CN115624409B

CN115624409B - Intelligent scald monitoring platform and use method thereof

Info

Publication number: CN115624409B
Application number: CN202211637439.6A
Authority: CN
Inventors: 朱赟; 刘浩; 刘鹏飞
Original assignee: Jiangsu Science Standard Medical Testing Co ltd
Current assignee: Jiangsu Kebiao Medical Technology Group Co.,Ltd.
Priority date: 2022-12-20
Filing date: 2022-12-20
Publication date: 2023-03-10
Anticipated expiration: 2042-12-20
Also published as: CN115624409A

Abstract

The invention belongs to the technical field of scald monitoring platforms, and particularly relates to an intelligent scald monitoring platform and a using method thereof, wherein the intelligent scald monitoring platform comprises: the scald experiment mechanism carries out scald experiments on the experiment body bearing mechanism so that the experiment body data detection mechanism detects various physical signs of the experiment body, and the experiment body data detection mechanism feeds corresponding data back to the scald experiment mechanism so that the scald experiment mechanism adjusts output power according to the data; the scald experiment mechanism and the experiment body data detection mechanism also upload corresponding data to the display mechanism for display; the scald temperature automatic control device disclosed by the invention can realize automatic regulation of the scald temperature, overcomes the problem that a traditional scald device cannot keep a constant temperature condition, further ensures an experiment effect, monitors various physical signs of an experiment body in the scald experiment process, can improve the accuracy of an experiment detection result, and performs data display by mutual interaction of data, can timely control the experiment process, is adaptive to experiment bodies of various specifications, and reduces the equipment cost.

Description

Intelligent scald monitoring platform and use method thereof

Technical Field

The invention belongs to the technical field of scald monitoring platforms, and particularly relates to an intelligent scald monitoring platform and a using method thereof.

Background

Traditional scald device is direct to place the experimental body on the semicircle barrel to bind the experimental body, need to dip the skin that the experimental body exposes in the boiling water, and need spray the liquid medicine for the experimental body on the experimental body at the experimentation, scald temperature is difficult to adjust, can not keep the constant temperature condition simultaneously, and the temperature of boiling water can change, thereby influences the experiment effect.

Traditional scald device also can't monitor the experimental body and scald each item sign in the experimentation, can cause experiment testing result accurate not enough.

And the unable adaptation of traditional scald device is the experimental body of various sizes, and the experimental body of every kind of specification need be equipped with an solitary scald device, and equipment cost is high, need spray the liquid medicine for the experiment body on the experimental body simultaneously at the experimentation, and the liquid medicine for the experiment body possesses certain corrosivity, and traditional scald device can't handle the liquid medicine for the experiment body, and the liquid medicine for the experiment body is the liquid form and adheres to the surface of scalding the device, easily causes its life to reduce.

Therefore, there is a need to develop a new intelligent scald monitoring platform and a method for using the same to solve the above problems.

Disclosure of Invention

The invention aims to provide an intelligent scald monitoring platform and a using method thereof.

In order to solve the technical problem, the invention provides an intelligent scald monitoring platform, which comprises: the scald experiment mechanism, the experiment body data detection mechanism, the experiment box, the display mechanism and the experiment body bearing mechanism; the experimental body bearing mechanism is arranged in the experimental box and used for fixing the experimental body; the scald experiment mechanism carries out scald experiments on the experiment body bearing mechanism so as to enable the experiment body data detection mechanism to detect temperature data, heart rate data and image data of the experiment body, and the experiment body data detection mechanism feeds back corresponding data to the scald experiment mechanism so as to enable the scald experiment mechanism to adjust output power according to the data; scald experiment mechanism, experiment body data detection mechanism still upload to display mechanism with corresponding data and show.

Further, scald experimental mechanism includes: the system comprises a first operating machine table, a first processor, a first human-computer interaction module, a heater, an air pump and a first communication module, wherein the first human-computer interaction module is electrically connected with the first processor; the first operating machine is positioned at the outer side of the experiment box, the first processor, the first human-computer interaction module and the first communication module are arranged on the first operating machine, and the heater and the air pump are positioned in the experiment box; the first human-computer interaction module is in data communication with the first processor, so that the first processor drives the heater and the air pump to work, and the air pump sprays hot air towards the experimental body on the experimental body bearing mechanism to perform a scald experiment; the first processor sends the heating temperature, the air speed and the air quantity to the experimental body data detection mechanism and the display mechanism through the first communication module.

