CN208444496U - A kind of integration electro physiology and Hemodynamics simulator - Google Patents
A kind of integration electro physiology and Hemodynamics simulator Download PDFInfo
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- CN208444496U CN208444496U CN201721539457.5U CN201721539457U CN208444496U CN 208444496 U CN208444496 U CN 208444496U CN 201721539457 U CN201721539457 U CN 201721539457U CN 208444496 U CN208444496 U CN 208444496U
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Abstract
The utility model discloses a kind of integrated electro physiology and Hemodynamics simulators, including shell, simulate heart, aorta, cardinal vein, display screen, blood pump, central processing unit, heater, the simulation heart is provided on the shell, the simulation endocardial is provided with the blood pump, described simulation heart one end is provided with the aorta, branch artery is provided on the aorta, the aorta is internally provided with arterial blood pressure sensor, the simulation heart other end is provided with the cardinal vein, the cardinal vein is internally provided with venous pressure sensor, temperature sensor is provided with below the cardinal vein, branch vein is provided on the cardinal vein.Beneficial effect is: the utility model can simulate the principle of dynamics of blood operation, people are facilitated to get information about sanguimotor path, display screen can show the blood pressure situation in blood vessel, and simulation human body temperature environment simultaneously, be more conducive to carrying out medicine and biological study.
Description
Technical field
The utility model relates to biomethanics equipment technical fields, dynamic more particularly to a kind of integrated electro physiology and blood
Mechanical simulation device.
Background technique
Hemodynamics is a branch of biomethanics, and main task is that the theory and method of applied fluid mechanics is ground
The reason of blood is along vascular circulation flowing, condition, state and various influence factors are studied carefully, to illustrate rule, the life of blood flow
Manage meaning and the relationship with disease.Blood circulation system is made of heart, blood and blood vessel.With general fluid power system phase
Than blood circulation system has the characteristics that many.Firstly, blood vessel is the elastic tube for having countless branches, blood vessel is maintaining globality same
When blood is delivered to each organ of whole body.Secondly, blood is a kind of suspension for containing a large amount of solid components (haemocyte), blood
Liquid contains cell, protein, ion needed for low-density lipid and conveying nutrient and discharge waste.Red blood cell accounts for entire blood
About 40% or so of liquid product.In most of arteries, blood shows as Newtonian fluid feature, normocyte hematocrit state
Under, blood viscosity is 4 centipoises (cP).The incompressible non-newtonian viscous fluid feature of blood is then the research category of Biorheology, is had
Numerous studies.And heart is a pump extremely complex by nerve-body fluid factor controlling, structure, the periodic motion of heart pump exists
Intra-arterial produces pulsating condition.
It is most of at present to study that hemodynamic device is all simpler to be answered, and it is not accurate enough to simulate human body environment, nothing
Method accurately realizes the simulated experiment and the experiment of extension clinical medicine of blood of human body operation.
Utility model content
The purpose of this utility model is that solve the above-mentioned problems and provides a kind of integrated electro physiology and blood is dynamic
Mechanical simulation device.
The utility model achieves the above object through the following technical schemes:
A kind of integration electro physiology and Hemodynamics simulator, including shell, simulation heart, aorta, cardinal vein,
Display screen, blood pump, central processing unit, heater are provided with the simulation heart on the shell, and the simulation endocardial is set
It is equipped with the blood pump, described simulation heart one end is provided with the aorta, branch artery, the master are provided on the aorta
Artery is internally provided with arterial blood pressure sensor, and the simulation heart other end is provided with the cardinal vein, the cardinal vein
It is internally provided with venous pressure sensor, temperature sensor is provided with below the cardinal vein, branch is provided on the cardinal vein
Vein, branch vein side are provided with the display screen, are provided with function button, the function button below the display screen
Lower section is provided with switch button, and the enclosure interior is provided with the heater, is provided with the center above the heater
Processor, the shell rear are provided with rotating mechanism, and bracket is provided on the rotating mechanism, is provided with below the shell
Supporting leg is provided with universal wheel on the supporting leg.
In above structure, after device is powered, the switch button is pressed, device brings into operation, and passes through the function
Button inputs some control commands, and device brings into operation, and the blood pump can generate pump pressure, goes out blood from the simulation heart
Come, is flowed along the aorta, into the branch artery of distribution, later by returning to simulation heart in the cardinal vein
Place, the arterial blood pressure sensor and the venous pressure sensor can detect the blood pressure size in artery and vein, pass to
Signal can be passed to the display screen, allow the operator to get information about by the central processing unit, the central processing unit
Pressure value facilitates adjustment pressure, reaches most accurately simulated environment, the temperature of the temperature sensor detector,
The temperature for reaching human body is enabled devices to, by accurate numerical value, is more convenient to carry out various experiments.
