light source assembly 3 to be turned off, so that a patient is prevented from being scalded, and the use safety and reliability of the therapeutic apparatus are guaranteed.

In an alternative embodiment, the therapeutic apparatus further comprises a voice broadcast device, and the voice broadcast device is connected with the controller; and the controller controls the voice broadcasting device to carry out voice broadcasting according to the comparison result of the temperature value detected by the temperature sensor 5 and the preset temperature threshold value.

Specifically, the therapeutic apparatus further comprises a voice broadcasting device, the voice broadcasting device can be installed in the cylindrical shell 1, the preset temperature threshold is set according to actual conditions, for example, the preset temperature threshold is 50 ℃ when children are treated according to different age groups; for adult treatment, the preset temperature threshold is 60 degrees celsius. The temperature sensor 5 and the voice broadcasting device are both connected with the controller, the temperature value detected by the temperature sensor 5 is larger than a preset temperature threshold value, the controller controls the voice broadcasting device to conduct voice broadcasting, and the voice broadcasting device broadcasts first voice information, so that medical staff can take measures in time. Meanwhile, the controller controls the light source assembly 3 to be turned off, so that the patient is prevented from being scalded. After the light source assembly 3 is turned off for a period of time, the controller controls the light source assembly 3 to be turned on again, and treatment of the treatment part of the patient is continued.

In the embodiment of the utility model, the temperature value detected by the temperature sensor 5 is larger than the preset temperature threshold, and the controller controls the voice broadcasting device to conduct voice broadcasting while controlling the light source assembly 3 to be closed, so that the use safety of the therapeutic apparatus is further guaranteed.

In an alternative embodiment, the ranging sensor 4 is connected to the controller; and the controller controls the voice broadcasting device to conduct voice broadcasting according to the comparison result of the distance value detected by the distance measuring sensor 4 and the preset distance threshold value.

Specifically, the ranging sensor 4 is also connected to the controller, and the preset distance threshold includes a first preset distance threshold and a second preset distance threshold, where the values of the first preset distance threshold and the second preset distance threshold are set according to actual requirements. For example, the first preset distance threshold is 100 millimeters and the second preset distance threshold is 200 millimeters.

The distance value detected by the distance measuring sensor 4 is larger than a second preset distance threshold value, which indicates that the relative distance between the light source assembly 3 and the treatment part is larger, so that the treatment effect is poor; the distance value detected by the distance measuring sensor 4 is smaller than the first preset distance threshold, which indicates that the relative distance between the light source assembly 3 and the treatment part is too small, and the patient can be scalded. The distance value that range sensor 4 detected is less than or equal to the second and presets the distance threshold value, and is greater than or equal to the first and presets under the condition that distance threshold value, and the relative distance of light source subassembly 3 and treatment position is in the range of preseting the distance at this moment, satisfies the treatment requirement, and the controller control voice broadcast ware carries out voice broadcast, and voice broadcast ware reports second voice information, and suggestion light source subassembly 3 has moved to preset position, and actuating mechanism 6 stops driving tubular housing 1 removal for light source subassembly 3 is located preset position department.

In the embodiment of the utility model, in the process of driving the cylindrical shell 1 to move by the driving mechanism 6, the distance measuring sensor 4 detects the relative distance between the light source assembly 3 and the treatment part in real time, the distance value detected by the distance measuring sensor 4 is positioned in the preset distance range, and the controller controls the voice broadcasting device to carry out voice broadcasting, so that the convenience of adjusting the position of the light source assembly 3 is improved.

In an alternative embodiment, as shown in fig. 1 and 2, the drive mechanism 6 comprises a boom assembly 601; the arm support assembly 601 comprises a first arm section 6011 and a second arm section 6012, one end of the first arm section 6011 is movably connected with the base, the other end of the first arm section 6011 is movably connected with one end of the second arm section 6012, and the other end of the second arm section 6012 is movably connected with the cylindrical shell 1.

Specifically, the driving mechanism 6 includes a base and a boom assembly 601, where the boom assembly 601 includes a first arm segment 6011 and a second arm segment 6012, and two ends of the first arm segment 6011 are defined as a first end of the first arm segment 6011 and a second end of the first arm segment 6011, respectively; the two ends of the second arm section 6012 are a first end of the second arm section 6012 and a second end of the second arm section 6012, respectively.

