RU197891U1 - HEART ACTIVITY SENSOR INTEGRATED WITH WEARABLE ACCESSORIES - Google Patents

Abstract

The utility model relates to medical equipment, namely, devices for monitoring heart activity. The device includes a sensor for measuring heart activity. The sensor for measuring heart activity is configured to perceive the electrical signals of the heart of the user, calculating heart activity data, wirelessly transmitting heart activity data to a receiving device. The sensor is connected to the first and second electrodes through the associated wires. The wires pass inside the cables. The first electrode is integrated with one accessory to provide contact with the skin of the user in the first place inside the area where the accessory is used by the user. The second electrode is configured to contact the skin of the user at a second location, the second location is different from the first location on the skin of the user. A convenient, cumbersome monitor of cardiac activity is provided, and reliability is increased when measuring the user's heart rate. 24 s.p. f-ly, 11 ill.

Description

Technical field

[0001] The present utility model relates to portable heart activity monitors, portable heart rate monitoring systems, portable electrocardiography systems, and the like. In particular, this description relates to an apparatus that integrates a cardiac measurement sensor integrated with wearable devices and accessories.

State of the art

[0002] Athletic activity is an important factor for many people in maintaining a healthy lifestyle. It is considered useful to track and record cardiac activity data especially during exercise. There are many instruments designed to monitor the activity of the human heart. For example, the most common device is a heart rate monitor, which includes a chest strap with two electrical contacts that create contacts on the user's chest and include a monitor for measuring a person’s heart rhythm. This type of heart rate monitor is considered uncomfortable by many users.

[0003] Other heart rate monitors include light-based technology. These heart rate monitors typically include a light source and a light detector. Light emanating from a source and directed through the user's skin is reflected back and perceived by the light receiver. An optical heart rate monitor measures the speed of blood flow through the veins and calculates the heartbeat. Optical heart rate monitors are typically integrated into wearable accessories such as watches, bracelets and headphones. One of the well-known drawbacks of optical heart rate monitors is the inaccuracy in measuring a person’s heart rate, especially in motion.

[0004] Electrocardiography devices are more accurate, but they are usually bulky, limited in mobility, or require the use of an additional device that is tightly attached to the user's chest. In addition, it was found that electrocardiography devices permanently attached to the user's chest are inconvenient to use. Accordingly, in this area there is still a need to improve heart rate monitors, provide them with greater reliability, are user friendly and integrate with existing wearable devices, fashion accessories and clothing.

SHORT DESCRIPTION

[0005] This section is presented to describe aspects and embodiments of this utility model in a simplified form, which are further described in the detailed description section of example embodiments. This short description is not intended to identify key features or essential features of the claimed subject matter of the utility model and is not intended to be used as an aid in determining the scope of the claimed subject matter of the utility model. Aspects of embodiment of the present utility model are intended to overcome at least some of the disadvantages known in the art.

[0006] In accordance with one aspect of the present utility model, a device for monitoring heart activity is provided. The device is a sensor, commonly called a heart rate monitor or HRM, that is integrated or attached to existing wearable accessories, fashion accessories, and clothing that a person wears. The heart control sensor uses an electrocardiogram (ECG) method with at least two electrodes attached to the skin.

[0007] Wearable devices and accessories that can be integrated with a heart activity sensor include, but are not limited to: earbuds with earbuds, earbuds attached to the ear or in front of the ear, and earphones with one ear, glasses, mask, visor, helmet, cap, hood, cap lining, bandage, bandana or swimming cap.

[0008] The heart activity monitoring system consists of at least one sensor and at least two electrodes connected to human skin. A sensor with electrodes can be integrated into an existing device, accessory or clothing, or be a standalone touch device. The sensor can detect an electrical signal generated by the heart muscles, calculate heart activity data, such as heart rate, heart rate variability and heart rate, and transmit it to a host device, such as a smartphone, watch, or other monitoring device, commonly called a receiving device. Then, the receiving device processes the signals, displays and stores data on cardiac activity.

[0009] Additional objects, advantages, and new features of the examples will be set forth in part in the following description and will in part become apparent to those skilled in the art after studying the following description and the attached drawings, or may be studied in the manufacture or operation of the examples. The objects and advantages of concepts can be realized and achieved using methodologies, tools, and combinations that are specifically noted in the attached utility model formula.

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] Practical, but not limiting embodiments of the utility model are shown in the accompanying drawings, in which similar elements are shown as links and in which:

[0011] Fig. 1 is a view illustrating a block diagram of a heart activity monitoring system;

[0012] Fig. 2A illustrates one embodiment of a heart activity monitoring sensor integrated with a wireless headset;

[0013] Fig. 2B illustrates another embodiment of a heart activity monitoring sensor integrated with a wireless headset;

[0014] Fig. 3A shows one use case of a headset with a heart activity monitoring sensor;

[0015] Fig. 3B shows another use case of a headset with a heart activity monitoring sensor;

[0016] Fig. 4A is a front view illustrating one example of how a user can use a headset with a heart activity monitoring sensor;

[0017] Fig. 4B is a rear view illustrating one example of how a user can use a headset with a heart activity monitoring sensor;

[0018] Fig. 4C is a front view illustrating one example of how a user can use a headset with a heart activity monitoring sensor;

[0019] Fig. 4D shows a rear view of a male user, illustrating one example of how a user can use a headset with a heart activity monitoring sensor;

[0020] Fig. 5A shows a left side view of a user, illustrating one example of how a user can use a heart activity monitoring sensor attached to the back of a cap;

[0021] Fig. 5B is a right-side view of a user, illustrating one example of how a user can use a heart activity monitoring sensor attached to the back of a cap;

[0022] Fig. 5C shows a detailed view of one embodiment of a heart activity monitoring sensor attached to the back of a cap;

