CN111111109A

CN111111109A - Medical respiratory muscle training system based on network

Info

Publication number: CN111111109A
Application number: CN202010017578.3A
Authority: CN
Inventors: 刘凤娟; 孙荣丽; 武晓; 王鹏飞; 高玉磊
Original assignee: Qingdao Central Hospital
Current assignee: Qingdao Central Hospital
Priority date: 2020-01-08
Filing date: 2020-01-08
Publication date: 2020-05-08
Anticipated expiration: 2040-01-08
Also published as: CN111111109B

Abstract

The invention provides a network-based medical respiratory muscle training system which comprises a hardware subsystem, a software subsystem and a determination subsystem, wherein the hardware subsystem comprises a respiratory training device, the respiratory training device comprises a filter tip, a cylinder and a piston, the piston is positioned in the cylinder, an opening at one end of the cylinder is communicated with the filter tip, the opening at the other end of the cylinder is provided with the piston, the piston is connected with a resistance control unit through an elastic piece, the resistance control unit is controlled through a motor, the motor is electrically connected with a controller, a wireless transmission module, a card reading module and a touch screen module are arranged in the controller, the software subsystem comprises an evaluation server, and the determination subsystem is a breathing machine function determination. The invention has the beneficial effects that: the respiratory muscle training system has the advantages of reasonable design, simple structure, safety and reliability, capability of evaluating respiratory muscles of patients and judging whether the functions of the respiratory muscles of users are normal or not, and meanwhile, a respiratory muscle training prescription is provided for the patients with the respiratory muscle dysfunction, and finally, the training execution condition is recorded.

Description

Medical respiratory muscle training system based on network

Technical Field

The invention relates to the technical field of medical equipment, in particular to a medical respiratory muscle training system based on a network.

Background

Respiratory system diseases are common diseases and frequently encountered diseases, main pathological changes are in trachea, bronchus, lung and chest cavity, cough, chest pain and respiration are affected in light patients, and severe patients are suffered from dyspnea, hypoxia and even respiratory failure to die. Mortality in cities is the 3 rd bit, while in rural areas is the first bit. It should be further appreciated that due to air pollution, smoking, aging population and other factors, the incidence and mortality of chronic obstructive pulmonary disease (chronic obstructive pulmonary disease, including chronic bronchitis, emphysema and pulmonary heart disease), bronchial asthma, lung cancer, pulmonary disseminated interstitial fibrosis, pulmonary infection and other diseases at home and abroad are continuously reduced. Due to factors such as physical and chemical factors and biological factor inhalation caused by air pollution, smoking and industrial economic development, age-aging of population and the like, the incidence rate of respiratory diseases such as lung cancer and bronchial asthma is obviously increased in recent years, and chronic obstructive pulmonary diseases are high (more than 8% in the population over 40 years old).

At present, most respiratory system disease patients need to receive respiratory muscle function training, with the maturity of lung rehabilitation idea and the implementation of lung rehabilitation technology, a hospital urgently needs a respiratory muscle function training device to exercise the respiratory muscle function of the patients, because a person normally inhales, diaphragm contraction and external intercostal muscle contraction, when forcefully inhales, auxiliary muscles need to be inhaled, such as the assistance of trapezius muscles and oblique muscles, the chest is widely lifted as a result of the muscle contraction, the thoracic space is expanded to the limit, and therefore the inspiratory muscles need to be exercised, thereby increasing the strength and tolerance of the respiratory muscle. Inspiratory muscle training is now widely used in chronic obstructive pulmonary patients, and is particularly influential in this particular population due to the weakness of the inspiratory muscles in this population of patients due to chest wall physical abnormalities (excessive pressure breathing due to expiratory airflow limitation) and inadequate effort during high demand ventilation.

