CN110292712B - Terahertz wave physical therapy device for lymphangioleiomyomatosis - Google Patents

Abstract

The invention relates to a terahertz wave physical therapy device for lymphangioleiomyomatosis, which comprises a processing end, a wave transmitting terminal and a bracket component for mounting the wave transmitting terminal, wherein the processing end is used for processing and controlling transmission signals and terahertz wave frequency signals and controlling and processing data of an integral system; the bracket component comprises a cross rod and a girder rod extending downwards from two ends of the cross rod; the lower end of the cross rod is provided with a plurality of coaxial cable interfaces, and a wiring channel for placing coaxial cables for connecting the coaxial cable interfaces and the processing end is arranged in the coaxial cable interfaces; the wave transmitting terminal comprises a shell and a horn-shaped sucker arranged on the front side of the shell, a terahertz wave generator is arranged in the shell, a wiring extending to the outside is arranged at the rear end of the shell, and a cable interface is formed by splicing the end part of the wiring with a coaxial cable interface; the front side of the terahertz wave generator is provided with a waveguide window, and the waveguide window is provided with a wave-collecting lens covering the waveguide window. The physiotherapy instrument has accurate positioning during physiotherapy and improved physiotherapy effect.

Description

Terahertz wave physical therapy device for lymphangioleiomyomatosis

Technical Field

The invention relates to the technical field of terahertz wave physiotherapy, in particular to a terahertz wave physiotherapy device for lymphangioleiomyomatosis.

Background

Scientific research has found that electromagnetic waves have unexpected biological effects on organisms, such as affecting cell growth, gene expression, and the like. Usually, millimeter waves and submillimeter waves can only penetrate a living body to a depth of less than 1mm, and the millimeter waves and the submillimeter waves bring curative effects on diseases of organs in the deep part of a human body. With the development of terahertz technology, the limitation of millimeter wave treatment is gradually broken through, the terahertz wave treatment has less or no side effect on human bodies, and nowadays, the medical crisis caused by abuse of antibiotics is more and more emphasized by the medical field. Terahertz waves radiated by existing biological wave functional materials can generate a resonance effect on a human body, and the phenomenon that the human body generates a heat effect phenomenon and a water molecule resonance phenomenon is caused, so that the kinetic energy of cells of the human body is increased, and the state of micro-motion or micro-massage is kept. The material has the effects of promoting blood circulation and improving microcirculation; secondly, the blood viscosity can be reduced; thirdly, the cells can be activated; fourthly, the metabolism can be strengthened; fifthly, the paint can resist ultraviolet rays; sixthly, the growth of harmful bacteria can be prevented; seventhly, the balance of the channels and collaterals can be adjusted.

Therapeutic instruments for treating human body by using electromagnetic waves are developed at present, and the treatment of deep internal organs of human body is achieved by radiating electromagnetic waves to human epidermis. For example, the prior art includes terahertz wave physiotherapy instruments, quantum generators, terahertz wave physiotherapy instruments and the like for treating and curing common diseases, such as a terahertz wave physiotherapy instrument probe disclosed in patent CN 102895742A; the terahertz wave focusing device comprises a terahertz wave generator, a wave focusing lens and a sucker; the terahertz generator comprises a generator main body and a waveguide window, wherein the generator main body is used for generating terahertz waves, and the terahertz waves generated by the generator main body are transmitted through the waveguide window to be emitted; the wave-gathering lens is arranged on the waveguide window, covers the waveguide window and is used for gathering the terahertz waves; the physiotherapy instrument is adsorbed on the preset treatment position of the human body through the sucking disc. However, the existing electromagnetic wave physiotherapy instrument only has the treatment function, does not compare and diagnose the effects before and after treatment, can only judge the effects intuitively by patients, and inevitably brings certain disadvantages to the improvement of the treatment effect and the treatment method. The wave transmitting terminals of the existing terahertz wave physiotherapy instrument cannot be uniformly set and managed, and the physiotherapy operation is inconvenient.

