CN107616903A - A kind of new breathing couples the anti-thrombotic equipment of limb vein of matching - Google Patents

Abstract

The invention relates to a respiratory coupling matching anti-thrombosis device of extremities, the device is composed of more than two inflatable and deflated airbags and strips for inflating and deflated airbags; The inflated and deflated strips have a breathing sensor and a pressure sensor. Under the control of the microprocessor, they are regularly inflated and deflated according to the breathing signal fed back by the breathing sensor, and the inflation pressure is adjusted according to the pressure signal fed back by the pressure sensor. Its advantages are as follows: formation of directional pressure, controllable and adjustable inflation pressure, adaptation to shaping, controllable and adjustable pressure rhythm and time, and can be used to prevent venous thrombosis in limbs.

Description

A new type of respiratory coupling matching device for anti-venous thrombosis of extremities

technical field

The invention relates to the technical field of medical devices, in particular to a breathing coupling matching device for preventing venous thrombosis of extremities.

Background technique

Venous thrombosis of extremities is a common peripheral vascular disease with insidious onset, which can cause complications such as extremity edema, extremity venous valve insufficiency, acute and chronic pulmonary embolism, and severe cases can lead to sudden death of patients. There are many causes of venous thrombosis in the extremities, and the common ones are active immobilization, passive immobilization, less exercise or no exercise of the extremities. Active immobilization, for example, after various operations, the patient takes active non-exercise measures due to pain; passive immobility, such as limb fractures or trauma, requires the patient to immobilize the limbs to prevent exercise from aggravating the condition; Weak, long-term bedridden patients often cause venous thrombosis in the extremities due to less or no exercise. Therefore, in the course of clinical treatment, it is necessary to massage the limbs of the patient to promote the venous return of the limbs and prevent the occurrence of venous thrombosis in the limbs. However, inappropriate timing of extremities massage, inaccurate control of massage intensity and massage cycle rhythm can all lead to the formation of venous thrombosis in extremities. Simultaneously, carrying out long-term extremity massage to long-term bedridden patient will bring huge economic pressure to patient and family, increase a large amount of manpower and material cost. Therefore, there is an urgent need for a device for the prevention of venous thrombosis in the extremities, which can realize multiple functions such as regular pressing on the extremities, controllable intensity, adjustable pressing rhythm, and adjustable pressing time, so as to prevent the formation of venous thrombosis in the extremities, and at the same time liberate the accompanying personnel. Save manpower and material resources to achieve both economic and social benefits.

Chinese patent document CN101267793A discloses a compression device for a limb comprising: an inflatable sleeve surrounding the limb, a conduit attached to the sleeve and delivering fluid to the sleeve for controlling the fluid flow control system, memory. Chinese patent document CN201899686U discloses a deep vein thrombosis treatment instrument, which is composed of a strap, an air pump, a reversing valve, a pressure sensor and a control circuit. The strap surrounding the thigh is composed of two upper and lower independent inflatable air bags Composition, the strap is tied on one thigh of the human body, and the air is slowly injected into the two inflatable air bags within a certain period of time. A wave-like slight pressure is obtained, which promotes the return of blood in the veins. Chinese patent document CN202589894U discloses a portable device for prevention and treatment of deep venous thrombosis, which includes an airbag and a control and detection unit bidirectionally connected to the airbag through an air circuit unit. The high-efficiency medical air pump is controlled by an intelligent control chip to inflate and deflate the airbags, and then deeply pressurize and relax the blood vessels of the human feet and legs. However, there is no report about the respiratory coupling matching anti-extremity venous thrombosis device of the present invention.

The respiratory coupling matching anti-thrombosis device of extremities of the present invention can be used as a special medical device product, and can also be used as a civilian auxiliary extremity massage device. The patent was funded by the following projects: Three-year action plan to promote clinical skills and clinical innovation capabilities of municipal hospitals (16CR3105B); technology transfer and promotion project of the Science and Technology Department of Shanghai Jiao Tong University School of Medicine (ZT201710, ZT201711); Shanghai Science and Technology Committee Medical Guidance Science and Technology Project (15411969100, 16411969300); Shanghai Jiaotong University Medical-Industrial Interdisciplinary Research Fund (YG2015MS28); Shanghai Municipal Health and Family Planning Commission Fund (201440290, 201640043).

Contents of the invention

The object of the present invention is to provide a breathing coupling matching anti-thrombotic device for extremities to address the deficiencies in the prior art.

