CN221285758U - Wearable dynamic electrocardiograph acquisition equipment - Google Patents

Abstract

The utility model discloses wearable dynamic electrocardiograph acquisition equipment, belongs to the technical field of electrocardiograph acquisition, and solves the problems that electrocardiograph acquisition equipment is inconvenient to use for patients and poor in experience in the prior art. The wearable dynamic electrocardiograph acquisition equipment comprises a lead assembly, an electrocardiograph acquisition assembly and an electrode plate, wherein the lead assembly is connected with the electrocardiograph acquisition assembly, and the electrode plate is respectively connected with the lead assembly and the electrocardiograph acquisition assembly; when in use, the electrode plate is placed at the position to be detected of a human body for electrocardiographic acquisition. The wearable dynamic electrocardiograph acquisition equipment does not obstruct the daily actions of the patient, and the electrocardiograph acquisition assembly of the wearable dynamic electrocardiograph acquisition equipment is small in size and light in weight, and the electrocardiograph acquisition assembly and the electrode sheet are attached to the chest, so that discomfort is not caused to the patient, and the experience of the patient is good.

Description

Wearable dynamic electrocardiograph acquisition equipment

Technical Field

The utility model belongs to the technical field of electrocardiograph acquisition, and particularly relates to wearable dynamic electrocardiograph acquisition equipment.

Background

Along with the development of dynamic electrocardiograph monitoring technology, in clinic, dynamic electrocardiograph is widely used for recording the continuous dynamic electrocardiograph activity process for 24 hours or more in the daily life state of a patient, and analyzing and processing are carried out by a computer so as to find arrhythmia, myocardial ischemia and the like which are not easy to find in conventional body surface electrocardiograph examination, and provide important objective basis for clinical diagnosis, treatment and judging curative effect.

In order to facilitate people to monitor the physical condition at any time, some medical instrument companies develop different wearable electrocardio acquisition devices at present, but the following defects generally exist: most wearable acquisition devices adopt a structure mode of a single lead and a 12-lead 10 electrode to acquire signals; because the single lead has only 2 electrodes, the acquired signal data is required to be very accurate, otherwise, the judgment of a doctor can be influenced, and in the actual operation process, the acquired data can be interfered because a patient wearing the collector can not walk, and the clinical diagnosis of the doctor is influenced; the accuracy of data acquired by adopting a 12-lead 10-electrode or 3-lead 5/7-electrode structure mode meets the requirements, but the daily activities of patients are affected, and the experience is poor; the reason is that 10 lead wires of the 12-lead collecting device are led out from the collecting device, the tail ends of the 10 lead wires (or 5/7 lead wires of the 3 leads) of the 12 leads are connected with a plurality of corresponding electrodes attached to the upper body of a patient, the lead wires are more and can obstruct the daily actions of the patient, in addition, the collecting device is larger, the weight is more than 100g, the collecting device is provided with a matched hanging and packing machine, and then the collecting device is hung on the waist or put into a trouser pocket, so that the daily life of the patient is influenced, and inconvenience is caused to the patient.

Disclosure of utility model

The utility model aims to provide wearable dynamic electrocardiograph acquisition equipment, which solves the problems that electrocardiograph acquisition equipment is inconvenient to use for patients and experience is poor in the prior art.

In order to achieve the above purpose, the technical scheme of the utility model is realized as follows: the wearable dynamic electrocardiograph acquisition device comprises a lead assembly, an electrocardiograph acquisition assembly and an electrode plate, wherein the lead assembly is connected with the electrocardiograph acquisition assembly, and the electrode plate is respectively connected with the lead assembly and the electrocardiograph acquisition assembly; when in use, the electrode plate is placed at a position to be detected of a human body for electrocardiographic acquisition.

In some embodiments, the lead assembly includes four leads and a lead wire, the number of leads arranged corresponding to the number of leads arranged; and the electrocardio acquisition assembly is respectively connected with the four lead parts through four lead wires.

In some embodiments, the lead assembly further comprises a male connector, the electrocardiograph acquisition assembly is connected with one ends of four lead wires through the male connector, and the other ends of the four lead wires are connected with the lead piece.

In some embodiments, the electrocardiograph acquisition component comprises an upper shell component and a lower shell component, wherein the upper shell component comprises an upper shell, a wire and a key, wherein the wire and the key are arranged in the upper shell, one end of the wire is connected with the key, and the other end of the wire is connected with the lower shell component.

In some embodiments, the lower shell assembly comprises a lower shell, a metal snap fastener and a main control board, wherein the metal snap fastener and the main control board are arranged in the lower shell, the other end of the wire is connected with the main control board, the metal snap fastener is arranged on the main control board and is connected with the main control board, and the electrode plate is connected with the metal snap fastener.

