An ultrashort wave treatment cabin for precisely treating a lesion site of a human body

By setting up multiple radiation zones and an energy distribution system in the ultra-shortwave therapy device, combined with temperature sensors and position indicator lights, the problem of the inability of existing devices to provide precise treatment has been solved. This enables precise treatment and real-time feedback of the lesion site, improving treatment effectiveness and comfort.

CN224345300UActive Publication Date: 2026-06-12ANYANG XIANGYU MEDICAL EQUIP

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANYANG XIANGYU MEDICAL EQUIP
Filing Date
2025-05-28
Publication Date
2026-06-12

AI Technical Summary

Technical Problem

Existing shortwave diathermy equipment cannot accurately select the treatment site, lacks feedback mechanisms and positioning accuracy, resulting in poor treatment outcomes.

Method used

Multiple independent radiation zones and energy distribution systems were designed, combined with temperature sensors and position indicator lights, to achieve precise treatment of different parts of the human body. The power and voltage of the energy generator were adjusted through the control board, and the treatment effect was fed back in real time.

Benefits of technology

It enables precise treatment of lesions in the human body, improves treatment effectiveness and patient comfort, and reduces damage to non-treated areas.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses an ultra-shortwave therapy chamber for precisely treating lesions on the human body, comprising: a chamber body with multiple radiation zones arranged sequentially along the axial direction of the chamber body, each radiation zone equipped with a radiator, and each radiator capable of independent operation; and an energy distribution system, including a power supply, an energy generator, a power distributor, and relays connected sequentially; the relays are connected to the radiators, and the number of relays corresponds one-to-one with the number of radiators. The chamber body is configured with multiple radiation zones for different parts of the human body, enabling subdivided treatment of different areas, resulting in more precise treatment and better effects. Furthermore, a temperature sensor collects body temperature for real-time feedback, allowing for power adjustment based on body temperature during treatment; and a position indicator light marks the treatment site, improving positioning accuracy and treatment effectiveness.
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Description

Technical Field

[0001] This utility model relates to the field of medical equipment technology, and in particular to an ultra-shortwave therapy chamber for precisely treating lesions in the human body. Background Technology

[0002] With the improvement of living standards, people are paying more attention to their health. Currently, the incidence of chronic diseases such as overuse injuries, degenerative diseases, and related inflammations is on the rise. Ultrashortwave therapy is an effective method for treating these chronic diseases. Ultrashortwave therapy emits pulsed energy to the body in a comprehensive manner, causing the body's water molecules and cells to vibrate and rub against each other at high speed, generating internal heat and thus achieving a therapeutic effect.

[0003] Currently, devices using shortwave diathermy on the market still have some drawbacks:

[0004] 1. Existing ultra-shortwave equipment provides full-coverage treatment and cannot be precisely segmented according to body parts or affected areas, thus failing to accurately select the areas requiring treatment.

[0005] 2. Existing shortwave diathermy equipment lacks a feedback mechanism during treatment, making it impossible to obtain the patient's true feelings or treatment status.

[0006] 3. Existing shortwave diathermy equipment does not indicate the area being treated during the treatment process; the operator must rely entirely on visual judgment to determine whether the patient's treatment area is within the correct treatment zone. Utility Model Content

[0007] The purpose of this invention is to provide an ultra-shortwave therapy chamber for precise treatment of lesions in the human body. The chamber is equipped with multiple radiation zones for different parts of the human body, enabling more precise treatment and better results.

[0008] To achieve this objective, the present invention adopts the following technical solution:

[0009] A shortwave therapy chamber for precisely treating lesions in the human body includes:

[0010] The cabin has multiple radiation zones arranged sequentially along its axial direction. Each radiation zone is equipped with a radiator, and each radiator can independently generate an electric field.

[0011] as well as

[0012] An energy distribution system includes a power supply, an energy generator, a power divider, and a relay connected in sequence.

[0013] The relays are connected to the radiators, and the number of relays corresponds one-to-one with the number of radiators.

[0014] In some implementations, there are four radiation zones, namely a first radiation zone, a second radiation zone, a third radiation zone, and a fourth radiation zone;

[0015] The first radiation zone is equipped with the first radiator, the second radiation zone is equipped with the second radiator, the third radiation zone is equipped with the third radiator, and the fourth radiation zone is equipped with the fourth radiator.

[0016] In some implementations, a control board is also included, which can adjust the power of the energy generator.

[0017] In some implementations, the control panel can set the power level of the energy generator before treatment;

[0018] During treatment, the control board can adjust the output voltage of the power supply, thereby regulating the power of the energy generator.

[0019] In some embodiments, a temperature sensor is also included, with a temperature sensor provided on the top or side of each radiation zone;

[0020] The temperature sensor is connected to the control board for data transmission.