In addition, the prior art does not provide a specific targeted probe for a specific part of a human body, for example, the lymphangioleiomyoma disease is a rare disease characterized by diffuse cystic changes of the lung, lymphatic vessel abnormality and abdominal tumors; the disease can be daily conditioned based on the physical therapy effect of terahertz, and when the existing terahertz physical therapy instrument is used, the wave frequency efficiency is low, a plurality of probes are required to be used for simultaneous operation, and the wiring of the probes is messy at the moment, so that the working efficiency of medical workers is influenced; the existing probe can not observe the physical therapy condition of the patient in real time.

Disclosure of Invention

The invention aims to provide a terahertz wave physiotherapy device for lymphangioleiomyomatosis, which realizes the visualization of a terahertz physiotherapy process, and the positioning of the physiotherapy process is more accurate, so that the physiotherapy effect is improved.

In order to achieve the above purpose, the technical scheme adopted by the invention is as follows:

a terahertz wave physiotherapy device for lymphangioleiomyomatosis comprises a processing end, a wave transmitting terminal connected with the processing end and a bracket component for mounting the wave transmitting terminal, wherein the processing end is used for processing and controlling transmission signals and terahertz wave frequency signals and controlling and processing data of an integral system;

the bracket component comprises a cross rod and a beam extending downwards from two ends of the cross rod, and the bottom of the beam is provided with a clamping component clamped on the side edge of the bed plate of the treatment bed; the lower end of the cross rod is provided with a plurality of coaxial cable interfaces, and a wiring channel for placing coaxial cables for connecting the coaxial cable interfaces and the processing end is arranged in the coaxial cable interfaces;

the wave transmitting terminal comprises a shell and a horn-shaped sucker arranged on the front side of the shell, a terahertz wave generator is arranged in the shell, a wiring extending to the outside is arranged at the rear end of the shell, and a cable interface is formed by splicing the end part of the wiring with the coaxial cable interface; the terahertz wave generator is used for receiving the electromagnetic signal sent by the processing end, amplifying and frequency doubling the electromagnetic signal, generating a terahertz wave frequency spectrum in a specific frequency range and radiating the terahertz wave frequency spectrum; the front side of the terahertz wave generator is provided with a waveguide window, and the waveguide window is provided with a wave-collecting lens covering the waveguide window.

Furthermore, the thermal infrared imager is further included and connected to the cross rod through a transverse moving mechanism.

Furthermore, a sliding groove is formed in the side edge of the cross rod, a supporting bracket is arranged on the upper portion of the thermal infrared imager, a sliding block is arranged on the supporting bracket, and the sliding block is arranged on the sliding groove.

Furthermore, the support bracket comprises two side walls and a bottom plate, an adjusting space with a distance of 20-50mm is reserved between the bottom plate and the thermal infrared imager, the side edge of the thermal infrared imager is connected with the two side walls through a rotating shaft, an angle adjusting mechanism is connected to the rotating shaft side of one side wall, the angle adjusting mechanism comprises a pull rod and a connecting part connected with the pull rod and the rotating shaft, an extending part with external threads is arranged outside the rotating shaft in an outward extending mode, and a locking nut for fixing the connecting part is sleeved on the extending part.

Furthermore, an accommodating cavity is arranged on the side edge of the front end of the sucker, and a chest-abdomen type respiration sensor is arranged at the bottom of the accommodating cavity; still be equipped with the passageway on the sucking disc lateral wall, chest abdomen formula respiration sensor's electric wire is worn out the casing from the passageway, is connected to the cable interface.