In some embodiments, the lead member is a lead snap that is connected to the electrode tab.

In some embodiments, the upper housing assembly further comprises a key pad disposed on the key.

In some embodiments, the upper housing assembly further comprises a light guide post connected to the lower housing assembly.

In some embodiments, the lower housing assembly further comprises a female connector that is connected with the main control board.

In some embodiments, the lower housing assembly further comprises a power source, the power source being connected to the main control board.

In some embodiments, a bluetooth module and a warning module are further arranged in the lower shell, and the main control board is respectively connected with the bluetooth module and the warning module.

Compared with the prior art, the wearable dynamic electrocardiograph acquisition equipment does not obstruct the daily actions of a patient, and the electrocardiograph acquisition assembly of the wearable dynamic electrocardiograph acquisition equipment is small in size and light in weight, and the electrocardiograph acquisition assembly and the electrode sheet are attached to the chest, so that discomfort is not caused to the patient, and the experience of the patient is good.

Drawings

Fig. 1 is a schematic structural diagram of a wearable dynamic electrocardiograph acquisition device according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of a lead assembly and an electrocardiograph acquisition assembly of a wearable dynamic electrocardiograph acquisition device according to an embodiment of the present utility model;

Fig. 3 is an exploded schematic view of an electrocardiograph collection assembly of the wearable dynamic electrocardiograph collection device according to an embodiment of the present utility model.

In the figure, 1, lead assembly, 11, lead member, 12, lead wire, 13, male connector, 2, electrocardiograph acquisition assembly, 21, upper shell assembly, 211, upper shell, 212, wire, 213, key, 214, key pad, 215, light guide post, 22, lower shell assembly, 221, lower shell, 222, metal snap fastener, 223, main control board, 2231, connector, 224, female connector, 225, power source, 3, electrode pad.

Detailed Description

The present utility model will be described in further detail with reference to specific embodiments in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

In the description of the present utility model, it should be clearly understood that terms such as "vertical", "horizontal", "longitudinal", "front", "rear", "left", "right", "upper", "lower", "horizontal", and the like indicate an orientation or a positional relationship based on that shown in the drawings, and are merely for convenience of describing the present utility model, and do not mean that the apparatus or element referred to must have a specific orientation or position, and thus should not be construed as limiting the present utility model. In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1, the wearable dynamic electrocardiograph acquisition device provided by the embodiment of the utility model comprises a lead assembly 1, an electrocardiograph acquisition assembly 2 and an electrode sheet 3, wherein the lead assembly 1 is connected with the electrocardiograph acquisition assembly 2, and the electrode sheet 3 is respectively connected with the lead assembly 1 and the electrocardiograph acquisition assembly 2; when in use, the electrode plate 3 is placed at the position to be detected of a human body for electrocardiographic acquisition.

More specifically, the electrocardio acquisition component 2 has the length of 50mm, the width of 50mm, the thickness of less than or equal to 15mm and the weight of less than or equal to 30g, and the electrocardio acquisition component 2 has the advantages of small size and light weight.

After the scheme is adopted, the wearable dynamic electrocardiograph acquisition equipment does not obstruct the daily actions of a patient, and the electrocardiograph acquisition component 2 of the wearable dynamic electrocardiograph acquisition equipment is small in size and light in weight, the electrocardiograph acquisition component 2 and the electrode sheet 3 are attached to the chest, so that discomfort is not caused to the patient, and the experience of the patient is good.

In the specific implementation process of this embodiment, as shown in fig. 1, the lead assembly 1 includes four lead members 11 and lead wires 12, and the number of the lead wires 12 corresponds to the number of the lead members 11; the electrocardiograph acquisition component 2 is respectively connected with four lead pieces 11 through four lead wires 12.

More specifically, the wearable dynamic electrocardiograph acquisition device adopts a 3-lead 5-electrode mode to acquire signals, the lead wire 12 does not obstruct the daily actions of a patient, meanwhile, the lead wire 12 is prevented from being arranged in the human body clothes, the acquisition device is arranged outside the clothes, a plurality of inconveniences are caused to the patient, the number of the lead wires 12 is reduced, and the acquired data accuracy is met.

In a specific implementation process of this embodiment, as shown in fig. 2, the lead assembly 1 further includes a male connector 13, and the electrocardiograph acquisition assembly 2 is connected to one ends of four lead wires 12 through the male connector 13, and the other ends of the four lead wires 12 are connected to the lead member 11.

