CN219128042U - Local warm immune induction therapeutic apparatus for upper respiratory tract mucous membrane - Google Patents

Abstract

The utility model relates to an upper respiratory tract mucosa local-temperature heat immune induction therapeutic apparatus, which comprises a display, wherein one side of the display is provided with a control box, a treatment mechanism is arranged in the control box, the treatment mechanism comprises a hard mirror body (5) or a control handle (7), the bottom of the hard mirror body (5) is connected with one end of an optical fiber (3) and a wire (4), the control handle (7) is connected with one end of the optical fiber (3) and the wire (4), and the top end of the control handle (7) is provided with a soft mirror body (8). According to the utility model, the umbrella-shaped heating device is used for precisely heating the affected part, so that the treatment end is prevented from deviating from the treatment target point in the treatment process, the discomfort during treatment can be effectively reduced, the treatment effect can be improved, the cure rate is improved, and the recurrence rate is reduced.

Description

Local warm immune induction therapeutic apparatus for upper respiratory tract mucous membrane

Technical Field

The utility model relates to the technical field of immunity induction therapeutic equipment, in particular to a local warm and hot immunity induction therapeutic equipment for upper respiratory tract mucous membrane.

Background

Human papillomaviruses (Human papillomavirus, HPV) are a group of common circular DNA viruses that specifically infect human epithelial cells and produce a variety of clinical symptoms. To date, about 200 species-specific and tissue-specific HPV have been identified. Viruses fall into three general categories depending on the site of infection on the skin or mucosa: cutaneous viruses, mucosal cutaneous viruses, and viruses associated with rare autosomal recessive diseases. Mucosal cutaneous HPV types can be further classified into low-risk HPV (Lowrisk HPV, LR-HPV) mainly associated with benign warts or epithelial lesions, and High-risk HPV (High risk HPV, HR-HPV) according to oncogenic potential. HR-HPV includes an extremely diverse population associated with a risk of malignancy progression, including oropharyngeal, cervical, vulvar, vaginal, penile and anal cancers.

Endogenous warmth is a condition characterized by a failure of thermoregulation resulting in an increase in body temperature. Warming occurs when the body generates or absorbs heat in excess of the heat it dissipates. Warming can be deliberately induced by drugs or medical devices, applied to the whole body or locally, for the treatment of certain diseases. The immunomodulatory effects of thermotherapy have prompted interest in thermotherapy in adjuvant immunotherapy, particularly in the treatment of tumors. Series of studies indicate that local warming achieves good therapeutic effects in the treatment of skin and mucosal diseases of HPV infection.

Papillomas of the nose, throat are common benign tumors that are considered likely to be associated with HPV infection and detected in a large number of tissue samples. Aiming at papillomas of nose, pharynx and throat, most of treatment means mainly comprise surgical treatment, including cold instruments, lasers and the like, pain, bleeding, local irritation and secondary infection can be caused, and the recurrence rate is high. Therefore, according to the prior experience, a warm-heat treatment device-upper respiratory mucosa local warm-heat immune induction therapeutic apparatus suitable for treating the papilloma of nose, throat and throat is developed.

Disclosure of Invention

The utility model aims to provide a local warm immune induction therapeutic apparatus for upper respiratory mucosa, which solves the problems of pain, bleeding, local stimulation, secondary infection and higher recurrence rate caused by surgical treatment in the prior art.

The above object of the present utility model can be achieved by the following technical solutions: the utility model comprises the following steps: the device comprises a display (1), wherein a control box (2) is arranged on one side of the display (1), a treatment mechanism is arranged in the control box (2), an optical fiber (3) and a wire (4) are arranged on one side of the control box (2), the optical fiber (3) is arranged on one side of the wire (4), and a treatment mechanism is arranged on one side of the wire (4);

the treatment mechanism comprises a hard lens body (5) and a control handle (7), wherein the bottom of the hard lens body (5) is connected with one end of an optical fiber (3) and one end of a wire (4), the hard lens body (5) is replaced by the control handle (7), the control handle (7) is connected with one end of the optical fiber (3) and one end of the wire (4), and a soft lens body (8) is arranged at the top end of the control handle (7);

the treatment mechanism further comprises a treatment end II (9), the treatment end II (9) is arranged at one end of the hard lens body (5) or one end of the soft lens body (8), a camera probe (11) and a temperature sensor (12) are arranged inside the treatment end II (9), a light source (14) is arranged inside the treatment end II (9), a plurality of umbrella-shaped heating devices (15) are arranged inside the treatment end II (9), and the camera probe (11), the temperature sensor (12) and the light source (14) inside the treatment end II (9) are wrapped in the middle of the umbrella-shaped heating devices (15).

As a preferable scheme, a plurality of umbrella-shaped heating devices (15) are distributed in an annular array by taking the center of a second treatment end (9) as a circle center, and the umbrella-shaped heating devices (15) are uniformly arranged at intervals.

