阅读说明：本技术 动态心电分析的全信息展示及分析方法 (Full information display and analysis method for dynamic electrocardiogram analysis ) 是由 陈洪 方健 李洁 王胜 于 2021-01-07 设计创作，主要内容包括：本发明公开了动态心电分析的全信息展示及分析方法,属于医疗设备技术领域,动态心电分析的全信息展示及分析方法,本方案通过数据传输线将心电联贴片中的原始数据传输至用户手持端中,从而促使心电联贴片外端的电气接头热量增加,从而促使橡胶球囊受热膨胀,以此解除对内置磁铁块的磁屏蔽,并借助内置磁铁块对环形存储箱内的磁流体的吸引作用,可以促使磁流体顶开橡胶封片后从释放通孔中流出,并沿着侧传输导管流动,一方面可以借助磁流体的流动,可以吸收数据传输线在数据传输过程中产生的热量,另一方面借助磁流体的流动,可以促使外界空气进入只环形存储箱内,从而增加侧传输导管外侧的空气流动,以此提高数据传输线的散热效果。(The invention discloses a full information display and analysis method of dynamic electrocardiogram analysis, belonging to the technical field of medical equipment, the full information display and analysis method of dynamic electrocardiogram analysis is characterized in that original data in an electrocardiogram coupling patch is transmitted to a handheld end of a user through a data transmission line, so that the heat of an electric connector at the outer end of the electrocardiogram coupling patch is increased, a rubber balloon is promoted to be thermally expanded, the magnetic shielding of a built-in magnet block is relieved, the magnetic fluid in an annular storage box is attracted by the built-in magnet block, the magnetic fluid can be promoted to prop open a rubber sealing sheet and flow out from a release through hole and flow along a side transmission catheter, on one hand, the heat generated by the data transmission line in the data transmission process can be absorbed by the aid of the flow of the magnetic fluid, on the other hand, outside air can be promoted to enter the annular storage box only by the aid of the flow of, thereby increasing the air flow outside the side transmission conduit and improving the heat dissipation effect of the data transmission line.)

1. The full information display and analysis method of dynamic electrocardiogram analysis is characterized in that: the method comprises the following steps:

s1, placing the electrocardio-connection patch (1) in front of the chest of a human body, and transmitting the collected electrocardio data to a storage cloud (2) through an electric connector outside the electrocardio-connection patch (1);

s2, uploading data stored in the cloud (2) to a PC (3), synchronously presenting information classification modules containing heart beat waveform characteristics and heart beat rhythm characteristics of the electrocardio data on the same interface by adopting a full information display and analysis method of a one-station editing interface, and realizing interaction among the modules to the maximum extent;

and S3, finally, transmitting the obtained image-text information to the user handheld terminal (4), and inputting the original data into the user handheld terminal (4) through the data transmission line (5), so that the user can conveniently check the image-text information and the original data in a contrasting manner.

2. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 1, wherein: data transmission line (5) outer end in S3 is connected with annular storage box (6), data transmission line (5) outer end is connected with two mutual symmetrical side transmission pipe (7), annular storage box (6) outer end inlays establishes installs a plurality of evenly distributed' S waterproof ventilated membrane (8), annular storage box (6) inner wall is excavated release through-hole (9) that have two mutual symmetries and communicate each other with side transmission pipe (7), release through-hole (9) inner wall is connected with two rubber seals (10) that support each other tightly, data transmission line (5) outer end is connected with rubber sacculus (11), rubber sacculus (11) are located side transmission pipe (7) right side and are connected with side transmission pipe (7), rubber sacculus (11) in-connection has two mutual symmetrical built-in magnet piece (12).

3. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 2, wherein: the lateral transmission guide pipe (7) outer end is connected with a plurality of evenly distributed lateral bending short fibers (13), the bottom end of the lateral bending short fiber (13) is connected with a contact marble (14), a traction ball (15) is connected in the contact marble (14), and an air flow exchange hole (16) is dug at the outer end of the contact marble (14).

4. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 1, wherein: an electrical connector is installed at the outer end of the electrocardio-connecting patch (1), a sensor is installed in the electrical connector, and a USB interface is arranged at the upper end of the electrical connector.

5. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 2, wherein: the annular storage box (6) is filled with magnetic fluid (601), and the density of the magnetic fluid (601) is 1.2 g/ml.

6. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 2, wherein: the inner surface of the rubber saccule (11) is embedded with a plurality of uniformly distributed magnetism-insulating particles, and the magnetism-insulating particles are made of iron-nickel alloy material with the nickel content of 80%.

7. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 2, wherein: the built-in magnet block (12) is made of a single-sided magnet material.

8. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 2, wherein: the outer end of the rubber balloon (11) is connected with two mutually symmetrical (1101), and anti-skid lines are carved on the inner wall of the (1101).

9. The method for displaying and analyzing full information of dynamic electrocardiographic analysis according to claim 3, wherein: the traction ball (15) is made of 400-stainless steel materials, and an anti-rust paint layer is coated on the surface of the traction ball (15).

Technical Field

The invention relates to the technical field of medical equipment, in particular to a full-information display and analysis method for dynamic electrocardiogram analysis.

Background

Dynamic electrocardiography has been widely used in hospitals and examination centers all over the world as a simple and effective means for examining cardiac function. The doctor wears the dynamic electrocardiogram recorder from 1 day to a plurality of days for the patient according to the illness state of the patient. The obtained long-range dynamic electrocardiogram data are analyzed on a playback analysis system, the occurrence frequency of abnormal heart beats and fragments of the heart rate is counted, and finally an electrocardiogram analysis report is formed for a doctor to make a diagnosis reference.

Because the long-range electrocardiogram data has 10 to millions of heartbeats, the existing dynamic electrocardiogram playback analysis system can be classified according to the waveform characteristics of heartbeats and the rhythm characteristics of heartbeats, thereby simplifying the analysis process and improving the analysis efficiency. However, the current ecg replay analysis system usually only includes independent cardiac waveform template classification, independent scatter diagram classification, independent overlay diagram classification, or a combination of the three, and independent histogram classification. Because various classification information is on different pages, doctors are required to frequently switch back and forth between the pages when analyzing the electrocardiogram data, the analysis efficiency of the doctors is greatly reduced, meanwhile, the doctor can select a proper classification method to perform the electrocardiogram analysis, and the real functions of each classification module can not be exerted.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide a full information display and analysis method for dynamic electrocardio analysis, the scheme transmits original data in an electrocardio-patch to a handheld end of a user through a data transmission line, thereby promoting the heat of an electric joint at the outer end of the electrocardio-patch to be increased, promoting a rubber balloon to be thermally expanded so as to relieve the magnetic shielding of an internal magnet block, promoting a magnetic fluid to flow out of a release through hole after pushing open a rubber sealing sheet by virtue of the attraction of the internal magnet block to the magnetic fluid in an annular storage box and flow along a side transmission conduit, on one hand, the heat generated in the data transmission process of the data transmission line can be absorbed by virtue of the flow of the magnetic fluid, on the other hand, external air can be promoted to enter the annular storage box only by virtue of the flow of the magnetic fluid so as to increase the air flow outside the side transmission conduit, thereby improving the heat dissipation effect of the data transmission line.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

The full information display and analysis method of dynamic electrocardiogram analysis comprises the following steps:

s1, placing the electrocardio-connection patch in front of the chest of a human body, and transmitting the collected electrocardio data to a storage cloud end through an electric connector outside the electrocardio-connection patch;

s2, uploading the data stored in the cloud to a PC, synchronously presenting information classification modules containing heart beat waveform characteristics and heart beat rhythm characteristics of the electrocardio data on the same interface by adopting a full information display and analysis method of a 'one-station editing' interface, and realizing interaction among the modules to the greatest extent;

and S3, finally, transmitting the obtained image-text information to a handheld end of the user, and inputting the original data into the handheld end of the user through a data transmission line, so that the user can conveniently check the image-text information and the original data in a contrasting manner.

Furthermore, the outer end of the data transmission line in the S3 is connected with an annular storage box, the outer end of the data transmission line is connected with two mutually symmetrical side transmission catheters, the outer end of the annular storage box is embedded with a plurality of uniformly distributed waterproof breathable films, the inner wall of the annular storage box is provided with two mutually symmetrical release through holes communicated with the side transmission catheters, the inner wall of each release through hole is connected with two mutually abutted rubber sealing sheets, the outer end of the data transmission line is connected with a rubber balloon, the rubber balloon is positioned at the right side of the side transmission catheter and connected with the side transmission catheter, two mutually symmetrical built-in magnet blocks are connected in the rubber balloon, original data in the electrocardio coupling patch is transmitted to a user handheld end through the data transmission line, so that the heat of an electrical connector at the outer end of the electrocardio coupling patch is increased, and the rubber balloon is heated, the magnetic shielding of the built-in magnet block is removed, the magnetic fluid can be made to flow out of the release through hole after the magnetic fluid pushes the rubber sealing piece open by virtue of the attraction effect of the built-in magnet block on the magnetic fluid in the annular storage box and flow along the side transmission conduit, on one hand, the heat generated by the data transmission line in the data transmission process can be absorbed by virtue of the flow of the magnetic fluid, on the other hand, the external air can be made to enter the annular storage box only by virtue of the flow of the magnetic fluid, so that the air flow outside the side transmission conduit is increased, and the heat dissipation effect of the data transmission line is improved.