More specifically, in this embodiment, the central electric acquisition component 2 is connected with one ends of the four lead wires 12 through the male connector 13, so that the connection between the electrocardiograph acquisition component 2 and the lead component 1 is more stable, and meanwhile, the electrocardiograph acquisition component is not easy to fall off in the walking process of a patient.

In a specific implementation process of this embodiment, as shown in fig. 3, the electrocardiograph collection assembly 2 includes an upper shell assembly 21 and a lower shell assembly 22, the upper shell assembly 21 includes an upper shell 211, and a wire 212 and a key 213 disposed in the upper shell 211, one end of the wire 212 is connected to the key 213, and the other end of the wire 212 is connected to the lower shell assembly 22.

In a specific implementation process of this embodiment, as shown in fig. 3, the lower shell assembly 22 includes a lower shell 221, a metal snap fastener 222 and a main control board 223 disposed in the lower shell 221, the other end of the conductive wire 212 is connected with the main control board 223, the metal snap fastener 222 is disposed on the main control board 223 and connected with the main control board 223, and the electrode plate 3 is connected with the metal snap fastener 222.

More specifically, the wires 212 may be flexible flat cables, the keys 213 may be FPC soft keys, and the keys 213 perform functions of starting up and shutting down; the soft flat cable and the FPC soft keys reduce the friction with the skin of a patient, so that the comfort of the patient is improved when the patient uses the soft flat cable and the FPC soft keys; the soft flat cable is connected with the FPC soft key, the other end of the soft flat cable is connected with the main control board 223 in the lower shell 221, the main control board 223 is provided with a connector 2231, and the other end of the soft flat cable is connected with the connector 2231; the lower shell component 22 is provided with a metal snap fastener 222, the metal snap fastener 222 is connected with the electrode plate 3, the electrode plate 3 can be a general electrode plate on the market, and can be customized according to the requirement and can be matched with the metal snap fastener 222, and the metal snap fastener 222 transmits electrocardiograph data measured by the connected electrode plate 3 to the main control board 223.

In a specific implementation of this embodiment, as shown in fig. 2, the lead member 11 is a lead button, and the lead button is connected to the electrode sheet 3.

More specifically, the lead piece 11 is a lead snap fastener, the lead snap fastener is connected with the electrode slice 3, the electrode slice 3 can be a general electrode slice on the market, and can be customized according to the requirement and can be matched with the lead snap fastener, and the lead snap fastener transmits electrocardiographic data measured by the connected electrode slice 3 to the main control board 223 through the lead wire 12; in this embodiment, four lead buttons are connected with four electrode plates 3, metal buttons 222 are connected with 1 electrode plate 3 to form 3 lead 5 electrodes, signals are collected in the mode of 3 lead 5 electrodes, the number of lead wires 12 is reduced, and collected data accuracy is met.

In a specific implementation process of this embodiment, as shown in fig. 3, the upper shell assembly 21 further includes a key pad 214, and the key pad 214 is disposed on the key 213.

More specifically, the key pad 214 is disposed on the key 213 to protect the key 213 and reduce friction to the skin of the patient, thereby enhancing the feeling of experience.

In a specific implementation of this embodiment, as shown in fig. 3, the upper shell assembly 21 further includes a light guide pillar 215, and the light guide pillar 215 is connected to the lower shell assembly 22.

More specifically, the light guide pillar 215 is connected with the main control board 223 in the lower shell assembly 22, and the light guide pillar 215 displays the on-off state of the key 213, so that the patient can observe the on-off state of the equipment when using the equipment.

In a specific implementation of this embodiment, as shown in fig. 3, the lower shell assembly 22 further includes a female connector 224, where the female connector 224 is connected to the main control board 223.

More specifically, the connection of the male connector 13 with the female connector 224 transfers the data collected by the electrode sheet 3, which is snap-connected to the lead, to the main control board 223.

In a specific implementation of this embodiment, as shown in fig. 3, the lower shell assembly 22 further includes a power supply 225, where the power supply 225 is connected to the main control board 223.

More specifically, the lower housing assembly 22 further includes a power supply 225, the power supply 225 is connected to the main control board 223, and the power supply 225 provides power for the keys 213 and the light guide columns 215 connected to the main control board 223.

In the specific implementation process of this embodiment, a bluetooth module and a warning module are further disposed in the lower housing 221, and the main control board 223 is connected with the bluetooth module and the warning module respectively.

More specifically, the main control board 223 may be further connected to a bluetooth module and an alarm module, where the bluetooth module may be connected to a terminal device, and perform data transmission and control on the electrocardiograph acquisition component 2; the warning module monitors that the electrocardiograph acquisition data of the patient is abnormal, can upload electrocardiograph acquisition data to the terminal equipment and warn the patient in a mode of combining alarm or lamp flashing or alarm and lamp flashing, reminds the patient, and can remind doctors when uploading the data to the terminal equipment.