As another preferable scheme, a temperature and time display screen (17) is arranged on the front side of the control box (2).

As another preferable scheme, one side of the control box (2) is provided with a control box main switch (21) and a camera switch (22), and the control box main switch (21) is arranged at the top of the camera switch (22).

And secondly, a treatment end direction regulating knob (16) is arranged at the front side of the control handle (7). The connection structure at the treatment end direction adjusting knob (16) can adopt the adjusting structure of figure 2 in patent number 202021364690.6 named as an angle-adjustable electronic vagina endoscope.

In addition, a plurality of umbrella-shaped heating devices (15) are inserted into the treatment end II (9) when not in use, and the umbrella-shaped heating devices (15) extend out of the treatment end II (9) and open when in use.

The upper respiratory tract mucosa local temperature thermal immune induction therapeutic apparatus has the characteristics and advantages that:

the umbrella-shaped heating device has a plurality of tooth-shaped protrusions on the contact surface, which is beneficial to fully and uniformly heating the tumor, is also beneficial to fixing the tumor, prevents the tumor from falling off and shifting during treatment, and prevents the surrounding normal tissues from being damaged while fully heating the lesion part. The umbrella-shaped heating device can be used for heating the tumor, so that the wound during treatment can be reduced, the pain of a patient can be reduced, the treatment effect can be improved, the cure rate can be improved, and the recurrence rate can be reduced.

Drawings

FIG. 1 is a schematic diagram of a hard mirror and a second treatment end according to the present utility model;

FIG. 2 is a schematic view of the structure of the second therapeutic end in FIG. 1 according to the present utility model;

FIG. 3 is a schematic diagram of a soft lens body and a second therapeutic end according to the present utility model;

FIG. 4 is a schematic view of the structure of the second therapeutic end in FIG. 3 according to the present utility model;

FIG. 5 is a schematic view of the umbrella-shaped heating device according to the present utility model extending from the second treatment end of the rigid lens body;

FIG. 6 is a schematic view of the treatment end II provided in FIG. 5 according to the present utility model;

FIG. 7 is a schematic view of the umbrella-shaped heating device according to the present utility model extending from the second treatment end of the soft lens body;

FIG. 8 is a schematic view of the treatment end II provided in FIG. 7 according to the present utility model;

FIG. 9 is a schematic view of a hard lens structure according to the present utility model;

FIG. 10 is an enlarged view of A of FIG. 9 provided by the present utility model;

FIG. 11 is a schematic view of the structure of the soft lens body according to the present utility model;

FIG. 12 is a schematic view of a treatment end I of the soft lens body according to the present utility model;

FIG. 13 is a schematic view of the internal structure of the control box provided by the present utility model;

FIG. 14 is a schematic view of light passing through a control box according to the present utility model.

Fig. 15 to 20 are schematic circuit diagrams of the present utility model.

Fig. 21 is a schematic view of the rack and pinion structure of the present utility model.

In the figure: the device comprises a display 1, a control box 2, an optical fiber 3, a wire 4, a hard lens 5, a treatment end I6, a control handle 7, a soft lens 8, a treatment end II 9, an LED lamp 10, a camera 11 probe, a temperature sensor 12, an infrared ray emitting port 13, an illumination light source 14, an umbrella-shaped heating device 15, a treatment end direction regulating knob 16, a temperature time display screen 17, an illumination light source switch 18, an infrared light switch 19, an energy regulating part 20, a control box main switch 21, a camera switch 22, an infrared light source 23, a convex lens 24, a concave lens 25, an optical filter 26, an optical cable receiving device 27, an optical cable 28, a regulating knob 29, a rack 30 and a gear 31.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. 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.

As shown in fig. 9 and 10, the present utility model may also be provided with a treatment end 6.

The utility model provides a local warm immune induction therapeutic apparatus for upper respiratory tract mucous membrane, which comprises a display 1, wherein one side of the display 1 is provided with a control box 2, a processing mechanism is arranged in the control box 2, one side of the control box 2 is provided with an optical fiber 3 and a wire 4, the optical fiber 3 is arranged on one side of the wire 4, and one side of the wire 4 is provided with a therapeutic mechanism;

the treatment mechanism comprises a hard lens body 5, the bottom of the hard lens body 5 is connected with one end of an optical fiber 3 and a wire 4, one end of the hard lens body 5 is provided with a treatment end I6, the hard lens body is replaced by a control handle, the control handle is connected with one end of the optical fiber and the wire, the top end of the control handle is provided with a soft lens body, and the treatment end I is arranged at one end of the soft lens body.

