RU225457U1 - SMART WATCH - Google Patents

Abstract

The utility model relates to electronics, namely to computerized wristwatches with extended functionality. A smart watch with a function for monitoring the user's health indicators, containing a case, a bracelet and sensors that monitor the user's health parameters, characterized in that the case is designed to be detachable from the bracelet and contains a processor, an accelerometer and grooves, the bracelet has a base platform on which latches are located and contact pads, sensors that monitor the user’s health parameters are located on the base platform of the bracelet; Moreover, when receiving a signal from the accelerometer about a change in the position of the body, the processor is configured to automatically rotate the image with the user’s health parameters at an angle that ensures alignment of the displayed information with the user’s field of view, and in the absence of a signal from the accelerometer, the body is configured to rotate in the plane of the base platform by an angle that ensures that the image with the user’s health parameters aligns with the user’s field of view. The technical result of the claimed utility model is the automatic combination of the display image with indicators of monitoring the user's health with the user's field of view during various manipulations performed by the hand on which the smart watch is placed. 4 salary f-ly, 8 ill.

Description

Field of technology

The utility model relates to electronics, namely to computerized wristwatches with extended functionality. In particular, smart watches display time, indicators of physical activity and health of the user.

State of the art

There are a number of technical solutions aimed at developing smart watches that, in addition to the time, are capable of displaying the user’s health indicators on their screen.

The closest analogue of the claimed utility model is the smart watch device known from patent WO 2015/177594 A2 dated November 26, 2015.

This design of a smart watch contains a belt (bracelet) designed to be worn on a part of the body and having an internal surface in contact with the part of the body when worn by the user, a housing with a display and sensors such as a heart rate monitor, pulse oximeter, temperature, ECG, accelerometer.

The known design of the prototype watch has a significant drawback, which is that for better results in measuring health indicators, the smart watch must be placed on the inside of the wrist, where the greatest contact of the sensors with the surface of the skin is achieved, which leads to significant discomfort, expressed in , that with this placement the image on the display is rotated perpendicular to the horizontal plane of visual perception.

This makes viewing health indicators inconvenient, and in some cases with a problem with the cervical spine, difficult.

Thus, the objective of this utility model is to create a smart watch device with the ability to display images of the user’s activity and health indicators in a plane aligned with the user’s field of view.

The technical result of the claimed utility model is to expand the functionality of smart watches by providing both automatic and mechanical combination of images with indicators of monitoring the user's health with the user's field of view during various manipulations performed by the hand on which the smart watch is placed.

Disclosure of utility model

Just like its closest analogue, the proposed smart watch device contains a belt (bracelet), a housing with a display and health monitoring sensors.

The difference between the claimed smartwatch device and its analogue is that the image of health parameters on the display rotates when detecting the movement/rotation of the hand, either automatically or mechanically following the rotation of the body.

The set goal, the technical result required and obtained when using the utility model, is achieved by the fact that a smart watch with a function for monitoring the user’s health indicators contains a case, a bracelet and sensors that monitor the user’s health parameters, and the case contains a processor, an accelerometer and grooves, the bracelet has a platform the base on which the clamps and contact pads are located, sensors that monitor the user’s health parameters are located on the base platform of the bracelet; Moreover, when receiving a signal from the accelerometer about a change in the position of the body, the processor is configured to automatically rotate the image with the user’s health parameters at an angle ensuring alignment of the displayed information with the user’s field of view, while the body is removable with the ability to rotate in the plane of the bracelet base platform at an angle, ensuring the combination of the image with the user’s health parameters with the user’s field of view and securing the case in a given position by aligning the grooves on the case with the latches on the bracelet.

In this case, the rotation angle is 90, 180, 270 and 360 degrees in both directions.

In addition, the smart watch is designed with the ability to block automatic rotation or the ability to set a specific rotation angle.

In addition, the bracelet contains a power source.

In this case, the power supply of the bracelet is designed to receive a charge from the case.

Brief description of drawings

The essence of the utility model is illustrated by drawings.

In fig. 1 shows a general view of a smart watch.

In fig. Figure 2 shows a version of the clock with software blocking the rotation of the dial image (HOLD).

In fig. Figure 3 shows the automatic rotation of the smart watch display using the built-in accelerometer sensor of the smart watch.