Further, the test body data detection mechanism includes: the second operating machine table, the second processor, a second man-machine interaction module, an infrared temperature sensor, a heart rate sensor, a camera and a second communication module are electrically connected with the second processor; the second operating machine is positioned at the outer side of the experimental box, the second processor, the second man-machine interaction module and the second communication module are arranged on the first operating machine, and the infrared temperature sensor, the heart rate sensor and the camera are positioned in the experimental box; the second man-machine interaction module is in data communication with the second processor, so that the second processor can respectively detect temperature data, heart rate data and image data of the experimental body through the infrared temperature sensor, the heart rate sensor and the camera; the second processor sends the temperature data, the heart rate data and the image data of the experimental body to the scald experiment mechanism and the display mechanism through the second communication module.

Further, the display mechanism includes: the third processor, a third man-machine interaction module and a third communication module are electrically connected with the third processor; and the third man-machine interaction module is in data communication with the third processor, and the third processor receives corresponding data sent by the scald experiment mechanism and the experiment body data detection mechanism through the third communication module.

Further, the experimental body bearing mechanism comprises: the device comprises a semicircular cylinder, a fixing component, two bandages and four bandages; the fixed components are movably arranged on two sides of the semi-cylinder; the semi-cylinder is used for placing an experimental body, and the bottom of the semi-cylinder is provided with a scalding hole for exposing an experimental part of the experimental body; each bandage is movably buckled on the fixing component and is used for binding the abdomen or the back of the experimental body in the semi-cylinder; one end of each binding band is tied on the fixing component, and the other end of each binding band is tied on the corresponding foot of the experimental body.

Further, the fixing assembly includes: four fixing units; the outer side walls of the two sides of the semi-cylinder are respectively provided with corresponding limiting grooves, and each limiting groove is arranged along the axial direction of the semi-cylinder; two fixing units are respectively installed on each limiting groove, each fixing unit moves to a corresponding position in the limiting groove according to the size of the experiment body, one end of one bandage is buckled on one fixing unit, and the other end of the bandage crosses over the experiment body in the semicircular cylinder to be buckled on the corresponding fixing unit so as to bind the abdomen or back of the experiment body in the semicircular cylinder; each fixing unit moves to the outer side of the corresponding foot of the experimental body, one end of each binding belt is tied to the fixing unit, and the other end of each binding belt is tied to the corresponding foot of the experimental body.

Further, the fixing unit includes: the device comprises a T-shaped block, a fixed column and a plurality of limit buckles; the A block of the T-shaped block is movably and limitedly arranged in the limiting groove through each limiting buckle, the B block of the T-shaped block is exposed out of the limiting groove, and a buckling hole is formed in the B block of the T-shaped block and used for buckling the end part of the bandage; the fixing column is longitudinally arranged on the B block of the T-shaped block and used for fastening the end part of the binding band.

Furthermore, a square subslot and a trapezoid subslot are arranged in the limiting groove, the square subslot movably limits the A block of the T-shaped block, and the B block of the T-shaped block penetrates out of the trapezoid subslot; the cross section of the trapezoid sub-groove is in a right trapezoid shape, the right-angle side of the right trapezoid is positioned at the top of the trapezoid sub-groove, and the oblique side of the right trapezoid is positioned at the bottom of the trapezoid sub-groove; when the tip lock of bandage is downthehole at the lock, the bandage is the bow member on the semicircle barrel, and sprays as the liquid medicine for the laboratory body on the bandage, the liquid medicine for the laboratory body of bandage guide drips towards the B piece and the spacing groove of T-shaped piece, and then the liquid medicine for the laboratory body is followed the lock drips or flows out from the spacing groove under the trapezoidal subslot guide.

