CN110477882B - Ring-type monitoring equipment and monitoring system - Google Patents

Abstract

The application discloses ring formula guardianship equipment and monitored system. The ring formula guardianship equipment includes: a housing, a battery and a circuit board assembly; the shell comprises an annular part and a protruding part, wherein the inner space of the annular part is used for accommodating the battery, and the inner space of the protruding part is used for accommodating the circuit board assembly; the battery is used for supplying power for the circuit board assembly; the circuit board assembly comprises a processing unit and a monitoring unit; the monitoring unit is used for acquiring physiological parameter data of a wearer, and the processing unit is used for carrying out corresponding operation according to the acquired physiological parameter data.

Description

Ring type monitoring device and monitoring system

Technical Field

The application relates to the technical field of monitoring equipment, in particular to ring-type monitoring equipment and a monitoring system.

Background

The general guardianship wrist-watch or guardianship bracelet is all great in size and weight. When the guardianship wrist-watch or guardianship bracelet are worn on user's wrist, because the influence of the volume and the weight of device for the heavy burden of the user who wears guardianship wrist-watch or guardianship bracelet feels comparatively obvious. Furthermore, such a watch or bracelet may adversely affect the daily life and work of the user to some extent.

Disclosure of Invention

An object of the application is to provide a ring formula guardianship equipment and monitor system to solve the current relatively poor problem of guardianship wrist-watch or guardianship bracelet experience effect.

In order to solve the above technical problem, the present application provides a ring type monitoring device, including: a housing, a battery, and a circuit board assembly. The shell comprises an annular part and a protruding part, wherein the inner space of the annular part is used for accommodating the battery, and the inner space of the protruding part is used for accommodating the circuit board assembly; the battery is used for supplying power to the circuit board assembly; the circuit board assembly comprises a processing unit and a monitoring unit; the monitoring unit is used for acquiring physiological parameter data of a wearer, and the processing unit is used for carrying out corresponding operation according to the acquired physiological parameter data.

The finger ring type monitoring equipment can be worn on the fingers of a wearer, physiological parameter data are acquired through the skin of the fingers of the wearer, and body information of the wearer is known in real time through the acquired physiological parameter data. The occupied space of ring formula guardianship equipment and the weight of self are all less, and the person of also being convenient for to wear carries and deposits to improve and use experience.

In one embodiment, the battery is in an unsealed ring shape, an opening is formed between two ends of the battery, and the circuit board assembly is located at the opening. The unclosed ring-shaped battery can increase the capacity of the battery to improve the cruising ability of the monitoring device, and can utilize the space formed by the shell as much as possible to improve the integration level of the monitoring device and reduce the size of the monitoring device.

In one embodiment, the battery is a thin film battery and is attached to the inner surface of the annular portion. Wherein, the volume of the monitoring device can be reduced and the miniaturization of the monitoring device can be further realized through the thin film battery.

In one embodiment, the ring-type monitoring device further comprises a wireless coil; the wireless coil is annular, and the wireless coil with the battery is in radial direction range upon range of setting, just the battery is located wireless coil's periphery, wireless coil is used for supplying the battery realizes wireless charging. Based on this, the ring formula monitoring device need not set up the interface that charges for charging outside the casing to this monitoring device's volume and weight are reduced.

In one embodiment, the wireless coil further comprises a main body and a connecting portion; the connecting part is arranged on the surface of the main body in a protruding mode, and the connecting part is electrically connected with the battery. The connection part is electrically connected with one end of the battery close to the opening in a contact manner, so that the connection stability between the wireless coil and the battery can be improved; and the relative position relationship among the battery, the circuit board assembly and the wireless coil can be determined, so that the ring type monitoring device can be conveniently installed.

In one embodiment, the battery includes a plurality of battery cells connected in series in sequence, and the battery extends in a direction along the curvature of the annular portion of the case. The yield of the battery unit is higher than that of the thin-film battery, so that the manufacturing cost of the monitoring equipment can be reduced.

In one embodiment, the ring-type monitoring device further comprises a solar cell, wherein the solar cell is arranged on the outer surface of the protruding portion and is electrically connected with the circuit board assembly through a lead or a connecting terminal, so that the cruising ability of the monitoring device is improved.

In one embodiment, the monitoring unit extends at least partially from the housing and is positioned adjacent to or in contact with the skin of a wearer's finger to obtain physiological parameter data. Through the through hole, the accuracy of the monitoring unit for acquiring the physiological parameter data of the wearer can be improved, and the physiological parameter data of the wearer can be monitored in real time or at high frequency.

In one embodiment, the housing includes a top wall, a bottom wall, a first side wall and a second side wall, the first side wall and the second side wall being disposed between the top wall and the bottom wall; the top wall, the first side wall, the second side wall and the bottom wall collectively form an interior space for housing the battery and the circuit board assembly. Wherein, based on the structure of the shell, the ring type monitoring device has enough internal space to accommodate the electronic components.