The inside of treatment end one 6 is equipped with camera probe 11 and temperature sensor 12, the inside of treatment end one 6 is equipped with infrared ray emitting port 13, is located the outside of the inside camera probe 11 of treatment end one 6, temperature sensor 12 and infrared ray emitting port 13 is equipped with a plurality of LED lamps 10, the LED lamp 10 is established inside treatment end one 6, a plurality of the LED lamp 10 uses the center of treatment end one 6 as the centre of a circle to carry out annular array distribution, a plurality of evenly spaced sets up between the LED lamp 10, through set up the illumination light source that LED lamp 10 can provide for the shooting of camera probe 11 evenly at the outer end of treatment end one 6.

Further, the treatment mechanism further comprises a treatment end I, the treatment end I is replaced by the treatment end II, the treatment end II is installed at one end of the hard lens body or one end of the soft lens body, the treatment end II and the treatment end I are both internally provided with a camera probe and a temperature sensor, the treatment end I is internally provided with an infrared emission port, the treatment end I is internally provided with a light source, the camera probe, the temperature sensor and the infrared emission port which are positioned in the treatment end I are externally provided with a plurality of LED lamps, the LED lamps are positioned in the treatment end I, the treatment end I is internally provided with a plurality of umbrella-shaped heating devices, the camera probe, the temperature sensor and the light source which are positioned in the treatment end II are wrapped among the umbrella-shaped heating devices, and the treatment end I are provided with two different ends so that the treatment mechanism has different treatment modes, thereby the application range of the treatment mechanism can be expanded.

Further, a plurality of LED lamps are distributed in an annular array by taking the center of the first treatment end as the center of a circle, a plurality of LED lamps are uniformly arranged at intervals, and an illumination light source can be provided for shooting of a camera probe by uniformly arranging the LED lamps at the outer end of the first treatment end.

Furthermore, the umbrella-shaped heating devices are distributed in an annular array by taking the center of the second treatment end as the center of the circle, and the umbrella-shaped heating devices are uniformly arranged at intervals and can be used for heating treatment of the treatment area.

Further, the processing mechanism comprises an infrared light source, the infrared light source is arranged on one side inside the control box, a convex lens is arranged on one side of the infrared light source, a concave lens is arranged on one side of the convex lens, two filters 26 which are arranged in parallel are arranged on one side of the concave lens (a front filter filters ultraviolet light and visible light emitted by the infrared light source 23, a rear filter is used for intercepting infrared light with required wavelength, the transmittance of the rear filter to the infrared light with the wavelength of 800-1000 nm is more than or equal to 85%), an optical cable receiving device is arranged on one side of the filter, a plurality of optical cables are connected on one side of the optical cable receiving device, one end of each optical cable penetrates through the control box and extends out of one side of the control box, and the optical cables are arranged between the display and the control box.

Further, the temperature and time display screen is arranged on the front side of the control box, and the temperature value and the treatment time monitored by the temperature sensor can be observed through the temperature and time display screen.

Further, the control box front side is equipped with light source switch, infrared light switch and energy regulation and control part from left to right in proper order, light source switch, infrared light switch and energy regulation and control part all establish in temperature display screen bottom, can control LED lamp and light source through utilizing the light source switch, can control the infrared ray emission mouth and work utilizing the infrared light switch.

Further, control box one side is equipped with control box master switch and camera switch, control box master switch establishes at the camera switch top, can control the switch of whole control box through control box master switch, can control the operation of camera probe through the camera switch.

Further, the front side of the control handle is provided with a treatment end direction regulating knob, and the direction of the first treatment end or the second treatment end can be controlled by regulating the treatment end direction regulating knob, so that the treatment accuracy is improved.

Furthermore, when not in use, the umbrella-shaped heating devices are inserted into the second treatment end, when in use, the umbrella-shaped heating devices extend out of the second treatment end and are opened, the umbrella-shaped heating devices are arranged to be capable of shrinking and expanding (the shrinking and expanding structures are applied to a plurality of devices and belong to the conventional structural design), the second treatment end can be conveniently inserted into the human body for treatment, and then the umbrella-shaped heating devices are expanded for subsequent heating operation after reaching the inside of the human body.

As shown in the figure, the second treatment end can be arranged at the front end of the rack, the rack is arranged in the hard mirror body (5) or the soft mirror body (8), the rack is meshed with the gear, and the gear is controlled to rotate by an adjusting knob (29) on the hard mirror body (5) or the control handle (7) to control the pushing-out and the retraction of the second treatment end. The rack may be a flexible rack.

According to the utility model, two different treatment ends are arranged at one end of the soft lens body and one end of the hard lens body, so that the utility model can be suitable for different treatment situations, and the application range of the utility model is enlarged.