The respiratory muscle function evaluation equipment in the market at present works independently, respiratory training is directly carried out on the equipment after evaluation is finished, and the price is high, so that the respiratory muscle function evaluation equipment is not suitable for respiratory training of a large number of patients in hospitals one by one. Still another class of respiratory muscle function training ware is disposable individual use product, can not accurate regulation respiratory resistance, and special person is special, is not suitable for the hospital to carry out the respiratory training, and the regulation mode is manual regulation moreover, and regulation precision and speed all can not reach hospital's operation standard, and most importantly can not the automatic execution training prescription, are not suitable for the hospital to carry out the respiratory training, only are suitable for family expenses.

How to solve the above technical problems is the subject of the present invention.

Disclosure of Invention

In order to solve the defects of the prior art, the invention provides the network-based medical respiratory muscle training system which is reasonable in design, simple in structure, safe and reliable.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention provides a network-based medical respiratory muscle training system which comprises a hardware subsystem, a software subsystem and a determination subsystem, wherein the hardware subsystem comprises a respiratory training device (14), the respiratory training device (14) comprises a filter tip (1), a cylinder (2) and a piston (3), the piston (3) is positioned in the cylinder (2), an opening at one end of the cylinder (2) is communicated with the filter tip (1), and an opening at the other end of the cylinder (2) is provided with the piston (3);

the piston (3) is connected with a resistance control unit through an elastic part, the resistance control unit is controlled through a motor (4), the motor (4) is electrically connected with a controller (5), and a wireless transmission module (12), a card reading module (13) and a touch screen module are arranged in the controller (5);

the software subsystem comprises an evaluation server (6), and the evaluation server (6) is provided with a wireless transmission module (12), a card reading module (13) and a Bluetooth module (16);

the measuring subsystem is a ventilator function measuring device (15).

The piston (3) is connected to the bottom of the cylinder (2) in a sliding manner, the piston (3) comprises a circular plate (301) and a piston limiting rod (302), the central shaft of the circular plate (301) is coaxial with the central shaft of the cylinder (2), both the inner bottom and the outer bottom of the cylinder (2) are provided with limiting grooves (201), the limiting grooves (201) at the inner bottom of the cylinder (2) are connected with the piston limiting rod (302) in a sliding manner, and the piston limiting rod (302) is vertically arranged at the edge of the bottom surface of the circular plate (301);

the disc plate (301) is provided with the elastic piece fixedly connected with the center of the plate surface of the piston limiting rod (302), the elastic piece is a tension spring (7), and the other end of the tension spring (7) is fixedly connected with the resistance control unit.

The resistance control unit comprises a threaded rod (10), a connecting plate (1001) is arranged at the top end of the threaded rod (10), the connecting plate (1001) is arranged in parallel with the circular plate (301), a connecting plate limiting rod (1002) is arranged at the edge of the top surface of the connecting plate (1001), and the connecting plate limiting rod (1002) is connected to the limiting groove (201) of the outer bottom of the air cylinder (2) in a sliding mode;

the resistance control unit comprises a box body (8), the box body (8) is fixedly connected with the air cylinder (2), the motor (4) is arranged in the box body (8), an output shaft of the motor (4) is fixedly connected with a worm (9) and is coaxial with a central rotating shaft of the worm (9), and the end part of the worm (9) is rotatably connected to the inner wall of the box body (8);

box (8) rotate and are connected with worm wheel (11), worm wheel (11) top surface is provided with and runs through the screw hole of worm wheel (11), screw hole internal thread connects threaded rod (10), just the center pivot of worm wheel (11) with the center pivot of threaded rod (10) is coaxial, worm wheel (11) with worm (9) cooperation.

The filter tip (1) is movably inserted into an opening at one end of the cylinder (2), and a disposable blowing nozzle is arranged on the filter tip (1).

The controller (5) is connected with a wireless transmission module (12) of the evaluation server (6) through the wireless transmission module (12).

The controller (5) is provided with a battery pack and a power plug.

The breathing machine function measuring device (15) can measure the maximum inspiratory pressure and the maximum expiratory pressure, and measured values are transmitted to the evaluation server (6) through the Bluetooth module (16).