[0023] Fig. 5D shows a left side view of a user, illustrating another example of how a user can use a heart activity monitoring sensor attached to the front of a cap;

[0024] Fig. 5E is a right-side view of a user, illustrating another example of how a user can use a heart activity monitoring sensor attached to the front of a cap;

[0025] Fig. 6A is a front view of a user illustrating one example of how a user may use a cap with a heart activity monitoring sensor;

[0026] Fig. 6B shows a rear view of a user, illustrating one example of how a user can use a cap with a heart activity monitoring sensor;

[0027] Fig. 7 illustrates a heart activity monitoring sensor integrated in a helmet;

[0028] Fig. 8A illustrates a heart activity monitoring sensor integrated in glasses;

[0029] Fig. 8B shows a front view of a user illustrating one example of how a user can use glasses with a heart activity monitoring sensor;

[0030] Fig. 8C shows a rear view of a user, illustrating one example of how a user can use glasses with a heart activity monitoring sensor;

[0031] Fig. 9 shows a heart activity monitoring sensor integrated with ski goggles;

[0032] Fig. 10 shows a heart activity monitoring sensor integrated with water glasses;

[0033] Fig. 11A shows a front view of a user illustrating one example of how a user can use a heart activity monitoring sensor integrated in a pendant chain; and

[0034] Fig. 11B shows a rear view of a user, illustrating one example of how a user can use a heart activity monitoring sensor integrated in a pendant chain.

DETAILED DESCRIPTION OF EXAMPLES OF IMPLEMENTATION OF A USEFUL MODEL

Introduction

[0035] The following detailed description of embodiments of the utility model includes links to the accompanying drawings, which are part of the detailed description. The approaches described in this section are not the prior art with respect to the utility model stated in the formula and cannot be included in the prior art by inclusion in this section. The drawings show illustrations in accordance with examples of practical implementation. These examples, which are also referred to herein as “examples,” are described in sufficient detail to enable those skilled in the art to practice the subject. Options may be combined, other options may be used, or structural, logical and operational changes may be made without departing from the scope of what is claimed. Therefore, the following detailed description should not be construed in a limiting sense, and the scope is determined by the accompanying claims and their equivalents.

[0036] Examples of a practical embodiment will be presented with reference to a headset or device for monitoring cardiac activity. This headset and device may be implemented using electronic equipment, computer software, or any combination thereof. The implementation of such examples in the form of hardware or software depends on the specific application and design constraints imposed on the overall system. For example, an element or part of an element, or any combination of elements, can be implemented using a “data processor”, which includes one or more microprocessors, microcontrollers, central processing units (CPUs), digital signal processors (DSPs), user-programmable gate arrays (PPVM), programmable logic integrated circuits (FPGAs), state machines, closed logic, discrete hardware circuits, and other suitable equipment configured to perform various functions described in this description. Data processing may be performed by software, firmware or middleware (collectively referred to as “software”). The term "software" in the broad sense refers to instructions, instruction sets, code, code segments, program code, programs, subprograms, software components, applications, software applications, software packages, objects, executable files, threads, procedures, functions, which may be referred to as software, firmware, middleware, microcode, hardware description language, or otherwise.

[0037] Accordingly, in one or more embodiments, the functions described herein may be implemented in hardware, software, or any combination thereof. If the functions are implemented in software, they may be stored or encoded in the form of one or more instructions or code on a non-readable readable medium. A computer-readable storage medium includes computer storage media. The storage medium may be any medium accessible by a computer. By way of example, and not limitation, such a machine-readable medium may comprise random access memory, random-access memory, read-only electrically erasable programmable memory, a magnetic storage disk, solid state memory, or any other storage device, combinations of the above types of computer-readable media, or any other medium that can be used to store executable code in the form of instructions or data structures that can be accessed by a computer.

[0038] For the purposes of this patent document, the terms "or" and "and" mean "and / or" unless otherwise indicated in the context of their use or expressly provided otherwise. The terms “consisting”, “consisting”, “includes” and “including” are used interchangeably and are not intended to be limiting. For example, the term “including” should be interpreted to mean “including, but not limited to.”

[0039] It should also be understood that the terms "first", "second", "third", etc. may be used herein to describe various elements. These terms are used to distinguish one element from another, but do not imply the required sequence of elements. For example, the first element can be called the second element, and, similarly, the second element can be called the first element, without going beyond the scope of this utility model. In addition, it should be understood that when an element is referred to as “connected” or “connected” or “paired” with another element, it can be directly paired or connected, or connected to another element or intermediate elements may be present. In contrast, when an element is called “directly on” or “directly connected” or “directly connected” to another element, there are no intermediate elements.

[0040] The term "receiving device" means any computing or electronic device with data processing and data transfer capabilities, including, but not limited to, a mobile device, cell phone, mobile phone, smartphone, Internet phone, user equipment, mobile terminal, tablet computer, laptop, desktop computer, workstation, thin client, personal digital assistant, multimedia player, navigation system, game console, portable computer, smartwatch, entertainment system, infotainment console, trip computer, bicycle computer or virtual reality device .

[0041] The term "headphone" should be construed to mean any device that can be placed in or near the user's outer ear in order to output audio signals or reduce noise. The term “earphone” also means any or all of the following meanings, or should be interpreted as meaning that one or more of the following elements are an element of the “earphone”: headphones, in-ear headphones, on-ear headphones, speaker, ear capsule, ear bud, hearing aid and an acoustic device in the ear.

[0042] The term "headset" is to be understood as a device including at least one earphone, or a device including at least one earphone and microphone. Thus, the headset can be made with either a single earphone (mono) or a dual earphone (mono on both ears or stereo). The term “headphones” is used here to mean a pair of headphones or speakers that are attached close to the user's ears. Examples of headphones may be covering, boosting, ear capsule, or in-ear headphones. In-ear headphones are small headphones, sometimes also called headphones, that plug into the ear canal or fit into the outer ear. Although the options for this description are limited to wired headphones, those with technical skills will appreciate that the same or similar options can be implemented using wireless headphones or a wireless headset.

