TWM557892U - Physiological parameter cloud nursing system - Google Patents

Abstract

The present invention provides a physiological parameter cloud care system comprising at least one physiological sensing patch, a transmission device and a cloud server. The at least one physiological sensing patch is attached to the human body to obtain at least one physiological parameter of at least one human body, and converts the at least one physiological parameter into a first transmission signal related to a first communication protocol. The transmission device is in telecommunication connection with the physiological sensing patch for receiving the first transmission signal, and the transmitting device further converts the first transmission signal into a second transmission signal output related to a second communication protocol. . The cloud server is in telecommunication connection with the transmission device, the cloud server has a database, the cloud server receives the second transmission signal, and converts the second transmission signal into the at least one physiological parameter and Stored in this database. The system of the creation can simultaneously monitor the physiological parameters and transmission of multiple people and record them on the cloud system to provide intelligent devices or computers for artificial wisdom judgment.

Description

Physiological parameter cloud care system

This creation is a kind of care system, especially a kind of physiological parameter cloud care system that can monitor the physiological parameters of multiple people at the same time and transmit and record them on the cloud system to provide intelligent devices or computers for artificial intelligence judgment.

Today's era has shifted from the era of agro-industrialization to the era of industrialization. Due to the development of industry and commerce, work has occupied most of the adult's time. Therefore, if there are elderly or chronic diseases in the family or if there are newborn children, the home care will be taken. The demand is often the burden of young adults at home.

Because home care takes a long time to stay with the care recipient, but in some cases, it is inevitable that the young people in the family will not be able to accompany the caregiver at any time because they need to go out to work or handle affairs. If an elderly person, a chronic disease patient, or a child has an accident when the caregiver goes out, it may be because the caregiver cannot find it immediately, or if it is found too late and the timing of the rescue is delayed.

In addition, in another case, in the confinement center or in the nursing home where the elderly or the inconvenient person is inconvenience, there are often cases in which the physical condition of the caretaker is abnormal because the nursing staff is insufficient or the caretaker is negligent. Therefore, when discovered, the golden time for lifesaving has often been delayed.

In combination with the above requirements, if there is a cloud care system that can instantly monitor the physiological parameters of multiple people and transmit them and record them on the cloud system to provide intelligent devices or computers for artificial intelligence judgment, the home care staff or the moon can be reduced. Opportunities for regrets between sub-centers, hospitals, or the elderly.

The present invention provides a physiological parameter cloud care system, which is applied to the field of home or medical, can simultaneously monitor physiological parameters of multiple people, and transmit the physiological parameters to the cloud server and store in the cloud server. The cloud server can perform artificial intelligence interpretation on the stored physiological parameter information, and issue a warning when the physiological parameter is abnormal. In addition, the user can obtain the information of the physiological parameters through the smart handheld device or the electronic computing device, such as a computer or a notebook computer, so that the physiological condition of the caretaker can be instantly known.

The present invention provides a physiological parameter cloud care system, which can further capture images about the caretaker and transmit the image to the cloud server for storage. The user can obtain the information of the image through a smart handheld device or an electronic computing device, such as a computer or a notebook computer, so as to instantly understand the state of the caretaker.

In a use case, the hospital firstly knows the physiological parameters of the patient in the hospital in order to know the health of the patient in time to prevent any critical situation. In addition, when you are in the patrol room, you don't need to disturb the patient to know the health parameters of all patients.

In a use case, patients who are unwilling to be hospitalized can also directly transmit physiological parameters to the hospital through this device, so that the hospital can directly understand any critical situation of the patient and get help when necessary.

The design of the creation can reduce the discomfort caused by the patient wearing a plurality of measuring instruments at the same time, and also save the measurement time and analysis time that the medical staff must spend for the patient.

The present invention provides a physiological parameter cloud care system, which obtains at least one physiological parameter of a human body through a physiological sensing patch, such as: heartbeat, body temperature, blood pressure, pulse, electrocardiogram, respiration rate, blood oxygen concentration and the like, and can pass through Wireless communication, such as wireless network protocol, wireless RF communication, broadband network communication, Bluetooth communication, Zigbee, Thread, 3G communication protocol or 4G communication protocol for information transmission, due to the thinness of the physiological sensing patch structure Therefore, the caregiver can be used without any burden or uncomfortable feeling to achieve the monitoring effect.

In an embodiment, the present invention provides a physiological parameter cloud care system including at least one physiological sensing patch, a transmission device, and a cloud server. The at least one physiological sensing patch is attached to the human body to obtain at least one physiological parameter of at least one human body, and converts the at least one physiological parameter into a first transmission signal related to a first communication protocol. The transmission device is in telecommunication connection with the physiological sensing patch for receiving the first transmission signal, and the transmitting device further converts the first transmission signal into a second transmission signal output related to a second communication protocol. . The cloud server is in telecommunication connection with the transmission device, the cloud server has a database, the cloud server receives the second transmission signal, and converts the second transmission signal into the at least one physiological parameter and Stored in this database.

In an embodiment, each of the physiological sensing patches further has at least one sensor and a wireless transmission unit. The at least one sensor is configured to obtain the at least one physiological parameter about the human body. The wireless transmission unit is electrically connected to the at least one sensor for converting the at least one physiological parameter into a first transmission signal related to the first communication protocol.

In an embodiment, the transmission device further has a receiving unit, a processing unit and a transmitting unit. The receiving unit receives the first transmission signal. The processing unit is electrically connected to the receiving unit for converting the first transmission signal into a second transmission signal about the second communication protocol. The transmitting unit is electrically connected to the processing unit for outputting the second transmission signal.