The touch screen module of the controller (5) can set training resistance and training time for single machine state training and can display battery power, networking state, working mode, current resistance and current training time;

and displaying the name of the training personnel and the information of the training prescription in a networking state.

The use process of the device is as follows: need set up respirator trainer network parameter (need pass through the real computer of connecting of WIFI side) before using, concrete parameter has: 1. a fixed IP address can be set or a DHCP server system automatically acquires network setting; 2. evaluating a server IP address; then, setting network parameters at a software server side: once a fixed IP address is required, it cannot be assigned by DHCP protocol.

The controller firstly carries out networking check after being started, if the network is smooth, the equipment automatically establishes communication with the evaluation server, and if the network is not communicated or cannot be connected with the server, the controller enters a single-machine working mode and can manually set training resistance for training; if the network is normally connected with the server, the equipment enters a network working mode, the equipment is provided with an independent switch to control the wireless transmission module to be started, and the training of the single breathing muscle can be carried out under the condition that the network is normally connected with the server; in the network edition working mode, a patient firstly reads a patient medical insurance card by using a card reading module of an evaluation server, and collects the card number, name, sex and age information of the patient medical insurance card, the patient performs maximum inspiratory pressure and maximum expiratory pressure measurement on a respiratory function measuring device, the measurement result is automatically uploaded to an evaluation server system through a Bluetooth module, and the evaluation server system automatically uploads the measurement result to the evaluation server system according to a formula [ male: MIP =143-0.55 × age, MEP =268-1.03 × age, female: MIP =104-0.51 × age, MEP =170-0.53 × age, unit is cm H2O (1cm H2O:. apprxeq.0.098 kPa) ] calculates standard maximum inspiratory pressure and maximum expiratory pressure values; the evaluation server system automatically compares the difference between the measured value and the standard value of the maximum inspiratory pressure and the maximum inspiratory pressure of the patient, displays the ratio of the measured value and the standard value, and prompts that the measured value is qualified when the measured value is more than or equal to 60 percent of the standard value; if the judgment result is unqualified, the evaluation server system issues a training prescription, the initial value is 30% of the maximum inspiratory pressure and the maximum expiratory pressure, the training time is 20 minutes, and medical staff can manually modify the training prescription according to the actual situation. If the evaluation result is qualified, the system can also issue a training prescription for the patient to improve the physical state, but manual confirmation is needed, and the principle that the qualified people issue the training prescription is consistent with that of the unqualified people. After the medical staff determines the training prescription, the medical staff manually clicks a 'save' button, the system saves the training prescription, and the maximum inspiratory pressure, the maximum expiratory pressure value and the patient information are automatically stored and can not be changed; the patient swipes a medical insurance card at a card reading module of the controller, the controller records the card number of the medical insurance card and calls a training prescription corresponding to the card number on the evaluation server, the breathing training device automatically adjusts the training pressure to be consistent with the training prescription in the evaluation server through a motor, the controller adjusts the resistance of the breathing training device by controlling the rotation number of the motor, the setting range of the breathing training resistance is 5-35 cm water column, and the minimum adjusting range of each time is 1cm water column. And obtaining the number of rotation turns of the motor corresponding to each centimeter of water column according to a previous experiment. When the training resistance needs to be adjusted each time, the controller firstly records the number of rotation turns of the motor corresponding to the current position, then calculates the number of forward rotation or reverse rotation turns according to a set value to reach the set value, and then drives the motor to rotate. The motor control worm is rotatory, the worm drives the worm wheel simultaneously and rotates, because worm wheel and threaded rod threaded connection, and the worm wheel rotates and connects in the box, spacing between the connecting plate at threaded rod top and the cylinder, the threaded rod just can realize steady lift, be connected between threaded rod and the extension spring, thereby realize the tensile adjustment of extension spring, the piston just can be in suitable position, when the patient breathes the training, the training of patient respiratory muscle can be realized to the resistance of piston, controller automatic timing, when the time reaches training prescription regulation time, equipment can pass through wireless transmission module with training information and return the aassessment server, the aassessment server is saved this information in this patient information, concrete content contains the training number of times, the inspiration time of training at every turn.