[0043] The term "clothing" should be construed to mean any item of clothing worn on the user's body and in contact with the upper body of the user. Some examples of clothing include a T-shirt, T-shirt or pullover.

[0044] The term "heart activity" should be interpreted as meaning any vital, natural or biological activity of the human heart, including the heartbeat or electrical activity of the heart. The term "cardiac activity signal" means an analog signal characterizing the cardiac activity of the user. The term "data on cardiac activity" refers to any digital data characterizing the cardiac activity of the user. Some examples of a cardiac activity signal include, but are not limited to, an electrocardiogram (ECG) signal, a cardiac activity waveform, or a pulsed cardiac activity signal. Some examples of cardiac activity data include, but are not limited to, heart rate, heart rate per minute, heart rate variability, heart rate, or any other vital biometric data related to heart activity.

[0045] As indicated above, aspects of the implementation of this utility model provide a device for monitoring cardiac activity. In other words, variations of this utility model relate to integrating a cardiac measurement sensor into a headset or headset, hat or helmet, glasses, and other wearable accessories or clothing. A heart activity measurement sensor is typically configured to sensitize, detect or measure one or more cardiac activities of a user, generate cardiac activity data, and transmit cardiac activity data to a receiving device, such as a mobile phone or server for further processing, recording to memory, or output to the screen.

[0046] A heart activity measuring sensor consists of at least two electrodes configured to directly connect to a user's body. One electrode is placed inside the ear canal or fitted into the outer ear of the consumer, and establishes reliable electrical contact with the skin. Another electrode can be placed on the chest or under the arm, in the armpit, on the neck, shoulder, or on the back of the consumer. In some embodiments, a cardiac activity measurement unit may be included in the headset controller.

[0047] In another embodiment, the first electrode is placed inside a cap or helmet and makes reliable electrical contact with the skin of the forehead. The second electrode can be placed on the chest or under the arm, in the armpit, on the neck, shoulder or on the back of the user.

[0048] However, in another embodiment, the first electrode is placed inside the glasses on the nose holders and frame of the temple and establishes reliable electrical contact with the skin on the nose, on the temple and behind the ear. The second electrode can be placed on the chest or under the arm, in the armpit, on the neck, shoulder or back of the user.

[0049] In another embodiment, the first electrode is placed inside safety glasses on the eye pads and makes reliable electrical contact with the skin around the eye and temple. The second electrode can be placed on the chest or under the arm, in the armpit, on the neck, shoulder or back of the user.

[0050] And in another embodiment, the first electrode is placed inside a pendant hanging on the neck and makes reliable electrical contact with the skin on the chest. The second electrode may be placed on or around the user's neck.

[0051] The heart activity measuring unit may further comprise one or more sensors connected to the electrodes and configured to measure electrical signals captured by the electrodes and generated by the heart muscles, filter the ECG signal, process this ECG signal, calculate various ECG data from the heart, and transmit heart data to the receiving device.

Hardware Architecture

[0052] In the drawings, exemplary hardware architecture embodiments are described. The drawings are schematic illustrations of idealized embodiments. Thus, the implementation examples discussed herein should not be construed as being limited to the specific illustrations presented herein, but these implementation examples may include deviations and differ from the illustrations presented here.

[0053] In the figure. 1 is a block diagram showing an example of a heart activity monitoring device 100, also called a heart activity monitoring sensor, connected to a receiver via a wireless protocol such as Bluetooth, ANT +, ZigBee or another wireless protocol for measuring and recording human heart activity characteristics .

[0054] The sensor system 100 for monitoring the activity of the heart consists of two electrodes 103 and 105 connected to the sensor body 101 through electrical wires or electrically conductive polymers. Both electrodes 103 and 105 are connected to the input of a voltage amplifier (AC AMP) 109. The output signal of the AC AMP 109 is the amplified voltage between the two electrodes 103 and 105. The output of the AC AMP 109 is connected to the analog input of the microcontroller (MCU) 113. The MCU 113 processes the data voltage and calculates heart activity data. It stores the resulting data in a data warehouse 121, such as flash memory. The MCU 113 is connected to a wireless transmitter 107, such as Bluetooth, ANT +, ZigBee, or another wireless transmitter.

[0055] Modern integrated circuits (ICs) can have an MCU 113, an AMP 109, a transmitter 107 and a data storage 117 combined into a single IC or commonly referred to as a microchip. Battery 121 provides power for sensor 101. It may be a rechargeable battery or a disposable (non-rechargeable) battery.

[0056] The transmitter 107 may be wirelessly connected to the receiver 119 via a similar wireless transmitter 111 integrated in the receiver. The receiving device may be a mobile phone, watch, tablet, computer, or any other device capable of receiving wireless signals, processing, displaying, saving or relaying data to another device. A transmitter 107 can transmit signals so that multiple receivers can receive data simultaneously.

[0057] Fig. 2A illustrates one embodiment of a heart control sensor integrated in a wireless headset 200 in an ear. The headset consists of a left 205 and a right earphone, and a headset controller 223. The headset controller 223 comprises a battery (battery), a wireless transmitter, and audio control functions such as volume control and a multi-function programmable button. These features are commonly found in traditional headsets. In addition, the headset controller 223 contains components of a heart activity monitoring sensor, logically illustrated inside the sensor body 101 in FIG. 1. Some components, such as a battery, wireless transmitter, data storage, and MCU, can be used for two purposes: headset control and heart activity monitoring.

