CN113057644A - Data acquisition device - Google Patents

Abstract

The application discloses data acquisition device belongs to medical technical field. The data acquisition device that this application embodiment provided includes electrocardio monitoring clothing and portable data collection station, and this electrocardio monitoring clothing is including clothes body and a plurality of electrode of leading, wherein: the plurality of lead electrodes are all installed on the clothes body, each lead electrode is matched with the corresponding human body lead position, and the lead electrodes are electrically connected with the portable data acquisition unit. The user can wear the electrocardio monitoring clothes, and the lead electrode on the electrocardio monitoring clothes can be in contact with the human body lead position of the user due to the fact that the position of the lead electrode on the clothes body is matched with the human body lead position, and the user can carry out electrocardio measurement by opening the portable data acquisition device. The electrocardio condition is measured through the data acquisition device, the operation is simple, the professional doctor is not required to paste the lead electrodes on the body of the user in a one-to-one correspondence manner, the heart rate measurement is not limited by the occasion, the application occasion of the electrocardio monitoring clothes is wide, and the flexibility is high.

Description

Data acquisition device

Technical Field

The application relates to the technical field of medical treatment, in particular to a data acquisition device.

Background

The electrocardiographic monitoring is the most basic examination means for diagnosing cardiovascular diseases, carries out real-time electrocardiographic monitoring on users to find the abnormal change of electrocardiography in time, and has important significance for preventing and treating the cardiovascular diseases.

In the related art, users usually use an electrocardiograph to perform electrocardiographic measurement, for example, when the users intend to perform electrocardiographic measurement, they need to go to a hospital, and a professional medical staff operates the electrocardiograph to perform measurement. The specific measurement process can be that a user can lie on a hospital bed, and medical personnel paste each lead electrode of the electrocardio monitor at the human body lead position of the user in a one-to-one correspondence manner.

In the course of implementing the present application, the inventors found that the related art has at least the following problems:

when the electrocardio monitor is used, professional medical personnel need to operate the electrocardio monitor, so that the electrocardio monitor has large use limitation and poor flexibility.

Disclosure of Invention

The embodiment of the application provides a data acquisition device, which can solve the problems in the related art. The technical scheme is as follows:

provides a data acquisition device, which comprises an electrocardio monitoring coat and a portable data acquisition device, wherein,

the electrocardio monitoring coat comprises a coat body and a plurality of lead electrodes arranged on the coat body, wherein each lead electrode is matched with the corresponding human body lead position;

the portable data acquisition unit is electrically connected with the plurality of lead electrodes through lead wires.

In a possible implementation manner, the garment body is provided with positioning holes at positions corresponding to the human body lead positions, and the positioning holes are matched with the corresponding lead electrodes.

In one possible implementation manner, the electrocardiogram monitoring clothes further comprises a plurality of lead wires;

the plurality of lead wires are arranged on the clothes body, and each lead electrode is electrically connected with at least one lead wire;

all the lead wires are converged, and the end parts of the lead wires, which are far away from the corresponding lead electrodes, are accommodated in the lead wire plug.

In one possible implementation mode, the electrocardiogram monitoring clothes further comprises a tree-shaped lead wire fixing body, the lead wire fixing body is installed on the clothes body, a lead wire between each lead electrode and the portable data acquisition unit is located in the lead wire fixing body, and the lead electrodes connected with the lead wires are installed on the clothes body through the lead wire fixing body;

the lead wire fixing body comprises a main rod body and a plurality of branch rod bodies, each branch rod body is connected to the main rod body, at least one lead wire is installed in each branch rod body, all the lead wires are converged in the main rod body, and at least one lead wire is extended from the main rod body to the position of the corresponding lead electrode.

In a possible implementation manner, a containing bag matched with the portable data collector is arranged on the clothes body, and the portable data collector is located in the containing bag; the garment body comprises an inner liner and an outer layer, and the outer layer is matched with the inner liner and is arranged on the inner liner; the portable data acquisition unit and the plurality of lead electrodes are arranged on the lining, and the portable data acquisition unit, the plurality of lead electrodes and the lead wires are arranged between the lining and the outer layer.

In a possible implementation manner, the portable data collector comprises a shell, a data collecting component, a transmission component and a power supply component, wherein the data collecting component, the transmission component and the power supply component are located in the shell, the power supply component is respectively connected with the data collecting component and the transmission component electrically, the data collecting component comprises a lead wire interface, and a position of the lead wire interface on the shell is provided with a lead wire connecting opening.

In one possible implementation manner, the portable data collector further includes a charging interface; a charging opening is formed in the position, corresponding to the charging interface, of the shell; the lead wire interface and the charging interface are positioned on the same side of the shell, and the charging interface is in a shielding state when the lead wire interface is connected with the lead wire plug.

In one possible implementation, the housing includes a first housing, a second housing, and a middle shell;

the first shell and the second shell are fixed on the middle shell, and the first shell and the second shell are opposite in position;

the lead wire connecting opening and the charging opening are both located on the middle shell.

The data acquisition component, the transmission component and the power supply component are integrated on a circuit board, and the circuit board is connected with the first shell and the middle shell through screws; the second shell is fixedly connected with the middle shell through a buckle of the second shell.

In a possible implementation manner, the portable data collector further includes at least one indicator light, the at least one indicator light is electrically connected to the data collecting component and the power supply component, and the state of the at least one indicator light is used to indicate whether the lead electrodes are collecting the electrocardiographic signals, or indicate the accuracy of collecting the electrocardiographic signals by the lead electrodes, or indicate the working state of the portable data collector.

In a possible implementation manner, the portable data collector further includes a storage component, the storage component is located in the housing, and the storage component is electrically connected to the data collection component, the transmission component, and the power supply component, respectively;

the portable data acquisition device also comprises a processing component, the processing component is positioned in the shell, and the processing component is respectively and electrically connected with the data acquisition component, the transmission component and the power supply component;

the portable data collector further comprises a sound collecting component, the sound collecting component is located on the shell, and the sound collecting component is electrically connected with the transmission component and the power supply component.

The beneficial effects brought by the technical scheme provided by the embodiment of the application at least comprise:

the data acquisition device that this application embodiment provided includes electrocardio monitoring clothing and portable data collection station, and this electrocardio monitoring clothing is including clothes body and a plurality of electrode of leading, wherein: the plurality of lead electrodes are all installed on the clothes body, each lead electrode is matched with the corresponding human body lead position, and the lead electrodes are electrically connected with the portable data acquisition unit. When a user needs to measure the heart rhythm, the user can wear the electrocardio monitoring coat, and because the positions of the lead electrodes on the coat body are matched with the human body lead positions, the lead electrodes on the electrocardio monitoring coat can be in contact with the human body lead positions of the user, and the user can carry out electrocardio measurement by opening the portable data acquisition device. Therefore, when the data acquisition device is used for acquiring the electrocardiosignals of a user, the operation is simple, the professional doctor is not required to paste the lead electrodes on the body of the user in a one-to-one correspondence manner, so that the user does not need to go to a hospital to measure, the heart rate measurement is not limited by occasions, and further, the electrocardio monitoring garment is wide in application occasions and high in flexibility.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a data acquisition device according to an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a data acquisition device according to an embodiment of the present application;

FIG. 3 is a schematic structural diagram of a data acquisition device according to an embodiment of the present application;

FIG. 4 is a schematic structural diagram of a data acquisition device according to an embodiment of the present application;

FIG. 5 is a schematic structural diagram of a data acquisition device according to an embodiment of the present application;

fig. 6 is a schematic structural diagram of a portable data collector provided in an embodiment of the present application;

fig. 7 is a schematic structural diagram of a portable data collector provided in an embodiment of the present application;

fig. 8 is a schematic structural diagram of a lead plug according to an embodiment of the present disclosure;

fig. 9 is a schematic structural diagram of a portable data collector provided in an embodiment of the present application;

fig. 10 is a schematic structural diagram of a portable data collector provided in an embodiment of the present application;

fig. 11 is a schematic structural diagram of a portable data collector provided in an embodiment of the present application;

fig. 12 is a schematic structural diagram of a portable data collector provided in an embodiment of the present application;

fig. 13 is a schematic structural diagram of a portable data collector provided in an embodiment of the present application.

Description of the figures

1. Electrocardio monitoring clothing 2, portable data acquisition unit

11. Garment body 12, lead electrode

13. Lead wire 14, lead wire plug

15. Lead wire fixing body 21 and shell

22. Data acquisition component 23 and transmission component

24. Power supply unit 25, lead wire interface

26. Charging interface 27 and indicator light

28. Storage unit 29 and processing unit

30. Sound collection part 31 and power key

32. Sound playing component 111 and positioning hole

112. Storage bag 113 and inner liner

114. Outer layer 141, conductor

151. Main rod body 152 and branch rod body

211. Lead wire connection opening 212 and charging opening

213. First and second housings 214 and 214

215. Middle shell

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

The embodiment of the application provides a data acquisition device for collecting electrocardiosignals, and the data acquisition device comprises an electrocardio monitoring clothes 1 and a portable data acquisition device 2, and the portable data acquisition device 2 can be carried about, so that a user can measure the electrocardio condition at any time and any place. The portable data acquisition device 2 is matched with the wearable electrocardio monitoring clothes 1 for use, and then electrocardiosignals of a human body can be acquired. For example, the electrocardiograph monitoring garment 1 may have a storage bag 112 for storing the portable data acquisition device 2, the portable data acquisition device 2 is stored in the storage bag 112, the portable data acquisition device 2 is electrically connected to the lead electrode 12 on the electrocardiograph monitoring garment 1 through the lead wire 13, and after the user wears the electrocardiograph monitoring garment 1, the portable data acquisition device 2 is started, so that the electrocardiograph condition can be measured.