The device utilizes the structure of the evaluation server and the client, innovatively provides that expensive respiration evaluation equipment is used as the server, and the equipment is connected through a wireless network by developing special matching software and matching respiration training equipment. The respiratory training network system which is only evaluated by the evaluation equipment and trained by the cheap training equipment is realized.

Drawings

Fig. 1 is an overall schematic view of the present invention.

Fig. 2 is a schematic perspective view of the breathing training device of the present invention.

Fig. 3 is a front view of the respiratory training apparatus of the present invention.

Fig. 4 is a cross-sectional view of fig. 3.

Fig. 5 is a schematic perspective view of the cylinder of the present invention.

Fig. 6 is a schematic structural diagram of the interior of the box body of the respiratory training device of the present invention.

Wherein the reference numerals are: 1. a filter tip; 2. a cylinder; 201. a limiting groove; 3. a piston; 301. a circular plate; 302. a piston limit rod; 4. a motor; 5. a controller; 6. an evaluation server; 7. a tension spring; 8. a box body; 9. a worm; 10. a threaded rod; 1001. a connecting plate; 1002. connecting a plate limiting rod; 11. a worm gear; 12. a wireless transmission module 12; 13. a card reading module; 14. a respiratory training device; 15. a respiratory function measuring device; 16. and a Bluetooth module.

Detailed Description

Technical characteristics of the scheme can be clearly explained, and the scheme is explained through a specific implementation mode.

Referring to fig. 1 to 6, the embodiment is a medical respiratory muscle training system based on a network, and the system comprises a hardware subsystem, a software subsystem and a measurement subsystem, wherein the hardware subsystem comprises a respiratory training device 14, the respiratory training device 14 comprises a filter tip 1, a cylinder 2 and a piston 3, the piston 3 is located in the cylinder 2, an opening at one end of the cylinder 2 is communicated with the filter tip 1, the filter tip 1 is movably inserted into an opening at one end of the cylinder 2, and a disposable blowing nozzle is arranged on the filter tip 1.

2 other end openings of cylinder 2 set up

piston

3, 3 sliding connection of piston are in 2 bottoms of cylinder, piston 3 includes plectane 301 and piston gag lever post 302, the center pin of plectane 301 is coaxial with the center pin of

cylinder

2, 2 inner bottoms of cylinder all are provided with spacing groove 201 with the outer bottom, sliding connection piston gag lever post 302 in the spacing groove 201 of 2 inner bottoms of cylinder, piston gag lever post 302 sets up perpendicularly in the edge of plectane 301 bottom surface, plectane 301 sets up the face center department fixedly connected with elastic component of piston gag lever post 302, piston 3 is connected with the resistance control unit through elastic component, elastic component is extension spring 7, the other end fixed connection resistance control unit of extension spring 7.

Resistance control unit includes threaded rod 10, threaded rod 10 top is provided with connecting plate 1001, connecting plate 1001 and plectane 301 parallel arrangement, connecting plate 1001 top surface edge is provided with connecting plate gag lever post 1002, connecting plate gag lever post 1002 sliding connection is in the spacing groove 201 of 2 outsoles of cylinder, resistance control unit includes

box

8, 8 fixed connection cylinders 2 of box, be provided with motor 4 in the

box

8, 4 output shaft fixedly connected with worms 9 of motor are coaxial with the central pivot of worm 9, the tip of worm 9 rotates and connects in 8 inner walls of box, 8 rotations of box are connected with

worm wheel

11, 11 top surfaces of worm wheel are provided with the screw hole that runs through worm wheel 11, screw hole female connection threaded rod 10, and the central pivot of worm wheel 11 is coaxial with the central pivot of threaded rod 10, worm wheel 11.

