TWI645385B - Wireless monitor apparatus for measuring information of a body of a user and manufacturing method thereof, and apparatus for displaying information of a body of a user and related method thereof - Google Patents

Abstract

A wireless monitoring device that measures information about a user's body includes a first component, a second component, and a housing. The first component is for measuring the information. The second component is coupled to the first component, wherein the second component is configured to receive the information, generate a sensing signal according to the information, and transmit the sensing signal to a host. The outer casing is a portion for covering the first component and a portion of the second component, wherein a size of a portion of the outer casing corresponding to the second component is larger than a size of a portion of the outer casing corresponding to the first component, and the outer casing The outer casing has a shape.

Description

Wireless monitoring device for measuring information of a user's body and method of manufacturing the same, and device for displaying information of a user's body and related methods

The present invention relates to a wireless monitoring device for measuring information of a user's body, a method of manufacturing the same, and a device for displaying information of the user's body and related methods, and more particularly to a wireless device having a dome-shaped and stepless housing. The monitoring device and the method of manufacturing the same, and a device and related method that enable the user to easily know the relationship between the body temperature information of the user and the corrected temperature value of the user's body temperature information.

The prior art provides a strap-on product or a single piece of device that is clipped under the user's arm to measure information about the user's body. When the user uses the strap-type product, the user uses the strap of the strap-type product to cause the strap-type product to fix the sensing component of the strap-type product to the user through the arm of the user. The armpit is used to measure the information of the user's body. However, since the sensing element must be completely attached to the surface of the user's skin to sense the correct body temperature, the band must be tightly wrapped around the user's arm, causing the user's arm to feel uncomfortable. . In addition, since the monolithic device has a uniform shape, the user's armpit is uncomfortable due to the thickness, width and shape of the monolithic device. Therefore, the watchband product and the monolithic device provided by the prior art are not a good choice for the user.

An embodiment of the invention provides a wireless monitoring device that measures information about a user's body. The wireless monitoring device includes a first component, a second component, and a housing. The first component is for measuring the information. The second component is coupled to the first component, wherein the second component is configured to receive the information, generate a sensing signal according to the information, and transmit the sensing signal to a host. The outer casing is a portion for covering the first component and a portion of the second component, wherein a size of a portion of the outer casing corresponding to the second component is larger than a size of a portion of the outer casing corresponding to the first component, and the outer casing The outer casing has a shape.

Another embodiment of the present invention provides a method of fabricating a wireless monitoring device for measuring information of a user's body, wherein the wireless monitoring device includes a first component and a second component, the first component including a sensor and A metal wire, the sensor comprises a metal cap, a sensing module and a transmission line, and the second component comprises a sensing signal processor, a wireless communication unit, a power supply unit and a plastic cavity. The manufacturing method includes combining the sensing module, the metal cap and the transmission line; fixing the metal wire and the transmission line to the plastic cavity; positioning and clamping the sensor and the plastic cavity by using a first upper mold, and utilizing The mold heats a flexible material to form a lower portion of the outer casing of the wireless monitoring device; after the lower half of the outer casing is completed, the first upper mold is removed, and the second upper mold is used to heat the flexible portion The material forms the upper half of the outer casing of the wireless monitoring device. The portion of the outer casing corresponding to the second member is larger than the portion of the outer portion corresponding to the first member, and the outer casing has a meandering shape.

Another embodiment of the present invention provides a method of fabricating a wireless monitoring device for measuring information of a user's body, wherein the wireless monitoring device includes a first component and a second component, the first component including a sensor and A metal wire, the sensor comprises a metal cap, a sensing module and a transmission line, and the second component comprises a sensing signal processor, a wireless communication unit, a power supply unit and a plastic cavity. The manufacturing method includes combining the sensing module, the metal cap and the transmission line; fixing the metal wire and the transmission line to the plastic cavity; and in a first mold, coating the first time with a flexible material a component; in a second mold, coating the second component with the flexible material and coating the first component a second time, wherein the second mold cavity space is larger than the first mold cavity space; Wherein the flexible material forms a casing of the wireless monitoring device, the portion of the casing corresponding to the second component is larger than the portion of the casing corresponding to the first component, and the casing has a shape.