Furthermore, a plurality of liquid guide grooves are formed in the bottom of the trapezoidal sub-groove and communicated with the square sub-groove, and a plurality of air drying grooves are formed in the bottom of the liquid guide grooves; the A block of the T-shaped block is clamped into the corresponding liquid guide groove through each limiting buckle so as to limit the T-shaped block; the liquid medicine for the experiment flowing into the limiting groove flows out of the limiting groove under the guidance of the trapezoid sub-groove, the liquid guide groove and the air drying groove, and when the T-shaped block is turned over towards the bottom of the trapezoid sub-groove under the action of the gravity of the fixed column, the A block of the T-shaped block releases a gap between the liquid guide groove, the air drying groove and the square sub-groove, so that the square sub-groove, the trapezoid sub-groove, the liquid guide groove and the air drying groove are ventilated to air the liquid medicine for the experiment.

In another aspect, the present invention provides a method for using the above intelligent scald monitoring platform, comprising: the experimental body bearing mechanism is arranged in the experimental box and used for fixing the experimental body; the scald experiment mechanism carries out scald experiments on the experiment body bearing mechanism so as to enable the experiment body data detection mechanism to detect temperature data, heart rate data and image data of the experiment body, and the experiment body data detection mechanism feeds back corresponding data to the scald experiment mechanism so as to enable the scald experiment mechanism to adjust output power according to the data; the scald experiment mechanism and the experiment body data detection mechanism also upload corresponding data to the display mechanism for display.

The scald experiment device has the beneficial effects that the scald experiment mechanism and the experiment body data detection mechanism are arranged to realize automatic scald temperature adjustment, the problem that a traditional scald device cannot keep a constant temperature condition is solved, the experiment effect is further ensured, meanwhile, various physical signs of the experiment body in the scald experiment process are monitored, the accuracy of an experiment detection result can be improved, data are mutually and interactively displayed in a data manner, the experiment process can be timely controlled, the experiment body bearing mechanism is arranged to be adaptive to experiment bodies of various specifications, the equipment cost is reduced, liquid medicine for the experiment body can be drained and sprayed and quickly dried, and equipment corrosion is avoided.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a functional block diagram of an intelligent scald monitoring platform of the present invention;

fig. 2 is a block diagram of an intelligent scald monitoring platform of the present invention;

fig. 3 is a structural view of a scald experiment mechanism of the present invention;

FIG. 4 is a structural view of a specimen carrying mechanism of the present invention;

FIG. 5 is a block diagram of a bandage of the present invention;

FIG. 6 is a block diagram of a half cylinder of the present invention;

FIG. 7 is a block diagram of the securing assembly of the present invention;

FIG. 8 is a bottom block diagram of the retaining assembly of the present invention;

FIG. 9 is a block diagram of the spacing groove of the present invention;

FIG. 10 is a structural view of a liquid guide groove of the present invention;

FIG. 11 is a view of the non-inclined configuration of the T-block of the present invention;

fig. 12 is a structure view of the T-block of the present invention after it is tilted.

In the figure:

1. a scald experiment mechanism; 11. a first operating machine; 12. a first human-computer interaction module; 13. a heater; 14. an air pump;

2. a test body data detection mechanism; 21. a second operating machine; 22. a second human-computer interaction module;

3. an experimental box;

4. a display mechanism; 41. a third human-computer interaction module;

5. an experimental body bearing mechanism; 51. a semi-cylinder; 511. scalding the hole; 512. a limiting groove; 5121. a square sub-groove; 5122. a trapezoidal sub-groove; 5123. a liquid guide groove; 5124. an air drying groove; 52. a fixing assembly; 521. a fixing unit; 5211. a T-shaped block; 52111. a, block A; 52112. b, block; 521121, a fastening hole; 5212. fixing a column; 5213. a limit buckle; 53. a bandage.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

In this embodiment, as shown in fig. 1 to 12, this embodiment provides an intelligent scald monitoring platform, which includes: the scald experiment mechanism 1, the experiment body data detection mechanism 2, the experiment box 3, the display mechanism 4 and the experiment body bearing mechanism 5; wherein the experimental body bearing mechanism 5 is arranged in the experimental box 3 and used for fixing the experimental body; the scald experiment mechanism 1 carries out scald experiments on the experiment body bearing mechanism 5, so that the experiment body data detection mechanism 2 detects temperature data, heart rate data and image data of the experiment body, and the experiment body data detection mechanism 2 feeds back corresponding data to the scald experiment mechanism 1, so that the scald experiment mechanism 1 adjusts output power according to the data; scald experimental mechanism 1, experimental body data detection mechanism 2 still upload corresponding data to display mechanism 4 and show.