The second object of the present invention is to provide a control method of a respiratory coupling matching device for preventing venous thrombosis of extremities.

The third object of the present invention is to provide an application of a respiratory coupling matching device for preventing venous thrombosis in extremities.

In order to achieve the above object, the technical solution adopted by the present invention is: a respiratory coupling matching anti-thrombosis equipment of extremities. The strips are composed of strips; the strips for inflating and deflated airbags have breathing sensors and pressure sensors. Under the control of the microprocessor, they are regularly inflated and deflated according to the breathing signals fed back by the breathing sensors. The feedback pressure signal regulates the inflation pressure.

Further, the inflatable and deflated airbag is composed of an airbag body and a ventilation tube, the airbag body is in the shape of a cuboid as a whole, and the upper surface of the airbag body is connected to the ventilation tube.

Further, the strip for inflating and deflated airbags has an inflation channel, an air pump connected to the inflation channel, an inflation valve connected to the inflation channel, an inflation port connected to the inflation valve, a deflation channel, and a deflation channel. Channel connected deflation port, microprocessor, respiration sensor, pressure sensor at the outlet of the inflator pump.

Further, a ring-shaped protrusion is provided on the ventilation pipe.

Further, both ends of the airbag body have Velcro fasteners.

Further, the strip for inflating and deflated airbags is composed of an inflation strip and a deflation strip; the inflation strip is composed of an inflation strip body, an inflation channel, an inflation pump, an inflation valve, an inflation port, The first microprocessor, a switch, a battery, a pressure sensor, a respiration sensor connection line, a respiration sensor and a communication module, the inflatable strip body is provided with an inflatable channel, the inflatable channel is connected to the air pump, and the outlet of the air pump is provided with There is a pressure sensor, the inflation channel is connected to the inflation valve, the inflation valve is connected to the inflation port, and the inflation port matches the ventilation tube. The first microprocessor controls the inflation pump, the inflation valve, and the communication module. The first The microprocessor is connected to the switch, the switch is located on the upper surface of the body of the inflatable strip, the switch is connected to the battery, the first microprocessor is connected to the pressure sensor, and the first microprocessor is connected to the breathing sensor through the connection line of the breathing sensor. sensor connection; the deflation strip is composed of a deflation strip body, a deflation channel, a deflation valve, a deflation port, a second microprocessor, a switch, a battery, and a communication module, and the deflation strip body A deflation channel is provided, the deflation channel is connected with the deflation valve, the deflation valve is connected with the deflation port, and the deflation port is matched with the ventilation pipe, and the second microprocessor controls the deflation valve, and the second microprocessor is connected with the deflation port. The switch is connected, the switch is located on the upper surface of the deflation strip body, the switch is connected with the battery, and the second microprocessor is connected with the communication module.

Further, the strip for inflating and deflated airbag is composed of strip body, inflation channel, inflation pump, inflation valve, inflation port, deflation channel, deflation valve, deflation port, microprocessor, switch, battery , a pressure sensor, a breathing sensor connection line and a breathing sensor. The strip body is provided with an inflation channel and a deflation channel. The inflation channel is connected to the air pump. connection, the inflation valve is connected to the inflation port; the deflation channel is connected to the deflation valve, the deflation valve is connected to the deflation port, the microprocessor controls the inflation pump, the inflation valve, and the deflation valve, and the microprocessor is connected to the pressure sensor , the microprocessor is connected with the switch, the switch is located on the upper surface of the strip body, the switch is connected with the battery, and the microprocessor is connected with the respiration sensor through the respiration sensor connection line.

In order to achieve the above-mentioned second purpose, the technical solution adopted by the present invention is: the control method includes the following steps: after the air pump is turned on, according to the pressure signal fed back by the pressure sensor, under the control of the first microprocessor, the air pump Rotate at a suitable speed, according to the patient's respiratory rate fed back by the respiratory sensor, after the first microprocessor performs data processing, the frequency of opening and closing of the inflation valve and deflation valve is consistent with the patient's respiratory rate.

The control method includes the following steps: after the switch is turned on, the air pump is turned on, and according to the pressure signal fed back by the pressure sensor, under the control of the microprocessor, the air pump rotates at a suitable speed, and according to the respiratory rate of the patient fed back by the breathing sensor, After the microprocessor performs data processing, the frequency of opening and closing of the inflation valve and the deflation valve is consistent with the breathing frequency of the patient.