In a possible application scenario, the portable data acquisition device 2 is used in cooperation with a wearable electrocardiogram monitoring garment 1, the electrocardiogram monitoring garment 1 may include a plurality of lead electrodes 12, and a plurality of lead wires 13 connected to the lead electrodes 12 are converged to form a lead wire plug 14. Lead plug 14 is adapted to an interface (hereinafter referred to as lead interface 25) of portable data collector 2, and when lead plug 14 is inserted into the interface of portable data collector 2, lead electrode 12 and portable data collector 2 can be electrically connected through lead 13. Thus, after the user wears the electrocardiogram monitoring clothes 1, the lead electrodes 12 can be respectively attached to the lead positions on the body one by one; then, the user can measure the electrocardiosignal only by inserting the lead wire plug 14 into the lead wire interface 25 of the portable data collector 2 and starting the portable data collector 2, and the operation is simple without the cooperation of professional medical personnel.

Fig. 1 is a schematic structural diagram of a data acquisition device provided in an embodiment of the present application, and referring to fig. 1, the data acquisition device includes an electrocardiographic monitoring garment 1 and a portable data acquisition device 2, where the electrocardiographic monitoring garment 1 includes a garment body 11 and a plurality of lead electrodes 12 mounted on the garment body 11, each lead electrode 12 is adapted to a corresponding human body lead position, and the portable data acquisition device 2 is electrically connected to the plurality of lead electrodes 12 through a lead wire 13.

The data acquisition device that this application embodiment provided includes electrocardio monitoring clothing 1 and portable data collection station 2, and this electrocardio monitoring clothing 1 includes clothes body 11 and a plurality of electrode 12 that leads, wherein: the lead electrodes 12 are all installed on the garment body 11, each lead electrode 12 is matched with the corresponding human body lead position, and the lead electrodes 12 are electrically connected with the portable data acquisition unit 2. When a user needs to measure the heart rhythm, the user can wear the electrocardio monitoring clothes 1, and because the position of the lead electrode 12 on the clothes body 11 is matched with the human body lead position, the lead electrode 12 on the electrocardio monitoring clothes 1 can be contacted with the human body lead position of the user, and the user can carry out the electrocardio measurement by opening the portable data acquisition device 2. Therefore, when the data acquisition device is used for acquiring the electrocardiosignals of a user, the operation is simple, a professional doctor is not required to attach the lead electrodes 12 to the body of the user in a one-to-one correspondence manner, so that the user does not need to go to a hospital to measure, the heart rate measurement is not limited by occasions, and further, the electrocardio monitoring garment 1 is wide in application occasions and high in flexibility.

The following describes details of the electrocardiographic monitoring garment 1 and the portable data acquisition unit 2 included in the data acquisition device.

For the electrocardiogram monitoring clothes 1, a user can wear the electrocardiogram monitoring clothes 1 at ordinary times, the electrocardiogram monitoring clothes 1 can measure electrocardiogram data of the user and send the measured electrocardiogram data to the medical platform, and medical personnel can obtain an electrocardiogram of each user from the medical platform. Or, the electrocardiogram monitoring clothes 1 sends the measured electrocardiogram data to the associated user terminal, and the user checks the electrocardiogram of the user through the electrocardiogram application program installed on the terminal, so that the user wearing the electrocardiogram monitoring clothes 1 can know the electrocardiogram of the user in time, and the electrocardiogram monitoring clothes have important significance for preventing and treating cardiovascular diseases. The lead electrode 12 is a metal conductor for obtaining bioelectricity on the surface layer of the human body.

The lead electrode 12 may also be referred to as an electrocardiograph electrode, and is a metal conductor for obtaining bioelectricity on the surface layer of the human body.

In practice, lead electrode 12 may be removably mounted to garment body 11 to facilitate user replacement of lead electrode 12. Lead electrode 12 may also be a disposable electrode pad, and lead electrode 12 may be mounted on garment body 11 each time a user uses it.

The garment body 11 may also be referred to as a lead wire fixing garment, and is mainly used for fixing and carrying lead electrodes 12 and fixing lead wires 13 to be described below.

In implementation, the electrocardiograph monitoring garment 1 may be worn on a user, for example, the electrocardiograph monitoring garment 1 may be a pullover T-shirt as shown in fig. 1 in appearance, and the electrocardiograph monitoring garment 1 may also have an apron-shaped structure. The specific shape and structure of the electrocardiograph monitoring garment 1 are not limited in this embodiment, and the electrocardiograph monitoring garment 1 can be used for carrying a plurality of lead electrodes 12, the embodiment can be exemplified by a pullover T-shirt as shown in fig. 1, and electrocardiograph monitoring garments 1 in other shapes are similar to the electrocardiograph monitoring garment 1.

For convenience of introduction, the terms of inside, outside, up and down are introduced herein, wherein a surface of the electrocardiograph monitoring garment 1, which is in direct contact with a user after the user wears the electrocardiograph monitoring garment 1, is referred to as an inner surface, and a surface opposite to the inner surface is referred to as an outer surface. The positions of the sleeve heads of the electrocardio monitoring clothes 1 are taken as the upper part and the top part, the position opposite to the upper part is taken as the lower part, and the position opposite to the top part is taken as the bottom part.

In implementation, for convenience of wearing, the size of the electrocardiograph monitoring garment 1 is adapted to the size of a human body, for example, the electrocardiograph monitoring garment 1 can be divided into two sizes according to different sizes of men and women, wherein men correspond to one size of uniform size, and women correspond to one size of uniform size. For another example, the size of the electrocardiograph monitoring garment 1 is adapted to the size of the human body, and specifically, the electrocardiograph monitoring garment 1 can be divided into sizes according to the height and weight of the human body, and can include a plurality of sizes to adapt to users of different body types. For example, the electrocardiograph monitoring garment can be divided into S, M, L, XL, XXL and XXXL according to the height and weight of a male, and can be divided into S, M, L, XL, XXL and XXXL according to the height and weight of a female.

The position arrangement of each lead electrode 12 on the electrocardiograph monitoring garment 1 can be adjusted according to different men and women, so that the accuracy of the measurement result is improved. Hereinafter, the electrocardiogram monitoring clothes 1 with any size can be exemplified, and the electrocardiogram monitoring clothes 1 with other sizes are similar to the electrocardiogram monitoring clothes 1, so that the detailed description is omitted.

As shown in fig. 1, a plurality of lead electrodes 12 are disposed on an outer surface of the garment body 11, wherein the position and the number of the lead electrodes 12 may be determined according to a lead system to which the electrocardiograph monitoring garment 1 belongs, and the lead system of the electrocardiograph monitoring garment 1 may be one or more of 2 lead, 3 lead, 5 lead, 2 lead and 8 lead. The lead system of the electrocardiograph monitoring garment 1 can be 2 leads, or a combination of any two or any more of the above. For convenience of description, the present embodiment can be arranged according to the international universal lead system (i.e. the conventional 2-lead system) which is widely used at present. The position of each lead electrode 12 is adapted to the body lead position of the user corresponding to the electrocardiographic monitoring garment 1 with the size, for example, as shown in fig. 1, the lead electrode 12 placed at position a of the garment body 11 corresponds to the V1 lead of the chest lead, the lead electrode 12 placed at position B of the garment body 11 corresponds to the V2 lead of the chest lead, and the correspondence of other positions to the body lead positions is not listed. Further, one lead electrode 12 is mounted on the outer surface of the garment body 11 corresponding to each human body lead position.

The lead electrode 12 may be attached to the garment body 11 in various ways, for example, the lead electrode 12 may be attached to the garment body 11 by a pin. Alternatively, lead electrode 12 is provided with a mounting hole, and lead electrode 12 is sewn on garment body 11 through the mounting hole. Alternatively, lead electrode 12 is mounted on garment body 11 by snap fasteners. Alternatively, the lead wire 13 electrically connected to the lead electrode 12 is fixed to the garment body 11, and the lead electrode 12 is mounted to the garment body 11 through the lead wire 13, in a manner to be described in detail later.

Thus, when the user wears the electrocardiograph monitoring garment 1, the positions of the lead electrodes 12 correspond to the corresponding human body lead positions, so that after the user wears the electrocardiograph monitoring garment 1, the lead electrodes 12 can be attached to the corresponding human body lead positions. Therefore, in the process of measuring the electrocardio data of the user by using the electrocardio monitoring clothes 1, the cooperation of medical personnel is not needed, the user can measure the electrocardio condition of the user at home and in places such as working units, the electrocardio measurement is not limited by the places, and the electrocardio monitoring clothes 1 have wide application occasions. Moreover, the electrocardio monitoring clothes 1 are simple to operate, so that the electrocardio monitoring clothes 1 have strong practicability and flexibility.

In addition, a doctor can also acquire the electrocardio data of the user in time, know the heart rhythm condition of the user in time and set the optimal treatment opportunity for the user.

In a possible application, although the size of the electrocardiograph monitoring garment 1 can be divided into a plurality of sizes according to the height and the weight of a person, since the size of each user can be different, in order to adapt to as many users as possible, correspondingly, the electrocardiograph monitoring garment 1 has elasticity, and in order to make the user feel more comfortable after wearing the electrocardiograph monitoring garment 1, correspondingly, the electrocardiograph monitoring garment 1 has certain flexibility. For example, the electrocardiograph monitoring garment 1 may be made of a material having elasticity and flexibility.

In implementation, in order to enable the electrocardiograph monitoring garment 1 to be attached to a user so that the lead electrode 12 can be attached to a lead position of a human body, the electrocardiograph monitoring garment 1 may be made of a high-elasticity fabric, for example, the fabric may contain one or more of dupont lycra, chinlon, dacron and the like.