As shown in fig. 13 and 14, the processing mechanism includes an infrared light source 23, the infrared light source 23 is disposed on one side inside the control box 2, a convex lens 24 is disposed on one side of the infrared light source 23, a concave lens 25 is disposed on one side of the convex lens 24, two optical filters 26 disposed in parallel are disposed on one side of the concave lens 25, an optical cable receiving device 27 is disposed on one side of the optical filters 26, a plurality of optical cables 28 are connected on one side of the optical cable receiving device 27, one end of each optical cable 28 penetrates through the control box 2 and extends out of the control box 2, each optical cable 28 is disposed between the display 1 and the control box 2, a temperature display screen 17 is disposed on the front side of the control box 2, and a temperature value monitored by the temperature sensor 12 can be observed through the temperature display screen 17. The front side of the control box 2 is provided with a light source switch 18, an infrared light switch 19 and an energy regulating and controlling part 20 in sequence from left to right, the light source switch 18, the infrared light switch 19 and the energy regulating and controlling part 20 are all arranged at the bottom of the temperature display screen 17, the LED lamp 10 and the light source 14 can be controlled by utilizing the light source switch 18, and the infrared light switch 19 can be used for controlling the infrared emission port 13 to work. The control box 2 one side is equipped with control box master switch 21 and camera switch 22, control box master switch 21 establishes at camera switch 22 top, can control the switch of whole control box 2 through control box master switch 21, can control the operation of camera probe 11 through camera switch 22.

The implementation scene is specifically as follows: before the treatment, the patient should trim nose hair and clean nasal cavity, and the patient can take sitting posture and prone posture during the treatment. Spraying gunpowder into the nasal cavity of a patient, opening a control box main switch 21, opening an LED lamp 10 and a camera probe 11, enabling a doctor to hold a hard lens body 5 to slowly extend a first treatment end 6 into the nasal cavity of the patient, positioning a lesion part according to a real-time image of a display 1, opening an infrared emission port 13 and an energy regulation part 20, selecting treatment modes suitable for the patient, and setting each mode according to past experience and multiple test results, wherein for example, the mode 1 is that infrared light is used for 42 ℃ for 5 minutes, 44 ℃ for 5 minutes, 40 ℃ for 3 minutes and 44 ℃ for 5 minutes, infrared light emitted by the infrared emission port 13 irradiates the lesion part, and a temperature sensor 12 transmits the real-time temperature of the lesion part to the control box 2 and displays the temperature and the time on a display 17. Slowly taking out after the treatment is finished, and sterilizing the first treatment end 6.

As shown in fig. 11 to 12, the present utility model provides an upper respiratory tract mucosa local infrared immunity induction therapeutic apparatus, wherein a hard mirror body 5 is replaced by a control handle 7, the control handle 7 is connected with an optical fiber 3 and one end of a conducting wire 4, a soft mirror body 8 is arranged at the top end of the control handle 7, a first therapeutic end 6 is arranged at one end of the soft mirror body 8, a therapeutic end direction regulating knob 16 is arranged at the front side of the control handle 7, and the direction of the first therapeutic end 6 or the second therapeutic end 9 can be controlled by regulating the therapeutic end direction regulating knob 16, so as to improve the therapeutic accuracy.

The implementation scene is specifically as follows: before the treatment, the patient should trim nose hair and clean nasal cavity, and the patient can take sitting posture and prone posture during the treatment. Spraying gunpowder into the nasal cavity of a patient, opening a control box main switch 21, opening an LED lamp 10 and a camera probe 11, enabling a doctor to hold a soft lens body 8 to slowly extend a treatment end 6 into the nasal cavity or throat of the patient, positioning a lesion part according to a real-time image in a display 1, adjusting the direction of a treatment section by using a treatment end direction adjusting knob 16, fixing the position of the soft lens body 8 after positioning is completed, opening an infrared ray emitting port 13 and an energy adjusting part 20, selecting a treatment mode suitable for the patient, wherein each mode is set according to the past experience and multiple test results, such as the mode 1 is infrared light 42 ℃ for 5 minutes, 44 ℃ for 5 minutes, 40 ℃ for 3 minutes, 44 ℃ for 5 minutes, infrared light emitted by the infrared ray emitting port 13 irradiates the lesion part, and the temperature sensor 12 transmits the real-time temperature of the lesion part to the control box 2 and displays the temperature on a temperature display screen 17. Slowly taking out after the treatment is finished, and sterilizing the first treatment end 6.