The working flow provided by the embodiment of the utility model is as follows: the electrode plate 3 connected by the metal snap fastener 222 and the lead snap fastener is arranged at a patient to be tested, the 4 lead wires 12 are connected with the electrocardio acquisition component 2, the 5 electrode plates 3 are arranged at the patient to be tested to form 3 lead 5 electrodes to carry out electrocardio acquisition on the patient, the patient can press the key 213 to start the electrocardio acquisition component 2 to carry out electrocardio data acquisition, after the data acquisition is completed, the key 213 is pressed again to close, in the working process of the equipment, the light guide column 215 is lightened, the alarm module alarms when the data has an abnormal alarm, the electrocardio acquisition component 2 and the electrode plate 3 of the equipment are all attached to the chest, discomfort is not caused to the patient, meanwhile, the problem that the lead wires 12 are in the clothes of the human body is avoided, and the acquisition equipment is inconvenient to the patient outside the clothes is avoided.

In summary, the wearable dynamic electrocardiograph acquisition device adopts the 3-lead 5-electrode mode to acquire signals, the lead wire 12 does not obstruct the daily actions of the patient, the electrocardiograph acquisition component 2 of the wearable dynamic electrocardiograph acquisition device is small in size and light in weight, the electrocardiograph acquisition component 2 and the electrode sheet 3 are attached to the chest, discomfort is not caused to the patient, the lead wire 12 is prevented from being arranged in the clothes of the human body, the acquisition device is arranged outside the clothes, a plurality of inconveniences are caused to the patient, and the experience of the patient is good.

The present utility model is not limited to the above-mentioned embodiments, and any changes or substitutions that can be easily understood by those skilled in the art within the technical scope of the present utility model are intended to be included in the scope of the present utility model. Therefore, the protection scope of the present utility model should be subject to the protection scope of the claims.

Claims (8)

1. The wearable dynamic electrocardio acquisition equipment is characterized by comprising a lead assembly (1), an electrocardio acquisition assembly (2) and an electrode sheet (3), wherein the lead assembly (1) is connected with the electrocardio acquisition assembly (2), and the electrode sheet (3) is respectively connected with the lead assembly (1) and the electrocardio acquisition assembly (2); when in use, the electrode plate (3) is placed at a position to be detected of a human body for electrocardiographic acquisition; the lead assembly (1) comprises four lead pieces (11) and lead wires (12), wherein the number of the lead wires (12) corresponds to the number of the lead pieces (11); the electrocardio acquisition assembly (2) is respectively connected with the four lead parts (11) through four lead wires (12); the lead assembly (1) further comprises a male connector (13), the electrocardio acquisition assembly (2) is connected with one ends of four lead wires (12) through the male connector (13), and the other ends of the four lead wires (12) are connected with the lead piece (11).

2. The wearable dynamic electrocardiograph acquisition device according to claim 1, wherein the electrocardiograph acquisition component (2) comprises an upper shell component (21) and a lower shell component (22), the upper shell component (21) comprises an upper shell (211), a wire (212) and a key (213) which are arranged in the upper shell (211), one end of the wire (212) is connected with the key (213), and the other end of the wire (212) is connected with the lower shell component (22).

3. The wearable dynamic electrocardiograph acquisition device according to claim 2, wherein the lower shell component (22) comprises a lower shell (221) and a metal snap fastener (222) and a main control board (223) which are arranged in the lower shell (221), the other end of the wire (212) is connected with the main control board (223), the metal snap fastener (222) is arranged on the main control board (223) and is connected with the main control board (223), and the electrode sheet (3) is connected with the metal snap fastener (222).

4. The wearable dynamic electrocardiograph acquisition device according to claim 2, characterized in that the upper shell assembly (21) further comprises a key pad (214), the key pad (214) being provided on the key (213).

5. The wearable dynamic electrocardiograph acquisition device according to claim 2, characterized in that the upper shell assembly (21) further comprises a light guiding column (215), the light guiding column (215) being connected with the lower shell assembly (22).

6. The wearable dynamic electrocardiograph acquisition device according to claim 3, characterized in that the lower shell assembly (22) further comprises a female connector (224), the female connector (224) being connected with the main control board (223).

7. The wearable dynamic electrocardiograph acquisition device according to claim 3, characterized in that the lower shell assembly (22) further comprises a power source (225), the power source (225) being connected with the main control board (223).

8. The wearable dynamic electrocardiograph acquisition device according to claim 6 or 7, wherein a bluetooth module and a warning module are further arranged in the lower shell (221), and the main control board (223) is respectively connected with the bluetooth module and the warning module.