In one embodiment, the ring-shaped part surrounds a hollow area to form a finger ring for a finger to pass through, and the ring-shaped monitoring device further comprises a pad which is detachably arranged on the surface of the ring-shaped part facing the finger ring; wherein the pad is adapted to contact and secure the ring monitoring device to the wearer's finger.

The pad has certain elasticity, and the size of the finger ring type monitoring device can be adaptively adjusted, so that the finger ring type monitoring device can be matched with fingers with different sizes.

In one embodiment, the cushion includes opposing first and second ends spaced apart to receive the monitoring unit. Furthermore, the pad does not obstruct the monitoring unit or affect the process of the monitoring unit acquiring the relevant data of the wearer while the pad ensures that the ring type monitoring device is matched with the finger of the wearer.

In one embodiment, the surface of the pad facing the finger ring is provided with a convex part, and the convex part is used for abutting against the fingers of the wearer. After wearing the ring type monitoring equipment, the bulge part is abutted between the fingers of the wearer and the shell, and the wearing stability of the ring type monitoring equipment can be improved through the bulge part, so that the monitoring equipment is prevented from falling off from the fingers.

In one embodiment, the number of the protruding parts is one, and the protruding parts are arranged opposite to the monitoring unit. The raised portion and the wearer's finger produce a relative force to make the finger fit the monitoring unit as closely as possible. Therefore, the accuracy of the monitoring unit for acquiring the data of the relevant physiological parameters of the wearer can be improved, and the acquisition difficulty is reduced.

In one embodiment, the number of the convex parts comprises two or more, and the two or more convex parts are distributed at intervals on the inner side of the annular part. The acting force of the two or more than two convex parts on the fingers faces the finger ring of the monitoring equipment, so that the possibility that the ring-type monitoring equipment is separated from the fingers can be further reduced, and the wearing effect of the ring-type monitoring equipment is improved.

In one embodiment, the number of the pads is two or more, and the sizes of the convex parts of the two or more pads are different; the two or more pads selectively cooperate with the ring portion to form different wear sizes. The pads of different bulges are replaced according to the size of the fingers of the wearer, so that the ring type monitoring equipment can be adaptively matched, and the problem of wearing discomfort caused by the mismatch of the pads and the fingers of the wearer is reduced or eliminated.

In one embodiment, the ring-type monitoring device further comprises a charging interface, and the charging interface is arranged on the shell and electrically connected with the battery. Therefore, the wearer can select the charging mode of the charging interface according to the requirement, and compared with wireless charging, the wired charging mode has more ways, and the battery can be charged fully more conveniently.

In one embodiment, the circuit board assembly further comprises a wireless transmission unit, and the wireless transmission unit is electrically connected with the processing unit; the wireless transmission unit is used for responding to the instruction of the processing unit to transmit the acquired physiological parameter data or receive the instruction for controlling the ring type monitoring equipment. Through the cooperation of the wireless transmission unit and the processing unit, the ring type monitoring equipment can be set, or the setting for acquiring the physiological parameter data can be changed, so that the use experience is improved.

In one embodiment, the monitoring unit comprises a blood oxygen sensor, a heart rate sensor, an electrocardiogram sensor or an acceleration sensor; the blood oxygen sensor, the heart rate sensor, the electrocardio sensor or the acceleration sensor are respectively and electrically connected with the processing unit, and the processing unit can acquire blood oxygen data, heart rate data, electrocardio data or walking data of a wearer.

The application also provides a monitoring system which comprises a processing terminal and the ring type monitoring device. And the processing terminal receives and processes the physiological parameter data to obtain the physical index of the wearer. The monitoring system can acquire physiological parameter data of a wearer, and then analyze and process the physiological parameter data to obtain body indexes of the wearer, so that monitoring is better realized.

In one embodiment, the number of the ring-type monitoring devices includes two or more ring-type monitoring devices, and the two or more ring-type monitoring devices are used for being worn on different fingers of a wearer and respectively acquiring physiological parameter data of the wearer. The monitoring system can acquire at least two groups of physiological parameter data of the wearer, and then the physiological parameter data is analyzed and processed to obtain the physical index of the wearer. If the physical index of the wearer exceeds the normal range (such as the heart rate is too high or too low), the monitoring system can remind the wearer to pay attention by a set program, so that the monitoring is better realized.

The present application provides a monitoring device that is generally configured in the form of a ring. The ring-type monitoring device can be worn on the fingers of a wearer. Compared with other types of monitoring devices, the finger ring type monitoring equipment has the advantages that occupied space and self weight are small, so that the load feeling of a wearer is reduced, and the finger ring type monitoring equipment is convenient to carry and store. And then the monitoring equipment after wearing can acquire physiological parameter data through the skin of the fingers of the wearer, and know the body information of the wearer in real time through the acquired physiological parameter data so as to improve the use experience.