In order to further increase the use function of a kind of integrated electro physiology and Hemodynamics simulator, the shell
With the display screen nested encryptions, the shell and the function button nested encryptions, the switch button and the shell are embedding
Set connection.
In order to further increase the use function of a kind of integrated electro physiology and Hemodynamics simulator, the shell
It is connected by screw to the simulation heart, the blood pump and the simulation heart nested encryptions, the blood pump and the center
Processor is connected by conducting wire.
In order to further increase the use function of a kind of integrated electro physiology and Hemodynamics simulator, the shell
It is connected by screw to the central processing unit, the heater can be connected by screw to the shell, the heater
It is connect with the central processing unit by conducting wire.
In order to further increase the use function of a kind of integrated electro physiology and Hemodynamics simulator, the temperature
Sensor is connected by screw to the shell, and the temperature sensor is connect with the central processing unit by conducting wire, described
Central processing unit is connect with the display screen by conducting wire.
In order to further increase the use function of a kind of integrated electro physiology and Hemodynamics simulator, the active
Arteries and veins is connected through a screw thread with the simulation heart, and the cardinal vein is connected through a screw thread with the simulation heart, the branch vein
It is linked together with cardinal vein perforation, the aorta is linked together with branch artery perforation, the arterial pressure sensing
Device and the aorta nested encryptions, the venous pressure sensor and the cardinal vein nested encryptions.
In order to further increase the use function of a kind of integrated electro physiology and Hemodynamics simulator, the artery
Blood pressure sensor is connect with the central processing unit by conducting wire, and the venous pressure sensor passes through with the central processing unit
Conducting wire connection, the aorta and the shell pass through clamp connection, institute by clamp connection, the cardinal vein and the shell
It states shell to be connected by screw to the rotating mechanism, the rotating mechanism is connect with the bracket by pin shaft, the support
By being welded to connect, the supporting leg and the universal wheel pass through nested encryptions for leg and the shell.
The utility model has the beneficial effects that: the utility model can simulate the principle of dynamics of blood operation, it is convenient
People get information about sanguimotor path, while display screen can show the blood pressure situation in blood vessel, and simulation human body
Temperature environment is more conducive to carrying out medicine and biological study.
Detailed description of the invention
Fig. 1 is the main view of a kind of integrated electro physiology and Hemodynamics simulator described in the utility model;
Fig. 2 is the internal structure chart of a kind of integrated electro physiology and Hemodynamics simulator described in the utility model;
Fig. 3 is the left view of a kind of integrated electro physiology and Hemodynamics simulator described in the utility model.
The reference numerals are as follows:
1, shell;2, heart is simulated;3, aorta;4, branch artery;5, arterial blood pressure sensor;6, temperature sensor;7,
Venous pressure sensor;8, cardinal vein;9, branch vein;10, display screen;12, function button;12, switch button;13, bracket;
14, supporting leg;15, universal wheel;16, blood pump;17, central processing unit;18, heater;19, rotating mechanism.
Specific embodiment
The utility model is described in further detail with reference to the accompanying drawing:
As shown in Figure 1-Figure 3, a kind of integrated electro physiology and Hemodynamics simulator, including shell 1, simulation heart
2, aorta 3, cardinal vein 8, display screen 10, blood pump 16, central processing unit 17, heater 18 are provided with simulation heart on shell 1
2, for shell 1 for protection and installing component, simulation heart 2 is used to simulate the function of heart, and simulation heart 2 is internally provided with
Blood pump 16, blood pump 16 make blood flow for generating pump pressure, and simulation 2 one end of heart is provided with aorta 3, and aorta 3 is for defeated
Blood is sent, branch artery 4 is provided on aorta 3, for branch artery 4 for conveying blood, aorta 3 is internally provided with arterial pressure
Sensor 5, arterial blood pressure sensor 5 are used to monitor the blood pressure size in artery, and simulation 2 other end of heart is provided with cardinal vein
8, cardinal vein 8 is internally provided with venous pressure sensor 7 for conveying blood, cardinal vein 8, and venous pressure sensor 7 is for supervising
Venous pressure is surveyed, is provided with temperature sensor 6 below cardinal vein 8, temperature sensor 6 is used for monitoring device temperature, on cardinal vein 8
It is provided with branch vein 9, branch vein 9 is provided with display screen 10 for conveying blood, 9 side of branch vein, and display screen 10 is for showing
Device operation data, while blood flow Dynamic Graph is simulated, function button 12 is provided with below display screen 10, function button 12 is used
It is provided with switch button 12 below input function, function button 12, switch button 12 is for controlling on/off, in shell 1
Having heaters 18 is arranged in portion, and heater 18 manufactures human body temperature for heating device, is provided with central processing above heater 18
Device 17, central processing unit 17 are provided with rotating mechanism 19 for handling various signals, 1 rear of shell, and rotating mechanism 19 is for branch
Frame 13 rotates, and is provided with bracket 13 on rotating mechanism 19, bracket 13 is used to support apparatus for placing, support is provided with below shell 1
Leg 14, supporting leg 14 are used to support device, and 15 universal wheel 15 of universal wheel is provided on supporting leg 14 for mobile device.