In this embodiment, this embodiment is through setting up scald experimental mechanism 1, the automatic temperature of scalding of regulation is realized to experimental body data detection mechanism 2, overcome the problem that traditional scald device can't keep the constant temperature condition, and then guarantee the experiment effect, implement simultaneously and monitor the experimental body and scald each item sign in the experimentation, can improve the precision of experiment testing result, and data each other carries out the data ization demonstration, can in time manage and control the experimentation, it can the various specification experimental bodies of adaptation to set up experimental body bearing mechanism 5, reduce equipment cost, can also the drainage sprays the liquid medicine for the experimental body and air-dries rapidly, avoid corrosion apparatus.

In this embodiment, the scald experiment mechanism 1 includes: the system comprises a first operating machine table 11, a first processor, a first human-computer interaction module 12, a heater 13, an air pump 14 and a first communication module, wherein the first human-computer interaction module 12 is electrically connected with the first processor; the first operating machine 11 is positioned outside the experimental box 3, the first processor, the first human-computer interaction module 12 and the first communication module are installed on the first operating machine 11, and the heater 13 and the air pump 14 are positioned in the experimental box 3; the first human-computer interaction module 12 is in data communication with the first processor, so that the first processor drives the heater 13 and the air pump 14 to work, and the air pump 14 sprays hot air towards the experimental body on the experimental body bearing mechanism 5 to perform a scald experiment; the first processor sends the heating temperature, the wind speed and the wind volume to the experimental body data detection mechanism 2 and the display mechanism 4 through the first communication module.

In this embodiment, signal input and output can be realized to first human-computer interaction module 12 to can show picture image in real time, heater 13 itself has intelligent temperature control mode, can accurate control heating problem, and keep the constant temperature condition, and then improve the experiment effect, and air pump 14 itself possesses wind speed, amount of wind monitor function, and consequently this intelligence scald monitoring platform can intelligent control experiment condition, guarantees the experiment effect, and improves the precision of experiment testing result.

In the present embodiment, the test-volume data detecting means 2 includes: the second operating machine table 21, the second processor, a second man-machine interaction module 22 electrically connected with the second processor, an infrared temperature sensor, a heart rate sensor, a camera and a second communication module; the second operating machine 21 is positioned outside the experiment box 3, the second processor, the second human-computer interaction module 22 and the second communication module are arranged on the first operating machine 11, and the infrared temperature sensor, the heart rate sensor and the camera are positioned in the experiment box 3; the second human-computer interaction module 22 is in data communication with a second processor, so that the second processor respectively detects temperature data, heart rate data and image data of the experimental body through an infrared temperature sensor, a heart rate sensor and a camera; the second processor sends the temperature data, the heart rate data and the image data of the experimental body to the scald experiment mechanism 1 and the display mechanism 4 through the second communication module.

In this embodiment, the second human-computer interaction module 22 can realize signal input and output to can show picture image in real time, infrared temperature sensor, heart rate sensor, camera can realize that the control experimental body is scalding each item sign in the experimentation, can improve the precision of experiment testing result.

Heater 13 itself has intelligent control by temperature change mode, can accurate control heating problem to keep the constant temperature condition, and then improve the experiment effect, air pump 14 itself possesses wind speed, amount of wind monitor function, and consequently this intelligence scald monitoring platform can intelligent control experiment condition, guarantees the experiment effect, and improves the precision of experiment testing result.

In the present embodiment, the display mechanism 4 includes: the third processor, a third man-machine interaction module 41 and a third communication module which are electrically connected with the third processor; the third human-computer interaction module 41 is in data communication with the third processor, and the third processor receives corresponding data sent by the scald experiment mechanism 1 and the experiment body data detection mechanism 2 through the third communication module.