Drawings

Fig. 1 is a perspective view of a ring-type monitoring device according to an embodiment of the present application.

Fig. 2 is a front view of the ring monitoring device of fig. 1.

Fig. 3 is a schematic diagram of a battery according to an embodiment of the present application.

Fig. 4 is a schematic diagram of a wireless coil according to an embodiment of the present application.

FIG. 5 is an exploded view of a ring monitoring device according to an embodiment of the present application.

FIG. 6 is a schematic view of a housing according to an embodiment of the present application.

FIG. 7 is a schematic view of a housing according to another embodiment of the present application.

Fig. 8 is a perspective view of a gasket according to an embodiment of the present application.

Fig. 9 is a front view of the liner of fig. 8.

Figure 10 is a schematic diagram of the operation of a ring monitoring device according to an embodiment of the present application.

Fig. 11 is a schematic diagram of a monitoring system according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

As shown in fig. 1-10, embodiments of the present application provide a ring-type monitoring device 100, the monitoring device 100 being generally configured in the shape and size of a ring for wearing on a finger of a wearer. The monitoring device 100 can acquire the physiological parameter data through the skin of the finger of the wearer and know the body information of the wearer in real time through the acquired physiological parameter data. Such as: acquiring walking data of a wearer to know the daily amount of exercise of the wearer; alternatively, by acquiring heart rate data of the wearer, it is known whether the heart rate of the wearer is within a normal range.

Compared with a normal watch type or ring type monitoring device, the finger ring type monitoring device 100 provided by the application has smaller occupied space and self weight, and is convenient for a wearer to carry and store; the ring-type monitoring device 100 does not have obvious sense of burden (or sense of wear) after being worn, and has better use experience.

As shown in fig. 1-5, the ring monitoring device 100 includes a housing 110, a battery 120, and a circuit board assembly 130. The shell 110 generally presents a ring-like structure in the form of a finger ring, with the middle area enclosed by the shell 110 forming a finger ring; thus, a wearer's finger may wear the monitoring device 100 through a finger loop in the middle region of the ring-type monitoring device 100.

Specifically, the housing 110 is formed with an internal space (not shown) therein for accommodating electronic components (e.g., the battery 120 and the circuit board assembly 130) and protecting the electronic components provided in the internal space by the housing 110.

The housing 110 includes an annular portion 116 and a protruding portion 118, and an inner space of the annular portion 116 and an inner space of the protruding portion 118 communicate with each other. The interior space formed within the annular portion 116 is generally presented as an annular space. The protrusion 118 protrudes away from the finger ring (space for fingers to pass through), and the inner space formed by the protrusion 118 can accommodate the circuit board assembly 130; and thus form the architecture of the ring monitoring device 100. It should be appreciated that when the ring monitoring device 100 is worn, the ring portion 116 encircles the wearer's fingers and the protrusion 118 is located on one side of the wearer's back of the hand.

Referring to fig. 3, 5 and 10 in a synchronous manner, in one possible embodiment, the battery 120 has an unsealed ring shape and includes two opposite ends (i.e., two free ends, which are oppositely disposed); the battery 120 may be "C" shaped. Correspondingly, an opening 125 is formed between the two ends of the battery 120, and the circuit board assembly 130 is located at the opening 125.

In one embodiment, the circuit board assembly 130 may be embedded in the opening 125, i.e., the circuit board assembly 130 is located between two ends of the battery 120. The electrode connection terminals of the cells 120 are electrically connected to the circuit board assembly 130 to supply power to the circuit board assembly 130. Wherein the circuit board assembly 130 can be embedded between the batteries 120 through the opening 125 to reduce the size of the monitoring device 100 and further miniaturize the monitoring device 100.

In one embodiment, the circuit board assembly 130 may be disposed on a side of the opening 125 away from the finger ring and electrically connected to the battery 120, i.e., the circuit board assembly 130 is located above the battery 120. The battery can occupy more space to increase the capacity of the battery 120, thereby increasing the cruising ability of the monitoring device 100.

In one embodiment, the battery 120 may include a thin film battery that fits against the inner surface of the ring portion 116; specifically, the inner surface of the annular portion 116 is a surface facing the inner space of the annular portion 116. Thereby making the best use of the annular space of the housing 110 as possible while increasing the capacity of the battery 120 to increase the cruising ability of the monitoring device 100, to increase the integration of the monitoring device 100 and to reduce the size of the monitoring device 100.

In one embodiment, the battery 120 may also include a plurality of battery cells (not shown) connected in series, and the battery is configured in a ring shape to be disposed in the ring portion 116. The battery formed by the battery cells can also increase the capacity of the battery 120 and utilize the annular space of the case 110 as much as possible. The yield of the battery unit is higher than that of the thin film battery, so that the manufacturing cost of the monitoring device 100 can be reduced.