In fig. Figure 4 shows a side view of the smartwatch.

In fig. 5, 6 show the mechanical rotation of the smart watch display.

In fig. Figure 7 shows the bottom view of the smartwatch.

In fig. Figure 8 shows a block diagram of the elements included in the body of the smart watch.

Implementation of a utility model

Using a smartwatch with health monitoring has a number of benefits. Thanks to the use of such watches, the user in real time without visiting any medical institutions has the opportunity to monitor health indicators, such as: temperature, blood oxygen saturation level (saturation), heart rate (pulse), heart rate indicators (ECG), detection acute dehydration, sleep indicators, etc.

In addition, the use of smart watches also helps doctors track the patient’s health indicators, due to the ability, through the transceiver located in the smart watch body, to transmit health indicators over the network to the hospital server for further display on the doctor’s terminal.

To collect health indicators, smartwatches contain sensors such as: optical sensors, thermometer, GSP sensors, bioimpedance sensors (BioZ), electrocardiogram (ECG) sensors, biological sensors (for example, pulse, pulse oximetry, body temperature, blood pressure, body fat and etc.) or any combination thereof.

Smart watches have a composite design, in which the bracelet and the case are one device with the ability to detach the case from the bracelet to rotate it 90, 180, 270 or 360 degrees.

As shown in FIG. 5-7, the bracelet 2 consists of a base platform 5 and two straps, which are located on both sides of the base platform 5.

The bracelet 2 may be made of a flexible material to make it easier to wear the smart watch 1. Such material may be leather, rubber, silicone, synthetic resin, and the like.

The sensor unit 17 of health indicators is located on the bracelet 2, namely on the outer side of the base platform 5, which is adjacent to the skin surface of the inner side of the wrist.

The bracelet 2 contains a power source 13 to support the monitoring function of the user's activity and health indicators and a data storage module 14 (for example, memory) in which the monitoring results are stored.

Bracelet 2 also has the ability to separately charge the built-in power source 13 and the function of recharging from the power source located in the body 3 of the smart watch.

For these purposes, the corresponding contact pads 6 and 9 are located on the base platform 5 and the housing 3. The contact pads 6 and 9 are connected to the corresponding power supplies located in the housing 3 and the bracelet 2. When the housing 3 is fixed into the bracelet 2, the contact pads 6 and 9, as a result of which the charge from the power source located in the housing 3 is transferred to the power source of the bracelet 2.

In addition, contact pads 6 and 9 also serve to transmit data from sensors 17 located on the bracelet 2 to the memory unit 14 located in the housing 3.

As shown in FIG. 6, on the sides of the base platform 5 there are latches-clamps 7, which, when combined with the grooves 8 located on the body 3, ensure reliable fixation of the body 3 on the bracelet 2.

The grooves 8 located on the housing 3 provide the ability to rotate the housing 3 in the horizontal plane by 90, 180, 270, 360 degrees in both directions through mechanical rotation of the housing 2 and alternately changing the grooves 8, with which the latches 7 interact, and also ensure complete detachment of the housing 3 from bracelet 2.

To separate the case 3 and the bracelet 2, it is necessary to turn the case 3 counterclockwise until the latch 7 and the groove 8 open and pull the case 3 upward.

The case 3 of the smart watch 1 can be implemented in different designs, such as round, rectangular, square and others, and also have additional design elements, for example, precious stones, Swarovski crystals, drawings, engravings, etc.

In the case 3 of the smart watch 1 there are interconnected: communication unit 11, sensor unit 12, processor 10, power supply 13, memory unit 14, display unit 15, interface unit 16 as shown in the block diagram shown in Fig. 8.

The communication unit 11 provides wireless communication between the smart watch 1 and the wireless communication system, between two smart watches, between the smart watch 1 and an external server, between the smart watch 1 and the user’s personal device. The communication unit 11 is configured to receive broadcast transmission, mobile communications, Wi-Fi, Bluetooth, Personal Area Network (PAN), short-range communications, GPS.

The sensor unit 12 includes a plurality of sensors configured to sense internal information of the smartwatch, the environment of the smartwatch, user information, and the like. For example, sensor unit 12 may alternatively or additionally include sensors such as: a proximity sensor, light sensor, touch sensor, accelerometer, gyroscope, motion sensor, RGB sensor, infrared (IR) sensor, finger scanning sensor, ultrasonic sensor, optical sensor (for example, camera), microphone, battery indicator, environmental sensor (for example, barometer, hygrometer, thermometer, radiation detection sensor, heat sensor and gas sensor, among others) and others.