In above structure, after device is powered, switch button 12 is pressed, device brings into operation, and passes through function button 12
Some control commands are inputted, device brings into operation, and blood pump 16 can generate pump pressure, comes out blood from simulation heart 2, along master
Artery 3 flows, into the branch artery 4 of distribution, later by returning to simulation heart 2, arterial blood pressure sensor 5 in cardinal vein 8
The blood pressure size in artery and vein can be detected with venous pressure sensor 7, passes to central processing unit 17, central processing unit 17
Signal can be passed to display screen 10, allow the operator to get information about pressure value, facilitate adjustment pressure, reach most
Accurately simulated environment, the temperature of 6 detection device of temperature sensor, enables devices to the temperature for reaching human body, by accurate
Numerical value is more convenient to carry out various experiments.
In order to further increase use the function of a kind of integrated electro physiology and Hemodynamics simulator, shell 1 and
10 nested encryptions of display screen, shell 1 and 12 nested encryptions of function button, switch button 12 and 1 nested encryptions of shell, shell 1 with
Simulation heart 2 is connected by screw to, and blood pump 16 and simulation 2 nested encryptions of heart, blood pump 16 and central processing unit 17 pass through conducting wire
Connection, shell 1 are connected by screw to central processing unit 17, and heater 18 can be connected by screw to shell 1, heater 18
It is connect with central processing unit 17 by conducting wire, temperature sensor 6 is connected by screw to shell 1, temperature sensor 6 and centre
It manages device 17 to connect by conducting wire, central processing unit 17 is connect with display screen 10 by conducting wire, and aorta 3 passes through with simulation heart 2
It is threadedly coupled, cardinal vein 8 is connected through a screw thread with simulation heart 2, and branch vein 9 is linked together with the perforation of cardinal vein 8, aorta 3
It is linked together with the perforation of branch artery 4, arterial blood pressure sensor 5 and 3 nested encryptions of aorta, venous pressure sensor 7 and master are quiet
8 nested encryptions of arteries and veins, arterial blood pressure sensor 5 are connect with central processing unit 17 by conducting wire, venous pressure sensor 7 and centre
It manages device 17 to connect by conducting wire, by clamp connection, cardinal vein 8 passes through clamp connection, shell with shell 1 for aorta 3 and shell 1
1 is connected by screw to rotating mechanism 19, and rotating mechanism 19 is connect with bracket 13 by pin shaft, and supporting leg 14 passes through with shell 1
It is welded to connect, supporting leg 14 and universal wheel 15 pass through nested encryptions.
The basic principles and main features and advantage of the utility model have been shown and described above.The technical staff of the industry
It should be appreciated that the present utility model is not limited to the above embodiments, the above embodiments and description only describe this
The principle of utility model, on the premise of not departing from the spirit and scope of the utility model, the utility model also has various change
And improvement, these various changes and improvements fall within the scope of the claimed invention.The utility model requires protection scope
It is defined by appending claims and equivalents.