[0021] The control board adjusts the power of the energy generator based on the body temperature data collected by the temperature sensor.

[0022] In some implementations, each radiation zone is provided with two temperature sensors positioned opposite each other, with the two temperature sensors spaced 120 degrees apart.

[0023] In some implementations, position indicator lights are also included, with each radiation zone equipped with a position indicator light, and each position indicator light being capable of operating independently;

[0024] Each position indicator light can generate a downward-facing parallel beam of light.

[0025] The beneficial effects of this utility model are: the cabin is equipped with multiple radiation zones for different parts of the human body, which enables more precise treatment of different parts and better results.

[0026] Furthermore, a temperature sensor is installed to collect body temperature, and the power can be adjusted according to the body temperature during treatment;

[0027] Furthermore, location indicator lights are installed to mark the treatment site, improving the accuracy of positioning and enhancing the treatment effect. Attached Figure Description

[0028] Figure 1 This is a diagram showing the connection structure between the energy distribution system and the radiator of this utility model;

[0029] Figure 2 This is one of the structural diagrams of the cabin of this utility model;

[0030] Figure 3 This is the second structural diagram of the cabin of this utility model;

[0031] Figure 4 This is a connection structure diagram of the temperature sensor of this utility model;

[0032] Figure 5 This is the third structural diagram of the cabin of this utility model;

[0033] Figure 6 This is a connection structure diagram of the position indicator light of this utility model;

[0034] Wherein: 100-cabin body; 110-first radiation zone; 51-first radiator; 120-second radiation zone; 52-second radiator; 130-third radiation zone; 53-third radiator; 140-fourth radiation zone; 54-fourth radiator; 200-bed body; 71-first position indicator light; 72-second position indicator light; 73-third position indicator light; 74-fourth position indicator light; 8-temperature sensor; 1-power supply; 2-energy generator; 3-power distributor; 4-relay; 41-first relay; 42-second relay; 43-third relay; 44-fourth relay; 6-control board. Detailed Implementation

[0035] The present invention will now be described in further detail with reference to the accompanying drawings.

[0036] refer to Figure 1 and Figure 2 A shortwave therapy chamber for precise treatment of lesions in the human body, comprising:

[0037] The cabin 100 has multiple radiation zones arranged sequentially along its axial direction. Each radiation zone is equipped with a radiator, and each radiator can work independently or generate an electric field independently. The radiator can be a resonant cavity or other structures. The radiation zones are divided according to different parts of the human body. Therefore, multiple radiation zones correspond to different parts of the human body, and multiple radiators can perform ultra-shortwave radiotherapy on different parts of the human body.

[0038] The cabin 100 and the bed 200 can move or move relative to each other. A guide rail structure can be set between the cabin 100 and the bed 200, and they can move relative to each other through a stepper motor and a gear rack and other drive mechanisms.

[0039] And an energy distribution system, including a power supply 1, an energy generator 2, a power distributor 3 and a relay 4 connected in sequence;

[0040] Relay 4 is connected to the radiator, and the number of relays 4 corresponds one-to-one with the number of radiators.

[0041] The energy generator 2 can be a device such as a magnetron or a solid-state source that can generate ultra-shortwave energy signals; the power divider 3 distributes the energy signals into two or more channels, and can even distribute the power of each channel according to a certain ratio; the relay 4 is used to control the on / off state of each output terminal, that is, to control the on / off state of each radiator.

[0042] Therefore, treatment can be targeted at different parts of the patient's body. For example, treatment can be applied to one part of the patient's body or to multiple parts of the patient's body, achieving targeted and specialized treatment that is more precise, more effective, and reduces damage to non-treated areas.

[0043] Specifically, there are four radiation zones: the first radiation zone 110, the second radiation zone 120, the third radiation zone 130, and the fourth radiation zone 140.

[0044] The first radiation zone 110 is equipped with a first radiator 51, the second radiation zone 120 is equipped with a second radiator 52, the third radiation zone 130 is equipped with a third radiator 53, and the fourth radiation zone 140 is equipped with a fourth radiator 54.

[0045] The first radiator 51 is connected to the first relay 414, the second radiator 52 is connected to the second relay 424, the third radiator 53 is connected to the third relay 434, and the fourth radiator 54 is connected to the fourth relay 444, so that each radiator can be independently controlled, operate independently, and generate an electric field independently.

[0046] For example, the first radiation zone 110 corresponds to the feet, the second radiation zone 120 corresponds to the calves, the third radiation zone 130 corresponds to the thighs, and the fourth radiation zone 140 corresponds to the chest and shoulders (torso). Therefore, any one of the feet, calves, thighs, chest, or shoulders can be treated, or any two, three, or all four areas can be treated.

[0047] refer to Figure 1 The treatment chamber also includes a control board 6, which can adjust the power of the energy generator 2. The control board 6 has a microcontroller, or is connected to a microcontroller (SMT328S105K6), and can execute corresponding instructions.