Another embodiment of the present invention provides a method of fabricating a wireless monitoring device for measuring information of a user's body, wherein the wireless monitoring device includes a first component and a second component, the first component including a sensor and A metal wire, the sensor comprises a metal cap, a sensing module and a transmission line, and the second component comprises a sensing signal processor, a wireless communication unit, a power supply unit and a plastic cavity. The manufacturing method includes combining the sensing module, the metal cap and the transmission line; fixing the metal wire and the transmission line to the plastic cavity; and first covering the first component with a flexible material in a mold In the mold, the second member is coated with the flexible material and the first member is coated a second time; wherein the flexible material forms a housing of the wireless monitoring device, the housing corresponding to the second member The size of the portion is greater than the size of the portion of the outer casing that corresponds to the first component, and the outer casing has a meandering shape.

Another embodiment of the present invention provides an apparatus for displaying information of a user's body. The device includes a processor and a display. The processor is configured to receive the instant information of the user's body measured by the first device, and receive the user's body pair measured by the second device at each of the plurality of predetermined time points. The predetermined information should be generated at each predetermined time point, and according to a correction equation, the predetermined information corresponding to each predetermined time point, and the instantaneous information of the user's body corresponding to each predetermined time point, each predetermined time point is generated. Correction information. The display is a first curve for displaying instant information corresponding to the user's body and a second curve corresponding to correction information for a plurality of predetermined time points.

Another embodiment of the present invention provides a method of displaying information of a user's body, wherein the apparatus includes a processor and a display. The method includes the processor receiving an instant message of the user's body measured by a first device and a body of the user measured by the second device at each of a plurality of predetermined time points Predetermined information at each predetermined time point; the processor generates the predetermined information corresponding to each predetermined time point according to a correction equation, and the instantaneous information of the user's body corresponding to each predetermined time point, generating each predetermined time Correction information for the point; the display displays a first curve corresponding to the instant information of the user's body and a second curve corresponding to the correction information for the plurality of predetermined time points.

The present invention provides a wireless monitoring apparatus for measuring information of a user's body, a method of manufacturing the same, and an apparatus for displaying information of the user's body and related methods. The size of the portion of the wireless monitoring device corresponding to the second component of the wireless monitoring device is greater than the size of the portion of the housing corresponding to the first component of the wireless monitoring device, and the housing is in the shape of the dome, wherein the housing pair The shape of the portion of the first member should be the shape of the crotch-shaped tail and the portion corresponding to the second member. Therefore, since the first member is arbitrarily bent to fit under the armpit of a user, the size of the portion of the outer casing corresponding to the first member is small, and the outer casing corresponds to the shape of the portion of the first member. The tail of the 蝌蚪 shape, so the wireless monitoring device does not make the user uncomfortable when monitoring the body temperature information of the user for a long time. In addition, the manufacturing method first coats the first component with a flexible material, and covers the second component with the flexible material and the second component a second time, so the first component is None of the manufacturing methods need to be fixed, and the housing does not have a difference between the first component and the second component. Therefore, the present invention can overcome the process difficulty of the manufacturing method without a gap, and because the outer casing does not have the difference between the first member and the second member, the present invention can increase the comfort of the user and cause Waterproof without a gap or seam. In addition, the apparatus for displaying information of the user's body and related methods provided by the present invention enable the user to easily know between the body temperature information about the user and the corrected temperature value of the user's body temperature information. relationship.

Referring to FIG. 1, FIG. 1 is a schematic diagram showing the appearance of a wireless monitoring device 100 for measuring information of a user's body disclosed in the first embodiment of the present invention. As shown in FIG. 1, the wireless monitoring device 100 includes a first component 102, a second component 104, and a housing 106. As shown in FIG. 1, the first component 102 includes a sensor end and a connecting section. The sensor end is located at one end of the first component 102 relative to the second component 104. The connecting segment connects the second component 104 and the sensor end, and the cross section shape of the connecting section is a curved rectangular shape. The flat type includes the metal cap 1022 of the sensor 1024 included in the first component 102 and the upper cover 1042 of the plastic cavity 1041 included in the second component 104 (but in another embodiment of the present invention, the plastic cavity 1041 has an upper cover And the lower cover), the outer casing 106 encloses the first component 102 and the second component 104, and the outer casing 106 has no difference between the first component 102 and the second component 104 (ie, the outer casing 106 is in the first component 102, and There is no segment or segmentation between a component 102 and the second component 104, and the outer casing 106 is a flexible material. For example, in an embodiment of the invention, the flexible material may be a silicone rubber. , a rubber, a polyethylene (Polyethylene, PE), a thermoplastic elastomer (Thermoplas Tic Elastomer, TPE) or PolyVinyl Chloride (PVC). However, the invention is not limited to the flexible material being the above material. Further, in an embodiment of the invention, the first component 102 One of the long sides of the cross section of the connecting section or the side of the side called the smaller zone rate extends to the sensor end having a metal cap 1022 and the other long side of the opposite side or the other side of the smaller zone rate The sensor end does not have a sensor, that is, the sensor end has only a single-sided exposed sensor 1024, so that the sensor 1024 can completely contact a user's body without being externally The sensor 1024 is affected by environmental factors such as temperature and humidity. The metal cap 1022 of the sensor 1024 included in the first component 102 can be a SUS 304 steel cap, but the invention is not limited to the metal cap 1022. A SUS 304 steel cap. In addition, as shown in Fig. 1, the size of the portion of the outer casing 106 corresponding to the second member 104 is larger than the size of the portion of the outer casing 106 corresponding to the first member 102, and the outer casing 106 has a meandering shape. That is, as shown in FIG. 1, the shape of the portion of the outer casing 106 corresponding to the first member 102 is The shape of the 蝌蚪-shaped tail and the portion corresponding to the second member 104 is the 蝌蚪-shaped head.