[0058] The earmolds 201 and 211 are made of an electrically conductive polymer such as latex, silicone or synthetic rubber with additives that allow electric current to pass through the low-resistance material. The liner can also be made of soft or spongy material with elements of electrical conductors in the material. The purpose of the insert is to fit neatly into the ear canal and establish reliable electrical contact with the skin. The earbuds 201 and 211 can be replaced and installed on the base 203 and 213 of the headphones. The base for the insert is made of a metal or electrically conductive material and is electrically connected to the insert in the ear. The base for the left earphone earbud 203 is connected to a wire 207, which then passes through the headphone assembly 205 into a cable 219. Cable 219 contains wires for the left earphone audio signal and an additional wire 207 used as an electrode for a heart activity monitoring sensor.

[0059] Similarly, the right earpiece has an electrically conductive insert 211 that is worn on the base 213 and connected via a wire 215 to the headset controller 223. The wire 215 is part of the cable 217, which also contains wires for the right sound of the headphones.

[0060] The headset controller 223 is connected to the right earphone 213 via cable 217 and to the left earphone 205 via cable 219. Both cables 217 and 219 contain wires 207 and 215 connecting the earbuds. These wires are connected in the headset controller 223 and are shown as the first electrode 103 in Fig. 1 to monitor heart activity.

[0061] The second electrode, shown as 105 in FIG. 1 is connected to the headset controller 223 via cable 225. Cable 225 is an insulated cable with one wire and has an electrical connector 227 at the end for connection to a second electrode. Connector 227 may be a clip, like a crocodile clip, hook, latch, or any other type of connector that makes a reliable electrical connection to the electrode. Cables 225 and 221 can be clamped or tied 229 to hold them together to prevent excessive hanging.

[0062] In another embodiment illustrated in FIG. 2B, the wireless headset may have a frame 235 with earbuds in the ear for the right ear 231 and for the left ear 233 made of an electrically conductive material such as a conductive polymer, latex or silicone. The earbuds 231 and 233 in the ear are connected through electrical wires inside the frame 235 to the headset controller 237. The wires connecting the two earbuds in the ear can be connected together in the headset controller 237 and shown as the first electrode 103 in Fig. 1. Cable 239 is used to connect the headset controller 237 via a connector 241 to the second electrode, which is also shown as 105 in Fig. 1. The headset controller 237 contains the heart control sensor components shown inside the sensor housing 101 in FIG. 1.

[0063] However, in another embodiment, the headset may contain only one earphone 213, shown in Fig. 2A, with a first electrode integrated in the earbud and connected to the headset controller 223 via a cable 217. The headset controller 223 is connected to the second electrode via a connector 227 and an electrode wire 225.

[0064] The headset can be made in various shapes and materials by connecting to one or two headphones. The shape can be in the form of a single headset with a speakerphone inserted in the ear. Regardless of the shape of the headset and the number of headphones, the principle of the utility model remains the same: one or both headphones provide electrical contact with the skin in or around the ear as the first electrode 103, as shown in Fig. 1. The second electrode is attached to the skin other than the ear, and connected to the connector 227 or 241 and shown as electrode 105 in Fig. 1.

[0065] The above description of the headset has focused on a heart activity monitoring system and does not include descriptions of several common components present in most headphones for transmitting audio signals. A traditional headset controller may have similar components as shown in fig. 1, such as MCU 113, AC AMP 109, transmitter 107 and data storage 117, which can be integrated into a single IC. For both functions, a common set of components can be used: sound transmission and monitoring of cardiac activity. The entire system with sound and a heart activity monitoring sensor can share one battery 121 and can be integrated into one housing.

Examples illustrating the use of a headset

[0066] In the figure. 3A shows one embodiment of using a wireless headset in the ear with a sensor to monitor the activity of the heart 300. The left earphone 303 with an electrically conductive insert 301 is installed in the ear canal. A cable 305 connects the earphone 303 to the headset controller 307. Cable 311 connects the headset controller 307 to the earpiece of the right ear. A cable 309 connects the headset controller 307 to the electrode wire 310 via a detachable connector 313. The cable 309 is a single-core insulated wire and has an electrical connector 313. The connector 313 may be a clip, such as a crocodile clip, a hook, a snap button, or other type of connector establishing reliable electrical contact with the electrode wire 310.

[0067] Another mounting option is shown in Fig. 3B. The headset controller 315 is connected via cable 319 to the electrode wire 325 through a removable connector 323. The electrode wire 325 is installed on the back of the user. A cable 317 connects the headset controller 315 to the earpiece of the right ear. Sliding clip 321 holds both cables 317 and 319 together to prevent excessive hanging.

[0068] The electrodes 310 and 325 may be a simple metal wire, a metal conductive chain hanging on the neck, or an electrically conductive necklace, strip of tape or cable made of an electrically conductive polymer. The wires of the electrodes 310 and 325 may have an electrical insulating coating, allowing the user to isolate certain parts of the second electrode from electrical contact with the skin of the user. Both electrodes may be partially insulated, subjecting only a small portion to electrical contact with the skin of the user, or may not be insulated at all.

[0069] The following four figures illustrate how electrodes 310 and 325 establish a reliable electrical connection with skin on a human body. Fig. 4A, fig. 4B, fig. 4C and fig. 4D illustrate options for wearing a wireless headset in the ear with a heart activity monitoring sensor and electrodes connected to different parts of the body for a man and a woman. The heart activity sensor uses clothing and other items that people wear to tightly connect the second electrode to the skin. Since men and women have different clothing accessories, electrodes use the features of each clothing.

[0070] As shown in FIG. 4A, women 400 usually wear a bra 407. Bras are designed for sports, recreation and everyday use. All bras have common attributes, such as a snug fit to the chest area, under the chest, under the armpits, and around the back. In one embodiment, the headset controller 401 also has an electrode connecting wire 403, which is further connected to the electrode wire 409. The wire 403 may use a specially designed connector to accommodate the matching connectors 313 or 323, as shown in Fig. 3. This can be a clip, such as a crocodile clip, hook, latch, or other type of connector, making reliable electrical contact with the electrode wire 409.