On the basis of the technical scheme, the processing end comprises

The signal source generator is used for generating a signal source of the low-frequency terahertz wave signal;

the terahertz wave signal modulation module is used for modulating the amplitude of a low-frequency terahertz wave signal of a signal source in different pulse and sine modes by controlling the electrical frequency and inputting the modulated terahertz electromagnetic wave signal to a wave transmitting terminal;

the main control module is used for processing and controlling signals of a processing end, controlling the transmitting signals of the wave transmitting terminal 2 and acquiring and processing the signals;

the position adjusting module is used for issuing an adjusting instruction to the power mechanism of the vertical rod so as to automatically adjust the position of the wave transmitting terminal;

the terahertz wave generator of the wave transmitting terminal includes

The frequency expansion module is used for receiving the modulated low-frequency terahertz electromagnetic wave signal, amplifying and frequency doubling the low-frequency terahertz electromagnetic wave signal and generating a specific terahertz wave frequency spectrum;

the energy storage module is connected with the frequency expansion module and used for storing energy by using a high-voltage high-capacitance capacitor before the wave transmitting terminal does not transmit the radio frequency terahertz wave;

and the radiation module is a radiation antenna connected with the energy storage module and is used for directionally radiating the terahertz waves.

Further, the wave transmitting terminal further comprises

The temperature control module is used for monitoring the temperature of the energy storage module, comparing the temperature with a set threshold value, and cooling through the cooling circuit unit when the temperature exceeds the set threshold value;

the energy storage module is formed by connecting a coupling circuit unit, a capacitance circuit unit and a cooling circuit unit in parallel; wherein, the cooling circuit unit is provided with a switch, and the cooling element adopts a Peltier cooling fin.

Further, the processing end also comprises

And the thermal infrared image data processing and analyzing module is used for acquiring thermal infrared image energy information of the human body measuring part acquired by the thermal infrared imager in real time, acquiring thermal infrared image energy data of the human body measuring part through digital-to-analog conversion, generating a thermal distribution image through the thermal infrared image energy data, and analyzing and acquiring the inflammation part with high energy.

Further, the processing end also comprises

The respiratory signal processing module is used for performing digital-to-analog conversion on the acquired respiratory signal, acquiring respiratory information of the patient in real time, comparing the respiratory information with normal respiratory frequency and judging whether the respiratory information is normal or not;

the abnormal alarm module is used for sending out voice and/or stopping radiation work alarm when the respiratory information of the respiratory signal processing module is not in the normal range value;

and the data storage module is used for storing the heat distribution image, the breathing condition information, the related medical history information and the health condition information of the patient during the past and current physical therapy.

Furthermore, the processing end further comprises a timing module connected with the main control module, and the timing module is used for controlling the working time of the terahertz wave generator in each wave transmitting terminal.

The terahertz wave physiotherapy device for the lymphangioleiomyomatosis disease is provided with the fixing device for the symptomatic disease, and the wave transmitting terminal is connected to the cross rod according to the actual situation to carry out physiotherapy operation by the cross rod arranged on the bed board or other supports during use, so that the manual operation of a doctor is reduced, and the physiotherapy efficiency is improved. The terahertz wave simulation physical therapy device adjusts the bandwidth of the transmitted terahertz wave through the modulator, and adjusts the wavelength of the terahertz wave to realize physical therapy on the chest and abdomen part of a human body under a specific condition with high power and/or specific terahertz frequency; the terahertz wave generating device is provided with the energy storage module to ensure that the terahertz wave energy is effectively transmitted to the radiation antenna, so that the radiation antenna realizes high gain and effectively realizes the expected physical therapy effect; meanwhile, the damage to the human body and the device caused by overhigh temperature of the wave transmitting device is avoided through the arrangement of the cooling element. In the physical therapy process, the thermal infrared imager collects infrared thermal imaging energy data of a physical therapy part of a human body, on one hand, the diseased part can be visually observed, whether the wave transmitting terminal is at the diseased part or not can be automatically judged according to the thermal imaging of the diseased part and the position data of the wave transmitting terminal, and influence change when terahertz waves are irradiated can be observed in real time, so that diagnosis basis is provided for medical staff.