Please refer to FIG. 2, which is a schematic diagram illustrating the functional blocks of the wireless monitoring device 100, wherein the housing 106 is not depicted in FIG. As shown in FIG. 2, the first component 102 includes a sensor 1024, wherein the sensor 1024 has a metal cap 1022, a sensing module 1023, and a transmission line 1026, and the transmission line 1026 is coupled to the sensing module 1023. The sensing module 1023 is coupled to the metal cap 1022. The second component 104 includes a sensing signal processor 1044, a wireless communication unit 1046, a power supply unit 1048, and a plastic cavity 1041. FIG. 2 does not depict the plastic. Cavity 1041. The sensor 1024 can measure the information of the user's body through the metal cap 1022. When the information is integrated temperature information, the sensing module 1023 can be a thermistor, and the sensor 1024 can be placed in the use. Your majesty. However, when the information is a blood pressure information, a heartbeat information, or a heart rate information, the sensor 1024 can be placed in a corresponding area of the user's body. As shown in FIG. 2, the sensing signal processor 1044 is coupled to the transmission line 1026 for receiving the information through the transmission line 1026, and accordingly generates a sensing signal SS. The wireless communication unit 1046 is coupled to the sensing signal processor 1044. To transmit the sensing signal SS to a host 108, wherein the host 108 can be a portable electronic device (a portable electronic device is a handheld mobile device), a desktop computer, a notebook computer, and an internet network. A server on the road or a medical detecting device, but the present invention is not limited to the host 108 being the above device. In addition, the wireless communication unit 1046 can pass a Wireless Fidelity (Wi-Fi), a wireless local area network (WLAN), a purple bee short-range wireless transmission standard (IEEE 802.15.4, Zigbee), A Bluetooth, a Wireless Wide Area Network (WWAN), a Global System for Mobile Communications (GSM), a General Packet Radio Service (GPRS), a Third generation (3G), a fourth generation (4G), a fifth generation of mobile communication (fifth generation, 5G) or an actor network theory + (actor) The network theory+, Ant+) technology transmits the sensing signal SS to the host 108. As shown in FIG. 2, the power supply unit 1048 is configured to supply power to the sensing signal processor 1044 and the wireless communication unit 1046. In an embodiment of the invention, the power supply unit 1048 is a lithium battery or a lithium ion. The battery, but the invention is not limited to the power supply unit 1048 being a lithium battery or a lithium ion battery. In addition, the sensing signal processor 1044, the wireless communication unit 1046, and the power supply unit 1048 are disposed in the plastic cavity 1041, and the plastic cavity 1041 has an upper cover 1042 as shown in FIG.