[0071] The electrode wire 409 may be installed under the shoulder strap of the bra and extended down under the chest 411, pressed tightly to the skin with the strap of the bra. The electrode cable 411 makes reliable electrical contact under the bra with the skin. The electrode wire 409 may be insulated in some parts, which allows electrical contact to be established in certain areas of the body. For example, in one embodiment, the electrode wire 409 is insulated under the shoulder strap and only makes electrical contact under the chest 411.

[0072] In another embodiment, the wire of electrode 409 is insulated under the shoulder strap and makes electrical contact with the armpit. It does not extend to the chest 411. However, in another embodiment, the electrode wire 409 is not insulated at all and creates electrical contact under the shoulder strap.

[0073] A rear view of the device integrated with the headset is shown in Fig. 4B. A cable 405 connects both ears to audio and electrode wires.

[0074] Although the electrode wire 409 is designed for a separate element from the bra 407, it can be sewn, glued or welded inside the shoulder strap and under the chest of the bra or integrated into the fabric of the bra. Regardless of the design of the electrode cable, the principle of the utility model remains the same: the electrode uses a bra as a tool to press it firmly against the skin to establish a reliable electrical connection.

[0075] Fig. 4C and fig. 4D illustrates another possibility of how a person can carry a device. A 450 man usually wears clothing, such as a shirt, or tight-fitting clothing, especially when playing sports. As shown in fig. 4C, the right earphone 415 and the left earphone 417 are connected to the headset controller 421 via the right 425 and left 419 cable. A cable 423 connects the headset controller 421 to the electrode cable 431 via the connector 427. The connector 427 may be a clip, like a crocodile clip, hook, latch, or other type of connector that makes reliable electrical contact with the electrode wire 431. The connector 427 can also be attached to clothing on the collar to prevent the electrode cable from hanging out when the user is in motion.

[0076] Fig. 4D illustrates a rear view of a person 450 with a device. The electrode wire can be stretched under the armpit to the back of a person 435, and then fixed to the collar of the clothes 433.

[0077] The electrode wire 431 and 435 provides a reliable electrical connection to the armpit. To prevent the electrode cable from dangling when a person is moving, the electrode wire can be fixed to the clothing collar using a clip 427, and then to the back with a clip 433. The clamps provide sufficient tension on the electrode cable 431 so that it is pressed tightly against the skin by an armpit for reliable electrical connection.

[0078] In another embodiment, the electrode wire 431 may make electrical contact with the skin on the chest or on the back. In this embodiment, the electrode wire 431 cannot be attached to clothes or fixed at only one point 427 or 433 to prevent dangling. However, in another embodiment, the electrode wire 431 can be sewn, glued, pasted or welded into clothing, making reliable electrical contact on the human body: on the neck, chest, armpit, or on the back.

[0079] There are many other mounting options for the electrode cable 409, 411, 431 and 435. Regardless of the mounting options for the electrode cable for a male or female, the principle of the utility model remains the same: the first electrode establishes a reliable electrical connection to the skin in one or both ears through earmolds or headphones, while the second electrode establishes a reliable electrical connection with the skin in other parts of the body in order to measure the electrical signals generated by the heart. The first electrode is integrated with the earbud of the headphone. The second electrode may be made in the form of an electric wire, an electrically conductive polymer cable, strip or strip. The second electrode can be attached to clothing to establish a reliable connection with human skin, where the electrical connection can be of the best quality, such as armpit skin, under the female breast and between the female breast, neck, shoulder, chest and back of the user.

Examples illustrating the use of a cap

[0080] In the figure. 5A and Fig. 5B shows a heart control sensor integrated in a cap 500. In one embodiment, shown in FIG. 5A, a heart activity sensor 511 is attached to the back of the cap 501. Contact 503 is mounted on the inner lining of the cap 507. A second contact 523 can be mounted on the inner lining of the cap. Both contacts are connected by an electric wire 505 and 525, as shown in Fig. 5B. When the cap 501 is worn by a person, the lining of the cap with contacts 503 and 523 is pressed against the skin of the forehead. On the inner lining of the cap, additional contacts can be installed for better contact with the skin at several points on the forehead. All contacts are connected through an electric wire 505 and 525. Then contact 523 is connected via an electric cable 521 to a heart activity monitoring sensor 511 mounted on the back strap of the cap 527. Cable 521 can be fixed between the inner gasket of the cap and the outer part of the cap. Cable 521 is connected to the first contact of the sensor electrode 511, which is also logically illustrated as electrode contact 103 in Fig. 1.

[0081] The connection of the second electrode is created by the contact 513 connected to the sensor 511 via an electric cable 509, which is also shown as the second electrode 105 in Fig. 1. The electrode wire 515 is connected to the second electrode contact with a metal latch 513 and extends along the shoulder and back of a person 519 to connect to the skin. To prevent dangling while driving, cable 515 can be attached to collar 517 through a clip, such as a crocodile clip, button, hook, or latch.

[0082] In the figure. 5C shows one embodiment of a heart activity monitoring sensor 530 as a removable sensor 531 attached to a cap back strap 533, also shown as 527. Sensor 531 is attached to a cap back strap 533 through two metal snap buttons 543 and 545. The latch 545 is connected to the electric cable 535 or 521 on the right side. A latch 543 is connected to the second electrode via an electric cable 537, also shown as 509 on the left side of the head, and a metal latch 541, also shown as 513 on the left side. The second wire of the electrode 515 is connected to the latch 513.