In one embodiment, to improve the cruising ability of the monitoring device 100, the ring-type monitoring device 100 may include a solar cell (not shown) that may be disposed on the outer surface of the protrusion 118 and electrically connected to the circuit board assembly 130 in the housing 110 via wires or connection terminals. Specifically, a connection hole is provided on the case 110, and a lead or a connection terminal is connected to the circuit board assembly 130 (provided inside the case 110) and the solar cell (provided outside the case 110).

In another embodiment, the solar cell may be disposed in the inner space of the annular portion 116 or the protruding portion 118, and the portion of the casing 110 corresponding to the solar cell is designed to be a transparent and light-permeable region, so that the solar cell disposed in the casing 110 can obtain solar energy through the casing 110. Wherein the solar cell is used to convert solar energy into electrical energy to maintain the operation of the monitoring device 100.

The circuit board assembly 130 includes a circuit board (not shown), a processing unit 131 and a monitoring unit 132; the processing unit 131 and the monitoring unit 132 are disposed on the circuit board and electrically connected to each other through the circuit board. The monitoring unit 132 is configured to obtain physiological parameter data of the wearer, and the processing unit 131 is configured to perform corresponding operations according to the obtained relevant physiological parameter data.

In particular, "physiological parameter data" includes, but is not limited to: blood oxygen data, heart rate data, electrocardiogram data, and exercise-related step count or walking kilometers; "corresponding action" includes but is not limited to being: respectively storing the maximum value or the minimum value of each type of data according to the type of the acquired physiological parameter data; or, acquiring the relevant physiological parameter data of the wearer again at set intervals; or sending out an early warning signal according to the maximum value or the minimum value of the acquired physiological parameter data.

As shown in fig. 4, 5 and 10, in one embodiment, the ring monitoring device 100 further includes a wireless coil 150. The wireless coil 150 is disposed in the accommodating space and electrically connected to the battery 120, and specifically, the wireless coil 150 is substantially annular, the wireless coil 150 and the battery are stacked in a radial direction, and the wireless coil 150 is interposed between the case 110 and the battery 120. The wireless coil 150 is used for wirelessly charging the battery 120, so that the battery 120 maintains the normal operation of the circuit board assembly 130. Based on this, the ring-type monitoring device 100 does not need a charging interface for charging provided outside the housing 110, so as to reduce the volume and weight of the monitoring device 100. In addition, as one charging interface is omitted, the waterproof and dustproof performances of the monitoring device 100 can be improved.

The circuit board assembly 130 and the battery 120 are both disposed on the wireless coil 150, and the wireless coil 150 is formed with a second through hole 155 at a position corresponding to the through hole 115; the second through hole 155, similar to the through hole 115, is used for extending the monitoring unit 132, so that the monitoring unit 132 can extend to the outside of the housing 110.

Referring to fig. 3 to 5, the wireless coil 150 includes a main body 151 and a connecting portion 152; the body 151 has a ring shape, and the connection portion 152 is protrudingly provided on a surface of the body 151. The battery 120 is fitted around the periphery of the main body, and the connection portion 152 is adapted to contact one end of the battery 120. The connection portion 152 is located at the opening 125 of the battery 120 and can contact one end of the battery 120 close to the opening 125 to improve the stability of the connection between the wireless coil 150 and the battery 120. In particular, the connection portion 152 can also be used to determine the relative position of the battery 120, the circuit board assembly 130, and the wireless coil 150 to facilitate the installation of the ring-type monitoring device 100.

In one embodiment, the wireless coil 150 and the battery 120 are an integrated power structure, so that the wireless coil 150 and the battery 120 can be conveniently placed in the housing 110 together, thereby improving the installation efficiency of the monitoring device 100. On the other hand, when the ring-type monitoring device 100 is worn on the finger of the wearer, the swing amplitude and the swing frequency of the arm of the wearer are both larger in a normal state, and the possibility of looseness of the battery 120 and the wireless coil 150 in the housing 110 can be reduced through the integrated power supply structure of the battery 120 and the wireless coil 150, so as to improve the connection stability of the battery 120 and the wireless coil 150.

The ring-type monitoring device 100 may define a radial direction a, an axial direction b, and a circumferential direction c from a cylindrical coordinate system.

In one embodiment, as shown in fig. 1 to 6, the housing 110 includes a first housing 111 and a second housing 112; the first housing 111 and the second housing 112 are fixedly coupled to form the housing 110. The first casing 111 and the second casing 112 are distributed along the radial direction a, and the second casing 112 is located inside the first casing 111. The first housing 111 and the second housing 112 may be fixedly connected by gluing, snapping, or interference fit.