Please refer to FIG. 3 and FIG. 4, FIG. 3 is a schematic diagram illustrating the relationship between the wireless monitoring device 100 and an adult 200 usage scenario, and FIG. 4 is a schematic diagram illustrating the relationship between the wireless monitoring device 100 and a child 300 usage scenario. Because the outer casing 106 is in the shape of the weir and the outer casing 106 is the flexible material, the first component 102 can be flexibly bent to conform to the user's body. Therefore, as shown in FIG. 3, since the first member 102 is arbitrarily bent to fit under the armpit of the adult 200, the size of the portion of the outer casing 106 corresponding to the first member 102 is small, and the outer casing 106 corresponds to the first member. The shape of the portion of the 102 is the tail of the 蝌蚪 shape, so that the wireless monitoring device 100 does not make the adult 200 uncomfortable when monitoring the body temperature information of the adult 200 for a long time. In addition, as shown in FIG. 3, the wireless monitoring device 100 further includes a clamp 202 that can buckle the second component 104 on the garment 204 of the adult 200 through the garment 204 of the adult 200, that is, when the clamp 202 passes through the garment 204. When the second component 104 is snapped over the garment 204, the garment 204 is interposed between the clamp 202 and the second component 104. When the wireless monitoring device 100 measures the body temperature information of the adult 200 through the sensor 1024, a cover sheet 206 included in the wireless monitoring device 100 can directly cover the sensor 1024 to the skin of the adult 200 so that the sensor 1024 The measured body temperature information does not have a large deviation, and the cover sheet 206 can be a film. However, the present invention is not limited to the cover sheet 206 being a single film, that is, as long as the cover sheet 206 is an insulating sheet such as a heat insulating sheet which can isolate an external environment such as a monitoring value, it falls within the scope of the present invention. Additionally, in an embodiment of the invention, the surface of the cover sheet 206 may be coated with a layer of glue to conform to the positioning sensor 1024 to the skin of the adult 200. In addition, as shown in FIG. 4, when monitoring the body temperature information of the child 300 for a long time, the wireless monitoring device 100 can attach the second member 104 to the skin of the child 300 by using a patch included therein, wherein the sticker The sheet may be a double-sided tape, but the invention is not limited to the patch being a double-sided tape. In addition, since the patch is interposed between the second member 104 and the skin of the infant 300, the patch is not depicted in FIG. In addition, FIGS. 5(a)-5(b) are top and side views respectively illustrating when the clamp 202 is caught by the wireless monitoring device 100, wherein the width of the first component 102 in the top view is larger than that of the side view. Width, metal cap 1022 is located on a wider side of first component 102, and second component 104 is circular in a top view and larger in size than first component 102, wherein between first component 102 and second component 104 The joints are joined by a flexible material housing using an unequal angled surface to provide a unitary feel to the wireless monitoring device 100.

Please refer to FIG. 6. FIG. 6 is a schematic diagram showing a first curve RBTL related to the user's body temperature information displayed by a display 1082 of the host 108 when the wireless monitoring device 100 monitors the user's body temperature information for a long time. Wherein the vertical axis of Fig. 6 represents temperature and the horizontal axis of Fig. 6 represents time, and the first curve RBTL is a solid line. Because the wireless monitoring device 100 monitors the user's body temperature information for a long time, the user's body temperature information will inevitably be affected by the external environment in which the user is located. Therefore, as shown in FIG. 7, the user can input the body temperature information measured by the user using another device at a time point T1 (for example, the user measured with an ear thermometer at time T1). The body temperature information is transmitted to the host 108, and then the processor in the host 108 can measure the body temperature information measured by the device at the time point T1 and the wireless monitoring device 100 measured at the time point T1 according to a built-in correction equation. The user's body temperature information BTST1 produces a corrected temperature value CTV1, which can be generated by a numerical analysis method or an iterative method notified by those skilled in the art. Similarly, the user can input the body temperature information measured by the user using the device at a time point T2 (for example, the body temperature information measured by the user at the time point T2 with the ear thermometer) to the host 108. Then, the processor in the host 108 can calculate the body temperature information measured by the device at the time point T2 and the body temperature information BTST2 measured by the wireless monitoring device 100 at the time point T2 according to the built-in correction equation. A corrected temperature value CTV2 is generated, wherein the corrected temperature value CTV1 and the corrected temperature value CTV2 are located on a second curve CL displayed on the display 1082, wherein the second curve CL is a broken line. In addition, the plurality of corrected temperature values between the corrected temperature value CTV1 and the corrected temperature value CTV2 on the second curve CL may be between the time point T1 and the time point T2 by an interpolation method and the first curve RBTL. A plurality of body temperature information are generated correspondingly. Therefore, the host 108 can simultaneously display the first curve RBTL and the second curve CL through the display 1082 (as shown in FIG. 7), but the present invention is not limited to the first curve RBTL being a solid line and the second curve CL being A dashed line, that is, as long as the display 1082 represents the first curve RBTL and the second curve CL using two different patterns of curves, respectively, falls within the scope of the present invention. In addition, as shown in FIG. 8, the display 1082 can also display only the second curve CL after the time point T1. At this time, the display 1082 generates a prominent prompt (for example, an arrow 1084) at the time point T1 to prompt the user. The display 1082 displays only the second curve CL after the time point T1. That is to say, at the time point T1, the display 1082 simultaneously displays the eye-catching prompt, the user's body temperature information BTST1 and the corrected temperature value CTV1, and displays only the second curve CL after the time point T1. Therefore, the display manner of the display 1082 as shown in FIGS. 7 and 8 allows the user to easily know the relationship between the first curve RBTL regarding the body temperature information of the user and the second curve CL regarding the corrected temperature value. . The wireless monitoring device 100 can be a dedicated monitoring device or a handheld mobile device. The display 1082 of the wireless monitoring device 100 can display the graphical representations of the sixth, seventh, and eighth graphs separately, and can also be pressed or touched. The control screen switches between the illustrations to facilitate the user to view the graphical information.