[0083] In the figure. 5D and fig. 5E shows another embodiment of a heart control sensor attached to a cap 550. A sensor 551 shown on the left and a sensor 567 shown on the right can be attached to the front of the cap 555 using metal buttons 553 and 569. The first electrode connected via a snap button 569 to the conductive strip 565. The conductive strip 565 is made of an electrically conductive polymer and is mounted on the inner lining of the cap. Lane 565 makes electrical contact with the skin on the forehead. The second button 553 is connected to an electric cable 557 attached between the inner cap gasket and the outer side of the cap. Cable 557 is connected to a metal latch 561 mounted on the outside of the cap. The electrode wire 563 is attached to the connector 561 as a metal latch and drops down the shoulder under the clothes onto the back of the user.

[0084] Fig. 6A and fig. 6B illustrate one of many options for wearing a cap 600 with the proposed heart activity monitoring sensor. A heart activity monitoring sensor 601, attached to the back of the cap, is connected to the electrode wire 605 through a connector 603. The electrode wire 605 extends down to the shoulder and further under the clothes along the back of the user. The electrode wire 605 may be secured to the collar 607 using a latch or clip, such as a crocodile clip, to prevent the cable 609 from hanging out during movement. Then, the electrode wire 609 may extend along the back of the user with the armpit 611, and then extend along the chest to the collar in front 613. The electrode wire may be attached to the collar 613 with a clip hook or snap-fit button to prevent excessive dangling when moving.

[0085] Mounting options for the second electrode cable for male and female are also shown in Fig. 4A, fig. 4B, fig. 4C, Fig. 4D, fig. 5A, fig. 5B, fig. 6A and fig. 6B. These mounting options are also applied to the electrode wire connected to the heart control sensor on the cap, as shown in all the illustrations in fig. 5 and fig. 6.

Helmet examples

[0086] In the figure. 7 shows a heart activity monitor integrated with a bicycle helmet 700. In one embodiment, the sensor is integrated with a bicycle helmet 701. The sensor 709 can be attached to the back of the helmet with two metal snap buttons similar to those shown in fig. 5A and Fig. 5B. The first electrode is connected by an electric cable 707 to the conductive gaskets 703 on the left and right side of the helmet. The conductive pads are connected on both sides by cable 705. The pads 703 are mounted so that when they put on the helmet, they make close contact with the skin of the forehead. Gaskets 703 may be made of metal or a conductive polymer and attached to the inside of the helmet, which is worn over the forehead when worn. The second electrode is connected via cable 711 to a metal latch 713 on the back of the helmet. The second wire of electrode 715 can be attached by means of a metal snap button 713 to the helmet and lowers down to the back of the user who wears it.

Mounting options for the second electrode cable for a man and a woman are shown in Fig. 4A, fig. 4B, fig. 4C, Fig. 4D, fig. 5A, fig. 5B, fig. 6A and fig. 6B. These mounting options can also be applied to the electrode cable connected to the heart control sensor on the helmet, as shown in fig. 7. The heart rate sensor can also be integrated with other helmets for skiing, snowboarding and other activities similar to the bicycle helmet shown in fig. 7.

Examples illustrating the use of glasses

[0087] In the figure. 8A shows a heart activity sensor 800 built into the glasses 801. A heart activity sensor 813 can hang on a cable 809 attached to the glasses 801 and can also be attached to a clothing collar 821. Two cables 813 can be attached to the electrodes via connectors 811 and 815. The first wire of the electrode 809 is attached to the sensor 813 using a connector 811. The wire of the electrode 809 is installed inside or near the frame of glasses 805, then along the upper frame of the glass 803 and is connected to the nose holders 807. The nose holders 807 are made of electrically conductive polymer and provide electrical contact with the skin under the nasal pads. The electrode wire 805 can be mounted on the frame of the glasses so that it establishes additional contact with the skin around the temples and behind the ears.

[0088] The second wire of the electrode 817 is connected to the heart activity monitoring sensor 813 using a metal snap button 815. The second wire of the electrode 817 can be installed under the clothing collar from the back of the user 819 under the armpit, and then along the chest 825. The second wire of the electrode 817 can be fixed on clothing on the collar 821 and on the front on the collar 823 with a hook, a clip such as a crocodile clip, a clip or a latch to prevent the cable 819 from hanging when moving.

[0089] In the figure. 8C shows how the first electrode wire can be

mounted on both sides of the frame of glasses 830. The left wire of the electrode 839 and the right wire of the electrode 845 are installed through both temples of the glasses. Cables 839 are also shown as 809 in fig. 8A. Both cables of the electrodes 839 and 845 are connected to the sensor 841 monitoring the activity of the heart through the connector 847. The second wire of the electrode is connected to the sensor 841 with the connector 849. The second wire of the electrode creates reliable contact with the skin under the armpit and on the back 843.

[0090] In the figure. 8B shows a front view of a user who wears glasses 830. The second electrode wire is mounted under the armpit and front 837 and is attached to clothing 835. The front view also shows where the first electrode connects through the nose holders 833 and the frame of the glasses 831.

[0091] Mounting options for the second electrode cable for male and female are shown in Fig. 4A, fig. 4B, fig. 4C, Fig. 4D, fig. 5A, fig. 5B, fig. 6A and fig. 6B. These mounting options are also applied to the electrode cable connected to a heart control sensor attached to the glasses, as shown in fig. 8A, fig. 8B and fig. 8C.

Examples illustrating the use of glasses for sports

[0092] In the figure. 9 shows a heart control sensor 900 combined with ski goggles 901. A heart activity sensor 915 can hang on a cable 911 attached to goggles 901, and can also be attached to underwear collar 927. Two wires of the electrode are attached to the sensor 915 through connectors 913 and 917. The first wire of the electrode 911 is electrically connected to the sensor 915 with the connector 913. The first wire of the electrode 911 is attached by a connector 907 mounted on the goggle strap 909. The connector 907 is electrically connected to the first contact strips 903 and 931 of the electrodes through the electrode cables 905 and 929. The contact strips 903 and 931 are made of electrically conductive material and are embedded in the inner pads of the glasses 901. The inner pads of the goggles with contact strips 903 and 931 are pressed against the forehead and cheekbones of the user's face and establish a reliable electrical connection with the skin.