The physical therapy instrument has novel design, is used for physical therapy of lymphangioleiomyomatosis by terahertz waves, has obvious physical therapy effect, and can greatly shorten the physical therapy period of patients. Compared with the traditional medicine and operation physical therapy effect, the terahertz wave simulation physical therapy instrument has no side effect and has better effect.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the overall structure of a terahertz wave physiotherapy device for treating lymphangioleiomyomatosis according to the invention;

fig. 2 is a schematic structural diagram of one embodiment of a wave transmitting terminal of the present invention;

FIG. 3 is a schematic structural diagram of an embodiment of a thermal infrared imager in accordance with the present invention;

fig. 4 is a schematic structural diagram of a wave transmitting terminal according to still another embodiment of the present invention;

FIG. 5 is a schematic diagram of an embodiment of the whole functional module structure of the terahertz wave physical therapy apparatus for treating lymphangioleiomyomatosis according to the present invention

Fig. 6 is a schematic diagram of the circuit connection of the energy storage module.

Detailed Description

The following describes a specific embodiment of the terahertz wave physiotherapy apparatus for treating lymphangioleiomyomatosis according to the present invention with reference to the following examples. The following examples are only used to illustrate the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby; various changes and modifications can be made by one skilled in the art without departing from the spirit and scope of the invention, and all equivalent technical solutions also fall within the scope of the invention, which is defined by the claims.

Fig. 1 shows a terahertz wave physiotherapy device for lymphangioleiomyomatosis, the physiotherapy device includes processing terminal 1, wave emission terminal 2 that is connected with processing terminal 1 and installation wave emission terminal 2's bracket component 3, processing terminal 1 is used for transmission signal, terahertz wave frequency signal processing, control and the data processing of whole system.

The bracket component 3 comprises a cross rod 30 and a bridging rod 32 extending downwards from two ends of the cross rod 30, and a clamping component clamped at the side edge of the bed plate of the treatment bed is arranged at the bottom of the bridging rod 32; the lower end of the cross bar 30 is provided with a plurality of coaxial cable interfaces 33, and a wiring channel for placing coaxial cables for connecting the coaxial cable interfaces 33 and the processing end 1 is arranged in the coaxial cable interfaces 33. In some examples, as shown in fig. 1, the spreader bar is a telescopic adjusting bar, and a ruler can be arranged on the adjusting bar to ensure that four corners are adjusted to the same horizontal plane; the clamping assembly 37 is a concave structure with a side opening, and a locking screw 38 is arranged on the bottom plate of the clamping assembly to lock the clamping plate on the bed board.

As shown in fig. 2, the wave transmitting terminal 2 includes a housing 20 and a horn-shaped suction cup 22 disposed at the front side of the housing 20, a terahertz wave generator 23 is disposed in the housing 20, a connection wire 26 extending to the outside is disposed at the rear end of the housing 20, and an end of the connection wire 26 is plugged into a cable interface 30 of the coaxial cable interface 33; the terahertz wave generator 23 is used for receiving the electromagnetic signal sent by the processing end 1, amplifying and frequency doubling the electromagnetic signal, generating a terahertz wave frequency spectrum in a specific frequency range, and radiating the terahertz wave frequency spectrum; the front side of the terahertz wave generator 23 is provided with a wave guide window 24, and the wave guide window 24 is provided with a wave collecting lens 25 covering the wave guide window.

In another embodiment of the present invention, the apparatus further comprises a thermal infrared imager 4, wherein the thermal infrared imager 4 is connected to the cross bar 30 by a lateral moving mechanism, as shown in fig. 1.