In implementation, in order to improve the accuracy of the electrocardiograph measurement result, the electrocardiograph monitoring garment 1 is directly attached to the human body, that is, the electrocardiograph monitoring garment 1 directly contacts with the skin of the user, or the user can wear a thin shirt. Since the electrocardiograph monitoring garment 1 is directly contacted with the user, in order to avoid the reaction of overstimulation after the user wears the electrocardiograph monitoring garment 1, for example, allergy occurs after the user wears the electrocardiograph monitoring garment 1, and in order to avoid the occurrence of the reaction, correspondingly, the material of the electrocardiograph monitoring garment 1 has biocompatibility. Therefore, after the user wears the electrocardio monitoring clothes 1, no overstimulation reaction is generated, and no harm is caused to the human body.

The material of the electrocardiogram monitoring clothes 1 has biocompatibility, that is, the electrocardiogram monitoring clothes 1 has a reaction grade of 1 grade on cytotoxicity, and the reaction grade is slight cytotoxicity through test. On skin sensitization, the test article showed no skin sensitization response as tested by the test. The irritation index for the test article was 0 on skin irritation by the test. As can be seen, the electrocardio monitoring clothes 1 basically do not affect the health of the user.

In implementation, the lead electrode 12 is used to contact with a user to form an electrical path between the apparatus and the surface layer of the human body, and then, in order to acquire electrocardiographic data of the user, the lead electrode 12 needs to be connected with the portable data acquisition unit 2 for acquiring data. The portable data collector 2 may be an electrocardiograph monitor capable of collecting and outputting electrocardiographic data, or may be a sensor only used for collecting data, and then may send the collected data to an instrument (such as an electrocardiograph monitor) used for outputting electrocardiographic data. In this embodiment, what instrument the lead electrode 12 is connected to is not limited, and the electrocardiographic data can be acquired.

In one possible application, the above-mentioned instrument may not be mounted on the garment body 11, and may be, for example, an electrocardiograph monitor placed on a table. When a user needs to measure, the user wears the electrocardio monitoring clothes 1 around the electrocardio monitor, and leads 13 led out from the electrocardio monitor are connected to the corresponding lead electrodes 12 for measurement.

For more convenient measurement by the user, the apparatus may be, for example, a portable data collector 2 which can be carried by the user, for example, in a pocket of clothes, etc., and when the user intends to measure the heart rhythm, the lead wires 13 led out from the portable data collector 2 may be connected to the respective lead electrodes 12 to perform the measurement.

By the way, when the user uses the electrocardio monitoring clothes 1 to measure the heart rate, the operation of professional medical personnel is not needed, so that the place where the user measures the heart rate is not limited to a hospital, and the user can measure the heart rate at any place such as home and work units. Even the user can carry with him or her an instrument for measuring the heart rate, the electrocardiographic monitoring garment 1 can periodically perform electrocardiographic monitoring on the user, or perform electrocardiographic monitoring on the user when finding that the user has an abnormal condition. Therefore, the electrocardio monitoring clothes 1 are simple to operate, wide in use occasions, high in practicability and flexibility.

In one possible application, the apparatus may also output an electrocardiogram for viewing by a user, for example, the apparatus is an electrocardiogram monitor having a display screen for displaying the electrocardiogram. The instrument can also upload the electrocardiogram data to a medical platform, so that medical personnel can acquire the electrocardiogram of each user from the medical platform, and the user can acquire the electrocardiogram from the medical platform through an electrocardiogram application program installed on a mobile phone. Or the instrument can be connected with the mobile phone of the user through Bluetooth, and the collected data can be sent to the mobile phone of the user.

In a possible application, the portable data collector 2 for collecting the electrocardiographic data may be a portable electronic device, which can be carried by a user, and correspondingly, as shown in fig. 2, a storage bag 112 for placing the portable data collector 2 may be disposed on the garment body 11.

In implementation, a storage pocket 112 may be disposed on an outer surface of the garment body 11, and a storage space is formed between the storage pocket 112 and the garment body 11 for storing the portable data collector 2. When the user needs to measure, the user can take the portable data collector 2 out of the storage bag 112 and hold the portable data collector 2 to measure. Or, in order to further facilitate the measurement of the user, correspondingly, the storage bag 112 may further be provided with a wire port for passing the lead wire 13 connected between the lead electrode 12 and the portable data acquisition device 2, so that the user does not need to take out the portable data acquisition device 2 during the measurement, and the portable data acquisition device 2 is located in the storage bag 112 for measurement.

In one possible application, in order to avoid the portable data collector 2 placed in the pocket 112 from affecting the normal work and operation of the user, since most people use the right hand more often, accordingly, as shown in fig. 2, the pocket 112 may be located at a position close to the lower end of the garment body 11 and corresponding to the left position of the human body. For example, as shown in fig. 2, the storage bag 112 may be located at the lower left corner of the electrocardiograph monitoring garment 1, so that the normal living habits of the user are not affected even when the user wears the electrocardiograph monitoring garment 1.

In one possible application, the lead wires 13 for electrically connecting the lead electrodes 12 to the instrument may or may not be mounted on the garment body 11. For example, in the case where lead wire 13 is not mounted on garment body 11, each lead electrode 12 may be provided with a wire insertion hole, and when a user needs to measure a heart rhythm, lead wire 13 led from an instrument may be inserted into the wire insertion hole of lead electrode 12, so as to electrically connect lead electrode 12 with the instrument.

For another example, the lead wires 13 may be mounted on the garment body 11, and the electrocardiograph monitoring garment 1 further includes a plurality of lead wires 13, as shown in fig. 1, the lead electrodes 12 are electrically connected to the lead wires 13, for example, each lead electrode 12 is electrically connected to at least one lead wire 13, and an end of each lead wire 13 far from the lead electrode 12 is used for electrically connecting to the above-mentioned apparatus.

In one possible application, since the number of lead electrodes 12 is plural, the number of lead wires 13 is also plural, and in order to arrange the lead wires 13 and also to facilitate the operation of the user, correspondingly, as shown in fig. 3, all the lead wires 13 are converged, and the end portions of all the lead wires 13 far from the lead electrodes 12 are accommodated in the lead wire plugs 14.

The lead plug 14 is used to electrically connect with the above-mentioned instrument, for example, the lead plug 14 is adapted to a jack on the instrument, the lead plug 14 is connected with the jack of the instrument, and thus, each lead electrode 12 is electrically connected with the instrument.

Therefore, the lead wires 13 are regular on the clothes body 11, and the lead wires 13 cannot be damaged by being pulled by a user when the user wears the clothes. In addition, the user only needs to insert the conductor 141 of the lead wire plug 14 into the jack of the instrument to realize the electrical connection between each lead electrode 12 and the instrument, and the user does not need to connect each lead electrode 12 and the instrument one by one through the lead wires 13, thereby facilitating the operation of the user and bringing convenience to the heart rhythm measurement work of the user.

Alternatively, when the conductor 141 of the lead wire plug 14 is not inserted into the jack, in order to prevent the lead wire plug 14 from entering water to affect the measurement, correspondingly, as shown in fig. 3 and with reference to fig. 4, the lead wire plug 14 may include a waterproof cap and the conductor 141, and the electrocardiograph monitoring garment 1 is in an unused state, and the conductor 141 is located in the waterproof cap to protect the conductor 141.

Wherein, the waterproof cap can be made of plastic materials and has the effects of insulation and corrosion prevention.

Thus, when a user needs to measure, the conductor 141 of the lead wire plug 14 can be inserted into the jack of the instrument, and when the device is not in use, after the conductor 141 of the lead wire plug 14 is pulled out of the jack, as shown in fig. 4, a waterproof cap can be covered on the conductor 141 of the lead wire plug 14 to protect the conductor 141 of the lead wire plug 14 from entering water, dust, and the like.

In a possible application, in the case where the lead wire 13 is provided on the garment body 11, the lead wire 13 may be sewn to the garment body 11, or may be detachably attached to the garment body 11, or the like. The lead wires 13 are installed on the garment body 11, and accordingly, the lead electrodes 12 connected to the lead wires 13 can be installed on the garment body 11 through the lead wires 13.

In a possible application, the lead wire 13 is exposed to the outside, and on the one hand, the lead wire is easily damaged to cause an open circuit, and on the other hand, certain danger is caused to the user, and accordingly, as shown in fig. 4, the electrocardiograph monitoring garment 1 further comprises a lead wire fixing body 15, and the lead wire fixing body 15 is installed on the garment body 11; the lead wire 13 is installed in the lead wire fixing body 15; lead electrodes 12 connected to lead wires 13 are mounted on the garment body 11 through lead wire fixing bodies 15.

The lead wire fixing body 15 is used to hide and fix the lead wire 13, for example, between the lead electrode 12 and the storage bag 112 on the garment body 11.

As described above, all the lead wires 13 are gathered, and in order to adapt to the layout of the lead wires 13, correspondingly, as shown in fig. 4, the lead wire fixing body 15 may have a tree-shaped structure, including a main rod body 151 and a plurality of branch rod bodies 152, each branch rod body 152 is connected to the main rod body 151, at least one lead wire 13 is placed in each branch rod body 152, the gathered portion of all the lead wires 13 is received in the main rod body 151, and the lead wire plugs 14 formed by gathering all the lead wires 13 extend out of the main rod body 151. For example, as shown in fig. 4, a first end of the main shaft 151 may be located at a position corresponding to the position of the pouch 112, and each branch 152 is connected to a second end of the main shaft 151 and extends to a position corresponding to the lead electrode 12.

In an implementation, the shape of the main rod 151 may also be a vertical line, one end of the vertical main rod 151 is close to the receiving bag 112, and the other end is divided into a plurality of rods 152, and the plurality of rods 152 respectively extend to the lead electrodes 12. As shown in fig. 4, the main rod 151 may also be L-shaped, the L-shaped main rod 151 may be divided into two parts, i.e., a horizontal part and a vertical part, the horizontal part of the main rod 151 corresponds to the position of the storage bag 112, and the vertical part of the main rod 151 extends out of the plurality of rods 152.