The second wire of the electrode 919 is connected to the sensor 915 with a connector 917. The second wire of the electrode 919 is installed through the clothing collar to the back of the user 921, then passes through the armpit and stretched in front along the chest 923. The second electrode wire can be attached to the clothes on the collar 925 and 927 using a hook, clip, such as a crocodile clip, clasp, or latch to prevent cable from dangling while moving. For a person with technical knowledge, it is clear that other glasses can be connected to a heart control sensor in the same way with some options.

[0094] Mounting options for the second electrode cable for male and female are shown in Fig. 4A, fig. 4B, fig. 4C, Fig. 4D, fig. 5A, fig. 5B, fig. 6A and fig. 6B. These installation options are also used for an electrode cable connected to a heart activity monitoring sensor attached to safety glasses, as shown in Fig. 9.

Examples illustrating the use of swimming goggles

[0095] In the figure. 10 shows a heart activity monitoring sensor 1000 combined with swimming goggles 1001. A heart activity monitoring sensor 1011 can be attached to the back of a swimming goggle strap using a pair of sealed connectors 1009 and 1013. The first wire of electrode 1007 is electrically connected to connector 1009, which is connected to the first input of the sensor electrode 1011. At the other end, the electrode wire 1007 is electrically connected to the contact strips 1003 and 1027 of the electrodes through a spacer 1005. The contact strips 1003 and 1027 are made of electrically conductive material and are embedded in the inner cushion of the goggles. Pads of glasses with conductive strips 1003 and 1027 are pressed to the skin around the eyes and establish a reliable electrical connection with the skin.

[0096] The second wire of the electrode 1015 is electrically connected to a connector 1013, which is also electrically connected to the second input of the sensor electrode 1011. The second wire of the electrode 1015 can be attached to the swimmer’s back with a special suction cap 1017 or a waterproof self-adhesive pad or tape. The second electrode establishes a reliable electrical connection with the swimmer’s skin at the attachment point 1017.

[0097] A variant of a woman dressed in a swimming suit with a built-in bra is similar to a variant of the device with a bra, as shown in Fig. 4A and fig. 4B. 4. A man can also wear a full swimming suit with shoulder straps. Therefore, in another embodiment shown in fig. 10, the second wire of the electrode 1023 can be attached under the shoulder strap 1019 of the swimming suit and makes reliable electrical contact with the skin on the shoulder, chest and armpit. The second wire of the electrode 1023 is electrically connected by a connector 1013 to a transmitter 1011.

Examples illustrating the use of pendant and chain

[0098] In the figure. 11A and Fig. 11B shows a heart control sensor 1100 combined with pendant 1101 and necklace 1111. A heart control sensor can be integrated into pendant 1101. The first electrode is integrated into pendant 1101 as an electrically conductive pad and connects to the skin of the chest and neck. The pendant can make contact with the skin on the chest with its own weight and under clothes. A woman can take advantage of attaching a pendant under a bra, as shown in fig. 11A. Pendant 1101 can be attached or tucked under the bra to prevent the pendant from falling out of the bra when the user is in motion. The second electrode may be connected by a transmitter 1101 through insulated wires 1103 and 1109, also used as a necklace. The contacts 1105 and 1107 establish reliable contact with the skin and are connected to the input of the second electrode to the sensor 1101 via electrically conductive wire internal cables 1103 and 1109. In addition, part of the necklace 1111 can also be used as the second electrode by making electrical contact with the back of the neck. This electrode 1111 may be a simple electrical wire, a metal conductive circuit, or an electrically conductive polymer and is connected to contacts 1105 and 1107.

[0099] Other designs with a heart activity monitoring sensor attached or integrated into wearable accessories or devices with electrodes connected to the skin using existing skin contact points can be used using this utility model. The above examples presented in fig. 2 - fig. 11 is not limited to the wearable devices or accessories described and the electrode connection options. In accordance with this utility model, any wearable device or accessory can be enhanced using the heart control sensor disclosed in this application, in which the first electrode is connected using specific features of the wearable device, equipment or clothing. The second electrode is connected (in contact) with the skin, different from the place of connection (contact) of the first electrode, and uses existing wearable devices, equipment or clothing for close contact with the skin. Both electrodes are connected to a heart activity monitoring sensor to measure heart activity using electrical signals received from two electrodes.

[00100] Thus, a cardiac monitoring device has been described with various mounting options for wearable accessories. Although embodiments have been described with reference to specific exemplary embodiments, it is obvious that various modifications and changes can be made to these exemplary embodiments without departing from the broader spirit and scope of the present application. Accordingly, the description and drawings should be considered in an illustrative rather than restrictive sense.