In addition, when a child has a fever, the child may be less active due to his physiological reaction. For example, when the child has a fever, the child may become lethargic due to his physiological reaction. Because the child may be less active due to its physiological reaction, in another embodiment of the present invention, the wireless monitoring device 100 may further include a gravity sensor to detect the three of the gravity sensor. Change information of the axis (x-axis, y-axis, z-axis). Since the wireless monitoring device 100 is attached to the skin of the child by the method as shown in FIG. 4, the gravity sensor can generate the three-axis change information of the gravity sensor according to the activity of the child anytime and anywhere. . The sensing signal processor 1044 can then generate a sensing signal corresponding to the three-axis change information of the gravity sensor and transmit the sensing information corresponding to the three-axis change information of the gravity sensor through the wireless communication unit 1046. Signal to host 108. Therefore, when the host 108 determines that the activity of the child is reduced according to the sensing signal corresponding to the change information of the three axes of the gravity sensor and a reference value, the host 108 can further perform the above determination result and by the wireless monitoring device 100. The transmitted body temperature information of the child determines whether the child has a fever. After the host 108 determines that the child may have a fever, the host 108 may send a warning message to inform the parent of the child that the child may have a fever, wherein the warning message may be a special sound effect, a flashing light or a special sound effect combined with the flashing light.

In addition, please refer to the figures 1, 2, and 9-12, and FIG. 9 is a flowchart of a method of manufacturing a wireless monitoring apparatus for measuring information of a user's body disclosed in the second embodiment of the present invention. The manufacturing method of Fig. 9 is explained using the wireless monitoring device 100 of Figs. 1 and 2, and the detailed steps are as follows:

Step 900: Start;

Step 902: Combine the sensing module 1023, the metal cap 1022, and the transmission line 1026;

Step 904: Fix a metal wire 1028 and a transmission line 1026 in the plastic cavity 1041;

Step 906: Positioning the sensor 1024 and the plastic cavity 1041 by using a first upper mold, and hot pressing the flexible material with a lower mold to form a lower half of the outer casing 106 of the wireless monitoring device 100;

Step 908: After the lower half of the outer casing 106 is completed, the first upper mold is removed, and the flexible material is heat-pressed by a second upper mold to form an upper portion of the outer casing 106 of the wireless monitoring device 100;

Step 910: End.