Claims (7)
1. a kind of integration electro physiology and Hemodynamics simulator, it is characterised in that: including shell, simulation heart, active
Arteries and veins, cardinal vein, display screen, blood pump, central processing unit, heater are provided with the simulation heart, the simulation on the shell
Endocardial is provided with the blood pump, and described simulation heart one end is provided with the aorta, branch is provided on the aorta
Artery, the aorta are internally provided with arterial blood pressure sensor, and the simulation heart other end is provided with the cardinal vein,
The cardinal vein is internally provided with venous pressure sensor, is provided with temperature sensor, the cardinal vein below the cardinal vein
On be provided with branch vein, branch vein side is provided with the display screen, is provided with function button below the display screen, institute
It states and is provided with switch button below function button, the enclosure interior is provided with the heater, setting above the heater
There is the central processing unit, the shell rear is provided with rotating mechanism, and bracket, the shell are provided on the rotating mechanism
Lower section is provided with supporting leg, is provided with universal wheel on the supporting leg.
2. a kind of integrated electro physiology according to claim 1 and Hemodynamics simulator, it is characterised in that: described
Shell and the display screen nested encryptions, the shell and the function button nested encryptions, the switch button and the shell
Body nested encryptions.
3. a kind of integrated electro physiology according to claim 1 and Hemodynamics simulator, it is characterised in that: described
Shell is connected by screw to the simulation heart, the blood pump and the simulation heart nested encryptions, the blood pump with it is described
Central processing unit is connected by conducting wire.
4. a kind of integrated electro physiology according to claim 1 and Hemodynamics simulator, it is characterised in that: described
Shell is connected by screw to the central processing unit, and the heater can be connected by screw to the shell, described to add
Hot device is connect with the central processing unit by conducting wire.
5. a kind of integrated electro physiology according to claim 1 and Hemodynamics simulator, it is characterised in that: described
Temperature sensor is connected by screw to the shell, and the temperature sensor is connect with the central processing unit by conducting wire,
The central processing unit is connect with the display screen by conducting wire.
6. a kind of integrated electro physiology according to claim 1 and Hemodynamics simulator, it is characterised in that: described
Aorta is connected through a screw thread with the simulation heart, and the cardinal vein is connected through a screw thread with the simulation heart, the branch
Vein is linked together with cardinal vein perforation, and the aorta is linked together with branch artery perforation, the arterial pressure
Sensor and the aorta nested encryptions, the venous pressure sensor and the cardinal vein nested encryptions.
7. a kind of integrated electro physiology according to claim 1 and Hemodynamics simulator, it is characterised in that: described
Arterial blood pressure sensor is connect with the central processing unit by conducting wire, the venous pressure sensor and the central processing unit
It is connected by conducting wire, the aorta and the shell are connected by clamp connection, the cardinal vein and the shell by clip
It connects, the shell is connected by screw to the rotating mechanism, and the rotating mechanism is connect with the bracket by pin shaft, described
By being welded to connect, the supporting leg and the universal wheel pass through nested encryptions for supporting leg and the shell.
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Cited By (7)
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CN112687144A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Lung supporting device for helping lung contraction and expansion |
CN112687169A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Lung fixing and supporting equipment with heating function |
CN112687143A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Lung clamping and supporting equipment with heat preservation effect |
CN112687171A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Multi-functional lung clamping and supporting equipment |
CN112687170A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Multifunctional lung supporting equipment |
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2017
- 2017-11-17 CN CN201721539457.5U patent/CN208444496U/en active Active
Cited By (10)
Publication number | Priority date | Publication date | Assignee | Title |
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CN112687144A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Lung supporting device for helping lung contraction and expansion |
CN112687169A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Lung fixing and supporting equipment with heating function |
CN112687143A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Lung clamping and supporting equipment with heat preservation effect |
CN112687171A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Multi-functional lung clamping and supporting equipment |
CN112687170A (en) * | 2020-12-17 | 2021-04-20 | 杭州堃博生物科技有限公司 | Multifunctional lung supporting equipment |
CN112687171B (en) * | 2020-12-17 | 2022-09-27 | 杭州堃博生物科技有限公司 | Multi-functional lung clamping and supporting equipment |
CN112687144B (en) * | 2020-12-17 | 2022-09-27 | 杭州堃博生物科技有限公司 | Lung supporting device for helping lung contraction and expansion |
CN112687169B (en) * | 2020-12-17 | 2022-09-27 | 杭州堃博生物科技有限公司 | Lung fixing and supporting equipment with heating function |
CN113487949A (en) * | 2021-07-02 | 2021-10-08 | 深圳大学 | In-vitro diagnosis simulation system and method |
CN113539040A (en) * | 2021-07-21 | 2021-10-22 | 深圳市千帆电子有限公司 | Cardiovascular blood flow dynamics simulation method and system |
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