In this embodiment, the third human-computer interaction module 41 can realize signal input and output, and can display a picture image in real time, display various data in a datamation manner, and facilitate real-time monitoring in an experimental process.

In this embodiment, the specimen carrying mechanism 5 includes: a half cylinder 51, a fixing component 52, two bandages 53 and four bandages; the fixed components 52 are movably arranged on two sides of the semi-cylinder 51; the semi-cylinder 51 is used for placing an experimental body, and the bottom of the semi-cylinder 51 is provided with a scalding hole 511 for exposing an experimental part of the experimental body; each bandage 53 is movably buckled on the fixing component 52 and is used for binding the abdomen or the back of the experimental body in the semi-cylinder 51; one end of each binding band is tied on the fixing component 52, and the other end of each binding band is tied on the corresponding foot of the experimental body.

In this embodiment, two bandages 53 and four bandages can fix the experimental body on the semi-cylinder 51 to facilitate the experiment.

In this embodiment, the fixing assembly 52 includes: four fixing units 521; the outer side walls of the two sides of the semi-cylinder 51 are respectively provided with corresponding limiting grooves 512, and each limiting groove 512 is arranged along the axial direction of the semi-cylinder 51; two fixing units 521 are respectively installed on each limiting groove 512, each fixing unit 521 moves to a corresponding position in the limiting groove 512 according to the size of the experimental body, one end of one bandage 53 is buckled on one fixing unit 521, and the other end of the bandage 53 passes over the experimental body in the semi-cylinder 51 to be buckled on the corresponding fixing unit 521 so as to bind the abdomen or back of the experimental body in the semi-cylinder 51; each fixing unit 521 moves to the outside of the corresponding foot of the experimental body, one end of each binding band is tied on the fixing unit 521, and the other end of each binding band is tied on the corresponding foot of the experimental body.

In this embodiment, four fixed units 521 can slide on semi-cylindrical 51, after adjusting to the adaptation experimental body size, spacing fixing on semi-cylindrical 51, the experimental body of various specifications of adaptation need not all be equipped with an individual scald device to the experimental body of every specification, saves equipment cost.

In this embodiment, the fixing unit 521 includes: a T-shaped block 5211, a fixing column 5212 and a plurality of limit buttons 5213; the block A52111 of the T-shaped block 5211 is movably limited and mounted in the limiting groove 512 through the limiting buckles 5213, the block B52112 of the T-shaped block 5211 is exposed out of the limiting groove 512, and the block B52112 of the T-shaped block 5211 is provided with buckling holes 521121 for buckling the end parts of the bandages 53; the fixing post 5212 is longitudinally disposed on the B block 52112 of the T-block 5211 for fastening the end of the strap.

In this embodiment, the T-shaped block 5211 mainly plays a role in fixing the bandage 53 and the bandage, the T-shaped block 5211 can slide in the limiting groove 512 and can be limited and clamped in the limiting groove 512, and the bandage 53 and the bandage can bind the experimental body at different positions, so that the experimental body can be adapted to various specifications of experimental bodies.

In this embodiment, a square sub-groove 5121 and a trapezoidal sub-groove 5122 are disposed in the limiting groove 512, the square sub-groove 5121 movably limits the a block 52111 of the T-shaped block 5211, and the B block 52112 of the T-shaped block 5211 passes through the trapezoidal sub-groove 5122; the cross section of the trapezoid sub-groove 5122 is in a right trapezoid shape, the right-angle side of the right trapezoid is positioned at the top of the trapezoid sub-groove 5122, and the oblique side of the right trapezoid is positioned at the bottom of the trapezoid sub-groove 5122; when the end of the bandage 53 is fastened in the fastening hole 521121, the bandage 53 is arched on the semi-cylinder 51, and when the liquid medicine for the experiment is sprayed on the bandage 53, the bandage 53 guides the liquid medicine for the experiment to drip toward the B block 52112 and the limiting groove 512 of the T-shaped block 5211, and further the liquid medicine for the experiment drips from the fastening hole 521121 or flows out from the limiting groove 512 under the guidance of the trapezoidal sub-groove 5122.