In step 902, as shown in FIG. 10, in an embodiment of the present invention, a plastic sleeve 901 can be combined with the sensing module 1023, the metal cap 1022, and the transmission line 1026 by a mold and a package. The metal cap 1022 can be in contact with the sensing module 1023. The plastic sleeve 901 can also strengthen the physical strength of the connecting portion of the first component 102 by a coating process, wherein the plastic sleeve 901 can be an acrylonitrile-butadiene-styrene. Acrylonitrile Butadiene Styrene (ABS) plastic sleeve, but the invention is not limited to the plastic sleeve 901 is an acrylonitrile-butadiene-styrene copolymer plastic sleeve. In addition, the sensing module 1023 can be coupled to one end of the transmission line 1026 using techniques well known to those skilled in the art (eg, soldering), and thus will not be described herein. In addition, because the degree of bonding between the sensor 1024 and the flexible material is poor, the sensor 1024 is coupled to the flexible material by a plastic sleeve 901. In step 904, as shown in FIG. 11, one end of the metal wire 1028 and the other end of the transmission line 1026 of the first component 102 can pass through a hole 10412 in the plastic cavity 1041 to fix the metal wire 1028 and the transmission wire 1026. The plastic cavity 1041, wherein the metal wire 1028 is used to increase the flexibility of the first component 102, avoiding the breakage of the transmission line 1026 of the first component 102 covered by the horizontal tensile force, and the metal wire 1028 is set. Between the sensor 1024 and the plastic cavity 1041. In yet another embodiment of the present invention, if the transmission line 1026 is relatively thick and the cross-sectional area of the transmission line has a high proportion of the overall cross-sectional area of the connection segment, the first component 102 will not include the metal line 1028. In another embodiment of the invention, the wire 1028 can be replaced by a strip of plastic. In step 906, as shown in Fig. 12, in the first upper mold, since the sensor 1024 and the plastic cavity 1041 are clamped, when the present invention utilizes the liquid flexible material (e.g., silicone, rubber) When the polyethylene, thermoplastic elastomer or polyvinyl chloride) forms the lower half of the outer casing 106 of the wireless monitoring device 100 in the lower mold, the first member 102 is not subjected to the liquid flow rate and pressure of the flexible material. Offset. Thus, when the flexible material is cured, the wire 1028 and the transmission line 1026 are not offset to the surface of the lower half of the outer casing 106. In addition, in the first upper mold, the manner of sandwiching the sensor 1024 and the plastic cavity 1041 is a technique well known to those skilled in the art, and therefore will not be described herein. In step 908, after the lower half of the outer casing 106 is completed, the upper half of the outer casing 106 of the wireless monitoring device 100 is formed in the second upper mold using the flexible material (as shown in Fig. 13). As shown in FIG. 13, since the lower half and the upper half of the outer casing 106 of the wireless monitoring device 100 are disposable formed in steps 906 and 908, the outer casing 106 is apparently in the first component 102 and the There is no such difference between the two components 104. In addition, after referring to the outer casing 106 shown in FIG. 1 and the flexible material disclosed by the present invention, the field of the invention has a notification that the first upper mold, the second upper mold, and the like can be easily designed. The lower mold, so will not be described here. In addition, as shown in FIG. 13, the outer casing 106 has the shape of the crucible, wherein the shape of the portion of the outer casing 106 corresponding to the first member 102 is the shape of the crotch-shaped tail and the portion corresponding to the second member 104. The head.

In addition, referring to FIG. 14, FIG. 14 is a flowchart of a method of manufacturing a wireless monitoring apparatus for measuring information of a user's body disclosed in a third embodiment of the present invention. The manufacturing method of Fig. 14 is explained using the wireless monitoring device 100 of Figs. 1 and 2, and the detailed steps are as follows:

Step 1400: Start;

Step 1402: Combine the sensing module 1023, the metal cap 1022, and the transmission line 1026;

Step 1404: fixing metal wire 1028 and transmission line 1026 in the plastic cavity 1041;

Step 1406: In a first mold, the first member 102 is removed from the metal cap 1022 of the sensor 1024 by the flexible material for the first time;

Step 1408: In a second mold, the second member 104 outside the upper cover 1042 of the plastic cavity 1041 and the first member outside the metal cap 1022 covering the sensor 1024 are covered with the flexible material. 102;

Step 1410: End.

The difference between the embodiment of Fig. 14 and the embodiment of Fig. 9 is that in step 1406, the first mold is applied to a portion of the outer casing 106 corresponding to the first member 102, wherein the first mold has a first hole The metal cap 1022 of the sensor 1024 can be embedded in the first hole, that is, when the first component 102 is placed in the first mold, the first hole can be connected to a vacuum pump. Wherein the vacuum pump can evacuate the first mold, the liquid flexible material can flow in the first mold; however, in another embodiment of the invention, the first hole can also For a closed hole without vacuuming, a magnetic substance such as a magnet is embedded in the first hole, so that the metal cap 1022 is magnetically adsorbed and positioned in the first hole by the magnet. Thus, after the flexible material is cured, the flexible material can first cover the first component 102 other than the metal cap 1022 of the sensor 1024. In step 1408, the second mold is applied to a portion of the outer casing 106 corresponding to the first component 102 and the outer casing 106 corresponds to the second component 104, wherein the second mold has a second hole, and the second The hole can embed the metal cap 1022 of the sensor 1024, that is, when the first component 102 covering the flexible material is placed in the second mold, the second hole can be connected to the vacuum pump. Wherein, because the vacuum pump can evacuate the second mold, the liquid flexible material can still flow in the second mold. Because in step 1408, when the first component 102 encasing the flexible material is placed into the second mold, the first component 102 encasing the flexible material already occupies the second component corresponding to the first component. For most of the portion of portion 102, the connecting portion of the first member 102 has a large volume and mass, and is not susceptible to the Bernoulli's principle to produce a transmission line 1026 of the connecting portion of the first member 102 due to ambient flow rate and pressure. The unevenness is offset, so that the first member 102 encasing the flexible material is subjected to a liquid liquid. The influence of the flow rate and pressure of the flexible material on the portion of the second mold corresponding to the first member 102 is small. Thus, after step 1408, when the flexible material is cured, the wire 1028 and the transmission line 1026 are not offset to the surface of the outer casing 106. In addition, in the first mold and the first mold, the first member 102 does not need to be fixed, and only the hole positioning is required. Additionally, the second mold cavity space is larger than the first mold cavity space. In addition, the remaining principles of the embodiment of FIG. 14 are the same as those of the embodiment of FIG. 9, and are not described herein again.