In another embodiment, as shown in fig. 7, the first housing 111 and the second housing 112 may also be distributed up and down along the axial direction b. In this embodiment, in addition to the above-described manner of glue bonding, snap fitting, interference fit, or the like, the first housing 111 and the second housing 112 may be fixedly connected by means of a threaded connection.

Through the above connection manner, the connection position of the first housing 111 and the second housing 112 is in a seamless connection state, and the housing 110 formed after the first housing 111 and the second housing 112 are fixedly connected has certain levels of waterproof and dustproof performances.

In one possible implementation scenario, even if the monitoring device 100 is worn by the wearer to perform a liquid-contacting action such as washing hands, there is no possibility of liquid (moisture in normal state) penetrating into the monitoring device 100 located on the fingers of the wearer, and the monitoring device 100 can still maintain a normal working state.

Thus, the housing 110 of the monitoring device 100 can be easily assembled or disassembled by the connection between the first housing 111 and the second housing 112. Such as: in the process of assembling the ring type monitoring device, the battery 120 and the electronic components such as the circuit board assembly 130 can be placed on the second housing 112 according to a predetermined mounting sequence, and then the first housing 111 and the second housing 112 are fixedly connected by the above connection method, so as to complete the assembly of the ring type monitoring device 100. When the ring-type monitoring device 100 fails, the first housing 111 and the second housing 112 are disengaged or are in an interference fit, so that the monitoring device 100 can be disassembled and the electronic components in the internal space can be checked.

Specifically, the first casing 111 and the second casing 112 may be made of metal, ceramic, or glass; alternatively, the first shell 111 and the second shell 112 may be made of a high polymer material, and the shell 110 formed on the basis of the high polymer material can reduce the weight of the monitoring device 100, so as to reduce the load feeling of the wearer. Specifically, the first shell 111 and the second shell 112 made of high molecular polymer material are easier to be integrally formed, so that the assembled monitoring device 100 can have a smaller volume for the wearer to wear. The first shell 111 and the second shell 112 are integrally formed to improve the performance (for example, the anti-falling performance and the anti-deformation performance) of the first shell 111 and the second shell 112.

Referring to fig. 1, 6 and 7, in one embodiment, the monitoring unit 132 extends at least partially from the housing 110 and is positioned adjacent to or in contact with the skin of the wearer's finger to obtain physiological parameter data. Specifically, the second housing 112 is provided with a through hole 115, and the through hole 115 communicates with the external space and the internal space of the housing 110 with respect to the external space. Wherein the aperture 115 is oriented toward the finger loop of the ring monitoring device 100, and at least a portion of the monitoring unit 132 extends from the aperture 115 and is positioned adjacent to or in contact with the skin of the wearer's finger to obtain physiological parameter data. It will be appreciated that when the monitoring unit 132 is brought into close proximity to the skin of the wearer's finger, the wearer's physiological parameter data may be acquired without necessarily requiring contact to acquire the data. Such as: when the distance between the monitoring unit 132 and the skin of the finger of the wearer is in the range of 1mm to 3mm, the wearer can acquire the physiological parameter data.

In one embodiment, the monitoring unit 132 is in contact with the skin of the finger of the wearer to improve the accuracy of the acquired physiological parameter data, and can monitor the physiological parameter data of the wearer in real time or at a high frequency to accurately acquire the periodic variation of the physiological parameter data, wherein the period may be a day, a preset period of time, or the like.

In one possible embodiment, as shown in fig. 6, the first housing 111 includes a top wall 110a and a first side wall 110c, and the second housing 112 includes a bottom wall 110b and a second side wall 110 d. The top wall 110a, the first side wall 110c, the second side wall 110d, and the bottom wall 110b collectively form an inner space for accommodating the battery 120 and the circuit board assembly 130.

In another possible embodiment, the first housing 111 includes a top wall 110a, a first side wall 110c and a second side wall 110d, and the second housing 112 includes a bottom wall 110 b. The top wall 110a, the first side wall 110c, the second side wall 110d, and the bottom wall 110b collectively form an inner space for accommodating the battery 120 and the circuit board assembly 130;

in yet another possible embodiment, the first housing 111 includes a top wall 110a, and the second housing 112 includes a bottom wall 110b, a first side wall 110c, and a second side wall 110 d. The top wall 110a, the first side wall 110c, the second side wall 110d, and the bottom wall 110b collectively form an inner space for accommodating the battery 120 and the circuit board assembly 130.

It should be understood that the first housing 111 and the second housing 112 collectively include a top wall 110a, a bottom wall 110b, a first side wall 110c, and a second side wall 110d as a whole. When the first housing 111 and the second housing 112 are fixedly connected, the top wall 110a and the bottom wall 110b are disposed opposite to each other, and the first side wall 110c and the second side wall 110d are disposed opposite to each other, so that the ring-type monitoring device 100 has enough internal space to accommodate the electronic components (e.g., the battery 120 and the circuit board assembly 130). The bottom wall 110b is formed with a through hole 115 for the monitoring unit 132 to extend out, and the side of the bottom wall 110b opposite to the top wall 110a faces the finger ring of the ring-type monitoring device 100; that is, the portion of the monitoring unit that extends out of the aperture 115 also faces the finger loop of the ring monitoring device 100.