In this embodiment, the stopper groove 512 is formed by the square sub groove 5121 and the trapezoidal sub groove 5122, so that the a block 52111 of the T block 5211 is stopped, the B block 52112 can be exposed from the trapezoidal sub groove 5122, and the B block 52112 is provided with the fastening hole 521121 to attach the bandage 53.

In this embodiment, the bandage 53 is made of leather, since the bandage 53 is to bind the experimental body, the bandage 53 is arched on the semi-cylinder 51, and the bandage 53 has a certain waterproof property, when the liquid medicine for the experimental body is sprayed on the experimental body, the liquid medicine for the experimental body is inevitably sprayed on the bandage 53, because the bandage 53 is bent, the liquid medicine for the experimental body is dripped towards the B block 52112 and the limiting groove 512 of the T-shaped block 5211 under the guidance of the bandage 53, and the liquid medicine for the experimental body has a certain corrosivity and cannot be adhered to the semi-cylinder 51 and the fixing component 52 in a liquid state, while the traditional scalding device directly adopts the semi-cylinder 51, the bandage 53 and the bandage, the liquid medicine for the experimental body is directly adhered to the semi-cylinder 51 to erode the semi-cylinder 51, the T-shaped block 5211 is provided, and the T-shaped block 5211 is provided with a fastening hole 521121, the liquid medicine for the experimental body is directly dripped from the fastening hole 521121 on the B block 52112, and the trapezoidal sub-groove 22 is an inclined surface, and can directly guide the liquid medicine for the experimental body to flow out from the limiting groove 51512.

In this embodiment, the bottom of the trapezoidal sub-groove 5122 is provided with a plurality of liquid guiding grooves 5123, the liquid guiding grooves 5123 are communicated with the square sub-groove 5121, and the bottom of the liquid guiding groove 5123 is provided with a plurality of air drying grooves 5124; the a block 52111 of the T-shaped block 5211 is clamped into the corresponding liquid guide groove 5123 through each limit buckle 5213 so as to limit the T-shaped block 5211; the chemical liquid for the experimental body flowing into the limiting groove 512 flows out of the limiting groove 512 under the guidance of the trapezoidal sub-groove 5122, the liquid guide groove 5123 and the air drying groove 5124, and when the T-shaped block 5211 is folded toward the bottom of the trapezoidal sub-groove 5122 under the action of the gravity of the fixed column 5212, the a block 52111 of the T-shaped block 5211 releases the gap between the liquid guide groove 5123, the air drying groove 5124 and the square sub-groove 5121, so that the square sub-groove 5121, the trapezoidal sub-groove 5122, the liquid guide groove 5123 and the air drying groove 5124 are ventilated to air-dry the chemical liquid for the experimental body.

In this embodiment, the air drying groove 5124 is trapezoidal, and the retaining buckle 5213 is just clipped into the opening of the air drying groove 5124 to prevent the T-shaped block 5211 from sliding in the retaining groove 512.

In this embodiment, the size of the square sub-groove 5121 is larger than the size of the a block 52111 of the T-shaped block 5211, so the a block 52111 can be folded in the square sub-groove 5121, the a block 52111 does not block the liquid guide groove 5123, the square sub-groove 5121, the trapezoidal sub-groove 5122, the liquid guide groove 5123 and the air drying groove 5124 can ventilate, the dripping and air drying of the liquid medicine for the experiment from the trapezoidal sub-groove 5122, the liquid guide groove 5123 and the air drying groove 5124 are accelerated, and the liquid medicine for the experiment is prevented from corroding the intelligent scald monitoring platform.

In this embodiment, the fixing post 5212 is disposed on the T-block 5211, and the top of the fixing post 5212 is further equipped with a weight to push the B-block 52112 to turn downward.