In order to achieve the above third objective, the technical solution adopted by the present invention is: the application of the device in the preparation of medical devices for preventing venous thrombosis.

The present invention has the advantage that:

1. Form directional pressure. The device of the present invention regularly inflates and deflates the air bag to form directional pressure on the veins of the extremities, and pushes the blood in the veins of the extremities to move directionally from the distal end to the proximal end, so as to prevent venous thrombosis of the extremities.

2. The inflation pressure is controllable and adjustable. The device of the present invention can control and adjust the pressure in the inflated and deflated air bag, so as to meet the massage strength requirements of limbs with different thicknesses, and realize the best massage effect.

3. Adapt to shaping. The device of the present invention is composed of a plurality of inflation and deflation units, and each inflation unit can be respectively fixed at different positions of the limbs to adapt to the shape of the limbs. This setting is conducive to uniform and sufficient pressure in each segment of the veins of the limbs, so as to realize the pressure of the veins of the limbs. best effect.

4. Pressure rhythm and time are controllable and adjustable. According to the patient's breathing frequency, the device of the present invention realizes that the pressing rhythm conforms to the physiological rhythm of the human body, so as to prevent limb ischemia and poor pressing effect caused by excessive pressing.

Description of drawings

Accompanying drawing 1 is a kind of structure schematic diagram of the device of respiratory coupling matching anti-venous thrombosis of extremities.

Accompanying drawing 2 is a structural schematic diagram of an inflatable and deflated airbag.

Accompanying drawing 3 is the structure diagram of inflatable strip and deflated strip.

Accompanying drawing 4 is the structure diagram of inflatable strip.

Accompanying drawing 5 is the structural representation of deflation strip.

Accompanying drawing 6 is a kind of control pattern diagram of the device of respiratory coupling matching anti-extremity venous thrombosis.

Accompanying drawing 7 is a schematic structural diagram of a respiratory coupling matching anti-extremity venous thrombosis device.

Accompanying drawing 8 is a structural schematic diagram of a strip body.

Accompanying drawing 9 is a control mode diagram of a device for breathing coupling matching anti-venous thrombosis of extremities.

detailed description

The specific implementation modes provided by the present invention will be described in detail below in conjunction with the examples.

The reference signs and components involved in the accompanying drawings are as follows:

100. Inflate and deflate airbag

101. Airbag body

102. Nylon velvet tape

103. Nylon hook strap

104. Air pipe

200. Inflatable strip

201. Inflatable strip body

202. Inflatable channel

203. Air pump

204. Inflatable valve

205. Inflatable port

206. The first microprocessor

207. switch

208. battery

209. Pressure sensor

210. Respiration sensor cable

211. Breath sensor

212. Communication module

300, deflation strip

301, deflation strip body

302. Venting channel

303. Air release valve

304. Vent

305. Second microprocessor

306: switch

307. battery

308. Communication module

400. Inflatable and deflated strips

401. Strip Body

402. Inflatable channel

403. Air pump

404. Inflatable valve

405. Inflatable port

406. Air release channel

407. Air release valve

408. Vent

409: Microprocessor

410: switch

411. battery

412: pressure sensor

413. Respiration sensor connection line

414: Breath sensor

Example 1

Please refer to accompanying drawings 1-6. Accompanying drawing 1 is a structural schematic diagram of the respiratory coupling matching anti-venous thrombosis device of the extremities in this embodiment. Accompanying drawing 2 is a structural schematic diagram of the inflatable and deflated airbag in this embodiment. Accompanying drawing 3 It is a schematic structural view of the inflatable strip and the deflated strip of the present embodiment. Accompanying drawing 4 is a schematic structural view of the inflatable strip of the present embodiment, and accompanying drawing 5 is a structural schematic diagram of the deflated strip of the present embodiment. 6 is a control mode diagram of the equipment of this embodiment.

The respiratory coupling matching anti-extremity venous thrombosis device consists of an inflatable and deflated air bag (100), an inflatable strip (200) and a deflated strip (300).

3 to 10 inflatable and deflated airbags (100) are placed side by side, and the inflatable and deflated airbags (100) are composed of an airbag body (101), a nylon velvet belt (102), a nylon hook belt (103) and a ventilation tube (104). composition. The airbag body (101) is a cuboid as a whole, and the upper surface of the airbag body (101) is provided with a nylon velvet tape (102) and a nylon hook belt (103) that cooperate with each other, and the upper surface of the airbag body (101) is connected to 4 air pipes. (104), the ventilation pipe (104) is provided with a circle of annular protrusions.