Wherein, lead line 13 and be located lead line fixed body 15, play arrangement and regular effect to lead line 13, the user can avoid dragging lead line 13 when wearing this electrocardio monitoring clothing 1, plays the guard action to lead line 13.

In one possible application, the lead wire fixing body 15 may be sewn on the outer surface of the garment body 11 so that the lead wire 13 and the lead electrode 12 may be secured to the garment body 11.

In one possible application, in order to facilitate the cleaning of the electrocardiograph monitoring garment 1, the lead wire fixing body 15 can be detachably mounted on the garment body 11. For example, the lead wire fixing body 15 may be mounted on the garment body 11 by a zipper, and for example, the lead wire fixing body 15 may be bonded on the garment body 11 by felt. Thus, when a user needs to clean the electrocardiogram monitoring clothes 1, the lead wire fixing body 15 on the electrocardiogram monitoring clothes 1 can be detached, then the electrocardiogram monitoring clothes 1 is cleaned, and after the cleaning is completed, the lead wire fixing body 15 is installed on the clothes body 11.

As described above, the lead electrode 12 is connected to the end of the lead wire 13, and the lead wire 13 is fixed to the lead wire fixing member 15, so that the lead wire fixing member 15 is attached to the garment body 11, and the lead electrode 12 can be fixed to the garment body 11 by the lead wire fixing member 15.

Therefore, after the user wears the electrocardiogram monitoring clothes 1, the electrode end of the lead electrode 12 can be attached to the body of the user, and the attaching position of the lead electrode 12 corresponds to the lead position of the human body. When the user uses the electrocardio monitoring clothes 1 to measure the electrocardio condition, no professional medical personnel are needed to operate, and great convenience is provided for the user.

In a possible application, in order to improve the accuracy of the electrocardiograph data acquisition of the electrocardiograph monitoring garment 1, correspondingly, as shown in fig. 4, a positioning hole 111 is provided at a position on the garment body 11 corresponding to the human body lead position.

The positioning hole 111 is used for limiting the position of the lead electrode 12, the lead electrode 12 needs to be positioned in the positioning hole 111 to correspond to the lead position of the human body, and the measurement result is accurate. Alignment aperture 111 is adapted to lead electrode 12, i.e., is adapted in shape and is adapted in size. Specifically, the size of registration aperture 111 is greater than or equal to the size of lead electrodes 12 so that each lead electrode 12 may be fully placed in the corresponding registration aperture 111.

The shape of pilot hole 111 may be adapted to the shape of lead electrode 12, for example, lead electrode 12 may be circular, pilot hole 111 may be circular, and pilot hole 111 may be rectangular.

In practice, lead electrode 12 may or may not be fixed in pilot hole 111. For example, where lead electrodes 12 are not secured in alignment apertures 111, each lead electrode 12 can be positioned adjacent a corresponding alignment aperture 111, e.g., each lead electrode 12 can be laid down around a corresponding alignment aperture 111. After the user wears the electrocardiograph monitoring garment 1, each lead electrode 12 can be manually pasted in the corresponding positioning hole 111, and since each positioning hole 111 corresponds to the corresponding human body lead position, the pasting position of the lead electrode 12 also corresponds to the human body lead position. Therefore, when the user measures the heart rhythm, the user can attach the lead electrodes 12 to the corresponding positioning holes 111, the operation is simple, and professional medical personnel are not required to attach the lead electrodes 12 to the body of the user one by one. Furthermore, when the user measures the heart rhythm each time, the user does not need to go to a hospital, the measurement can be carried out in any place, the application occasions of the electrocardio monitoring clothes 1 are wider, and the use flexibility is high.

For another example, in the case where lead electrode 12 is fixed in positioning hole 111, the electrode end of lead electrode 12 may be used to contact the human body. After the user wears the electrocardiograph monitoring garment 1, the lead electrodes 12 are fixed in the positioning holes 111, so that the lead electrodes 12 can be directly attached to the corresponding human body lead positions, and since each positioning hole 111 corresponds to the corresponding human body lead position, the lead electrodes 12 in the positioning holes 111 also correspond to the human body lead positions, and further, the user does not need to attach the lead electrodes 12 to the user by professional medical staff. Therefore, when the electrocardio monitoring clothes 1 are used for measuring the heart rhythm of a user, the electrocardio monitoring clothes are easy to operate, do not need professional medical personnel to operate, and bring great convenience to the use of the user.

In one possible application, the lead electrode 12, the lead wire 13, the lead wire fixing body 15, and the storage bag 112 are all located on a first surface of the garment body 11, where the first surface is a surface that is not in direct contact with a human body after the user wears the electrocardiograph monitoring garment 1. In this way, the lead electrodes 12, the lead wires 13, the lead wire fixing body 15, and the storage bag 112 on the garment body 11 are all located on the outer surface of the garment body 11, so that the comfort of the user wearing the electrocardiograph monitoring garment 1 can be improved.

In a possible application, since the lead electrode 12, the lead wire 13 and the lead wire fixing body 15 are all located on the outer surface of the garment body 11, after the user wears the electrocardiograph monitoring garment 1, the above components are all exposed to the outside, which is relatively aesthetic and easy to touch, and in order to avoid the above situation, the corresponding structures may be:

as shown in FIG. 5, the garment body 11 may include an inner liner 113 and an outer layer 114, the outer layer 114 fitting to the inner liner 113 and being mounted on the inner liner 113; a plurality of lead electrodes 12 and lead wire holders 15 are each mounted on inner liner 113, and a plurality of lead electrodes 12 and lead wire holders 15 are each located between inner liner 113 and outer layer 114.

The outer layer 114 is mainly used for shielding the lead electrode 12, the lead wire 13, the lead wire fixing body 15 and the like mounted on the liner 113, so as to improve the appearance of the electrocardiograph monitoring garment 1.

In implementation, when the lead electrode 12 is fixed in the positioning hole 111, the user may wear the electrocardiograph monitoring garment 1 without manually attaching the lead electrode 12 to the body. In this case, the outer layer 114 may be a piece of cloth, which may be attached to the inner liner 113. For example, outer layer 114 is sewn to inner liner 113. To facilitate cleaning, the edges of the outer layer 114 are attached to the inner liner 113 by zippers, for example.

For the case that lead electrode 12 is not fixed in positioning hole 111, user needs to manually stick lead electrode 12 in corresponding positioning hole 111, in this case, each measurement is performed by user operation, for user operation convenience, outer layer 114 may be as described above, and its edge is installed on lining 113 through zipper, and for each measurement, outer layer 114 is detached, and after user sticks lead electrode 12, outer layer 114 is installed on lining 113.

For another example, to further facilitate user manipulation, as shown in FIG. 5, the outer layer 114 may include a first portion and a second portion; the first portion is mounted to a first side of the liner 113 and the second portion is mounted to a second side of the liner 113, the first portion and the second portion being removably coupled, the first side and the second side of the liner 113 being opposite.

The first portion and the second portion of the outer layer 114 may be symmetrical with respect to the connection, for example, the first portion and the second portion may be symmetrical with respect to a central axis of the electrocardiograph monitoring garment 1.

In practice, the first and second portions of the outer layer 114 may be attached by a zipper, or alternatively, may be attached by buttons. In this embodiment, the connection manner between the first portion and the second portion is not limited, and the connection may be implemented.

Thus, when the user uses the electrocardiograph monitoring garment 1, the user can put the garment on the body, then the lead electrodes 12 are attached to the positions of the positioning holes 111, then the lead plug 14 of the lead wire 13 is inserted into the jack of the instrument for measuring electrocardiography, and finally the first part and the second part of the outer layer 114 are connected.

As for the portable data collector 2, as shown in fig. 6, the portable data collector 2 includes a housing 21, a data collecting part 22, a transmission part 23, and a power supply part 24, and the data collecting part 22, the transmission part 23, and the power supply part 24 are located in the housing 21. The data acquisition component 22 is configured to acquire an electrocardiographic signal of a human body based on the lead electrode 12 connected to the portable data acquisition device 2, the transmission component 23 is configured to transmit the acquired electrocardiographic signal to a data processing device, and the power supply component 24 is configured to provide power for the data acquisition component 22 and the transmission component 23.

A power supply component 24 provides power to the components of the portable data collector 2 to enable the various components to operate. The data acquisition part 22 of the portable data acquisition device 2 can be connected with the lead wire 13 of the electrocardiogram monitoring clothes 1, and acquires electrocardiosignals of a human body through the lead electrode 12 connected with the lead wire 13 of the electrocardiogram monitoring clothes 1. Specifically, after the user wears the electrocardiograph detection garment, the lead electrodes 12 can be respectively attached to the lead positions on the body one by one, so that the acquisition component can acquire electrocardiograph signals of the human body through the lead electrodes 12.

After the acquisition component acquires the electrocardiosignals, the electrocardiosignals can be transmitted to the transmission component 23, the portable data acquisition device 2 for acquiring the electrocardiosignals of the human body is provided by the transmission embodiment of the application, the data acquisition component 22 of the portable data acquisition device 2 can acquire the electrocardiosignals of the human body based on the lead electrode 12, so that the electrocardiosignals are transmitted to the data processing equipment by the transmission component 23, a user does not need to go to a hospital to perform electrocardio monitoring, and the electrocardio monitor does not need to directly perform the electrocardio monitoring on the human body.

In one possible implementation, the portable data collector 2 may be small in size to be carried around by a user, for example, it may have a flat box-like structure in appearance as shown in fig. 7, and may have dimensions of 75mm × 75mm × 15mm in appearance. The shape of the casing 21 of the portable data collector 2 corresponds to the appearance of the portable data collector 2, each component in the portable data collector 2 is located in the casing 21, and the casing 21 is used for protecting the components in the portable data collector 2.