Example 2

On the basis of embodiment 1, this embodiment provides a method for using the intelligent scald monitoring platform provided in embodiment 1, which includes: the experimental body bearing mechanism 5 is arranged in the experimental box 3 and used for fixing the experimental body; the scald experiment mechanism 1 carries out scald experiments on the experiment body bearing mechanism 5, so that the experiment body data detection mechanism 2 detects temperature data, heart rate data and image data of the experiment body, and the experiment body data detection mechanism 2 feeds back corresponding data to the scald experiment mechanism 1, so that the scald experiment mechanism 1 adjusts output power according to the data; the scald experiment mechanism 1 and the experiment body data detection mechanism 2 also upload corresponding data to the display mechanism 4 for display.

In conclusion, the scald experiment device has the advantages that the scald experiment mechanism and the experiment body data detection mechanism are arranged to realize automatic scald temperature adjustment, the problem that a traditional scald device cannot keep a constant temperature condition is solved, the experiment effect is further ensured, meanwhile, various physical signs of the experiment body in the scald experiment process are monitored, the accuracy of an experiment detection result can be improved, data are mutually and interactively displayed in a data mode, the experiment process can be timely controlled, the experiment body bearing mechanism is arranged to be capable of being matched with experiment bodies of various specifications, the equipment cost is reduced, liquid medicine for spraying the experiment bodies can be drained and is rapidly dried, and equipment corrosion is avoided.

The components selected for use in the present application (components not illustrated for specific structures) are all common standard components or components known to those skilled in the art, and the structure and principle thereof can be known to those skilled in the art through technical manuals or through routine experimentation.

In the description of the embodiments of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the several embodiments provided in the present application, it should be understood that the disclosed system, apparatus and method may be implemented in other ways. The above-described embodiments of the apparatus are merely illustrative, and for example, the division of the units is only one logical division, and there may be other divisions when actually implemented, and for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection of devices or units through some communication interfaces, and may be in an electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. The utility model provides an intelligence scald monitoring platform which characterized in that includes:

the scald experiment mechanism, the experiment body data detection mechanism, the experiment box, the display mechanism and the experiment body bearing mechanism; wherein

The experimental body bearing mechanism is arranged in the experimental box and used for fixing the experimental body;

the scald experiment mechanism carries out scald experiments on the experiment body bearing mechanism so as to enable the experiment body data detection mechanism to detect temperature data, heart rate data and image data of the experiment body, and the experiment body data detection mechanism feeds back corresponding data to the scald experiment mechanism so as to enable the scald experiment mechanism to adjust output power according to the data;

scald experiment mechanism, experiment body data detection mechanism still upload to display mechanism with corresponding data and show.

2. The intelligent scald monitoring platform of claim 1,

scald experiment mechanism includes: the system comprises a first operating machine table, a first processor, a first human-computer interaction module, a heater, an air pump and a first communication module, wherein the first human-computer interaction module is electrically connected with the first processor;

the first operating machine is positioned at the outer side of the experimental box, the first processor, the first human-computer interaction module and the first communication module are arranged on the first operating machine, and the heater and the air pump are positioned in the experimental box;

the first human-computer interaction module is in data communication with the first processor, so that the first processor drives the heater and the air pump to work, and the air pump sprays hot air towards the experimental body on the experimental body bearing mechanism to perform a scald experiment;

the first processor sends the heating temperature, the wind speed and the wind volume to the experimental body data detection mechanism and the display mechanism through the first communication module.

3. The intelligent scald monitoring platform of claim 1,

the experimental body data detection mechanism comprises: the second operating machine table, the second processor, a second man-machine interaction module, an infrared temperature sensor, a heart rate sensor, a camera and a second communication module are electrically connected with the second processor;

the second operating machine is positioned outside the experiment box, the second processor, the second man-machine interaction module and the second communication module are arranged on the first operating machine, and the infrared temperature sensor, the heart rate sensor and the camera are positioned in the experiment box;

the second man-machine interaction module is in data communication with the second processor, so that the second processor can respectively detect temperature data, heart rate data and image data of the experimental body through the infrared temperature sensor, the heart rate sensor and the camera;

the second processor sends the temperature data, the heart rate data and the image data of the experimental body to the scald experiment mechanism and the display mechanism through the second communication module.