The resistance control unit is controlled by a motor 4, the motor 4 is electrically connected with a controller 5, a wireless transmission module 12, a card reading module 13 and a touch screen module are arranged in the controller 5, the touch screen module of the controller 5 can set training resistance and training time for single machine state training, can display battery capacity, networking state, working mode, current resistance and current training time, and display names of training personnel and training prescription information in the networking state, and the controller 5 is provided with a battery pack and a power plug.

The software subsystem comprises an evaluation server 6, the evaluation server 6 is provided with a wireless transmission module 12, a card reading module 13 and a Bluetooth module 16, and the controller 5 is connected with the wireless transmission module 12 of the evaluation server 6 through the wireless transmission module 12.

The measuring subsystem is a breathing machine function measuring device 15, the breathing machine function measuring device 15 can measure the maximum inspiratory pressure and the maximum expiratory pressure, and the measured values are transmitted to the evaluation server 6 through the Bluetooth module 16.

The use process of the device is as follows: need set up 14 network parameters of respirator trainer and need pass through the real computer of WIFI side connection before using, specific parameter has: 1. a fixed IP address can be set or a DHCP server system automatically acquires network setting; 2. evaluating the server 6IP address; then, setting network parameters at a software server side: once a fixed IP address is required, it cannot be assigned by DHCP protocol.

After the controller 5 is started, firstly, the network check is carried out, if the network is smooth, the equipment automatically establishes communication with the evaluation server 6, if the network is not smooth or cannot be connected with the server, the controller 5 enters a single-machine working mode, and the training resistance can be manually set for training; if the network is normally connected with the server, the equipment enters a network working mode, the equipment is provided with an independent switch to control the wireless transmission module 12 to be started, and the training of the single breathing muscle can be carried out under the condition that the network is normally connected with the server.

In the network edition working mode, a patient firstly reads a patient medical insurance card by using the card reading module 13 of the evaluation server 6, and collects the card number, name, sex and age information of the patient medical insurance card, the patient performs maximum inspiratory pressure and maximum expiratory pressure measurement on the respiratory function measuring device 15, the measurement result is automatically uploaded to the evaluation server 6 system through the bluetooth module 16, and the evaluation server 6 system automatically uploads the maximum inspiratory pressure and the maximum expiratory pressure to the evaluation server 6 system according to a formula [ male: MIP =143-0.55 × age, MEP =268-1.03 × age, female: MIP =104-0.51 × age, MEP =170-0.53 × age, unit is cm H2O (1cm H2O:. apprxeq.0.098 kPa) ] calculates standard maximum inspiratory pressure and maximum expiratory pressure values; the system of the evaluation server 6 automatically compares the difference between the measured value and the standard value of the maximum inspiratory pressure and the maximum expiratory pressure of the patient, displays the ratio of the measured value and the standard value, simultaneously prompts that the measured value is qualified when being larger than 60% of the standard value and unqualified when being smaller than or equal to 60% of the standard value, the evaluation server 6 system issues a training prescription after judging that the measured value is unqualified, the initial value is 30% of the measured maximum inspiratory pressure and the maximum expiratory pressure, the training time is 20 minutes, medical personnel can manually modify the training prescription according to the actual condition, the medical personnel manually clicks a 'save' button after determining the training prescription, the system saves the training prescription, and the maximum inspiratory pressure, the maximum expiratory pressure and the patient information are automatically stored and can not be changed.

The patient swipes a medical insurance card at a card reading module 13 of the controller 5, the controller 5 records a card number of the medical insurance card and calls a training prescription corresponding to the card number on the evaluation server 6, the breathing training device 14 automatically adjusts the training pressure to be consistent with the training prescription in the evaluation server 6 through the motor 4, the controller 5 adjusts the resistance of the breathing training device 14 through controlling the rotation number of turns of the motor 4, the setting range of the breathing training resistance is 5-35 cm water column, and the minimum adjusting range of each time is 1cm water column. And obtaining the number of rotation turns of the motor corresponding to each centimeter of water column according to a previous experiment. When the training resistance needs to be adjusted each time, the controller 5 firstly records the number of rotation turns of the motor corresponding to the current position, then calculates the number of forward or reverse rotation turns according to a set value to reach the set value, and then drives the motor 4 to rotate.