The inflation strip (200) is composed of an inflation strip body (201), an inflation channel (202), an inflation pump (203), an inflation valve (204), an inflation port (205), a first microprocessor (206) , a switch (207), a battery (208), a pressure sensor (209), a breathing sensor connection line (210), a breathing sensor (211) and a communication module (212). The inflation strip body (201) is provided with an inflation channel (202), and the inflation channel (202) is connected with the air pump (203), and the outlet of the air pump (203) is provided with a pressure sensor (209), and the inflation channel ( 202) is connected with the inflation valve (204), and the inflation valve (204) is connected with the inflation port (205), and the inflation port (205) matches with the air pipe (104). The first microprocessor (206) controls the inflation pump (203), the inflation valve (204), the communication module (212), and the first microprocessor (206) is connected with the switch (207), and the switch ( 207) is located on the upper surface of the inflatable strip body (201), the switch (207) is connected to the battery (208), and the first microprocessor (206) is connected to the pressure sensor (209). The first microprocessor (206) is connected with the respiration sensor (211) through the respiration sensor connection line (210). The first microprocessor (206) is connected to the communication module (212), and the communication module (212) of the inflatable strip (200) can communicate with the communication module (308) of the deflation strip (300), or Communicate with mobile phones, computers, etc.

The deflation strip (300) consists of a deflation strip body (301), a deflation channel (302), a deflation valve (303), a deflation port (304), a second microprocessor (305), a switch (306), battery (307), and communication module (308). The deflation strip body (301) is provided with a deflation channel (302), and the deflation channel (302) is connected with the deflation valve (303), and the deflation valve (303) is connected with the deflation port (304). The air port (304) is matched with the vent pipe (104). Described second microprocessor (305) controls deflation valve (303), and second microprocessor (305) is connected with switch (306), and switch (306) is positioned at the upper surface of deflation strip body (301) , the switch (306) is connected to the battery (307). The second microprocessor (305) is connected with the communication module (308).

Example 2

The respiratory coupling of embodiment 1 is matched with the control program of the device for preventing venous thrombosis in the extremities, and it is used for the calf as an example:

A total of 5 inflatable and deflated airbags (100), numbered 1-5 from bottom to top.

After the switch (207) and switch (306) are turned on, the air pump (203) is turned on, and according to the pressure signal fed back by the pressure sensor (209), under the control of the first microprocessor (206), the air pump (203) operates with a suitable Rotate at a high speed to suit calves of different thicknesses. According to the patient's respiratory rate fed back by the respiratory sensor (211), after the first microprocessor (206) performs data processing, the opening and closing frequency of the inflation valve (204) and the deflation valve (303) are consistent with the patient's respiratory rate. The inflation valve (204) corresponding to the No. 1 inflatable and deflated airbag (100) is opened, and the No. 1 inflatable and deflated airbag (100) starts to inflate. After the No. 1 inflation and deflation air bag (100) is inflated, the No. 2 inflation and deflation air bag (100) starts to inflate. After the No. 2 inflation and deflation air bag (100) is inflated, the No. 3 inflation and deflation air bag (100) starts to inflate, the corresponding deflation valve (303) of the No. 1 inflation and deflation air bag (100) is opened, and the No. 1 inflation and deflation air bag (100) (100) Start to deflate. Inflate and deflate one by one in sequence. After the No. 5 inflation and deflation air bag (100) is inflated, the No. 1 inflation and deflation air bag (100) starts to inflate, and the No. 4 inflation and deflation air bag (100) starts to deflate, forming a cycle, which is regularly inflated and deflated.

Example 3

Please refer to accompanying drawing 2, accompanying drawing 7, accompanying drawing 8, accompanying drawing 9, accompanying drawing 2 is the schematic diagram of the inflation and deflation air bag of this embodiment, and accompanying drawing 7 is the respiratory coupling matching anti-extremity vein thrombosis of this embodiment The schematic diagram of the device, the accompanying drawing 8 is a schematic diagram of the inflation and deflation strip of this embodiment, and the accompanying drawing 9 is a control mode diagram of the device of this embodiment.

The respiratory coupling matching anti-extremity venous thrombosis device consists of an inflatable and deflated air bag (100) and an inflatable and deflated strip (400).