Specifically, as shown in fig. 3, a sliding groove 34 is formed in the side edge of the cross bar 30, a supporting bracket 40 is arranged at the upper portion of the thermal infrared imager 4, a sliding block 41 is arranged on the supporting bracket 40, and the sliding block 41 is arranged on the sliding groove 34. The support bracket 40 comprises two side walls 400 and a bottom plate 401, the bottom plate 401 and the thermal infrared imager 4 are provided with an adjusting space 402 with a distance of 20-50mm, the side edge of the thermal infrared imager 4 is connected with the two side walls 400 through a rotating shaft, the rotating shaft side of one side wall 400 is connected with an angle adjusting mechanism, the angle adjusting mechanism comprises a pull rod 405 and a connecting part 406 which is connected with the pull rod 405 and the rotating shaft, the outer side of the rotating shaft extends outwards to be provided with an extension part 407 with external threads, and the extension part 407 is sleeved with a locking nut 408 which is used for fixing the connecting part 406. And in a general working state, keeping a lens of the thermal infrared imager and a sucker of the wave emission terminal in the same direction, and if the detection part of the thermal infrared imager needs to be expanded or the detection part of the thermal infrared imager and the detection part of the thermal infrared imager are not consistent, loosening a locking nut and then pulling a pull rod to adjust the angle of the thermal infrared imager.

In some examples of the present invention, as shown in fig. 4, the front end side of the suction cup 22 is provided with a receiving cavity 220, and the bottom of the receiving cavity 220 is provided with a thoracoabdominal respiration sensor 221; the suction cup 22 is further provided with a channel 223 on the side wall, and the electric wire of the thoracoabdominal respiration sensor 221 passes through the housing 20 from the channel 223 and is connected to the cable interface 30.

In one embodiment of the overall architecture of the apparatus of the present invention, as shown in fig. 5, the processing terminal 1 comprises

A signal source generator 10 for generating a signal source of a low-frequency terahertz wave signal;

the terahertz wave signal modulation module 11 is used for modulating the amplitude of a low-frequency terahertz wave signal of a signal source in different pulse and sine modes by controlling the electrical frequency and inputting the modulated terahertz electromagnetic wave signal to the wave transmitting terminal 2;

the main control module 12 is used for processing and controlling signals of the processing terminal 1, controlling transmission signals of the wave transmitting terminal 2 and acquiring and processing the signals;

the position adjusting module 13 is configured to issue an adjusting instruction to the power mechanism of the vertical rod 31, so that the position of the wave transmitting terminal 2 is automatically adjusted;

the terahertz wave generating device 20 of the wave transmitting terminal 2 includes

The frequency expansion module 27 is configured to receive the modulated low-frequency terahertz electromagnetic wave signal, amplify and frequency-multiply the low-frequency terahertz electromagnetic wave signal, and generate a specific terahertz wave frequency spectrum; in some schemes, the frequency expansion link is a frequency multiplication link, and after receiving a signal source, the frequency multiplication link performs multiple amplification and frequency multiplication through a driving amplifier and a multi-stage frequency multiplier to obtain a required frequency multiplication signal of a terahertz wave frequency band;

the energy storage module 28 is connected with the frequency extension module 27 and is used for storing energy by using a high-voltage high-capacitance capacitor before the wave transmitting terminal 2 does not transmit the radio frequency terahertz wave;

and the radiation module 29 is a radiation antenna connected with the energy storage module 28 and is used for directionally radiating the terahertz waves.

As shown in fig. 6, the energy storage module 28 is formed by connecting a coupling circuit unit 280, a capacitor circuit unit 281, and a cooling circuit unit 282 in parallel; wherein, the cooling circuit unit 282 is provided with a switch, and the cooling element adopts a peltier cooling fin.

In this example, the wave transmitting terminal further includes

And the temperature control module 15 is used for monitoring the temperature of the energy storage module 28, comparing the temperature with a set threshold value, and cooling through the cooling circuit unit 29 when the temperature exceeds the set threshold value.

The device also comprises a thermal infrared imager 3, and the processing end also comprises

And the thermal infrared image data processing and analyzing module 14 is used for acquiring thermal infrared image energy information of the human body measurement part acquired by the thermal infrared imager in real time, acquiring thermal infrared image energy data of the human body measurement part through digital-to-analog conversion, generating a thermal distribution image through the thermal infrared image energy data, and analyzing and acquiring the inflammation part with high energy.