Furthermore, the outer end of the side transmission conduit is connected with a plurality of side bent short fibers which are uniformly distributed, the bottom ends of the side bent short fibers are connected with contact marbles, the contact marbles are connected with traction balls, the outer ends of the contact marbles are provided with air exchange holes, and the magnetic fluid can attract the traction balls by virtue of the flow of the magnetic fluid, so that the traction balls are promoted to drive the contact marbles to move, and when the contact marbles are contacted with the joints of the side bent short fibers and the side transmission conduit, the contact marbles are promoted to be extruded, so that the air flow around the data transmission line is further improved, and the heat dissipation efficiency of the data transmission line is improved.

Further, an electrical connector is installed at the outer end of the electrocardio connection patch, a sensor is installed in the electrical connector, a USB interface is arranged at the upper end of the electrical connector, data collected by the electrocardio connection patch can be conveniently uploaded to a storage cloud end through the sensor, and original data in the electrocardio connection patch can be conveniently transmitted to a user handheld end through the USB interface.

Furthermore, the annular storage box is filled with magnetic fluid, the density of the magnetic fluid is 1.2g/ml, and the magnetic fluid is arranged in the annular storage box and can be promoted to flow under the attraction of the built-in magnet block, so that heat generated by the data transmission line in the data process is taken away by means of the movement of the magnetic fluid.

Furthermore, a plurality of uniformly distributed magnetic insulation particles are embedded in the inner surface of the rubber balloon, the magnetic insulation particles are made of iron-nickel alloy material with the nickel content of 80%, the magnetic insulation particles can magnetically shield the built-in magnet blocks when the rubber balloon contracts, and the magnetic shielding of the built-in magnet blocks can be contacted by increasing the distance between the magnetic insulation particles after the rubber balloon expands.

Furthermore, the built-in magnet block is made of a single-sided magnet material, and the phenomenon that the built-in magnet blocks attract each other due to position change when the rubber balloon is inflated can be reduced by manufacturing the built-in magnet block by using the single-sided magnet material.

Further, the rubber ball bag outer end is connected with two mutual symmetries, the inner wall is carved with anti-skidding line, through setting up, can convenience of customers when feeling the heat too high, manually drags the rubber ball bag to the outside to impel the inflation of rubber ball bag.

Furthermore, the traction ball is made of 400-stainless steel material, the surface of the traction ball is coated with an anti-rust paint layer, the traction ball is made of 400-stainless steel material, and the anti-rust paint layer is arranged on the surface of the traction ball, so that the traction ball is not easy to rust in a long-term use process, and the service life of the traction ball can be prolonged.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) according to the scheme, the original data in the electrocardio-coupler patch is transmitted to the handheld end of a user through the data transmission line, so that the heat of an electric connector at the outer end of the electrocardio-coupler patch is increased, the rubber ball bag is expanded to release the magnetic shielding of the built-in magnet block, the magnetic fluid in the annular storage box is attracted by the built-in magnet block, the magnetic fluid can be made to flow out of the release through hole after jacking the rubber sealing sheet and flow along the side transmission conduit, on one hand, the heat generated by the data transmission line in the data transmission process can be absorbed by means of the flow of the magnetic fluid, on the other hand, the external air can be made to enter the annular storage box only by means of the flow of the magnetic fluid, so that the air flow outside the side transmission conduit is increased, and the heat dissipation effect of.

(2) The lateral transmission pipe outer end is connected with a plurality of evenly distributed lateral bending short fibers, the bottom end of the lateral bending short fiber is connected with a contact marble, the contact marble is connected with a traction marble, the outer end of the contact marble is provided with an air exchange hole, by means of the flowing of the magnetofluid, the magnetofluid can be promoted to attract the traction marble, so that the traction marble is promoted to drive the contact marble to move, and when the contact marble is contacted with the junction of the lateral bending short fiber and the lateral transmission pipe, the contact marble is promoted to be extruded, so that the air flowing around the data transmission line is further improved, and the heat dissipation efficiency of the data transmission line is improved.

(3) The electric joint is installed to heart electricity antithetical couplet paster outer end, installs the sensor in the electric joint, and the electric joint upper end is provided with the USB interface, through setting up the sensor, can conveniently with the heart electricity antithetical couplet in the data upload that the paster was gathered to the storage high in the clouds, through setting up the USB interface, can conveniently link the original data transmission in the paster to the handheld end of user with the heart electricity.