As shown in fig. 1, 2, 5, and 8, in one embodiment, the finger ring monitoring device 100 further includes a pad 140, and the pad 140 is removably disposed on the surface of the ring portion 116 facing the finger ring (i.e., on the side of the bottom wall 110b opposite the top wall 110 a). Wherein, the gasket 140 can be detachably connected with the housing 110 by means of snap-fit or interference fit. The pad 140 is adapted to contact and secure the ring monitoring device 100 to the wearer's finger.

Specifically, the material of the pad 140 may be rubber or silicone, and has certain elasticity. The pad 140 can adaptively adjust the size of the finger loop of the finger ring monitoring device 100, thereby allowing the finger ring monitoring device 100 to fit different sized fingers, rather than being limited to the portion of the population that has a finger size that just matches the shell 110.

Referring to fig. 1, 2, 5 and 8, the pad 140 includes a first end 140a and a second end 140b opposite to each other, and the first end 140a and the second end 140b form a space exposing the through hole 115. In this way, the cushion 140 does not obstruct the monitoring unit 132 or interfere with the process of the monitoring unit 132 acquiring the data related to the wearer while ensuring that the ring monitoring device 100 is matched to the wearer's finger. Wherein at least a portion of the monitoring unit 132 extends from the through hole 115; and in at least a portion of the monitoring unit 132 extending out of the bottom wall 110b, an end thereof remote from the housing 110 is flush or substantially flush with the first end 140a and/or the second end 140b of the pad 140.

In one embodiment, the surface of the pad 140 facing the finger loop is provided with a raised portion 145, the raised portion 145 being adapted to be held between the finger of the wearer and the monitoring device 100 when the finger loop monitoring device 100 is worn. Wherein the protruding portion 145 protrudes with respect to the other portion of the gasket 140; that is, the protrusions 145 extend toward the finger loops to reduce the size of the finger loops. Based on this, during the wearing process of the monitoring device 100, the convex portion 145 of the pad 140 will preferentially contact with the finger of the wearer and elastically deform under the squeezing action of the finger, so as to enhance the acting force (or friction force) between the pad 140 and the finger of the wearer. Furthermore, after the monitoring device 100 is worn, the protruding portion 145 abuts between the finger of the wearer and the bottom wall 110b, so that the wearing stability of the ring-type monitoring device 100 can be improved by the protruding portion 145, and the monitoring device 100 is prevented from falling off from the finger.

As shown in fig. 2 and 8, in an embodiment, the number of the protrusions 145 includes two or more, and two or more protrusions 145 are spaced apart on the inner side of the ring portion 116. Therefore, after the monitoring device 100 is worn, the two or more protrusions 145 can generate relative acting force with the fingers of the wearer relatively uniformly, and the acting force of the two or more protrusions 145 on the fingers is toward the finger ring of the monitoring device 100, so that the possibility that the ring-type monitoring device 100 is separated from the fingers can be further reduced, and the wearing effect of the ring-type monitoring device 100 can be improved.

In another embodiment, the number of the protrusions 145 may be one, and the protrusions are disposed opposite to the monitoring unit 132; that is, after wearing the monitoring device 100, the one protruding portion 145 and the monitoring unit 132 are located on opposite sides of the finger, and the protruding portion 145 and the finger of the wearer generate a relative force to make the finger fit the monitoring unit 132 as much as possible. Therefore, the accuracy of the monitoring unit 132 for acquiring the data of the relevant physiological parameters of the wearer is improved, and the acquisition difficulty is reduced.

To expand the range of users of the finger ring monitoring device 100 and to match different fingers of the same wearer, the number of pads 140 is two or more, and the size of the protrusions 145 on two or more pads 140 is different, as shown in fig. 1, 2, 8 and 9. Wherein two or more pads 140 selectively mate with the ring portion 116 to form different fit sizes. It should be understood that there is a general rule of variation in finger size among people of different age classes, such as: the size of the fingers of a wearer in their twenties is generally larger than the size of the fingers of a wearer in their teens, or alternatively, the size of the index or middle finger of the same wearer is generally larger than the size of the tail finger. Therefore, the pad 140 of different bulges 145 can be replaced according to the size of the fingers of the wearer, so that the ring type monitoring device 100 can be adaptively matched, and the problem of wearing discomfort caused by the mismatch between the pad 140 and the fingers of the wearer is reduced or eliminated.