Motor 4 control worm 9 is rotatory, worm 9 drives worm wheel 11 and rotates simultaneously, because worm wheel 11 and threaded rod 10 threaded connection, and worm wheel 11 rotates and connects in box 8, it is spacing between connecting plate 1001 at threaded rod 10 top and cylinder 2, threaded rod 10 just can realize steady lift, be connected between threaded rod 10 and the extension spring 7, thereby realize the tensile adjustment of extension spring 7, piston 3 just can be in suitable position, when the patient breathes the training, patient's breathing flesh's training can be realized to piston 3's resistance, controller 5 automatic timing, when the time reaches training prescription regulation time, equipment can pass training information through wireless transmission module 12 and return evaluation server 6, evaluation server 6 keeps this information in this patient information, concrete content contains the training number of times, the inspiration time of training at every turn.

The technical features of the present invention which are not described in the above embodiments may be implemented by or using the prior art, and are not described herein again, of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and variations, modifications, additions or substitutions which may be made by those skilled in the art within the spirit and scope of the present invention should also fall within the protection scope of the present invention.

Claims

1. A network-based medical respiratory muscle training system is characterized in that,

the device comprises a hardware subsystem, a software subsystem and a measuring subsystem, wherein the hardware subsystem comprises a breathing training device (14), the breathing training device (14) comprises a filter tip (1), a cylinder (2) and a piston (3), the piston (3) is positioned in the cylinder (2), an opening at one end of the cylinder (2) is communicated with the filter tip (1), and an opening at the other end of the cylinder (2) is provided with the piston (3);

the measuring subsystem is a ventilator function measuring device (15).

2. The network-based medical respiratory muscle training system as claimed in claim 1, wherein the piston (3) is slidably connected to the bottom of the cylinder (2), the piston (3) comprises a circular plate (301) and a piston limiting rod (302), the central axis of the circular plate (301) is coaxial with the central axis of the cylinder (2), both the inner bottom and the outer bottom of the cylinder (2) are provided with limiting grooves (201), the limiting groove (201) of the inner bottom of the cylinder (2) is slidably connected with the piston limiting rod (302), and the piston limiting rod (302) is vertically arranged at the edge of the bottom surface of the circular plate (301);

3. The network-based medical respiratory muscle training system as claimed in claim 2, wherein the resistance control unit comprises a threaded rod (10), a connecting plate (1001) is arranged at the top end of the threaded rod (10), the connecting plate (1001) is arranged in parallel with the circular plate (301), a connecting plate limiting rod (1002) is arranged at the edge of the top surface of the connecting plate (1001), and the connecting plate limiting rod (1002) is slidably connected with the limiting groove (201) of the outer sole of the cylinder (2);

4. The network-based medical respiratory muscle training system as claimed in claim 1, wherein the filter (1) is movably inserted into an opening at one end of the cylinder (2), and the filter (1) is provided with a disposable blowing nozzle.

5. The network-based medical respiratory muscle training system according to claim 1, wherein the controller (5) is connected to the wireless transmission module (12) of the evaluation server (6) via a wireless transmission module (12).

6. The network-based medical respiratory muscle training system according to claim 1, wherein the controller (5) is provided with a battery pack and a power plug.

7. The network-based medical respiratory muscle training system according to claim 1, wherein the ventilator function determination means (15) determines a maximum inspiratory pressure and a maximum expiratory pressure, and the measured values are transmitted to the evaluation server (6) via the bluetooth module (16).

8. The network-based medical respiratory muscle training system as claimed in claim 1, wherein the touch screen module of the controller (5) can set training resistance and training time for single-machine state training, and can display battery level, networking state, working mode, current resistance and current training time;