In one possible implementation, the power supply unit 24 is electrically connected to the data acquisition unit 22 and the transmission unit 23, respectively. The power supply unit 24 may include a battery and a management circuit, the battery is electrically connected to the management circuit, the management circuit is electrically connected to other components of the portable data collector 2, for example, the management circuit is electrically connected to the collection unit and the transmission unit 23.

The battery may be a rechargeable battery, such as a lithium battery, and the portable data collector 2 further includes a charging interface 26, and a charging opening is disposed on the housing 21 at a position corresponding to the charging interface 26; the power supply unit 24 is used for connecting to a data line via the charging interface 26. As shown in fig. 8, the housing 21 is provided with a charging opening at a position corresponding to the charging interface 26. In one possible implementation, the charging interface 26 includes at least one of a universal serial bus Type C (USB Type-C) interface, a MIcro (MIcro) USB interface, a lightning (lightning) interface, and a 30pin interface, where the pin means a pin.

In one possible implementation, the portable data collector 2 further comprises a lead wire interface 25, and the data collecting part 22 is used for connecting with the lead wire 13 through the lead wire interface 25. Wherein, a lead wire connecting opening 211 is disposed on the housing 21 corresponding to the lead wire interface 25. In one possible implementation, the lead Interface 25 is a High Definition Multimedia Interface (HDMI) Interface. In a possible implementation manner, one end of the lead wire 13 is connected with a plurality of lead electrodes 12, and the plurality of lead electrodes 12 are used for performing electrocardiographic detection on different lead positions of a human body to obtain electrocardiographic signals.

The lead wire interface 25 and the charging interface 26 are located on the same side of the housing 21, and the charging interface 26 is in a shielding state when the lead wire interface 25 is connected to the lead wire plug 14.

In one possible application, in order to avoid danger caused by the user performing electrocardiographic measurement while charging the portable data collector 2, correspondingly, as shown in fig. 8, the lead wire connection opening 211 and the charging opening are located on the same side of the housing 21, the distance between the lead wire connection opening 211 and the charging opening is smaller than a target value, and when the lead wire plug 14 matched with the lead wire interface 25 is inserted into the lead wire interface 25, the charging interface 26 is shielded by the lead wire plug 14.

The specific size of the target value is related to the size of the lead wire plug 14, for example, when the size of the lead wire plug 14 is small, the target value is also small, when the size of the lead wire plug 14 is large, the target value may be slightly larger, and the specific value of the target value may be determined by a technician according to the actual size of the lead wire plug 14.

In an implementation, in order to realize that when the lead wire plug 14 is inserted into the lead wire interface 25, the charging interface 26 is shielded by the lead wire plug 14, accordingly, the size of the lead wire plug 14 is relatively large, the charging opening is relatively close to the lead wire connection opening 211, and the distance between the charging interface 26 corresponding to the charging opening and the lead wire interface 25 corresponding to the lead wire connection opening 211 is relatively close, so that when the lead wire plug 14 is inserted into the lead wire interface 25, the charging opening is shielded by the lead wire plug 14. Another possible mode is that the lead wire plug 14 may include a conductor 141 as shown in fig. 9, and when the conductor 141 of the lead wire plug 14 is inserted into the lead wire interface 25, a portion between the conductor 141 of the lead wire plug 14 and the end of the lead wire 13 may block the charging interface 26, so that when the lead wire plug 14 is inserted into the lead wire interface 25, the charging interface 26 is blocked by the lead wire plug 14.

Thus, when the user charges the portable data collector 2, and the charging plug of the power adapter of the portable data collector 2 is inserted into the charging interface 26, the plug of the data line inserts the lead wire plug 14 into the lead wire interface 25, so as to cause interference, and further, the lead wire plug 14 cannot be inserted into the lead wire interface 25 to measure the electrocardiosignals. When the user inserts the lead wire plug 14 into the lead wire interface 25, the lead wire plug 14 will block the charging interface 26, so that the charging plug of the power adapter cannot be inserted into the charging interface 26. Therefore, the portable data acquisition device 2 cannot be charged and subjected to electrocardio measurement at the same time, so that danger caused by the electrocardio measurement when the user charges the portable data acquisition device 2 can be avoided, and the use safety of the portable data acquisition device 2 can be improved.

In a possible implementation manner, the process of sending the electrocardiographic signal by the transmission component 23 can include two manners: the sending is performed in real time and after buffering, and the embodiment of the application does not limit which sending method is specifically adopted.

For real-time transmission, the transmission component 23 is configured to execute the step of transmitting the acquired electrocardiographic signal to the data processing device when the electrocardiographic signal is acquired.

As shown in fig. 10, for sending after buffering, the portable data collector 2 further includes a storage component 28, the storage component 28 is located in the housing 21, and the storage component 28 is electrically connected to the data collecting component 22, the transmission component 23, and the power supply component 24 respectively. The storage component 28 is configured to cache the acquired electrocardiographic signals, and the transmission component 23 is configured to send the electrocardiographic signals cached in the target duration to the data processing device every target duration. The storage component may be electrically connected to the acquisition component and the power component 24, respectively.

In a possible application, the portable data acquisition device 2 can send the electrocardiographic signals acquired by the acquisition component to the computer device in real time through the transmission component 23, and can also store the electrocardiographic signals acquired by the acquisition component first and send the stored signals to the data processing device according to a certain period. In the former case, the acquisition unit of the portable data acquisition unit 2 may transmit the electrocardiographic signal to the transmission unit 23 after acquiring the electrocardiographic signal, and the transmission unit 23 transmits the electrocardiographic signal. In the latter, the period may be, for example, 1 second, and the electrocardiographic signals acquired by the acquisition means may be stored in the storage means 28, and the acquired electrocardiographic signals of one second are transmitted to the transmission means 23 every second, and transmitted by the transmission means 23.

The storage unit 28 may be a micro Secure Digital TF card, which is a short for Trans-flash card and is a micro SD (Secure Digital) card.

In one possible implementation, the housing 21 includes a first housing 213, a first housing 214 and a middle shell 215, the first housing 213 and the first housing 214 are fixed on the middle shell 215, and the first housing 213 and the first housing 214 are opposite to each other. The lead wire connection opening 211 and the charging opening are located on the middle case 215.

As shown in fig. 7 and with reference to fig. 8, the first housing 213 and the first housing 214 may be fixed to the middle shell 215, respectively, or the first housing 213 may be integrally formed with the middle shell 215 and the first housing 214 may be fixed to the middle shell 215, or the first housing 214 may be integrally formed with the middle shell 215 and the first housing 213 may be fixed to the middle shell 215, and so on. Therefore, the portable data acquisition device 2 has a compact structure, a small and exquisite appearance, is convenient for a user to carry, and improves the use universality.

For the data acquisition component 22, the data acquisition component 22 is used to electrically connect with the lead electrode 12, so as to acquire the electrocardiographic signal of the user. In practice, the internal circuit configuration of data acquisition component 22 is associated with the lead architecture used therewith, e.g., data acquisition component 22 may be compatible with one or more of 3-lead, 5-lead, 12-lead, and 18-lead architectures. In order to avoid noise interference affecting the measurement results.

In one possible implementation, the data acquisition component 22 may include an analog front-end chip, a filter circuit for filtering the acquired data, and an electrostatic protection circuit, wherein the influence of static electricity on the result of the electrocardiogram measurement can be avoided through the filter circuit. The electrostatic protection circuit is used for performing electrostatic protection on the portable data acquisition device 2. The interference of noise, static electricity and the like on the acquired electrocardiosignals can be avoided through the electrostatic protection, and the accuracy of the portable data acquisition device 2 for measuring the electrocardiosignals can be further improved. For example, the analog front end chip may be an ADS1298IPAGR analog front end chip. The filter circuit may be an RC filter circuit.

In a possible implementation manner, the portable data collector 2 and the data processing device may be connected in different manners, and specifically, the transmission component 23 is configured to send an electrocardiographic signal to the data processing device, and may include at least one of a bluetooth component or a WIFI (Wireless Fidelity) component. That is, the connection mode between the portable data collector 2 and the data processing device may be bluetooth connection or wireless network connection. The transmission unit 23 of the portable data collection unit 2 may, when in operation, first establish a communication connection with the data processing device to transmit the ecg signals based on the communication connection. Of course, the portable data collector 2 may also be connected to the data processing device through a data line, and the communication connection mode is not limited in this embodiment of the application.

In the above-mentioned mode of being connected with data processing equipment through wireless network, portable data collection station 2 can send the connection request to data processing equipment, is checked this portable data collection station 2 by data processing equipment, when checking and passing, sends the check to this portable data collection station 2 and passes, and then establishes communication connection between the two to data interaction.

In the above-mentioned mode of connecting through the bluetooth, portable data collection station 2 and data processing equipment can open the bluetooth function, and the user can select this portable data collection station 2 in data processing equipment's bluetooth matching list, and then, this data processing equipment sends bluetooth matching request to this portable data collection station 2, and this user confirms the operation in portable data collection station 2, and portable data collection station 2 sends the successful response of matching to data processing equipment, and then the two can establish communication connection. Of course, the user may also operate on the portable data collector 2, and then the portable data collector 2 sends a bluetooth matching request to the data processing device, and the data processing device sends a matching success response to the portable data collector 2.

In the above-mentioned mode of connecting through the data line, portable data collection station 2 and data processing equipment can carry out interface adaptation, and specifically, this portable data collection station 2 can write in the parameter of this portable data collection station 2's transmission interface in this data processing equipment, and then can with this data processing equipment between transmit electrocardiosignal through this transmission interface.