The first end of the first arm segment 6011 is movably connected with the base, for example, the first end of the first arm segment 6011 is rotatably connected with the base, and the first arm segment 6011 can rotate relative to the base. The second end of the first arm section 6011 is connected to the first end of the second arm section 6012 by an intermediate connection, for example, one end of the intermediate connection is rotatably connected to the second end of the first arm section 6011, and the other end of the intermediate connection is hinged to the first end of the second arm section 6012, whereby the second arm section 6012 can be rotated in a horizontal plane with respect to the first arm section 6011 while the second arm section 6012 can be rotated in a vertical plane with respect to the first arm section 6011. Through the rotation of the first arm section 6011 relative to the base and the rotation of the second arm section 6012 relative to the first arm section 6011, the cylindrical shell 1 can be driven to move in a larger range, and further accurate adjustment of the position of the light source assembly 3 is facilitated.

Further, a plurality of intermediate arm sections may be further provided between the first arm section 6011 and the second arm section 6012 to expand the moving range of the cylindrical housing 1 so that the light source assembly 3 can be quickly moved to a preset position. The bottom of base still can set up running gear, running gear includes a plurality of universal wheels, and the circumference of base is located to a plurality of universal wheel intervals, and the quantity of universal wheel is not do specifically spacing, and the quantity of universal wheel is four for example. The base can be conveniently moved to different working areas through the universal wheels, and the position of the therapeutic apparatus can be flexibly adjusted.

Under the condition that the number of the arm sections is multiple, two adjacent arm sections are hinged, one arm section of the arm sections is rotationally connected with the base, and the other arm section is movably connected with the outer wall surface of the cylindrical shell 1. The rotation and translation of the plurality of arm segments drive the cylindrical shell 1 to rotate and translate in a vertical plane and rotate and translate in a horizontal plane, thereby aligning the light source assembly 3 to the treatment part of the patient.

In the embodiment of the utility model, the arm support assembly 601 includes a first arm segment 6011 and a second arm segment 6012, the first arm segment 6011 is rotatably connected with the base, one end of the second arm segment 6012 is rotatably connected with the first arm segment 6011, the other end of the second arm segment 6012 is connected with the cylindrical shell 1, and the position of the light source assembly 3 can be flexibly adjusted through the first arm segment 6011 and the second arm segment 6012, so that the light source assembly 3 is beneficial to accurately aligning to the treatment part of a patient.

In an alternative embodiment, as shown in fig. 1 and 2, the drive mechanism 6 further comprises a connection assembly 602; the other end of the second arm segment 6012 is movably connected with the cylindrical shell 1 through a connecting component 602, and the connecting component 602 can drive the cylindrical shell 1 to rotate along a first direction and a second direction, wherein the first direction and the second direction are mutually perpendicular.

Specifically, the connection assembly 602 includes a first connection member 6021 and a second connection member 6022, one end of the first connection member 6021 is hinged to the second end of the second arm segment 6012, the other end of the first connection member 6021 is rotatably connected to one end of the second connection member 6022, and the other end of the second connection member 6022 is connected to the cylindrical housing 1.

The first connecting piece 6021 can rotate in the vertical plane relative to the second arm section 6012, the second connecting piece 6022 can rotate in the horizontal plane relative to the first connecting piece 6021, the position of the cylindrical shell 1 can be further accurately adjusted through the first connecting piece 6021 and the second connecting piece 6022, the accurate alignment of the light source assembly 3 to a treatment part is guaranteed, and the treatment effect is improved.

In the embodiment of the utility model, the second arm segment 6012 is connected with the cylindrical shell 1 through the connecting assembly 602, the connecting assembly 602 comprises a first connecting piece 6021 and a second connecting piece 6022, and the position of the light source assembly 3 can be further adjusted in a micro-scale by rotating the first connecting piece 6021 and the second connecting piece 6022, so that the accuracy of the position of the light source assembly 3 is further guaranteed.

In an alternative embodiment, as shown in fig. 1, the therapeutic apparatus further comprises a holding portion 8, wherein the holding portion 8 is provided on a side of the cover plate 7 facing away from the carrier plate 2.