In one embodiment, the monitoring device 100 may also include a charging interface (not shown) disposed on the housing 110 and electrically connected to the battery 120. Therefore, the monitoring device 100 provides another charging path, compared to wireless charging, wired charging, such as connecting a charger with a socket or connecting a charging cord with a computer, so as to fully charge the battery 120 more conveniently. The wearer can select different charging modes (wireless charging or wired charging) according to the use requirement or the use environment, so as to improve the use experience of the ring-type monitoring device 100.

As shown in fig. 5 and 10, in an embodiment, the circuit board assembly 130 further includes a wireless transmission unit 160, and the wireless transmission unit 160 is connected to the processing unit 131. The wireless transmission unit 160 is used for transmitting the acquired physiological parameter data in response to an instruction from the processing unit 131, or receiving an instruction for controlling the ring type monitoring device 100. Through the cooperation of the wireless transmission unit 160 and the processing unit 131, the ring-type monitoring device 100 can be set or the setting for acquiring the physiological parameter data can be changed, so as to improve the use experience.

It should be understood that the wireless transmission unit 160 includes, but is not limited to: WiFi or bluetooth. The wireless transmission unit 160 can transmit the acquired physiological parameter data to a processing terminal (such as a mobile phone or a computer or other electronic devices with data processing functions); instructions to control the ring monitoring device 100 include, but are not limited to: adjusting the frequency and time period of acquiring physiological parameter data, changing the type of physiological parameter data acquired, or ceasing acquisition of physiological parameter data of the wearer by the ring monitoring device 100.

Specifically, the monitoring unit 132 includes a blood oxygen sensor, a heart rate sensor, an electrocardiograph sensor, an acceleration sensor, or the like. The processing unit 131 correspondingly obtains blood oxygen data, heart rate data, electrocardiogram data or walking data of the wearer through the blood oxygen sensor, the heart rate sensor, the electrocardiogram sensor or the acceleration sensor. The processing unit 131 further transmits the acquired data through the wireless transmission unit 160, and the data is provided for the processing terminal to perform processing and analysis.

In addition, the monitoring unit 132 may also be a sensor of a type including a GPS (position) sensor or a proximity sensor, without limitation.

As shown in fig. 10, in one specific embodiment, the monitoring unit 132 illustratively includes an acceleration sensor 132a and an ecg sensor 132 b. The acceleration sensor 132a and the electrocardiograph sensor 132b are electrically connected to the processing unit 131, respectively, to transmit the acquired data to the processing unit 131; the acceleration sensor 132a and the electrocardiograph sensor 132b are also electrically connected to the battery 120, and power is supplied from the battery 120 to maintain the electric power required for the normal operation of the acceleration sensor 132a and the electrocardiograph sensor 132 b. Specifically, the processing unit 131 transmits the motion data acquired by the acceleration sensor 132a and the electrocardiographic data acquired by the electrocardiographic sensor 132b to the processing terminal through the wireless transmission unit 160, and the processing terminal analyzes the data.

In the ring monitoring device 100 of the above embodiment, the housing 110 is defined by a top wall 110a, a bottom wall 110b, a first side wall 110c, and a second side wall 110 d. And thus the cross-section of the housing 110 is substantially rectangular in shape. It should be understood that in some embodiments, the cross-section of the housing 110 also generally exhibits an elliptical or circular shape; thus, a wearer or technician may select or replace a differently shaped housing 110 as desired.

Referring to fig. 1 to 10, the ring-type monitoring device of the present application further includes a power distribution unit 170, the power distribution unit 170 electrically connects the battery 120 and the circuit board assembly 130, and the battery 120 supplies power to the components (e.g., the processing unit 131 and the monitoring unit 132) on the circuit board assembly 130 through the power distribution unit 170, so that the components, such as the processing unit 131 and the monitoring unit 132, can operate normally.

It should be understood that other components may also be integrated on circuit board assembly 130, such as: an alarm unit or a display unit, etc., and the battery 120 supplies power to the elements through the power distribution unit 170. In particular, the alarm unit may be an indicator light element or a speaker element.

Referring to fig. 1 to 11, the present application further provides a monitoring system 10, which includes a processing terminal 11 and a ring-type monitoring device 100. The processing terminal 11 receives and processes the acquired physiological parameter information, and then can acquire the physical index of the wearer to better realize monitoring.

In one embodiment, the number of ring monitoring devices 100 includes two or more (more than two). Two or more ring-type monitoring devices 100 are used for being worn on different fingers of the same wearer and respectively acquiring physiological parameter data of the wearer. Further, the processing terminal 11 receives and processes the acquired physiological parameter data to acquire a physical index of the wearer. At least two sets of physiological parameter data of the wearer can be acquired through the monitoring system 10, and then the processing terminal 11 analyzes and processes the physiological parameter data to obtain the physical index of the wearer. If the physical indicator of the wearer is out of the normal range (e.g., the heart rate is too high or too low), the monitoring system 10 can be programmed to alert the wearer to better monitor the body.