The display unit 15 may be configured as a touch screen and is capable of outputting various types of information such as audio, video, tactile output, health indicators, and the like.

The interface unit 16 serves to interact with various types of external devices that can be connected to the smart watch. The interface unit 16, for example, may include any of wired or wireless ports, external power supply ports, wired or wireless data ports, memory card ports, device connection ports having an identification module, audio input/output (I/O) ), video I/O ports, headphone ports, etc.

The memory 14 is used to store data to support various functions or features of the watch, as well as to store data received from sensors located in the bracelet 2.

The power supply 13 contains a battery and is configured to receive external power or provide internal power to supply the appropriate power required for the operating elements and components included in the watch.

Additionally, the smartwatch body 3 may include a user input unit (control buttons) consisting of at least one: touch key, push key, mechanical key, programmable key, etc., located on the side surface of the body and serving to provide the user's ability to enter information is indicated by position 18 on the side surface of the housing.

For better results of measuring health indicators, it is necessary that the sensors 17 are located on the inside of the wrist, where the greatest contact of the sensors 17 with the surface of the skin is achieved and where the veins are closest.

With this placement of the smart watch 1 on the hand to combine the image of the display 4 with the indicators of monitoring the user's health with the user's field of view during various manipulations performed by the hand, the smart watch 1 provides two functions. The first is the automatic display image rotation function. The second is the function of mechanical rotation of the watch case. Moreover, each of these functions can be performed either independently or simultaneously to increase the efficiency of using the watch.

Let's consider a specific example in which automatic image rotation and mechanical rotation of the body are carried out.

The user inserts the housing 3 into the bracelet 2 and fixes the housing 3 on the bracelet 2 by turning the housing 3 clockwise to align the grooves 8 on the housing 3 with the latches 7 on the platform of the base 5 of the bracelet 2. When fixing the housing 3 in the bracelet 2, alignment also occurs contact pads 6 and 9 located on the body 3 and the base platform 5 of the bracelet 2.

The user places the smart watch 1 on the inner surface of the wrist (right or left depending on the user's preference), ensuring the greatest contact of the sensors 17 for collecting health and activity data with the surface of the skin where the veins are most closely located.

Sensors 17 located on the bracelet 2 begin collecting indicators such as: temperature, blood oxygen saturation level (saturation), heart rate (pulse), heart rate indicators (ECG), detection of acute dehydration, sleep indicators, etc. .

The information of the transmitters 17 through interacting contact pads 6 and 9 is transmitted from the bracelet 2 to the memory 14 located in the housing 3, and is displayed on the display unit 15.

The user lifts, rotates, or otherwise manipulates the arm to view the displayed information on the display 4 of the smart watch 1.

When the hand moves (up, down, sideways, turn, etc.), the accelerometer determines the position (angle of rotation and side of location) of the user's hand (and, therefore, the position of the smart watch) and sends this data to the processor 10, which sends a signal to the display unit 15, where it automatically rotates the image of the display 4 with health indicators at the corresponding specific angle, ensuring the alignment of the displayed information with the user’s field of view, that is, strictly horizontally.

Thus, the rotation of the display 4 image can be 90, 180, 270, 360 degrees in both directions (depending on which hand the watch is located on). This is shown in detail in Fig. 3, where options a)-d) display the possible rotation of the strap 2 with the body 3 of the smart watch 1 on the user’s hand and the strictly horizontal position of the image of the indicators on the display screen 4 of the smart watch 1 to ensure alignment of the displayed information with the user’s field of view.

In this case, as shown in Fig. 1 and 2, through interaction with the watch interface or with the control buttons 18, the rotation lock function (HOLD) can be enabled or the ability to set a specific rotation angle of 90, 180, 270, 360 degrees in both directions.

Thus, the proposed smart watch 1, including the elements listed above, ensures that the image of the user’s health monitoring indicators is combined with the user’s field of view during various manipulations performed by the hand on which they are placed.