In one possible implementation manner, as shown in fig. 11, the portable data collector 2 further includes a sound collection component 30, the sound collection component 30 is located in the housing 21, and the sound collection component 30 is electrically connected to the transmission component 23 and the power supply component 24. The sound collection unit 30 is configured to collect a voice signal of a user based on a voice collection instruction. The transmission component 23 is also used to send the collected voice signal to the data processing device. In particular, the sound collection part 30 may include at least a microphone through which a voice signal of a user is collected. Therefore, if the user feels uncomfortable in the electrocardio monitoring process, the real feeling of the user can be conveyed to medical staff in a voice mode.

In this implementation, when the transmission unit 23 transmits the electrocardiographic signal, the acquired voice signal may be transmitted. Therefore, the electrocardio condition of the user can be obtained based on the electrocardiosignal, the real feeling of the user can also be obtained based on the voice signal, and the physical condition of the user can be more accurately judged by combining the electrocardiosignal and the voice signal. Specifically, the transmission method may adopt any one of the following methods:

firstly, the transmission component 23 is used for synchronously sending the electrocardiosignals and the voice signals collected in real time to the data processing equipment.

And in the second mode, the transmission component 23 is used for caching the acquired voice signals and sending the electrocardiosignals and the voice signals cached in the target duration to the data processing equipment every other target duration. It should be noted that the buffering step may be executed by the storage unit 28, so as to transmit the buffered voice signal to the transmission unit 23 for transmission.

And in a third mode, the transmission component 23 is configured to synchronously send the electrocardiographic signal and the voice signal acquired in the acquisition time period to the data processing device according to the acquisition time period of the voice signal. Therefore, the voice signal and the electrocardiosignal are completely synchronous, the correspondence between the voice signal and the electrocardiosignal can be improved, and the physical condition of the user can be more accurately obtained when the signals are analyzed.

In a possible implementation manner, the storage manner of the speech signal and the electrocardiographic signal may be a storage manner of a data block, the speech signal and the electrocardiographic signal may be stored in the data block, and the size of the data block is determined based on the number of bits and the sampling rate of the electrocardiographic signal and the speech signal. For example, each data block may store the cardiac signal and the voice signal collected within one second.

In a possible implementation manner, the portable data collector 2 may further have a signal processing function, and may send a processing result after processing the electrocardiosignal. As shown in fig. 12, the portable data collector 2 further includes a processing component 29, the processing component 29 is located in the housing 21, and the processing component 29 is electrically connected to the data collecting component 22, the transmission component 23 and the power component 24 respectively. The processing component 29 is configured to analyze and process the acquired electrocardiographic signal to obtain an analysis and processing result corresponding to the electrocardiographic signal, and the transmission component 23 is further configured to send the analysis and processing result to the data processing device.

For example, the processing part 29 internally includes a FATFS file system for generating a file based on the collected data. The processing component 29 of the portable data acquisition unit 2 has a simple processing function, can judge the received electrocardiosignals, and can remind the user in a flashing mode of the signal indicator lamp 27 if the electrocardiosignals are not in the corresponding threshold range so as to arouse the high attention of the user and enable the user to seek medical advice in time. Therefore, the user can directly obtain the physical condition of the user from the data processing equipment without carrying out electrocardiosignal processing steps by the data processing equipment or analyzing by medical personnel based on medical experience, and the processing efficiency of the electrocardiosignals is higher. And medical personnel can also more accurately analyze the physical condition of the user by combining the analysis and processing result and the electrocardiosignal.

In the embodiment of the present application, the portable data acquisition device 2 can analyze whether the electrocardiographic signal of the user is abnormal according to the normal waveform change rule of the electrocardiographic signal of the human body, and if the electrocardiographic signal is abnormal, the portable data acquisition device belongs to which common electrocardiographic abnormal condition, for example, the analysis processing may be arrhythmia analysis, ST analysis, atrial fibrillation and other analysis. Specifically, the processing unit 29 may perform the analysis processing procedure including filtering the electrocardiographic signal, positioning the QRS wave, and the like, and may further perform the electrocardiographic abnormality analysis on the electrocardiographic signal based on the positioning result of the QRS wave.

Specifically, the processing unit 29 is configured to perform the following steps one to three to implement an analysis process:

step one, filtering the electrocardiosignal.

The electrocardiographic signals acquired by the lead electrode 12 may include other waves in addition to the waves generated by the heart beating, and these waves may be regarded as interference to the electrocardiographic signals required by us, for example, power frequency interference of a data acquisition system, electrode polarization interference, myoelectric interference, baseline drift, and the like, so that the processing component 29 may filter the electrocardiographic signals first, and thus, based on the electrocardiographic signals after filtering, more accurate electrocardiographic conditions of the human body can be obtained.

Specifically, the filtering process may be implemented by a filter, for example, a high-pass filter, and the processing component 29 may input the electrocardiographic signal into the filter, and output the electrocardiographic signal in a certain frequency range, or filter the signal in a certain frequency range, where the certain frequency range may be set by a relevant technician according to the frequency characteristics of the electrocardiographic signal, and the filtered or reserved frequency range is not limited in the embodiment of the present application.

And step two, positioning the electrocardiosignals after filtering processing to obtain a positioning result of the QRS waves of the electrocardiosignals.

The QRS wave can reflect changes of the location and time of the left and right ventricular depolarization points, so that the processing unit 29 can locate the filtered electrocardiographic signal to obtain a location result of the QRS wave, and perform anomaly analysis on the electrocardiographic signal based on the location result.

The first downward wave is referred to as a Q wave, the upward wave is an R wave, and the second downward wave is an S wave. By positioning the electrocardiosignal in this way, whether the electrocardiosignal is abnormal or not can be analyzed according to the positioning result.

The positioning process can be realized in various ways, for example, a QRS wave positioning way based on a difference method can be adopted, amplitude and slope information of the filtered electrocardiosignals can be extracted, waveform fluctuation information is tracked according to an adaptive threshold, and a positioning result of the QRS wave is obtained. For another example, a QRS detection algorithm based on energy transformation and wavelet decomposition may be adopted, length and energy transformation may be performed on the filtered electrocardiographic signal, wavelet decomposition may be performed on the signal after energy transformation, and a positioning result of the QRS wave may be obtained.

And thirdly, carrying out electrocardio abnormity analysis on the electrocardiosignals based on the positioning result of the QRS wave to obtain the analysis processing result of the electrocardiosignals.

After the result of locating the QRS wave is obtained by the processing unit 29, the electrocardiosignal may be analyzed for abnormalities, such as whether or not an abnormality occurs in the heart rhythm of the user, and if so, what kind of abnormality occurs.

Specifically, the processing unit 29 may analyze abnormal problems that may occur to each electrocardiograph through the positioning result of the QRS wave, for example, may analyze whether the heart rhythm of the user is normal, whether the cardiac repolarization process is normal, and the like. In this third step, the processing unit 29 may perform at least one of the following two steps, namely step 3.1 and step 3.2, to perform anomaly analysis on the cardiac electrical signal.

Step 3.1, the processing unit 29 performs a heart rate analysis on the electrocardiographic signal based on the positioning result of the QRS wave to obtain a first analysis processing result of the electrocardiographic signal, where the first analysis processing result is used to indicate whether the heart rate of the electrocardiographic signal is normal or not and an abnormal type when the heart rate is abnormal.

And 3.2, analyzing the ST wave band of the electrocardiosignal by the processing part 29 based on the positioning result of the QRS wave to obtain a second analysis processing result of the electrocardiosignal, wherein the second analysis processing result is used for indicating whether the cardiac muscle repolarization process of the human body is normal.

The above two steps are merely exemplary illustrations of the processing unit 29 performing anomaly analysis, for example, arrhythmia, atrial fibrillation and other problems can be detected, and whether the cardiac repolarization process is normal, and the processing unit 29 can also perform other analyses on the cardiac signal, which can be set by a person skilled in the art according to the use requirement, and the embodiment of the present application is not limited thereto.

In a possible implementation manner, in the third step, the process that the processing unit 29 analyzes the positioning result of the QRS wave may be implemented by an electrocardiographic analysis model, and specifically, the processing unit 29 is configured to input the electrocardiographic signal and the positioning result of the QRS wave into the electrocardiographic analysis model, perform anomaly analysis on the electrocardiographic signal by the electrocardiographic analysis model, and output an analysis processing result of the electrocardiographic signal.

The electrocardiogram analysis model can be obtained by training based on a heart beat training set, and the heart beat training set can comprise a large number of electrocardiogram signals and corresponding analysis processing results. Specifically, a corresponding heartbeat training set can be established according to the data characteristics of the portable data acquisition device 2. For example, taking the portable data acquisition device 2 as a dynamic electrocardiograph recorder as an example, a training set of 6 thousands of heartbeats can be established according to the data characteristics of the dynamic electrocardiograph recorder.

In a specific possible embodiment, the electrocardiographic analysis model may be a Convolutional Neural Network (CNN) model, and the electrocardiographic analysis model extracts features of the input QRS wave, identifies the features, and outputs a classification result of the electrocardiographic signal, where the classification result is an analysis processing result of the electrocardiographic signal. In one possible implementation, the feature recognition algorithm may employ a PAN-TOMPKIN algorithm.

In a possible implementation manner, the above-mentioned electrocardiographic analysis model may further have a denoising function, and after the portable data acquisition device 2 inputs the electrocardiographic signal into the electrocardiographic analysis model, the electrocardiographic signal may be processed by the electrocardiographic analysis model according to the target noise level, so as to obtain the electrocardiographic signal from which the noise corresponding to the target noise level is removed. The processing unit 29 is further configured to process the electrocardiographic signal according to the target noise level by the electrocardiographic analysis model, so as to obtain the electrocardiographic signal from which the noise corresponding to the target noise level is removed. The target noise level may be set by a person skilled in the art according to requirements or experience, and the embodiment of the present application is not limited thereto. After the electrocardiosignal is subjected to noise preprocessing, the accuracy of subsequent identification can be effectively improved.