As shown in fig. 11, the number of ring monitoring devices 100 illustratively includes two, and the types of physiological parameters acquired by the two monitoring devices 100 may be the same or different. In particular, the two sets of physiological parameter data acquired by the two monitoring devices 100 may be of the same type or different types.

In a specific implementation scenario, the left hand and the right hand of the wearer respectively wear one monitoring device 100, wherein one monitoring device 100 obtains electrocardiographic data of the wearer, and the other monitoring device 100 obtains blood oxygen data of the wearer. The change values of the electrocardio data and the blood oxygen data in a period of time are counted through the processing terminal 11, and whether the electrocardio index and the blood oxygen index of the wearer are in a normal range is determined; or, when the processing terminal 11 determines that the acquired electrocardiographic data and/or blood oxygen data exceed the set threshold, the processing terminal sends out early warning information.

In another specific implementation scenario, the left hand and the right hand of the wearer respectively wear one monitoring device 100, the two monitoring devices 100 respectively obtain blood oxygen data of the wearer, the processing terminal 11 counts variation values of the two sets of obtained blood oxygen data within a period of time to determine whether the blood oxygen index of the wearer is within a normal range, and the processing terminal 11 sends out warning information when determining that the obtained blood oxygen data exceeds a set threshold.

While the foregoing is directed to embodiments of the present application, it will be appreciated by those skilled in the art that various changes and modifications may be made without departing from the principles of the application, and it is intended that such changes and modifications be covered by the scope of the application.

Claims (13)

1. A ring-type monitoring device, comprising: a housing, a battery, a wireless coil, and a circuit board assembly;

the shell comprises an annular part and a protruding part, wherein the inner space of the annular part is used for accommodating the battery, and the inner space of the protruding part is used for accommodating the circuit board assembly;

the battery is used for supplying power to the circuit board assembly;

the circuit board assembly comprises a processing unit and a monitoring unit; the monitoring unit is used for acquiring physiological parameter data of a wearer, and the processing unit is used for carrying out corresponding operation according to the acquired physiological parameter data; the battery is in an unsealed ring shape, an opening is formed between two ends of the battery, and the circuit board assembly is positioned at the opening;

the wireless coil is annular, the wireless coil and the battery are stacked in the radial direction, the battery is located on the periphery of the wireless coil, and the wireless coil is used for wirelessly charging the battery; the wireless coil comprises a main body and a connecting part; the connecting part is arranged on the surface of the main body in a protruding mode, the connecting part is located at the opening position of the battery and is in contact with one end of the battery, and the connecting part is used for determining the relative position relation among the battery, the circuit board assembly and the wireless coil.

2. The fingerstall monitoring device of claim 1, wherein the housing is provided with a through-hole communicating between an exterior space and an interior space of the housing, the through-hole being configured to allow at least a portion of the monitoring unit to extend out of the housing; the wireless coil forms a second through hole at a position corresponding to the through hole, and the second through hole is used for allowing the monitoring unit to extend out of the shell.

3. The ring monitoring device of claim 1, wherein the battery comprises a plurality of battery cells connected in series, the battery extending in a direction along the curvature of the loop portion of the housing.

4. The ring monitoring device of claim 1, further comprising a solar cell disposed on an outer surface of the protrusion and electrically connected to the circuit board assembly.

5. The ring monitoring device according to claim 4, wherein the hollow area enclosed by the ring portion forms a finger loop for a finger to pass through, the ring monitoring device further comprising a pad removably attached to a surface of the ring portion facing the finger loop, the pad adapted to contact and secure the ring monitoring device to a finger of a wearer.

6. The ring monitoring device of claim 5, wherein the cushion includes opposing first and second ends that define a space therebetween to receive the monitoring unit.

7. The ring monitoring device of claim 6, wherein the surface of the pad facing the finger loop is provided with a raised portion for resting against a finger of a wearer.

8. The ring monitoring device of claim 7, wherein the number of projections is one and is disposed directly opposite the monitoring unit.

9. The ring monitoring device of claim 7, wherein the number of projections comprises two or more projections spaced apart on an inner side of the ring portion.

10. The ring monitoring device of claim 7, wherein the number of pads is two or more, the size of the raised portions on the two or more pads being different; the two or more pads selectively cooperate with the ring portion to form different wear sizes.

11. The ring-type monitoring device of claim 1, further comprising a charging interface disposed on the housing and electrically connected to the battery.

12. A monitoring system comprising a processing terminal and a ring monitoring device according to any one of claims 1 to 11;

and the processing terminal receives and processes the physiological parameter data to obtain the physical index of the wearer.

13. The monitoring system of claim 12, wherein the number of ring monitoring devices comprises two or more ring monitoring devices, the two or more ring monitoring devices being configured to be worn on different fingers of a wearer and to acquire physiological parameter data of the wearer, respectively.

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