(4) The annular storage box is filled with magnetic fluid, the density of the magnetic fluid is 1.2g/cm, and the magnetic fluid can be prompted to flow under the attraction of the built-in magnet block by arranging the magnetic fluid in the annular storage box, so that heat generated by the data transmission line in the data process can be taken away by means of the movement of the magnetic fluid.

(5) The inner surface of the rubber saccule is embedded with a plurality of uniformly distributed magnetic insulation particles, the magnetic insulation particles are made of iron-nickel alloy materials with the nickel content of 80%, the magnetic insulation particles can magnetically shield the built-in magnet blocks when the rubber saccule contracts, and the magnetic shielding of the built-in magnet blocks can be contacted by increasing the distance between the magnetic insulation particles after the rubber saccule expands.

(6) The built-in magnet block is made of a single-sided magnet material, and the phenomenon that the built-in magnet blocks attract each other due to position change when the rubber balloon is inflated can be reduced by manufacturing the built-in magnet block by using the single-sided magnet material.

(7) The outer end of the rubber ball bag is connected with two mutually symmetrical structures, anti-skidding lines are carved on the inner wall, and through setting, a user can conveniently pull the rubber ball bag to the outer side manually when feeling that the heat is too high, so that the rubber ball bag is enabled to expand.

(8) The traction ball is made of 400-stainless steel material, the surface of the traction ball is coated with the anti-rust paint layer, and the traction ball made of 400-stainless steel material and the anti-rust paint layer arranged on the surface of the traction ball can be used for promoting the traction ball not to be easily rusted in a long-term use process, so that the service life of the traction ball can be prolonged.

Drawings

FIG. 1 is a diagram of interaction between functional modules according to the present invention;

FIG. 2 is a diagram of a "one-site editing" interface of the present invention;

FIG. 3 is a block diagram of the invention as a whole;

FIG. 4 is a cross-sectional view of the present invention between the user's hand-held end and the ECG patch;

FIG. 5 is a cross-sectional view of a data transmission line portion according to the present invention;

FIG. 6 is a schematic view of the structure at A in FIG. 5;

fig. 7 is a sectional view of a side-bent short fiber part of the present invention.

The reference numbers in the figures illustrate:

1 electrocardio allies oneself with paster, 2 storage cloud end, 3 PC, 4 user handheld ends, 5 data transmission lines, 6 annular storage box, 601 magnetic current body, 7 side transmission pipes, 8 waterproof ventilated membrane, 9 release through-holes, 10 rubber mounting pieces, 11 rubber sacculus, 12 built-in magnet piece, 13 side bending short fibers, 14 contact marble, 15 traction marble, 16 air exchange holes.

Detailed Description

The drawings in the embodiments of the invention will be combined; the technical scheme in the embodiment of the invention is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the invention; but not all embodiments, are based on the embodiments of the invention; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; 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.

Example 1:

referring to fig. 1-3, the method for displaying and analyzing the full information of dynamic electrocardiographic analysis includes the following steps:

s1, placing the electrocardio-connected patch 1 in front of the chest of a human body, and transmitting the collected electrocardio data to the storage cloud end 2 through an electric connector outside the electrocardio-connected patch 1;

s2, uploading the data stored in the cloud 2 to the PC 3, synchronously presenting information classification modules containing heart beat waveform characteristics and heart beat rhythm characteristics of the electrocardio data on the same interface by adopting a full information display and analysis method of a one-station editing interface, and realizing interaction among the modules to the greatest extent;

and S3, finally, transmitting the obtained image-text information to the user handheld terminal 4, and inputting the original data into the user handheld terminal 4 through the data transmission line 5, so that the user can conveniently check the image-text information and the original data.

The invention adopts a full information display and analysis method of 'one-station editing' interface, synchronously presents the heart beat waveform characteristic and heart beat rhythm characteristic information classification modules containing electrocardio data on the same interface, realizes interaction among the modules to the maximum extent, enables a doctor to carry out complete and simple electrocardio analysis on one interface, helps the doctor to comprehensively and efficiently observe heart beat morphology and heart beat rhythm rule information, further forms a correct and complete dynamic electrocardio report, and provides accurate basis for the doctor to diagnose a patient.