As shown in fig. 1, fig. 2, fig. 5 and fig. 6, the utility model provides a therapeutic apparatus for local warm immune induction of upper respiratory tract mucosa, the therapeutic mechanism further comprises a second therapeutic end 9, the second therapeutic end 9 replaces the first therapeutic end 6 at one end of the hard mirror body 5, the second therapeutic end 9 is installed at one end of the hard mirror body 5, a camera probe 11 and a temperature sensor 12 are arranged in the second therapeutic end 9, a light source 14 is arranged in the second therapeutic end 9, a plurality of umbrella-shaped heating devices 15 are arranged in the second therapeutic end 9, the camera probe 11, the temperature sensor 12 and the light source 14 in the second therapeutic end 9 are wrapped in the middle of the plurality of umbrella-shaped heating devices 15, two different ends of the second therapeutic end 9 and the first therapeutic end 6 are arranged, so that the therapeutic apparatus has different therapeutic modes, the application range of the therapeutic apparatus can be expanded, the plurality of umbrella-shaped heating devices 15 are distributed in a circular array with the center of the second therapeutic end 9 as the center, the plurality of umbrella-shaped heating devices 15 are uniformly arranged at intervals, the umbrella-shaped heating devices 15 can be used for expanding the inner portion of the therapeutic apparatus, and the inner portion of the human body can be heated by expanding the second therapeutic end 9, and then the inner portion of the human body can be conveniently heated by expanding the second therapeutic end 9, and the inner portion can be conveniently expanded into the inner portion of the human body by expanding the second therapeutic end 9, and the inner portion by expanding the second heating device, and the inner portion can be conveniently expanded into the inner portion 15, and the inner portion of the human body can be heated by the human body after the inner portion is heated by the heating device through the heating device.

The implementation scene is specifically as follows: before the treatment, the patient should trim nose hair and clean nasal cavity, and the patient can take sitting posture and prone posture during the treatment. Spraying gunpowder into the nasal cavity of a patient, opening a control box main switch 21, opening a light source switch 18 and a camera switch 22, enabling a doctor to hold a hard lens body 5 to slowly extend a treatment end II 9 into the nasal cavity of the patient, positioning a lesion part according to a real-time image in a display 1, opening an umbrella-shaped heating device 15 switch after positioning is completed to enable the umbrella-shaped heating device 15 to be wrapped on the lesion part, fixing a device of the umbrella-shaped heating device 15, selecting a treatment mode suitable for the patient through an energy regulating and controlling part 20, wherein each mode is set according to past experience and multiple test results, for example, the mode 1 is used for treating for 5 minutes at 42 ℃, the temperature is 44 ℃ for treating for 5 minutes, the temperature is 40 ℃ for treating for 3 minutes, the temperature is 44 ℃ for treating for 5 minutes, and the heat emitted by the umbrella-shaped heating device 15 acts on the lesion part, and the control box main switch 21 transmits the real-time temperature of the lesion part to the control box 2 and displays the temperature on a temperature display screen 17. And after the treatment is finished, slowly taking out the medicine, and sterilizing the second treatment end 9.

As shown in fig. 3, 4, 7 and 8, the utility model provides a local warm-hot immune induction therapeutic apparatus for upper respiratory tract mucous membrane, wherein the therapeutic end I6 at one end of the soft lens body 8 is replaced by the therapeutic end II 9, and the therapeutic end II 9 is arranged at one end of the soft lens body 8.

The implementation scene is specifically as follows: before the treatment, the patient should trim nose hair and clean nasal cavity, and the patient can take sitting posture and prone posture during the treatment. Spraying gunpowder into the nasal cavity of a patient, opening a control box main switch 21, punching a card light source switch 18 and a camera switch 22, enabling a doctor to hold a soft lens body 8 to slowly stretch a treatment end two 9 into the nasal cavity or throat of the patient, positioning a lesion part according to a real-time image in a display 1, adjusting the treatment end two 9 by using a treatment end direction adjusting knob 16, opening an umbrella-shaped heating device 15 after positioning is completed to enable the umbrella-shaped heating device 15 to wrap the lesion part, fixing the position of the soft lens body 8, selecting a treatment mode suitable for the patient through an energy adjusting part 20, wherein each mode is set according to the past experience and a plurality of test results, for example, the mode 1 is 42 ℃ for 5 minutes, the treatment is 44 ℃ for 5 minutes, the treatment is 40 ℃ for 3 minutes, the heat emitted by the umbrella-shaped heating device 15 is applied to the lesion part at the temperature, and the temperature sensor 12 transmits the lesion part to the control box 2 in real time and displays the lesion part on a temperature display screen 17. And after the treatment is finished, slowly taking out the medicine, and sterilizing the second treatment end 9.

The light source switch (18) adopts an EL357N chip OP1, the input end of the OP1 is connected with the switch SW1, and the output end of the OP1 is connected with the B12.

The infrared light switch (19) adopts an EL357N chip OP2, the input end of the OP2 is connected with the switch SW2, and the output end of the OP2 is connected with the A13.

The camera switch (22) adopts an EL357N chip OP3, the input end of the OP3 is connected with the switch SW3, and the output end of the OP3 is connected with the B13.

The energy regulating part (20) adopts TLC549MD chips U11, 7 pins G1 of the U11 and 2 pins of the U11 are respectively connected with a resistor R32 and a potentiometer R28 through a resistor R31; 5 pins G5 of U11, 6 pins G2 of U11. Energy is regulated and controlled through a potentiometer R28, and a regulation signal is AD converted by U11 and then is input to U1.