The user inserts the housing 3 into the bracelet 2 and fixes the housing 3 on the bracelet 2 by turning the housing 3 clockwise to align the grooves 8 on the housing 3 with the latches 7 on the base platform 5 of the bracelet 2. When fixing the housing 3 in the bracelet 2, the contact contacts are also aligned pads 6 and 9 located on the body 3 and the base platform 5 of the bracelet 2.

The user places the smart watch on the inner surface of the wrist (right or left, depending on the user's preference), ensuring the greatest contact of the sensors 17 for collecting health and activity data with the surface of the skin where the veins are most closely located.

Sensors 17 located on the bracelet 2 begin collecting indicators such as, for example, temperature, blood oxygen saturation level (saturation), heart rate (pulse), heart rate indicators (ECG), acute dehydration detection, sleep indicators, etc. P.

The information of the transmitters 17 through interacting contact pads 6 and 9 is transmitted from the bracelet 2 to the memory 14 located in the housing 3, and is displayed on the display unit 15.

The user lifts, rotates or otherwise manipulates the arm to view the displayed information on the display of 4 smart watches 1.

If there is no signal from the accelerometer (loss of signal, breakdown of the accelerometer, too fast raising of the hand), the processor 10 cannot automatically rotate the image of the display 4 with health indicators to combine the displayed information with the user's field of view.

As a result, information is displayed at an angle that is inconvenient for viewing.

For such a case, the smart watch 1 provides a mechanical rotation of the body 3, through which the body 3 of the smart watch is rotated in the plane of the base platform 5 of the bracelet 2 clockwise or counterclockwise (depending on the choice of the hand on which the smart watch is located) by alternately changing the grooves 8 located on the side surface of the body 3 in the latches 7 located on the sides of the base platform 5 to align the image of the user's health monitoring indicators on the display 4 with the user's field of view.

Each groove 8 provides rotation of the housing 3 by 90, 180, 270, 360 degrees, respectively.

Thus, the proposed smart watch 1, including the elements listed above, ensures that the image of the user’s health monitoring indicators is combined with the user’s field of view during various manipulations performed by the hand on which they are placed.

When using the smart watch 1, the user can also use the function of separating the body 3 of the smart watch 1 from the bracelet 2, for example, to replace the bracelet 2 with another one.

For these purposes, the user rotates the body 3 of the smart watch 1 counterclockwise in the plane of the base platform 5.

When a position is reached in which the latch 7 located on the side surface of the base platform 5 does not interact with the groove 8 located on the side surface of the body 3, it is necessary to pull the body 3 up to separate it from the bracelet 2.

Taking into account the novelty of the set of essential features, the technical solution of the problem, the materiality of all general and specific features of the utility model, proven in the section “State of the art” and “Disclosure of the utility model”; the technical feasibility and industrial applicability of the proposed device, proven in the section “Implementation and industrial implementation of the utility model”; solving the assigned problems and confidently achieving the required technical result when implementing and using a utility model, in our opinion, the declared device satisfies all the requirements for patentability for utility models.

The analysis also shows that all the general and specific features of a utility model are essential, since each of them is necessary, and all together they are not only sufficient to achieve the goal of the utility model, but also allow its implementation in an industrial way.

Claims (10)

1. A smart watch with a function for monitoring the user’s health indicators, containing a body, a bracelet and sensors that monitor the user’s health parameters, characterized in that the housing contains a processor, an accelerometer and slots, the bracelet has a base platform on which latches and contact pads are located, sensors that monitor the user’s health parameters are located on the base platform of the bracelet; Moreover, when receiving a signal from the accelerometer about a change in the position of the body, the processor is configured to automatically rotate the image with the user’s health parameters at an angle that ensures alignment of the displayed information with the user’s field of view, wherein the body is removable with the ability to rotate in the plane of the bracelet base platform at an angle that ensures alignment of the image with the user’s health parameters with the user’s field of view and securing the body in a given position by aligning the grooves on the body with the latches on the bracelet. 2. Smart watch according to claim 1, characterized in that the rotation angle is 90, 180, 270 and 360 degrees in both directions. 3. Smart watch according to claim 1, characterized in that it is designed to block automatic rotation or to set a specific rotation angle. 4. Smart watch according to claim 1, characterized in that the bracelet contains a power source. 5. Smart watch according to claim 1, characterized in that the power source of the bracelet is configured to receive a charge from the case.