In a possible implementation manner, the portable data acquisition device 2 may perform statistics according to analysis processing results of the electrocardiographic signals acquired within a period of time, so as to obtain analysis processing results corresponding to the electrocardiographic signals within the period of time, and thus, may send the electrocardiographic signals acquired within the period of time and the corresponding analysis processing results to the data processing device. Specifically, the processing unit 29 is configured to analyze and process the electrocardiographic signals acquired in real time to obtain an analysis result corresponding to the electrocardiographic signal at each time, count the analysis results corresponding to the electrocardiographic signals at a plurality of times, and determine the analysis results corresponding to the electrocardiographic signals at the plurality of times according to the count result.

The division of the multiple moments can be set by related technical personnel according to requirements, that is, the duration of each statistic can be set by related technical personnel according to requirements, for example, the electrocardiosignal acquired within 5 minutes can be subjected to the statistics and sent, and the embodiment of the present application does not limit the statistics.

The data transmission process may further include any one of the following three cases:

in the first case, the processing unit 29 analyzes and processes the acquired electrocardiographic signal and transmits an analysis result corresponding to the electrocardiographic signal to the data processing device.

In the second case, the processing unit 29 analyzes and processes the acquired electrocardiographic signal and transmits the acquired electrocardiographic signal and an analysis result corresponding to the electrocardiographic signal to the data processing device.

And thirdly, the processing component 29 analyzes and processes the acquired electrocardiosignals and controls the state of the target indicator lamp 27 according to the analysis and processing result, and the extinguishing state and the lighting state of the target indicator lamp 27 are used for indicating the normality or abnormality of the electrocardiosignals.

In the first and second cases, the processing unit 29 may analyze and process the cardiac electrical signal, so as to transmit the analysis and processing result to the data processing device, but the cardiac electrical signal is not transmitted in the first case, so that the medical staff can directly know the physical condition of the user from the analysis and processing result. In the second case, the electrocardiosignal and the analysis processing result are synchronously sent, so that medical personnel can more accurately analyze the physical condition of the user according to the electrocardiosignal and the analysis processing result.

In the third case, the portable data collector 2 may be provided with one or more indicator lights 27, and the number of the indicator lights 27 may be one or more, for example, the normal and abnormal states of the physical condition of the user may be indicated by the turning-off and turning-on of one indicator light 27. For another example, which abnormal state the user is currently in may be indicated by the turning off and on of the plurality of indicator lamps 27. For another example, the one or more indicator lights 27 may also be used to indicate the connection status of the lead electrodes 12, and when the connection of one lead electrode 12 fails, the indicator light 27 or the indicator light 27 corresponding to the lead electrode 12 in the plurality of indicator lights 27 is turned on.

Specifically, the portable data acquisition device 2 further includes at least one indicator lamp 27, the at least one indicator lamp 27 is electrically connected to the data acquisition component 22 and the power supply component 24, respectively, and the state of the at least one indicator lamp 27 is used to indicate whether the lead electrodes 12 are acquiring an electrocardiographic signal, or indicate the accuracy of acquiring an electrocardiographic signal by the lead electrodes 12, or indicate the working state of the portable data acquisition device 2.

One or more indicator lamps 27 can be further installed on the portable data acquisition device 2 to indicate whether the electrocardiosignal is abnormal or not according to the analysis processing result. For example, an indicator lamp 27 may be installed, and when the analysis processing result indicates an abnormal cardiac signal, the portable data acquisition device 2 may control the indicator lamp 27 to light up. For another example, a plurality of indicator lights 27 may be installed, and when the analysis processing result indicates an abnormality in the electrocardiographic signal, the portable data acquisition unit 2 may control, according to the type of the abnormality in the analysis processing result, the indicator light 27 corresponding to the type of the abnormality among the plurality of indicator lights 27 to be turned on.

For example, an indicator lamp 27 may be installed, and when the analysis processing result indicates an abnormal cardiac signal, the portable data acquisition device 2 may control the indicator lamp 27 to light up. For another example, a plurality of indicator lights 27 may be installed, and when the analysis processing result indicates an abnormality in the electrocardiographic signal, the portable data acquisition unit 2 may control, according to the type of the abnormality in the analysis processing result, the indicator light 27 corresponding to the type of the abnormality among the plurality of indicator lights 27 to be turned on.

In one possible application, one or more indicator lights 27 are mounted on the housing 21, each indicator light 27 being electrically connected to the processing component 29 and the power component 24, respectively. Wherein one or more indicator lights 27 are mounted on the housing 21, for example, and may be heat staked to the center housing 215.

In implementations, the indicator light 27 may be a signal indicator light 27, a power indicator light 27, or an antenna indicator light 27. For example, all of the one or more indicator lights 27 may be the signal indicator light 27, the power indicator light 27, or the antenna indicator light 27, and for example, the one or more indicator lights 27 may also have one or two or three of the power indicator light 27, the signal indicator light 27, and the antenna indicator light 27.

The signal indicator lamp 27 can be used for indicating whether the acquired electrocardiosignals are abnormal or not. The power indicator light 27 may be used to indicate the current charge condition of the power supply unit 24. The antenna indicator lamp 27 may be used to indicate whether the transmitting part 23 is currently capable of transmitting data or the like.

In one possible embodiment, the one or more indicator lights 27 includes a power indicator light 27, and the brightness of the power indicator light 27 may be linear with the power of the power component 24. Specifically, when the amount of electricity in the power supply section 24 is sufficient, the brightness of the power supply indicator lamp 27 is strong; when the power supply section 24 has a small amount of power, the power indicator lamp 27 has a weak brightness. Or, the power supply indicator 27 may be turned on, turned off, or the like, to determine the power condition of the power supply unit 24, specifically, when the power supply unit 24 has sufficient power, the power supply indicator 27 is in a normally on state; when the power supply section 24 has a small amount of power, the power indicator lamp 27 is in a blinking state; in the case where the power supply unit 24 is not powered or the amount of power is particularly low, the power indicator lamp 27 is in an off state.

In one possible embodiment, the one or more indicator lights 27 include a plurality of power indicator lights 27, and the number of lights emitted by the power indicator lights 27 may be related to the amount of power supplied by the power component 24. For example, when the power supply unit 24 has a high capacity, the power indicator lamp 27 is fully lighted; when the electric quantity of the power supply part 24 is moderate, half of the power supply indicator lamps 27 emit light, and the other half of the power supply indicator lamps 27 are in an off state; when the power supply section 24 has a low capacity, one of the power supply indicator lamps 27 is in a light-on state, and the remaining power supply indicator lamps 27 are in an off state.

It can be seen that after the user starts the portable data collector 2, the current electric quantity condition of the power supply part 24 can be judged through the current state of the power supply indicator lamp 27, and then the portable data collector 2 can be charged in time, so as to avoid delaying the normal use of the user. The user charges portable data collection station 2 in time, has also protected portable data collection station 2, can avoid power supply unit 24 to last work under the low-power condition, and then can prolong portable data collection station 2's life.

In one possible application, the one or more indicator lights 27 may include a signal indicator light 27, and the signal indicator light 27 may be used to indicate whether the acquired cardiac electrical signal is abnormal. Specifically, when the user uses the electrocardiograph monitor and the portable data acquisition unit 2 to measure the electrocardiographic condition, each lead electrode 12 corresponds to one electrocardiographic signal, if a lead electrode 12 is not attached to the corresponding lead position, the processing unit 29 can detect that the electrocardiographic signal corresponding to the lead electrode 12 is far from the electrocardiographic signal under normal conditions, that is, the electrocardiosignal corresponding to the lead electrode 12 is abnormal, and at this time, the processing unit 29 can control the signal indicator lamp 27 to flash, to alert the user that, based on the flashing of signal indicator light 27, each lead electrode 12 can be examined, and in turn, when the portable data acquisition device 2 is used for carrying out electrocardio measurement and the operation is wrong, the signal indicator lamp 27 can remind the user, so that the effectiveness of the electrocardio measurement result is enhanced.

In a possible application, the one or more indicator lights 27 may include an antenna indicator light 27, and the antenna indicator light 27 may be used to indicate whether the transmission component 23 is capable of transmitting data currently, for example, if the portable data collector 2 is in a good connection state with a computer device, the antenna indicator light 27 is in a lighting state after the portable data collector 2 is started, and if the portable data collector 2 is in a starting state and the antenna indicator light 27 is in a turning-off state, it indicates that a problem occurs in the connection state between the portable data collector 2 and the computer device, so as to draw attention of a user and enable the user to perform a corresponding operation.

In one possible implementation, the status of the indicator light 27 may include turning on or off, or blinking or long-lighting, or color, etc., for example, when the power is low, the color of the power indicator light 27 may be red, and when the power is charged, the color of the power indicator light 27 may be blue, which is only an exemplary illustration. The above states can be set by the relevant technical personnel according to the requirements, and the embodiment of the application does not limit the setting.

In one particular example, three indicator lights 27 may be included: a signal indicator light 27, a power indicator light 27, and a wireless indicator light 27. The three indicator lights 27 may be different colors. For example, the power indicator 27 may be yellow in color, the signal indicator 27 may be green in color, and the wireless indicator 27 may be blue in color. Wherein, power indicator 27 is used for instructing the electric quantity of this portable data collection station 2, and signal indicator 27 is used for instructing the operating condition of this portable data collection station 2, and this wireless indicator 27 is used for instructing the network connection state of this portable data collection station 2.