In addition, in another embodiment of the present invention, a third mold is applied to a portion of the outer casing 106 corresponding to the first component 102 and a portion of the outer casing 106 corresponding to the second component 104, wherein the third mold has a first Three holes, and the third hole can embed the metal cap 1022 of the sensor 1024. When the first component 102 and the second component 104 are placed in the third mold, the third hole can be connected to the vacuum pump, wherein the vacuum pump can vacuum the third mold, so the liquid state The flexible material can flow in the third mold, and the amount of the flexible material in the liquid state can cure the flexible material, the flexible material can cover the sensor 1024 for the first time. The first component 102 outside the metal cap 1022. Additionally, after the flexible material first covers the first component 102 other than the metal cap 1022 of the sensor 1024, the step as described in step 1410 can be performed in the third mold to effect the flexibility. The material covers the second component 104 outside the upper cover 1042 of the plastic cavity 1041 and the first component 102 that covers the metal cap 1022 of the sensor 1024 a second time.

In summary, the outer casing of the wireless monitoring device provided by the present invention corresponds to a size of a portion of the second component of the wireless monitoring device that is larger than a size of a portion of the outer casing corresponding to the first component of the wireless monitoring device, and the outer casing. In the shape of the crucible, wherein the shape of the portion of the outer casing corresponding to the first member is the tail of the crucible shape and the portion corresponding to the portion of the second member is the head of the crucible shape, the cross of the second member The maximum length of the section is greater than 2 cm, and the first component has a cross-sectional maximum length of less than 1 cm within 5 cm of the sensor end and the sensor end extending to the connecting section. Therefore, since the first member is arbitrarily bent to fit under the armpit of the user, the size of the portion of the outer casing corresponding to the first member is small, and the outer casing corresponds to the shape of the portion of the first member. The tail of the 蝌蚪 shape, so when the wireless monitoring device monitors the body temperature information of the user for a long time, the first component can fit the body of the user without making the user uncomfortable and improve the comfort of the contact. . In addition, the wireless monitoring device provided by the present invention is configured to first coat the first component with the flexible material, and coat the second component with the flexible material and the second component for the second time. Therefore, the first component does not need to be fixed in the manufacturing method, and the outer casing has no difference between the first component and the second component. Therefore, the present invention can reduce the process difficulty of the manufacturing method, and because the outer casing does not have the difference between the first member and the second member, the present invention can increase the comfort and aesthetics of the user. The above are only the preferred embodiments of the present invention, and all changes and modifications made to the scope of the present invention should be within the scope of the present invention.