The infrared emission component connected with the infrared light source 23 comprises a TLP250 chip OP4, a pin 2 of the OP4 is connected with a pin C11, pins 6 and 7 of the OP4 are respectively connected with one end of a resistor R29 and one end of a resistor R30, the other end of the resistor R29 and the other end of the resistor R30 are connected with a grid electrode of an IRFP260NPB tube Q5, a drain electrode of the Q5 is connected with +12V, and a source electrode of the Q5 is connected with VOUT through an inductor L10. The pin 2 of the OP4 receives the control signal of U1, changes the duty ratio of Q5, carries out PWM power adjustment, and controls the luminous intensity of the infrared light source 23, which is equivalent to a BUCK type constant current source circuit.

R35 is used for detecting current, through detecting the voltage on R35, convert the electric current of VOUT, through controlling the electric current, control infrared light's intensity. And the constant current source current detection resistor is used for controlling the infrared working current by detecting the voltage of R35 and changing the duty ratio of Q5. VOUT is used to control the voltage of the infrared light source 23 and thus the intensity of the infrared light.

The AD module adopts TLC549MD chip U10, 7 pins D11 of U10, 5 pins C14 of U10, and 6 pins D12 of U10.

U10 converts the analog quantity into a digital signal; and converting the detected current value signal of the infrared light source into a digital signal and sending the digital signal to the FPGA, and controlling the Q5 duty ratio after the FPGA acquires the signal. The 2 pin of U10 is the input terminal of the detection current.

The temperature display screen 17 adopts LCD_192_64 temperature display screens DIS1, 1-19 pins of DIS1 are respectively and correspondingly connected with GND, +3. V, F2, F1, E5, D4, D2, D1, C2, B1, R1, M8, L7, M6, P3, N3 and +5V, GND.

One end of a control box main switch (21) S1 is connected with a mains supply plug, the other end of the control box main switch S1 is connected with the input end of an LRS-200-12 switching power supply through a fuse F1, and the output end of the LRS-200-12 switching power supply is connected with +12V.

The +12V2 is connected with the 2 pin of the URB1205LD chip POW1 through an inductor L4, the 3 pin of the POW1 is respectively connected with the Vin end of the + V, AMS1117-3.3 chip U9, and the Vout end of the U9 is connected with +3.3V through an inductor L5.

+12v2 is connected to pin 2 of the chip POW2 via inductors L6 and L8 in sequence, and pin 4 of POW2 is connected to VCC5 via inductor L7.

The +5V is connected with the 4 pin and the 1 pin of the RT8096CHGJ5 chip U46, the 3 pin of the U46 is respectively connected with +2.5V and one end of a resistor R324 through an inductor L17, the other end of the R324 is respectively connected with the 5 pin of the U46 and one end of a resistor R325, and the other end of the R325 is respectively connected with GND and the 2 pin of the U46.

The +2.5V is connected with the 4 pin and the 1 pin of the RT8096CHGJ5 chip U48, the 3 pin of the U48 is respectively connected with +1.2V and one end of a resistor R331 through an inductor L19, the other end of the R331 is respectively connected with the 5 pin of the U48 and one end of a resistor R332, and the other end of the R332 is respectively connected with GND and the 2 pin of the U48.

The camera module of the camera probe 11 comprises an SI2302 pipe Q3 (Q3 receives an output signal of M1, controls E5 to flash, judges the working state of the camera according to the interval duration of E5 to flash), the drain electrode of the Q3 is connected with +3.3V through a light emitting diode E5, and the grid electrode of the Q3 is connected with OV_STORBE;

3 pins of the crystal oscillator Y1 are connected with OV_XCLK;

XC6206P152MR chip U5 3 pin +3.3v, U5 2 pin VCC1.5V;

XC6206P282MR chip U6 3 pin +3.3v, U6 2 pin VCC2.8V1;

XC6206P282MR chip U8 3 pin +3.3V, U8 2 pin AVDD and DOVDD; u5, U6, U8 provide the required voltages for M1.

13, 1, 8, 6, 5, 3, 7, 9, 17, 12, 14, 16, 18, 20, 22, 21, 19, 24, 11, 10, 4 pins of the OV5640 chip M1 are respectively connected with OV_XCLK, OV STORBE, E11, E10, A9, B9, C9, D9, A10, B10, F11, A15, F10, F9, A11, B11, A12, VCC2.8V1, DOVDD, VCC1.5V, AVDD.

U1 receives the signal of M1 (after the signal of M1 is collected by U1, the signal is stored, and then the communication HDMI signal format is sent by J1), and the signal is displayed by a display. M1 is the camera probe for gather video signal.