A plurality of inflatable and deflated airbags (100) are placed side by side, and the inflatable and deflated airbags (100) are composed of an airbag body (101), a nylon velvet tape (102), a nylon hook tape (103) and a ventilation tube (104). The airbag body (101) is a cuboid as a whole, and the upper surface of the airbag body (101) is provided with a nylon velvet tape (102) and a nylon hook belt (103) that cooperate with each other, and the upper surface of the airbag body (101) is connected to the ventilation pipe (104 ), the ventilation pipe (104) is provided with a circle of annular protrusions.

The inflation and deflation strip (400) consists of a strip body (401), an inflation channel (402), an inflation pump (403), an inflation valve (404), an inflation port (405), an inflation channel (406), Composed of deflation valve (407), deflation port (408), microprocessor (409), switch (410), battery (411), pressure sensor (412), respiration sensor connection line (413) and respiration sensor (414) . The strip body (401) is provided with an inflation channel (402) and a deflation channel (406), the inflation channel (402) is connected to the air pump (403), and the outlet of the air pump (403) is provided with a pressure sensor ( 412), the inflation passage (402) is connected with the inflation valve (404), and the inflation valve (404) is connected with the inflation port (405); the deflation passage (406) is connected with the deflation valve (407), and the deflation valve (407) Connect with the vent (408). Described microprocessor (409) controls inflation pump (403), inflation valve (404), deflation valve (407), and microprocessor (409) is connected with pressure sensor (412), and microprocessor (409) is connected with pressure sensor (412). The switch (410) is connected, the switch (410) is located on the upper surface of the strip body (401), the switch (410) is connected to the battery (411), and the microprocessor (409) is connected to A breath sensor (414) is connected.

In order to make the connection between the inflatable and deflated airbags (100) more firm, ordinary strips can also be added to connect with the inflatable and deflated airbags (100) through methods such as Velcro.

Example 4

The respiratory coupling of embodiment 3 matches the control program of the device for preventing venous thrombosis in the extremities, taking the arm as an example:

A total of 5 inflatable and deflated air bags (100) are numbered 1-5 from the distal end to the proximal end.

After the switch (410) is turned on, the air pump (403) is turned on, and according to the pressure signal fed back by the pressure sensor (412), under the control of the microprocessor (409), the air pump (403) rotates at a suitable speed to suit different Thick arms. According to the patient's respiration rate fed back by the respiration sensor (414), after the microprocessor (409) performs data processing, the opening and closing frequency of the inflation valve (404) and the deflation valve (407) are consistent with the patient's respiration rate. The inflation valve (404) corresponding to the No. 1 inflatable and deflated airbag (100) is opened, and the No. 1 inflatable and deflated airbag (100) starts to inflate. After the No. 1 inflation and deflation air bag (100) is inflated, the No. 2 inflation and deflation air bag (100) starts to inflate. After the No. 2 inflation and deflation air bag (100) is inflated, the No. 3 inflation and deflation air bag (100) starts to inflate, the corresponding deflation valve (407) of the No. 1 inflation and deflation air bag (100) is opened, and the No. 1 inflation and deflation air bag (100) Start to deflate. Inflate and deflate one by one in sequence. After the No. 5 inflation and deflation air bag (100) is inflated, the No. 1 inflation and deflation air bag (100) starts to inflate, and the No. 4 inflation and deflation air bag (100) starts to deflate, forming a cycle, which is regularly inflated and deflated.

This patent was funded by the following projects: Three-year Action Plan for Promoting Clinical Skills and Clinical Innovation Ability of Municipal Hospitals (16CR3105B); Technology Transfer Promotion Project of Science and Technology Department of Shanghai Jiaotong University School of Medicine (ZT201710, ZT201711); Medical Guidance Category of Shanghai Science and Technology Committee Science and Technology Project (15411969100, 16411969300); Shanghai Jiaotong University Medical-Industrial Interdisciplinary Research Fund (YG2015MS28); Shanghai Municipal Health and Family Planning Commission Fund (201440290, 201640043).

The above is only a preferred embodiment of the present invention, it should be pointed out that for those of ordinary skill in the art, without departing from the method of the present invention, some improvements and supplements can also be made, and these improvements and supplements should also be considered Be the protection scope of the present invention.