The respiratory signal processing module 17 is configured to perform digital-to-analog conversion on the acquired respiratory signal, obtain respiratory information of the patient in real time, compare the respiratory information with a normal respiratory frequency, and determine whether the respiratory information is normal;

an abnormal alarm module 18, which is used for sending out voice and/or stopping radiation work alarm when the respiration information of the respiration signal processing module 17 is not in the normal range value;

the data storage module 16 is used for storing the heat distribution image, the breathing condition information, the related medical history information and the health condition information of the patient during the past and current physical therapy;

a timing module 19 connected to the main control module 12, the timing module 19 being configured to control an operating time of the terahertz wave generator 23 in each of the wave transmitting terminals 2.

It should be noted that, as will be understood by those skilled in the art, the processor according to the present invention has functions of implementing data acquisition, wavelength modulation, and timing according to the present invention, and the functions may be implemented by hardware, or by hardware executing corresponding software. The hardware or software includes one or more modules corresponding to the above-described functions. The processor includes an application program for storing modules that perform the functions of the modules of the present invention. The functions can be realized by hardware, and the functions can also be realized by executing corresponding software by hardware. In some examples, the main control unit may be a programmable gate array chip or an application specific integrated circuit chip.

Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware.

The above examples only show some embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (6)

1. The terahertz wave physical therapy device for the lymphangioleiomyomatosis disease is characterized by comprising a processing end (1), a wave transmitting terminal (2) connected with the processing end (1) and a bracket component (3) provided with the wave transmitting terminal (2), wherein the processing end (1) is used for processing and controlling transmission signals and terahertz wave frequency signals and controlling and processing data of the whole system;

the bracket component (3) comprises a cross rod (30) and a beam (32) extending downwards from two ends of the cross rod (30), and a clamping component clamped on the side edge of the bed plate of the treatment bed is arranged at the bottom of the beam (32); the lower end of the cross rod (30) is provided with a plurality of coaxial cable interfaces (33), and a wiring channel for placing coaxial cables for connecting the coaxial cable interfaces (33) and the processing end (1) is arranged in the coaxial cable interfaces;

the wave transmitting terminal (2) comprises a shell (20) and a horn-shaped sucker (22) arranged on the front side of the shell (20), a terahertz wave generator (23) is arranged in the shell (20), a connection wire (26) extending to the outside is arranged at the rear end of the shell (20), and the end part of the connection wire (26) is connected with a cable interface (30) of the coaxial cable interface (33) in an inserting mode; the terahertz wave generator (23) is used for receiving the electromagnetic signal sent by the processing end (1), amplifying and frequency doubling the electromagnetic signal, generating a terahertz wave frequency spectrum in a specific frequency range and radiating the terahertz wave frequency spectrum; a waveguide window (24) is arranged on the front side of the terahertz wave generator (23), and a wave-collecting lens (25) covering the waveguide window (24) is arranged on the waveguide window;

the thermal infrared imager (4) is connected to the cross rod (30) through a transverse moving mechanism; an accommodating cavity (220) is formed in the side edge of the front end of the sucking disc (22), and a chest-abdomen type respiration sensor (221) is arranged at the bottom of the accommodating cavity (220); a channel (223) is further arranged on the side wall of the sucker (22), and an electric wire of the thoracoabdominal respiration sensor (221) penetrates out of the shell (20) from the channel (223) and is connected to the cable interface (30);

a sliding groove (34) is formed in the side edge of the cross rod (30), a supporting bracket (40) is arranged at the upper part of the thermal infrared imager (4), a sliding block (41) is arranged on the supporting bracket (40), and the sliding block (41) is arranged on the sliding groove (34); support bracket (40) includes both sides wall (400) and bottom plate (401), bottom plate (401) with thermal infrared imager (4) keep somewhere to have the interval to be adjustment space (402) of 20-50mm, the side and both sides wall (400) of thermal infrared imager (4) are connected through the pivot, and the pivot side of one of them lateral wall (400) is connected with angle adjusting mechanism, angle adjusting mechanism includes pull rod (405) and connects pull rod (405) with connecting portion (406) of pivot, the outside extension (407) that is equipped with the external screw thread of taking, the cover is equipped with fixedly on extension (407) lock nut (408) of connecting portion (406).