The processing mechanism inside the control box adopts the chips U1, U1 of R4, T4, L7, M6, P3, N3, T3, R3, N6, N5, K8, M7, T5, R5, T6, R6, T7, R7, M8, L8, P6, P8, N8, T8, R8 and T2 of the chips U1, and is correspondingly connected with the ports of SDRAM_CLK, SDRAM_D13L7, M6, P3, N3, SDRAM_D13, SDRAM_D0, N6, N5, K8, M7, SDRAM_D12, SDRAM_D2, SDRAM_D11, SDRAM_D3, SDRAM_D10, SDRAM_D4, M8, L8, N0, SDRAM_D8, SDRAM_D7, SDRAM_D9, SDRAM_D6 and SDRAM_D15;

the C1 and H2 ports of the U1 are correspondingly connected with the EPCS_ASDO and the EPCS_DATA0 respectively;

the ports B16 and C16 of U1 are respectively connected with the I2C1_SDA and the I2C1_SCL correspondingly;

the ports of N13, M12, K16, K15, L16, L15, N16, N15, P16 and R16 of U1 are respectively connected with HDMI_CEC_ A, HDMI _HPD, HDMI_TX2_ N, HDMI _TX2_ P, HDMI _TX1_ N, HDMI _TX1_ P, HDMI _TX0_ N, HDMI _TX0_ P, HDMI _TXC_ N, HDMI _TXC_P;

n11, M10, T9, R9, L9, M9, N9, P11, T10, R10, T11, R11, T12, R12, T13, R14, T15, T14, P14, N12, M11 of U1 are respectively associated with SDRAM_A3, SDRAM_D0, SDRAM_D1, SDRAM_CKE, SDRAM_WE, SDRAM_D1, SDRAM_A2, SDRAM_A9, SDRAM_A0, SDRAM_A8, SDRAM_CAS, SDRAM_A7, SDRAM_RAS, SDRAM_A6, SDRAM_CS, SDRAM_A5, SDRAM_B0, SDRAM_B1, SDRAM_A10, SDRAM_A4, SDRAM_A1, SDRAM_A11, SDRAM_A12

Correspondingly connected;

the H1 port of U1 is connected with EPCS_CLK;

pins 6, 2 and 5 of W25Q64 chip U7 are respectively connected with EPCS_CLK, EPCS_DATA0 and EPCS_ASDO.

Pins 23 to 26, 29 to 34, 22, 35, 36, 20, 21, 18, 17, 16, 19, 15, 39, 38, 37 of the MT48LC16M16A2B4 chip U2 are correspondingly connected with SDRAM_A0, SDRAM_A1, SDRAM_A2, SDRAM_A3, SDRAM_A4, SDRAM_A5, SDRAM_A6, SDRAM_A7, SDRAM_A8, SDRAM_A9, SDRAM_A10, SDRAM_A11, SDRAM_A12, SDRAM_BA0, SDRAM_B1, SDRAM_RAS, SDRAM_CAS, SDRAM_WE, SDRAM_CS, SDRAM_DM0, SDRAM_DM1, SDRAM_CLK, and SDRAM_CKE respectively;

2, 4, 5, 7, 8, 10, 11, 13, 42, 44, 45, 47, 48, 50, 51, 53 of U2 are correspondingly connected with sdram_d0, sdram_d1, sdram_d2, sdram_d3, sdram_d4, sdram_d5, sdram_d6, sdram_d7, sdram_d8, sdram_d9, sdram_d10, sdram_d11, sdram_d12, sdram_d13, sdram_d14, sdram_d15, respectively. The shooting speed of the camera is inconsistent with the transmission speed of the hdmi signal, the U1 converts the video signal input by the M1 into the transmission format of the hdmi signal, the converted signal is temporarily stored in the U2, and then the converted signal is transmitted to the display through the J1 interface, so that the continuity of the video signal is maintained.

The 3 pins of the crystal oscillator Y2 are connected with the FPGA_CLK.

1, 3, 4 and 6 pins of the SRV05-4 chip U3 are respectively and correspondingly connected with the HDMI_DATAN2_CN, the HDMI_DATAP2_CN, the HDMI_DATAP1_CN and the HDMI_DATAN1_CN; the 1, 3, 4 and 6 pins of the SRV05-4 chip U4 are respectively connected with the HDMI_CLKN_CN, the HDMI_CLKP_CN, the HDMI_DATAP0_CN and the HDMI_DATAN0_CN correspondingly. U3, U4 are used for protecting HDMI interface after overvoltage; the function is similar to a zener diode array.

2-pin I2C1_SDA of the 2SK3018 pipe Q1, 1-pin +3.3V of the Q1 and 3-pin DDC_SDA of the Q1; 2-pin I2C1_SCL of 2SK3018 pipe Q2, 1-pin +3.3V of Q2, 3-pin DDC_SCL of Q2; 2SK3018 pipe Q4 has 2 pins HDMI_CEC_A, Q4 has 1 pin +3.3V, and Q4 has 3 pins HDMI_CEC_CON. Q1, Q2, Q4 are used for level shifting; FPGA is 3.3V, HDMI is 5V; level shifting is performed.