Claims (10)

1. A respiratory coupling matching anti-extremity venous thrombosis device, characterized in that the device is composed of more than 2 inflation and deflation airbags and a strip for inflation and deflation of the inflation and deflation airbags; The inflatable and deflated strips of the deflated airbag are equipped with a respiration sensor and a pressure sensor. Under the control of the microprocessor, they are regularly inflated and deflated according to the respiration signal fed back by the respiration sensor, and the inflation pressure is adjusted according to the pressure signal fed back by the pressure sensor. . 2. The device according to claim 1, wherein the inflatable and deflated airbag is composed of an airbag body and a ventilation tube, the airbag body is in the shape of a cuboid as a whole, and the upper surface of the airbag body is connected to the ventilation tube. 3. The device according to claim 2, characterized in that, the strip for inflating and deflated airbags has an inflation channel, an air pump connected to the inflation channel, an inflation valve connected to the inflation channel, and an inflation valve Connected inflation port, deflation channel, deflation port connected with the deflation channel, microprocessor, respiration sensor, pressure sensor positioned at the outlet of the inflator pump. 4. The device according to claim 2, characterized in that a ring-shaped protrusion is provided on the ventilation pipe. 5. The device according to claim 2, wherein both ends of the airbag body have Velcro fasteners. 6. The device according to claim 3, characterized in that, the strips for inflating and deflated airbags are composed of inflatable strips and deflated strips; The inflatable strip is composed of an inflatable strip body, an inflation channel, an air pump, an inflation valve, an inflation port, a first microprocessor, a switch, a battery, a pressure sensor, a breathing sensor connection line, a breathing sensor and a communication module. The body of the above-mentioned inflatable belt is provided with an inflatable channel, the inflatable channel is connected to the air pump, the outlet of the inflatable pump is provided with a pressure sensor, the inflatable channel is connected to the inflatable valve, the inflatable valve is connected to the inflatable port, and the inflatable port is matched with the ventilation tube. The first microprocessor controls the air pump, the inflation valve, and the communication module. The first microprocessor is connected to the switch, which is located on the upper surface of the inflatable strip body, and the switch is connected to the battery. A microprocessor is connected with the pressure sensor, and the first microprocessor is connected with the respiration sensor through the connection line of the respiration sensor; The deflation strip is composed of a deflation strip body, a deflation channel, a deflation valve, a deflation port, a second microprocessor, a switch, a battery, and a communication module. The air channel, the air release channel is connected with the air release valve, the air release valve is connected with the air release port, and the air release port is matched with the air pipe, the second microprocessor controls the air release valve, and the second microprocessor is connected with the switch, The switch is located on the upper surface of the deflation strip body, the switch is connected with the battery, and the second microprocessor is connected with the communication module. 7. The device according to claim 3, characterized in that, the strip for inflating and deflating the air bag is composed of a strip body, an inflation channel, an air pump, an inflation valve, an inflation port, a deflation channel, a deflation Valve, air release port, microprocessor, switch, battery, pressure sensor, respiration sensor connection line and respiration sensor, the strip body is provided with an inflation channel, an air release channel, the inflation channel is connected with the air pump, and the air pump The outlet is provided with a pressure sensor, the inflation channel is connected with the inflation valve, and the inflation valve is connected with the inflation port; the deflation channel is connected with the deflation valve, and the deflation valve is connected with the deflation port, and the microprocessor controls the inflation pump and the inflation valve , The deflation valve, the microprocessor is connected to the pressure sensor, the microprocessor is connected to the switch, the switch is located on the upper surface of the strip body, the switch is connected to the battery, and the microprocessor is connected to the breathing sensor through the breathing sensor connection line. 8. The control method of the device according to claim 6, characterized in that the control method comprises the following steps: after the air pump is turned on, according to the pressure signal fed back by the pressure sensor, under the control of the first microprocessor, The inflatable pump rotates at a suitable speed. According to the respiratory rate of the patient fed back by the respiratory sensor, after the first microprocessor performs data processing, the frequency of opening and closing of the inflation valve and the deflation valve is consistent with the patient's respiratory rate. 9. The control method of the device according to claim 7, characterized in that the control method comprises the following steps: after the switch is turned on, the air pump is turned on, and according to the pressure signal fed back by the pressure sensor, under the control of the microprocessor , the air pump rotates at a suitable speed, according to the patient's respiratory rate fed back by the respiratory sensor, after the microprocessor performs data processing, the frequency of opening and closing the inflation valve and deflation valve is consistent with the patient's respiratory rate. 10. Application of the device according to any one of claims 1-7 in the preparation of medical devices for preventing venous thrombosis.