Specifically, the cover plate 7 is provided with a holding part 8 on one side facing away from the bearing plate 2, the holding part 8 is arc-shaped, a holding space is formed between the holding part 8 and the cover plate 7, and an operator can conveniently adjust the position of the cylindrical shell 1 through the holding part 8. Coarse adjustment is carried out on the position of the cylindrical shell 1 through the arm support assembly 601, and the medical staff holds the position of the cylindrical shell 1 through the connecting assembly 602 by hand, so that convenience in operation is facilitated.

In an alternative embodiment, as shown in fig. 1, the therapeutic apparatus further comprises a cone-shaped housing 9, the cone-shaped housing 9 having a small end and a large end, the small end being connected to one end of the cylindrical housing 1.

Specifically, the size of the cone housing 9 is set according to actual demands, the cone housing 9 has a small end and a large end, the small end is matched with one end of the cylindrical housing 1, and the small end of the cone housing 9 is connected with one end of the cylindrical housing 1. The large end of the conical shell 9 faces the patient, the conical shell 9 has a horn mouth shape, and the conical shell 9 has the function of shielding light beams, so that personnel except the patient, especially children, are prevented from being injured by contacting the light beams emitted by the light source assembly 3.

The end face of the large end of the conical shell 9 contacts with the treatment part, or a gap of a few millimeters is reserved between the end face of the large end of the conical shell 9 and the treatment part, so that the light beam emitted by the light source assembly 3 can act on the treatment part of a patient to the greatest extent, and the treatment effect is improved.

The cone-shaped shell 9 is made of medical rubber, such as natural rubber, silicon rubber or butyl rubber, and the rubber material has certain flexibility. The cone-shaped shell 9 is made of rubber, and when the large end of the cone-shaped shell 9 is contacted with the treatment part of a patient, comfort of the patient is guaranteed.

In the embodiment of the utility model, the small end of the conical shell 9 is connected with the cylindrical shell 1, and the large end of the conical shell 9 is opposite to the treatment part of the patient, thereby being beneficial to ensuring the use safety of the therapeutic apparatus and improving the therapeutic effect.

In an alternative embodiment, as shown in fig. 2, the light source assembly 3 includes a first light source 301 and a second light source, where the first light source 301 includes a red light unit and a blue light unit, and the second light source is a light supplementing unit, and the light supplementing unit is disposed in a circumferential direction of the red light unit and the blue light unit.

Specifically, the red light unit comprises a plurality of red light LED lamps, and the red light unit is used for emitting red light with the wavelength of 625-740 nanometers to the treatment part of the patient, and the red light irradiates the treatment part, so that the metabolism of cells can be increased, the regeneration of the cells is enhanced, and the healing of wounds is promoted. The blue light unit comprises a plurality of blue light LED lamps, and is used for emitting blue light with the wavelength of 400-480 nanometers to the treatment part of the patient, and the blue light has the effects of sterilization and anti-inflammation. A plurality of red LED lamps and a plurality of blue LED lamps are installed at intervals in the middle region of the carrier plate 2.

The light supplementing unit comprises a plurality of light supplementing lamps 302, and the light supplementing lamps 302 are arranged in the circumferential direction of the outer sides of the red LED lamps and the blue LED lamps at intervals around the central axis of the bearing plate 2. The number of the light compensating lamps 302 is set according to actual requirements, for example, the number of the light compensating lamps 302 is four, six or eight, etc., and a plurality of the light compensating lamps 302 form a light compensating unit. The wavelength of the light emitted by the light supplementing lamp 302 is set according to actual requirements, for example, the light supplementing lamp 302 can emit purple light with the wavelength of 380-420 nanometers, and the purple light with the wavelength of 380-420 nanometers can be used for treating vitiligo, psoriasis and the like; the light supplement lamp 302 can also emit yellow light with the wavelength of 570-585 nanometers, and the yellow light with the wavelength of 570-585 nanometers has the effects of repairing red marks or erythema of the skin and the like; the light supplement lamp 302 may also emit red light with a wavelength of 625-740 nanometers; the light supplement lamp 302 may also emit blue light with a wavelength of 400-480 nanometers; the light supplement lamp 302 may also emit near infrared light with a wavelength of 700-1100 nm, and the type of the light supplement lamp 302 is installed according to actual requirements. For example, the light supplement lamp 302 emits near infrared light with a wavelength of 700-1100 nm, and the treatment part is irradiated by near infrared light, so that the local blood circulation can be improved, the metabolism of pain causing substances can be promoted, and the pain can be relieved. Near infrared light inhibits peripheral nerve impulses, conduction velocity, intensity and impulse frequency caused by pain stimulus. The near infrared light emitted by the light supplement lamp 302 also has an indicating effect.