The interface circuit of the display is correspondingly connected with HDMI_DATAP2_CN, HDMI_DATAN2_CN, HDMI_DATAP1_CN, HDMI_DATAN1_CN, HDMI_DATAP0_CN, HDMI_DATAN0_CN, HDMI_CLKP_CN, HDMI_CLKN_CN, HDMI_CEC_CON, NC0, HDMI_SCL_CON, HDMI_CON and + V, HDMI _HPD_CONSDA by adopting pins 1, 3, 4, 6, 7, 9, 10, 12, 13, 14, 15, 16, 18 and 19 of ATOM010130010052_HDMI_19P interfaces J1 and J1 respectively;

HDMI_DATAP2_CN is connected with HDMI_Tx2_P through C1;

HDMI_DATAN2_CN is connected with HDMI_TX2_N through C2;

HDMI_DATAP1_CN is connected with HDMI_Tx1_P through C3;

HDMI_DATAN1_CN is connected with HDMI_TX1_N through C4;

HDMI_DATAP0_CN is connected with HDMI_TX0_P through C5;

HDMI_DATAN0_CN is connected with HDMI_TX0_N through C6;

HDMI_CLKP_CN is connected with HDMI_TXC_P through C7;

HDMI_CLKN_CN is connected with HDMI_TXC_N through C8.

The therapeutic rhythm (temperature and time) in the utility model can achieve the effects of regulating the immunity of the organism and not damaging tissues through a great deal of researches, and has different therapeutic rhythms for diseases of different parts. The small temperature sensor can transmit the tissue heating temperature to the temperature display in real time so as to ensure the safety and the effectiveness of the treatment of patients.

The traditional treatment for the papilloma of nose, throat and throat is most invasive surgery treatment, the treatment mode is non-invasive, and the traditional research shows that the local thermotherapy can treat other lesion parts of one part of skin mucosa HPV infection diseases and can also recover the effect.

Claims (7)

1. The upper respiratory tract mucous membrane local warm immune induction therapeutic apparatus is characterized by comprising: the device comprises a display (1), wherein a control box (2) is arranged on one side of the display (1), a treatment mechanism is arranged in the control box (2), an optical fiber (3) and a wire (4) are arranged on one side of the control box (2), the optical fiber (3) is arranged on one side of the wire (4), and a treatment mechanism is arranged on one side of the wire (4);

the treatment mechanism comprises a hard lens body (5) or a control handle (7), wherein the bottom of the hard lens body (5) is connected with one end of an optical fiber (3) and one end of a wire (4), the control handle (7) is connected with one end of the optical fiber (3) and one end of the wire (4), and the top end of the control handle (7) is provided with a soft lens body (8);

the treatment mechanism further comprises a treatment end II (9), the treatment end II (9) is arranged at one end of the hard lens body (5) or one end of the soft lens body (8), a camera probe (11) and a temperature sensor (12) are arranged inside the treatment end II (9), a light source (14) is arranged inside the treatment end II (9), a plurality of umbrella-shaped heating devices (15) are arranged inside the treatment end II (9), and the camera probe (11), the temperature sensor (12) and the light source (14) inside the treatment end II (9) are wrapped in the middle of the umbrella-shaped heating devices (15).

2. The upper airway mucosa local-temperature heat immune induction therapeutic apparatus as claimed in claim 1, wherein a plurality of umbrella-shaped heating devices (15) are distributed in an annular array with the center of a second therapeutic end (9) as a circle center, and the umbrella-shaped heating devices (15) are uniformly arranged at intervals.

3. The upper airway mucosa local-temperature heat immune induction therapeutic apparatus according to claim 1, wherein a temperature and time display screen (17) is arranged on the front side of the control box (2).

4. The upper airway mucosa local-temperature heat immune induction therapeutic apparatus according to claim 1, wherein a control box main switch (21) and a camera switch (22) are arranged on one side of the control box (2), and the control box main switch (21) is arranged at the top of the camera switch (22).

5. The upper airway mucosa local-temperature heat immune induction therapeutic apparatus according to claim 1, wherein a therapeutic end direction regulating knob (16) is arranged on the front side of the control handle (7).

6. The upper airway mucosa local-temperature heat immune induction therapeutic apparatus as claimed in claim 1, wherein a plurality of umbrella-shaped heating devices (15) are inserted into the second therapeutic end (9) when not in use, and the umbrella-shaped heating devices (15) extend out of the second therapeutic end (9) and open when in use.

7. The upper airway mucosa local-temperature heat immune induction therapeutic apparatus according to claim 1, wherein the second therapeutic end (9) is arranged at the front end of a rack, the rack is arranged in the hard mirror body (5) or the soft mirror body (8), the rack is meshed with a gear, and the gear is controlled to rotate by an adjusting knob (29) on the hard mirror body (5) or the control handle (7).

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