Claims (40)

1. Device for monitoring heart activity, including a sensor for measuring heart activity, configured to perceive the electrical signals of the heart of a user, calculating heart activity data, wirelessly transmitting heart activity data to a receiving device, in which the sensor measuring the activity of the heart is connected to at least the first electrode and the second electrode through the corresponding wires that pass inside the cables, in which the first electrode is integrated with one accessory so that when the user wears the accessory, the first electrode is in contact with the skin of the user in the first place inside the area where the accessory is used by the user, wherein the second electrode is configured to contact a user's skin at a second location, the second location is different from the first location on the user's skin. 2. The device according to claim 1, in which at least one accessory can be one of the following: earphone, headphones, headset, hat, cap, helmet, bandana, headpiece, glasses, ski goggles, swimming goggles, safety glasses, pendant , a necklace, while the accessory provides direct contact of the first electrode with the skin of the user. 3. The device according to claim 2, in which, when the accessory is a headphone or headset with at least one earphone, the accessory is configured to provide placement in / on the user's ear and provide audio output; wherein the first electrode is integrated with one earphone in such a way that when this earphone is located in / on the user's ear, the first electrode contacts the skin of the user in the first place in / on the user's ear, and the second electrode is configured to contact the skin of the user at a second location that is outside the user's ear. 4. The device according to claim 3, in which the earphone has an elastic earbud in the ear, the first electrode being integrated with the elastic earbud. 5. The device according to claim 3, in which the headphones or headset includes a first earphone and a second earphone, each earphone having an elastic earbud in the ear, wherein the first electrode is integrated or connected to the elastic earbud of the first earphone. 6. The device according to claim 2, in which, when the accessory is a headphone or headset that includes a first earphone and a second earphone, the accessory is configured to provide placement in / on the user's ear and provide audio output; wherein the first earphone has an elastic insert in the ear, the elastic insert includes an electrically conductive material and is the first electrode. 7. The device according to claim 3, in which the sensor measuring the activity of the heart is connected to the first, second and third electrodes. 8. The device according to claim 7, in which the headphones or headset includes a first earphone and a second earphone, each earphone having an elastic earbud in the ear, the first electrode being integrated with an elastic earphone of the first earphone, and in which the third electrode is integrated with an elastic earphone the insert of the second earphone. 9. The device according to claim 2, in which the sensor measuring the activity of the heart is connected to the first, second and third electrodes, the accessory is a headphone or headset that includes a first earphone and a second earphone, and the accessory is configured to provide placement in / on the ear user and audio output; moreover, each of the headphones has an elastic earbud in the ear, each of the elastic earbuds includes an electrically conductive material and is the first and third electrodes, respectively. 10. The device according to claim 3, in which the headphones or headset includes a first earphone and a second earphone, and in which a heart activity measuring sensor is included in the headset controller. 11. The device according to claim 10, in which the headset controller is connected to the first earphone through the first cable and to the second earphone through the second cable, wherein the first cable includes at least three wires insulated from each other, wherein one of the three wires of the first cable is connected to the first electrode, the second wire of the first cable is configured to transmit the first audio signal, and the remaining wire is a common negative wire, and in which the second cable includes at least two wires isolated from each other and configured to transmit a second audio signal. 12. The device according to claim 10, in which the sensor measuring the activity of the heart is connected to the first, second and third electrodes, in which the headset controller is connected to the first earphone through the first cable and to the second earphone through the second cable, in which the first cable includes three wires isolated from each other, wherein one of the three wires is connected to the first electrode, the second wire is configured to transmit the first audio signal, and the remaining wire is a common negative wire, and in which the second cable includes three wires insulated from each other, wherein one of the three wires is connected to the third electrode, the second wire is configured to transmit a second audio signal, and the remaining wire is a common negative wire. 13. The device according to claim 2, in which, when the accessory is a hat, cap, helmet, bandana, hat, goggles, ski goggles, swimming goggles or goggles, the accessory includes an elastic insert, the first electrode being integrated with an elastic insert, and the first electrode is in direct contact with the skin of the user. 14. The device according to claim 2, in which, when the accessory is a hat, cap, helmet, bandana, hat, glasses, ski goggles, swimming goggles or goggles, the accessory includes an elastic insert, the elastic insert includes a conductive the material is the first electrode, while the first electrode is in direct contact with the skin of the user. 15. The device according to claim 2, in which, when the accessory is a hat, cap, helmet, bandana, headgear, goggles, ski goggles, swimming goggles or goggles, the accessory includes a metal insert, the first electrode being integrated with a metal insert, and the first electrode is in direct contact with the skin of the user. 16. The device according to claim 2, in which, when the accessory is a pair of glasses or goggles, the first electrode is in direct contact with the skin on the nose of the user or with the skin of the temple, above the ear or behind the ear of the user. 17. The device according to claim 2, in which, when the accessory is a pair of goggles, ski goggles, swimming goggles or goggles, the first electrode is in direct contact with the skin around the user's eyes. 18. The device according to claim 2, in which, when the accessory is a pendant or necklace, the first electrode is in contact with the skin of the user in the first position in the chest region of the user, and the second electrode is made with the possibility of contact with the skin of the user in the second position on the neck and around the neck of the user or in the upper region of the chest of the user. 19. The device according to p, in which the pendant includes a first electrode integrated with the outer casing of the pendant, the first electrode being in direct contact with the skin in the chest region of the user. 20. The device according to claim 19, in which the first electrode is made in such a way that it is in contact with the skin of the user under the clothes, such as a shirt, tight-fitting clothes or a bra of the user. 21. The device according to any one of claims 2 to 20, in which the sensor for measuring heart activity includes a voltage amplifier, to the input of which electrodes are connected, the output signal of which is an amplified voltage between the first and second electrodes, a microcontroller connected to the output of the voltage amplifier and capable of processing the output signal from the voltage amplifier and calculate data on the activity of the heart. 22. The device according to any one of claims 2 to 20, in which the second electrode is made in the form of an electric wire, an electrically conductive polymer cable or strip. 23. The device according to item 22, in which the second electrode is placed in the cable of the electrode so that when the user uses the device, the second electrode is in contact with the skin of at least one part of the body selected from: chest of the user, neck of the user, shoulder of the user, back of the user . 24. The device according to item 23, in which the cable of the second electrode includes an electrical insulating coating that allows the user to isolate parts of the second electrode from electrical contact with the skin of the user in places not intended for contact with the second electrode. 25. The device according to paragraph 24, in which the cable of the second electrode is made in such a way that it is in contact with the skin of the user under clothing, such as a shirt, tight-fitting clothing or bra of the user.

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