4. The intelligent scald monitoring platform of claim 1,

the display mechanism includes: the third processor, a third man-machine interaction module and a third communication module are electrically connected with the third processor;

and the third man-machine interaction module is in data communication with the third processor, and the third processor receives corresponding data sent by the scald experiment mechanism and the experiment body data detection mechanism through the third communication module.

5. The intelligent scald monitoring platform of claim 1,

the experimental body bearing mechanism comprises: the device comprises a semicircular cylinder, a fixing component, two bandages and four bandages;

the fixed components are movably arranged on two sides of the semi-cylinder;

the semi-cylinder is used for placing an experimental body, and the bottom of the semi-cylinder is provided with a scalding hole for exposing an experimental part of the experimental body;

each bandage is movably buckled on the fixing component and is used for binding the abdomen or the back of the experimental body in the semi-cylinder;

one end of each binding band is tied on the fixing component, and the other end of each binding band is tied on the corresponding foot of the experimental body.

6. The intelligent scald monitoring platform of claim 5,

the fixing assembly includes: four fixing units;

the outer side walls of two sides of the semi-cylinder are respectively provided with corresponding limiting grooves, and each limiting groove is arranged along the axial direction of the semi-cylinder;

two fixing units are respectively installed on each limiting groove, each fixing unit moves to a corresponding position in the limiting groove according to the size of the experimental body, one end of one bandage is buckled on one fixing unit, and the other end of the bandage crosses the experimental body in the semi-cylinder to be buckled on the corresponding fixing unit so as to bind the abdomen or back of the experimental body in the semi-cylinder;

each fixing unit moves to the outer side of the corresponding foot of the experimental body, one end of each binding belt is tied to the fixing unit, and the other end of each binding belt is tied to the corresponding foot of the experimental body.

7. The intelligent scald monitoring platform of claim 6,

the fixing unit includes: the device comprises a T-shaped block, a fixed column and a plurality of limit buckles;

the A block of the T-shaped block is movably and limitedly arranged in the limiting groove through each limiting buckle, the B block of the T-shaped block is exposed out of the limiting groove, and a buckling hole is formed in the B block of the T-shaped block and used for buckling the end part of the bandage;

the fixing column is longitudinally arranged on the B block of the T-shaped block and used for fastening the end part of the binding band.

8. The intelligent scald monitoring platform of claim 7,

a square subslot and a trapezoid subslot are arranged in the limiting groove, the square subslot movably limits the A block of the T-shaped block, and the B block of the T-shaped block penetrates out of the trapezoid subslot;

the cross section of the trapezoid sub-groove is in a right trapezoid shape, the right-angle side of the right trapezoid is positioned at the top of the trapezoid sub-groove, and the oblique side of the right trapezoid is positioned at the bottom of the trapezoid sub-groove;

when the tip lock of bandage is downthehole at the lock, the bandage is the bow member on the semicircle barrel, and sprays as the liquid medicine for the laboratory body on the bandage, the liquid medicine for the laboratory body of bandage guide drips towards the B piece and the spacing groove of T-shaped piece, and then the liquid medicine for the laboratory body is followed the lock drips or flows out from the spacing groove under the trapezoidal subslot guide.

9. The intelligent scald monitoring platform of claim 8,

the bottom of the trapezoid sub-groove is provided with a plurality of liquid guide grooves which are communicated with the square sub-groove, and the bottom of the liquid guide grooves is provided with a plurality of air drying grooves;

the A block of the T-shaped block is clamped into the corresponding liquid guide groove through each limiting buckle so as to limit the T-shaped block;

the liquid medicine for the experiment flowing into the limiting groove flows out of the limiting groove under the guidance of the trapezoid sub-groove, the liquid guide groove and the air drying groove, and when the T-shaped block is turned over towards the bottom of the trapezoid sub-groove under the action of the gravity of the fixed column, the A block of the T-shaped block releases a gap between the liquid guide groove, the air drying groove and the square sub-groove, so that the square sub-groove, the trapezoid sub-groove, the liquid guide groove and the air drying groove are ventilated to air the liquid medicine for the experiment.