[0048] Before treatment, the control panel 6 can set the power level of the energy generator 2; for example, the control panel 6 can generate commands through knobs, panel buttons, etc., to set the power level of the energy generator 2, which is generally set according to the patient's condition.

[0049] After the power setting is completed, the energy generator 2 operates at the rated voltage;

[0050] During treatment, if it is necessary to adjust the power of energy generator 2, control board 6 can adjust the output voltage of power supply 1, thereby adjusting the power of energy generator 2. During treatment, the power setting of energy generator 2 cannot be changed or adjusted. Adjusting the power setting requires interrupting treatment, which affects the treatment effect. In this case, if the power can be adjusted without interrupting treatment, the power of energy generator 2 can be adjusted by changing the output voltage of power supply 1, achieving floating power regulation. This means that the output voltage of power supply 1 is slightly higher or lower than the rated voltage of energy generator 2. For example, increasing the output voltage of power supply 1 increases the operating voltage and power of energy generator 2; similarly, decreasing the output voltage of power supply 1 decreases the operating voltage and power of energy generator 2.

[0051] Therefore, the power of the energy generator 2 needs to be adjusted through different means before and during treatment. Before treatment, the power setting of the energy generator 2 is adjusted directly, while during treatment, the power of the energy generator 2 is adjusted indirectly (through the external power supply 1), that is, by adjusting the operating voltage of the energy generator 2.

[0052] refer to Figure 3 and Figure 4 The treatment chamber also includes temperature sensors 8. Each radiation zone is equipped with a temperature sensor 8 on its top or side, that is, the first radiation zone 110, the second radiation zone 120, the third radiation zone 130 and the fourth radiation zone 140 are each equipped with a corresponding temperature sensor 8; the temperature sensor 8 of each radiation zone can work independently.

[0053] Temperature sensor 8 is connected to control board 6. Control board 6 adjusts the power of energy generator 2 based on the body temperature data collected by temperature sensor 8.

[0054] For example, during treatment, when the body temperature data collected by the temperature sensor 8 is greater than the preset value, the control board 6 reduces the output voltage of the power supply 1, causing the power of the energy generator 2 to decrease.

[0055] For example, during treatment, when the body temperature data collected by the temperature sensor 8 is lower than the preset value, the control board 6 increases the output voltage of the power supply 1, causing the power of the energy generator 2 to increase.

[0056] During treatment, because patients vary in height, weight, bone and muscle density, the absorption rate after coupling with the body also varies. This can lead to some patients generating too much heat at the treatment site, resulting in excessively high body temperature and causing discomfort or other unpleasant experiences. Alternatively, some patients may not experience a good thermal effect at the treatment site, thus affecting the treatment outcome.

[0057] Therefore, the temperature sensor 8 collects body temperature data, provides real-time feedback on the treatment status, improves the user experience, and ensures the effectiveness of the treatment.

[0058] Each radiation zone is equipped with two temperature sensors positioned 120 degrees apart, allowing for more comprehensive and accurate collection of the patient's body temperature.

[0059] refer to Figure 5 and Figure 6 The treatment chamber also includes position indicator lights. Each radiation zone is equipped with a position indicator light, and each position indicator light can work independently. The position indicator lights can be located on the top or side of the radiation zone.

[0060] Each position indicator light can generate a downward-facing parallel beam of light.

[0061] When four radiation zones are set, four corresponding position indicator lights are set, namely, first position indicator light 71, second position indicator light 72, third position indicator light 73 and fourth position indicator light 74. The first radiation zone 110 is equipped with the first position indicator light 71, the second radiation zone 120 is equipped with the second position indicator light 72, the third radiation zone 130 is equipped with the third position indicator light 73, and the fourth radiation zone 140 is equipped with the fourth position indicator light 74.

[0062] The position indicator light illuminates the patient's treatment area, aligning it with the corresponding radiation zone or ensuring the treatment area is within the designated radiation zone. For example, when treating a patient's lower leg, after the patient lies on the bed 200, the second position indicator light 72 emits a downward-facing parallel light. As the bed 200 and the chamber 100 move relative to each other, when the parallel light illuminates the patient's lower leg—for example, covering it or illuminating a preset position—it indicates that the patient's lower leg is aligned with the second radiation zone 120, and treatment can then begin. This improves positioning accuracy, thereby enhancing treatment effectiveness and reducing damage to non-treatment areas. The corresponding position indicator light remains illuminated throughout the treatment process.

[0063] A shortwave diathermy method for precisely treating lesions in the human body (working principle), comprising the following steps:

[0064] S1: The patient lies flat on the bed 200. The position indicator light of the corresponding radiation zone of the cabin 100 is activated and shines downward to form parallel light for the patient's treatment area.