In a specific example, when the power key 31 of the portable data collector 2 is pressed for a long time, the three indicator lights 27 turn off after being turned on, and then the signal indicator light 27 flashes to indicate that the portable data collector 2 is normally operated after being started. If lead electrode 12 is dropped, signal indicator light 27 will flash rapidly. When the power of the portable data collector 2 is low, the power indicator lamp 27 flashes, and when the portable data collector 2 is in a charging state, the power indicator lamp 27 is on for a long time. When the portable data collector 2 is fully charged, the power indicator 27 is turned off, and the signal indicator 27 is turned on. If this portable data collection station 2 is connected with data processing equipment through WIFI, wireless indicator 27 flickers, if this portable data collection station 2 is connected with electrocardio application, this wireless indicator 27 flickers. The battery capacity of the portable data collector 2 can be continuously used for 24 hours after being fully charged. Therefore, the user can be subjected to electrocardio detection for a long time, and the detected data is more accurate.

In one possible implementation, the portable data collector 2 may work normally under certain circumstances, for example, the working conditions may include environmental conditions, humidity conditions, and pressure conditions. In one specific example, the operating conditions of the portable data collector 2 may be: the environment temperature is plus 5-plus 45 deg.c, the relative humidity is 10-95%, no condensation is included, and the atmosphere pressure is 860-1060 hPa. It should be noted that this is merely an example, and the operating conditions may have a certain error from the above conditions, and this is not limited in the embodiments of the present application.

In one possible implementation, the data acquisition component 22, the transmission component 23 and the power supply component 24 are integrated on a circuit board, and the circuit board is connected with the first shell 213 and the middle shell 215 through screws; the first housing 214 is fixedly connected to the middle housing 215 by a snap-fit.

When the portable data collector 2 further comprises a storage component 28 and a processing component 29, the storage component 28 and the processing component 29 can also be integrated on the circuit board, and the electrical connection is realized through a flat cable on the PCB circuit board.

In one possible implementation manner, the portable data collector 2 further comprises a power key 31, the power key 31 is mounted on the housing 21, and the power key 31 is electrically connected to the power component 24. In one possible implementation, the first housing 214 is fixedly connected to the power key 31 and the at least one indicator light 27 of the portable data collector 2 by means of hot riveting. In the electrical connection relationship, the power key 31 is electrically connected to the processing part 29 and the power part 24, respectively.

The power key 31 is used to start and close the portable data collector 2, and the power key 31 may be a touch key disposed on the housing 21. The power key 31 may also be a mechanical key, and an opening is provided on the housing 21 at a position corresponding to the power key 31, and the power key 31 may be installed in the opening.

In a possible embodiment, the portable data collector 2 may have a display component thereon, and the processing component 29 may control the display component to display the measurement result. In order to reduce the processing function of the portable data acquisition device 2, correspondingly, after the electrocardiosignal is acquired by the portable data acquisition device 2, the electrocardiosignal is uploaded to a computer device, the computer device performs operations such as judgment, display and the like on the electrocardiosignal, in order to realize data transmission, the portable data acquisition device 2 may further include a transmission component 23, the transmission component 23 is located in the housing 21, and the transmission component 23 is electrically connected with the processing component 29 and the power supply component 24 respectively.

In one possible implementation manner, as shown in fig. 13, a sound playing part 32 may be further mounted on the portable data collector 2, and the sound playing part 32 may be electrically connected to the power supply part 24 and the collecting part. In particular, the sound playing part 32 may be a speaker. The portable data collector 2 can control the sound playing part 32 to make a sound according to the analysis processing result to alarm. The sound playing part 32 is used for alarming according to the analysis processing result. That is, when the analysis processing result indicates that the electrocardiographic signal is abnormal, the portable data acquisition unit 2 may control the sound playing unit 32 to make a sound. In another possible implementation manner, the sound playing part 32 is used for alarming according to the acquisition condition of the electrocardiograph signal. For example, when the electrocardiosignal acquisition is abnormal, an alarm can be given, so that the user can adjust the installation state of the portable data acquisition unit 2 in time.

The data acquisition device that this application embodiment provided includes electrocardio monitoring clothing and portable data collection station, and this electrocardio monitoring clothing is including clothes body and a plurality of electrode of leading, wherein: the plurality of lead electrodes are all installed on the clothes body, each lead electrode is matched with the corresponding human body lead position, and the lead electrodes are electrically connected with the portable data acquisition unit. The user can wear the electrocardio monitoring clothes, and the lead electrode on the electrocardio monitoring clothes can be in contact with the human body lead position of the user due to the fact that the position of the lead electrode on the clothes body is matched with the human body lead position, and the user can carry out electrocardio measurement by opening the portable data acquisition device. The data acquisition device is used for measuring the electrocardio condition, the operation is simple, a professional doctor is not required to paste the lead electrodes on the body of a user in a one-to-one correspondence manner, the heart rate measurement is not limited by occasions, and further, the electrocardio monitoring garment is wide in application occasions and high in flexibility.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A data acquisition device is characterized by comprising an electrocardio monitoring coat (1) and a portable data acquisition unit (2), wherein,

the electrocardio monitoring coat (1) comprises a coat body (11) and a plurality of lead electrodes (12) arranged on the coat body, wherein each lead electrode (12) is matched with the corresponding human body lead position;

the portable data acquisition unit (2) is electrically connected with the plurality of lead electrodes (12) through lead wires (13).

2. The data acquisition device according to claim 1, wherein the garment body (11) is provided with positioning holes (111) at positions corresponding to the leads of the human body, and the positioning holes (111) are matched with the corresponding lead electrodes (12).

3. The data acquisition device as claimed in claim 1, wherein the electrocardiograph monitoring garment (1) further comprises a plurality of lead wires (13);

the lead wires (13) are arranged on the clothes body (1), and each lead electrode (12) is electrically connected with at least one lead wire (13);

all the lead wires (13) are converged, and the end parts far away from the corresponding lead electrodes (12) are accommodated in a lead wire plug (14).

4. The data acquisition device according to claim 1, wherein the electrocardiograph monitoring garment (1) further comprises a tree-shaped lead wire fixing body (15), the lead wire fixing body (15) is installed on the garment body, a lead wire (13) between each lead electrode (12) and the portable data acquisition unit (2) is positioned in the lead wire fixing body (15), and the lead electrodes (12) connected with the lead wires (13) are installed on the garment body (11) through the lead wire fixing body (15);

wherein, lead fixed body of line (15) and include the dabber body (151) and a plurality of dabber body (152), every dabber body (152) is connected on the dabber body (151), installs at least one in every dabber body (152) lead line (13), all lead line (12) converge in the dabber body (151), at least one lead line (13) are followed the dabber body (151) extend to the position department that lead electrode (12) the place that corresponds.

5. The data acquisition device according to claim 1, characterized in that the clothes body (11) is provided with a receiving bag (112) adapted to the portable data acquisition unit (2), and the portable data acquisition unit (2) is located in the receiving bag (112); the garment body (11) comprises an inner liner (113) and an outer layer (114), wherein the outer layer (114) is matched with the inner liner (113) and is arranged on the inner liner (113); the portable data collector (2) and the lead electrodes (12) are arranged on the lining (113), and the portable data collector (2), the lead electrodes (12) and the lead wires (13) are arranged between the lining (113) and the outer layer (114).

6. The data acquisition device according to claim 1, wherein the portable data acquisition device (2) comprises a housing (21), a data acquisition component (22), a transmission component (23) and a power supply component (24), the data acquisition component (22), the transmission component (23) and the power supply component (24) are located in the housing (21), the power supply component (24) is respectively electrically connected with the data acquisition component (22) and the transmission component (23), the data acquisition component (22) comprises a lead wire interface (25), and a lead wire connection opening (211) is arranged on the housing (21) corresponding to the lead wire interface (25).

7. The data acquisition device according to claim 6, characterized in that the portable data collector (2) further comprises a charging interface (26); a charging opening (212) is formed in the position, corresponding to the charging interface (26), of the shell (21); the lead wire interface (25) and the charging interface (26) are located on the same side of the shell (21), and the charging interface (26) is in a shielding state when the lead wire interface (25) is connected with the lead wire plug (14).

8. The data acquisition device according to claim 6, characterized in that the housing (21) comprises a first housing (213), a second housing (214) and a middle shell (215);

the first shell (213) and the second shell (214) are fixed on the middle shell (215), and the first shell (213) and the second shell (214) are opposite in position;

the lead wire connection opening (211) and the charging opening (212) are both located on the middle case (215).

The data acquisition component (22), the transmission component (23) and the power supply component (24) are integrated on a circuit board, and the circuit board is connected with the first shell (213) and the middle shell (215) through screws; the second shell (214) is fixedly connected with the middle shell (215) through self-buckling.

9. The data acquisition device according to claim 1, wherein the portable data acquisition device (2) further comprises at least one indicator light (27), the at least one indicator light (27) is electrically connected to the data acquisition component (22) and the power supply component (24), respectively, and the state of the at least one indicator light (27) is used for indicating whether the lead electrodes (12) are acquiring electrocardiosignals, or indicating the accuracy of the lead electrodes (12) in acquiring electrocardiosignals, or indicating the working state of the portable data acquisition device (2).

10. The data acquisition device according to claim 6, wherein the portable data acquisition device (2) further comprises a storage component (28), the storage component (28) is positioned in the housing (21), and the storage component is electrically connected with the data acquisition component (22), the transmission component (23) and the power supply component (24), respectively;

the portable data acquisition device (2) further comprises a processing component (29), the processing component (29) is positioned in the shell (21), and the processing component (29) is electrically connected with the data acquisition component (22), the transmission component (23) and the power supply component (24) respectively;

the portable data collector (2) further comprises a sound collection component (30), the sound collection component (30) is located on the shell (21), and the sound collection component (30) is electrically connected with the transmission component (23) and the power supply component (24).

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