Referring to fig. 3-6, the outer end of the data transmission line 5 in S3 is connected with an annular storage box 6, the outer end of the data transmission line 5 is connected with two symmetrical side transmission conduits 7, the outer end of the annular storage box 6 is embedded with a plurality of uniformly distributed waterproof breathable films 8, the inner wall of the annular storage box 6 is cut with two symmetrical release through holes 9 which are mutually communicated with the side transmission conduits 7, the inner wall of the release through hole 9 is connected with two rubber sealing sheets 10 which are mutually abutted, the outer end of the data transmission line 5 is connected with a rubber balloon 11, the rubber balloon 11 is positioned at the right side of the side transmission conduit 7 and is connected with the side transmission conduit 7, two symmetrical internal magnet blocks 12 are connected in the rubber balloon 11, the original data in the electrocardio patch 1 is transmitted to the user hand-held end 4 through the data transmission line 5, thereby increasing the heat of the electrical connector at the outer end of the electrocardio patch, therefore, the rubber saccule 11 is promoted to be heated and expanded, so that the magnetic shielding of the built-in magnet block 12 is relieved, the magnetic fluid 601 in the annular storage box 6 is promoted to push the rubber sealing sheet 10 open by the aid of the attraction effect of the built-in magnet block 12 on the magnetic fluid 601 in the annular storage box 6 and then flow out of the release through hole 9 and flow along the side transmission conduit 7, on one hand, heat generated by the data transmission line 5 in the data transmission process can be absorbed by the aid of the flow of the magnetic fluid 601, on the other hand, external air can be promoted to enter the annular storage box 6 by the aid of the flow of the magnetic fluid 601, so that air flow outside the side transmission conduit 7 is increased, and the heat dissipation effect of the data.

Referring to fig. 7, the outer end of the side transmission duct 7 is connected to a plurality of side bent short fibers 13 which are uniformly distributed, the bottom end of the side bent short fiber 13 is connected to a contact marble 14, the contact marble 14 is connected to a traction marble 15, the outer end of the contact marble 14 is provided with an air exchange hole 16, by means of the flow of the magnetic fluid 601, the magnetic fluid 601 can attract the traction marble 15, so that the traction marble 15 drives the contact marble 14 to move, and when the contact marble 14 contacts the joint of the side bent short fiber 13 and the side transmission duct 7, the contact marble 14 is squeezed, so that the air flow around the data transmission line 5 is further improved, and the heat dissipation efficiency of the data transmission line 5 is improved.

Referring to fig. 4-6, an electrical connector is installed at the outer end of the electrocardiograph patch 1, a sensor is installed in the electrical connector, a USB interface is arranged at the upper end of the electrical connector, data collected by the electrocardiograph patch 1 can be conveniently uploaded into the storage cloud 2 by arranging the sensor, original data in the electrocardiograph patch 1 can be conveniently transmitted to the user handheld end 4 by arranging the USB interface, the magnetic fluid 601 is filled in the annular storage box 6, the density of the magnetic fluid 601 is 1.2g/cm, the magnetic fluid 601 can be made to flow under the attraction of the built-in magnet block 12 by arranging the magnetic fluid in the annular storage box 6, and therefore heat generated by the data transmission line 5 in the data process can be taken away by means of the movement of the magnetic fluid 601.

Referring to fig. 5, a plurality of uniformly distributed magnetic insulation particles are embedded in the inner surface of the rubber balloon 11, the magnetic insulation particles are made of iron-nickel alloy material with 80% of nickel content, the magnetic shielding of the internal magnet block 12 can be achieved by arranging the magnetic insulation particles when the rubber balloon 11 contracts, after the rubber balloon 11 expands, the magnetic shielding of the internal magnet block 12 can be achieved by increasing the distance between the magnetic insulation particles, the internal magnet block 12 is made of single-sided magnet material, the phenomenon that the internal magnet block 12 attracts each other due to the change of the position when the rubber balloon 11 expands can be reduced by manufacturing the internal magnet block 12 by using the single-sided magnet material, the outer end of the rubber balloon 11 is connected with two mutually symmetrical 1101, the inner wall of the 1101 is carved with anti-skid grains, and by arranging 1101, a user can conveniently pull the rubber balloon 11 outwards manually when feeling that the heat is too high, thereby causing the rubber balloon 11 to inflate.

Referring to fig. 7, the traction ball 15 is made of 400-stainless steel, the surface of the traction ball 15 is coated with an anti-rust paint layer, and the traction ball 15 made of 400-stainless steel and the anti-rust paint layer on the surface of the traction ball 15 can promote the traction ball 15 not to be easily rusted in a long-term use process, so that the service life of the traction ball 15 can be prolonged.

The above; but are merely preferred embodiments of the invention; the scope of the invention is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the invention are equally replaced or changed; are intended to be covered by the scope of the present invention.