2. The terahertz wave physical therapy device for lymphangioleiomyomatosis according to claim 1, wherein the treatment tip (1) comprises

A signal source generator (10) for generating a signal source of a low-frequency terahertz wave signal;

the terahertz wave signal modulation module (11) is used for modulating the amplitude of a low-frequency terahertz wave signal of a signal source in different pulse and sine modes by controlling the electrical frequency and inputting the modulated terahertz electromagnetic wave signal to the wave transmitting terminal (2);

the main control module (12) is used for processing and controlling signals of the processing end (1) and controlling and acquiring and processing transmitting signals of the wave transmitting terminal (2);

the position adjusting module (13) is used for issuing an adjusting instruction to a power mechanism of the diffraction rod (32) so as to automatically adjust the position of the wave transmitting terminal (2);

the terahertz wave generator (23) of the wave transmitting terminal (2) comprises

The frequency expansion module (27) is used for receiving the modulated low-frequency terahertz electromagnetic wave signal, amplifying and frequency doubling the low-frequency terahertz electromagnetic wave signal and generating a specific terahertz wave frequency spectrum;

the energy storage module (28) is connected with the frequency expansion module (27) and is used for storing energy by utilizing a high-voltage high-capacitance capacitor before the wave transmitting terminal (2) does not transmit radio frequency terahertz waves;

the radiation module (29) is a radiation antenna connected with the energy storage module (28) and used for directionally radiating the terahertz waves.

3. The terahertz wave physical therapy apparatus for lymphangioleiomyomatosis of claim 2, wherein the wave transmitting terminal further comprises

A temperature control module (15) for monitoring the temperature of the energy storage module (28), comparing the temperature with a set threshold value, and when the temperature exceeds the set threshold value, cooling by a cooling circuit unit (282);

the energy storage module (28) is formed by connecting a coupling circuit unit (280), a capacitance circuit unit (281) and a cooling circuit unit (282) in parallel; wherein the cooling circuit unit (282) is provided with a switch, and the cooling element of the cooling circuit unit adopts a Peltier cooling fin.

4. The terahertz wave physical therapy device for lymphangioleiomyomatosis of claim 2, wherein the treatment end further comprises

And the infrared thermal image data processing and analyzing module (14) is used for acquiring infrared thermal imaging energy information of the human body measuring part acquired by the infrared thermal imager in real time, acquiring infrared thermal imaging energy data of the human body measuring part through digital-to-analog conversion, generating a thermal distribution image through the infrared thermal imaging energy data, and analyzing and acquiring the inflammation part with high energy.

5. The terahertz wave physical therapy device for lymphangioleiomyomatosis of claim 4, wherein the treatment end further comprises

The respiratory signal processing module (17) is used for performing digital-to-analog conversion on the acquired respiratory signals, acquiring respiratory information of the patient in real time, comparing the respiratory information with normal respiratory frequency and judging whether the respiratory information is normal or not;

the abnormal alarm module (18) is used for giving out voice and/or stopping radiation work alarm when the respiratory information of the respiratory signal processing module (17) is not in the normal range value;

and the data storage module (16) is used for storing the heat distribution images, the breathing condition information, the related medical history information and the health condition information of the patients in the past and the current physiotherapy.

6. The terahertz wave physical therapy apparatus for lymphangioleiomyomatosis according to claim 2, wherein the processing terminal (1) further comprises a timing module (19) connected with the main control module (12), the timing module (19) is used for controlling the working time of the terahertz wave generator (23) in each of the wave emitting terminals (2).

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