[0065] S2: The cabin 100 and the bed 200 move relative to each other. When the parallel light shines on the treatment area, such as covering the treatment area or shining on the preset position, the relative movement stops.

[0066] S3: Set the power level of energy generator 2, the corresponding relay 4 closes, and the radiator in the corresponding radiation zone starts working to perform ultra-shortwave therapy;

[0067] S4: During the treatment, the corresponding temperature sensor 8 collects the body temperature data of the patient's treatment site, and the control board 6 adjusts the power of the energy generator 2 according to the body temperature data collected by the temperature sensor 8.

[0068] S5: Treatment complete.

[0069] The order of steps S2 and S3 can be interchanged.

[0070] Furthermore, step S4 specifically includes:

[0071] If the body temperature data is greater than the preset value, the control board 6 will reduce the output voltage of the power supply 1, thereby reducing the power of the energy generator 2;

[0072] If the body temperature data is lower than the preset value, the control board 6 increases the output voltage of the power supply 1, thereby increasing the power of the energy generator 2.

[0073] For example, when treating a patient's lower leg, the steps are as follows:

[0074] S1: The patient lies flat on the bed 200, and the second position indicator light 72 of the corresponding second radiation zone 120 of the cabin 100 works and shines downward to form parallel light;

[0075] S2: The cabin 100 and the bed 200 move relative to each other. When the parallel light shines on and covers the lower leg, the relative movement stops.

[0076] S3: Set the power level of the energy generator 2, and the corresponding second relay 42 closes, causing the second radiator 52 to be energized and start ultra-shortwave therapy.

[0077] S4: During the treatment, the corresponding temperature sensor 8 collects the body temperature data of the patient's lower leg, and the control board 6 adjusts the power of the energy generator 2 according to the body temperature data collected by the temperature sensor 8.

[0078] If the body temperature data of the calf is greater than the preset value, the control board 6 will reduce the output voltage of the power supply 1, thereby reducing the power of the energy generator 2.

[0079] If the body temperature data of the calf is lower than the preset value, the control board 6 increases the output voltage of the power supply 1, thereby increasing the power of the energy generator 2.

[0080] S5: Treatment complete.

[0081] Similarly, treatment can be performed on any one of the following areas: feet, calves, thighs, chest and shoulders (torso), or any two, three, or all four areas.

[0082] The above description only discloses some embodiments of this utility model. For those skilled in the art, various modifications and improvements can be made without departing from the inventive concept of this utility model, and these all fall within the protection scope of this utility model.

Claims

1. A shortwave therapy chamber for precisely treating lesions in the human body, characterized in that, include: The cabin (100) has multiple radiation zones arranged sequentially along its axial direction. Each radiation zone is equipped with a radiator, and each radiator can generate an electric field independently. as well as The energy distribution system includes a power supply (1), an energy generator (2), a power distributor (3), and a relay (4) connected in sequence. The relay (4) is connected to the radiator, and the number of the relays (4) corresponds one-to-one with the number of radiators.

2. The ultra-shortwave therapy chamber for precisely treating lesions in the human body according to claim 1, characterized in that, The radiation zone is divided into four areas: the first radiation zone (110), the second radiation zone (120), the third radiation zone (130), and the fourth radiation zone (140). The first radiation zone (110) is provided with a first radiator (51), the second radiation zone (120) is provided with a second radiator (52), the third radiation zone (130) is provided with a third radiator (53), and the fourth radiation zone (140) is provided with a fourth radiator (54).

3. The ultra-shortwave therapy chamber for precisely treating lesions in the human body according to claim 1, characterized in that, It also includes a control board (6) that can adjust the power of the energy generator (2).

4. The ultra-shortwave therapy chamber for precisely treating lesions in the human body according to claim 3, characterized in that, Before treatment, the control panel (6) can set the power level of the energy generator (2); During treatment, the control board (6) can adjust the output voltage of the power supply (1), thereby adjusting the power of the energy generator (2).

5. The ultra-shortwave therapy chamber for precisely treating lesions in the human body according to claim 4, characterized in that, It also includes a temperature sensor (8), and each of the radiation zones is provided with a temperature sensor (8) on the top or side; The temperature sensor (8) is connected to the control board (6) via data connection; The control board (6) adjusts the power of the energy generator (2) based on the body temperature data collected by the temperature sensor (8).

6. The ultra-shortwave therapy chamber for precisely treating lesions in the human body according to claim 5, characterized in that, Each of the radiation zones is provided with two temperature sensors (8) positioned opposite each other, with the two temperature sensors (8) spaced 120 degrees apart.

7. The ultra-shortwave therapy chamber for precisely treating lesions in the human body according to claim 1, characterized in that, It also includes position indicator lights, with each radiation zone equipped with a position indicator light, and each position indicator light can work independently; Each position indicator light can generate a downward-facing parallel beam of light.