100‧‧‧Wireless monitoring device

102‧‧‧ first part

104‧‧‧ second part

106‧‧‧Shell

108‧‧‧Host

1022‧‧‧Metal cap

1023‧‧‧Sense Module

1024‧‧‧ sensor

1026‧‧‧ transmission line

1028‧‧‧Metal wire

1041‧‧‧ plastic cavity

10412‧‧‧ Hole

1042‧‧‧Upper cover

1044‧‧‧Sensor signal processor

1046‧‧‧Wireless communication unit

1048‧‧‧Power supply unit

1082‧‧‧ display

1084‧‧‧ arrow

200‧‧‧Adults

202‧‧‧ fixture

204‧‧‧ clothes

206‧‧‧ Covering film

300‧‧‧Children

901‧‧‧ plastic case

BTST1, BTST2‧‧‧ body temperature information

CL‧‧‧second curve

CTV1, CTV2‧‧‧corrected temperature values

RBTL‧‧‧ first curve

SS‧‧‧Sensor signal

T1, T2‧‧‧ time points

900-912, 1400-1412‧‧‧ steps

Fig. 1 is a perspective view showing the appearance of a wireless monitoring device for measuring information of a user's body disclosed in the first embodiment of the present invention. Figure 2 is a schematic diagram illustrating the functional blocks of the wireless monitoring device. Figure 3 is a diagram showing the relationship between the wireless monitoring device and the adult. Fig. 4 is a view showing the relationship between the wireless monitoring device and the child. Figures 5(a)-5(b) are top and side views, respectively, illustrating when the clamp is snapped onto the wireless monitoring device. Figure 6 is a schematic diagram showing a first curve of the body temperature information displayed by the display of the host when the wireless monitoring device monitors the body temperature information of the user for a long time. Figure 7 is a schematic diagram showing a first curve of body temperature information about the user and a second curve relating to the corrected temperature value, simultaneously showing the display of the host. Figure 8 is a schematic diagram showing the first curve of the display of the host simultaneously displaying body temperature information about the user and a second curve relating to the corrected temperature value. Figure 9 is a flow chart showing a method of manufacturing a wireless monitoring device for measuring information of a user's body disclosed in a second embodiment of the present invention. Figure 10 is a schematic view showing the sensor of the plastic sleeve combined with the metal cap by means of encapsulation. Figure 11 is a schematic view showing that the metal wire and the transmission wire included in the first component are fixed to the plastic cavity through holes in the plastic cavity. Figure 12 is a schematic view showing the lower half of the outer casing of the wireless monitoring device formed in the liquid in the mold. Figure 13 is a schematic view showing the upper portion of the outer casing of the wireless monitoring device formed of the liquid flexible material in the mold. Figure 14 is a flow chart showing a method of manufacturing a wireless monitoring device for measuring information of a user's body disclosed in a third embodiment of the present invention.

Claims (10)

A wireless monitoring device for measuring information of a user's body, comprising: a first component, comprising a sensor, the sensor for measuring the information; a second component coupled to the first component, comprising a a sensing signal processor and a wireless communication unit coupled to the sensing signal processor, the sensing signal processor is configured to receive the information, the sensing signal processor generates a sensing signal according to the information, and the wireless The communication unit transmits the sensing signal to a host; and a housing for covering the portion of the first component and the portion of the second component; wherein the portion of the housing corresponding to the second component is larger than the housing pair The size of the portion of the first component should be such that there is no difference between the first component and the second component, and the outer casing has a meandering shape. The wireless monitoring device of claim 1, wherein the sensor comprises: a metal cap, wherein the metal cap exposes one side of the outer casing; a sensing module coupled to the metal cap, wherein the metal cap and the metal cap The sensing module is configured to measure the information; and a transmission line is coupled to the sensing module; the second component further includes: a power supply unit for supplying power to the sensing signal processor and the wireless communication And a plastic cavity, wherein the sensing signal processor, the wireless communication unit and the power supply unit are disposed in the plastic cavity, and the plastic cavity has an upper cover. The wireless monitoring device of claim 2, wherein the outer casing encloses the first component and the second component in addition to the metal cap of the sensor and the upper cover, wherein the outer casing is a flexible material. The wireless monitoring device of claim 2, wherein the first component further comprises: a metal wire, wherein one end of the metal wire is fixed through the plastic cavity, and the other end of the metal wire is fixed by a plastic sleeve, and the A wire is disposed between the sensor and the plastic chamber. The wireless monitoring device of claim 1 or 2, wherein the first component has a cross-sectional maximum thickness of less than 1 cm at one end of the sensor. The wireless monitoring device of claim 1 or 2, wherein the second component has a cross-sectional maximum thickness greater than 2 cm. The wireless monitoring device of claim 2, further comprising: a cover sheet for covering the sensor to the skin of the user; and a patch for attaching the second component to the use On the skin of the person. The wireless monitoring device of claim 2, further comprising: a cover sheet for covering the sensor to the skin of the user; and a clamp for fixing the second component by the user's clothes On the user's clothes. The wireless monitoring device of claim 1, wherein the information is integrated temperature information, a blood pressure information, a heartbeat information, or a heart rate information. The wireless monitoring device of claim 1, wherein the host is a portable electronic device, a desktop computer, a notebook computer or a server on an internet network.