The red light unit, the blue light unit and the light supplementing unit are respectively connected with the controller, and the controller can independently control the opening and closing of the red light unit, the opening and closing of the blue light unit and the opening and closing of the light supplementing unit. For example, the light supplementing unit is a near infrared light unit, the controller controls the red light unit and the near infrared light unit to be turned on, and red light emitted by the red light unit is surrounded in an area surrounded by near infrared light emitted by the near infrared light unit, so that the effect range of the red light on a treatment part can be accurately indicated. For example, the controller controls the blue light unit and the near infrared light unit to be turned on, and blue light emitted by the blue light unit is surrounded in an area surrounded by near infrared light emitted by the near infrared light unit, so that the blue light can accurately indicate the action range of the blue light on the treatment part.

The red light unit and the blue light unit can be alternately started, and the blue light unit irradiates the treatment part to play roles in killing bacteria and diminishing inflammation; and then the red light unit irradiates the treatment part to repair the cell tissue of the treatment part. The red light unit and the blue light unit are alternately started, so that the treatment effect is improved.

In the embodiment of the utility model, the red light unit, the blue light unit and the light supplementing unit are all connected with the controller, and the controller controls the opening or closing of the red light unit, the blue light unit and the light supplementing unit, so that the therapeutic apparatus has various working modes, and the therapeutic effect is improved.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. A therapeutic apparatus, comprising: the device comprises a cylindrical shell, a light source assembly, a ranging sensor, a controller and a driving mechanism;

one end of the cylindrical shell is provided with a bearing plate, the other end of the cylindrical shell is provided with a cover plate, the light source assembly and the distance measuring sensor are both arranged on the bearing plate, and the driving mechanism is movably connected with the cylindrical shell;

the controller is used for controlling the opening and closing of the light source assembly, the light source assembly is used for emitting light beams to the treatment part, the distance measuring sensor is used for detecting the relative distance between the emitting surface of the light source assembly and the treatment part, and the driving mechanism is used for driving the light source assembly to move to a preset position.

2. The therapeutic apparatus of claim 1, further comprising a temperature sensor disposed on the carrier plate for detecting a temperature of a treatment site.

3. The therapeutic apparatus of claim 2, wherein the temperature sensor is coupled to the controller, and wherein the controller controls the light source assembly to be turned off if the temperature value detected by the temperature sensor is greater than a preset temperature threshold.

4. The therapeutic apparatus of claim 3, further comprising a voice broadcaster connected to the controller;

and the controller controls the voice broadcasting device to conduct voice broadcasting according to a comparison result of the temperature value detected by the temperature sensor and a preset temperature threshold value.

5. The therapeutic apparatus of claim 4, wherein the ranging sensor is coupled to the controller;

and the controller controls the voice broadcasting device to conduct voice broadcasting according to a comparison result of the distance value detected by the distance measuring sensor and a preset distance threshold value.

6. The therapeutic apparatus of claim 1, wherein the drive mechanism comprises a boom assembly;

the arm support assembly comprises a first arm section and a second arm section, one end of the first arm section is used for being movably connected with the base, the other end of the first arm section is movably connected with one end of the second arm section, and the other end of the second arm section is movably connected with the cylindrical shell.

7. The therapeutic apparatus of claim 6, wherein the drive mechanism further comprises a connection assembly;

the other end of the second arm section is movably connected with the cylindrical shell through the connecting component, and the connecting component can drive the cylindrical shell to rotate along a first direction and a second direction, wherein the first direction and the second direction are mutually perpendicular.

8. The therapeutic apparatus of claim 1, further comprising a grip portion disposed on a side of the cover plate facing away from the carrier plate.

9. The therapeutic apparatus of claim 1, further comprising a cone-shaped housing having a small end and a large end, the small end being connected to one end of the cylindrical housing.

10. The therapeutic apparatus of claim 1, wherein the light source assembly comprises a first light source and a second light source, the first light source comprises a red light unit and a blue light unit, the second light source is a light supplementing unit, and the light supplementing unit is disposed in a circumferential direction of the red light unit and the blue light unit.