In an embodiment, the physiological parameter cloud care system has an image capturing unit that is in telecommunication connection with the processing unit, the image capturing unit generates a dynamic image about an environment, and the processing unit receives the dynamic image, and Converting the dynamic image into a third transmission signal about the second communication protocol, the cloud server receives the third transmission signal, and converts the third transmission signal into the dynamic image and stores the dynamic image in the database.

In an embodiment, each of the physiological sensing patches further has a sensor disposed inside the physiological sensing patch, or the sensor is attached to the human body by using a patch or attached to the human body. .

Please refer to FIG. 1A , which is a schematic diagram of an embodiment of a physiological parameter cloud care system according to the present invention. The cloud care system 2 includes at least one physiological sensing patch 20, a transmission device 21, and a cloud server 22. The at least one physiological sensing patch 20 is attached to the human body 90 (the caretaker) for acquiring at least one physiological parameter of at least one human body, and converting the at least one physiological parameter into a first communication The first transmission signal of the agreement. The human body, in the present embodiment, may be an elderly person, a patient or an infant, or the like, or a person having a monitoring need may be the human body in the present embodiment. Although the figure shows that two stickers are attached to each human body, it is not limited thereto, and the number of sensors attached to the human body can be determined according to the sensor function in the physiological sensing patch, so that one can be implemented. The number of the human body is not limited to a single person, but also to many people, in addition to each human body. For example, as shown in FIG. 1B, in this embodiment, a plurality of human bodies 90-92 are attached, and a physiological sensing patch 20 is attached to the human body 90. The first human body 91 is attached with a first physiological measuring patch 20a, and the second human body is attached. The second physiological sensing patch 20b is attached to the 92, and the physiological sensing patch 20, the first physiological sensing patch 20a and the second physiological sensing patch 20b are respectively transmitted corresponding to the human body 90, and the first The first outgoing signal 3a, the fourth transmitted signal 3b, and the fifth transmitted signal 3c of the physiological parameters of the human body 91 and the second human body 92 are transmitted to the transmitting device 21. It should be noted that the sensor of the physiological sensing patch 20, the first physiological sensing patch 20a and the sensing physiological parameter disposed in the second physiological sensing patch 20b may be the same or different sensors. . The physiological sensing patch 20 is designed as a sheet. In one embodiment, a release paper or a patch is disposed on one side thereof, and after being peeled off the release paper or the patch, it can be directly adhered to a specific part of the human body. . Moreover, in another embodiment, the physiological sensing patch 20 can also be constructed as a wearable structure. Therefore, the manner of fixing to the human body can be determined according to the needs of use, and is not limited by the manner shown. Since the physiological sensing patch 20 is thin and light, it can be used by the caregiver without feeling or uncomfortable, and the monitoring effect can be achieved.

The physiological parameter measured by the physiological sensing patch 20 may be a parameter such as a heartbeat, a body temperature, a blood pressure, a pulse, an electrocardiogram, a respiratory rate, a blood oxygen concentration, or a combination of at least two of the foregoing. In an embodiment, the at least one physiological parameter is converted into a first transmission signal related to the first communication protocol, and the first communication protocol may be a wireless network protocol, wireless RF communication, broadband network communication, Zigbee, Thread, 3G communication protocol or 4G communication protocol for information transmission. In this embodiment, the first communication protocol is a Bluetooth communication protocol, for example, a Bluetooth 4.0 communication protocol.

The transmission device 21 is electrically connected to the physiological sensing patch 20 for receiving the first transmission signal, and the transmission device 21 further converts the first transmission signal into a second communication protocol. Transmit signal output. The first communication protocol and the second communication protocol may be the same agreement or different communication protocols, and the selection is based on the needs of those skilled in the art. The second communication protocol, in one embodiment, may be one of a wireless network communication (wifi) protocol, a 3G communication protocol, and a 4G communication protocol, in this embodiment a wireless network communication protocol.

In addition, in an embodiment, the image capturing unit 23 can be integrated with the image capturing unit 23 for capturing a dynamic image about the environment in which the human body 90 is located. The image includes the environment and the caretaker, and the motion image is converted into a third transmission signal for the second communication protocol and transmitted to the cloud server 22. The image capturing unit 23 may be a CCD camera or a CMS camera or an infrared camera, but is not limited thereto. It should be noted that the image capturing unit 23 is integrated in the transmitting device 21 in this embodiment, but in another embodiment, the image capturing unit 23 can be independent of the transmitting device 21 and through the wired device. The motion picture is transmitted to the transmission device 21 in a wireless manner. In addition, the image capturing unit 23 is not a necessary component of the present creation, and the image capturing unit 23 can be selected according to requirements.

The cloud server 22 is in telecommunication connection with the transmission device 21, the cloud server 22 has a database, and the cloud server 22 receives the second transmission signal and/or the third transmission signal, and the The two transmission signals are converted into the at least one physiological parameter and stored in the database and/or the third transmission signal is converted into a dynamic image signal and stored in the database. The cloud server 22 further has a processor, and can determine the stored physiological parameters according to normal or abnormal physiological parameter reference data or clinical statistical data stored in the database, thereby confirming whether the monitored physiological parameters have abnormal. Once it is determined that the physiological parameter is abnormal, the cloud server 22 can generate a warning mechanism to send a warning message to the caregiver or the caregiver's family by voice or by means of communication. In addition, in the multi-person use mode, taking FIG. 1B as an example, the physiological sensing patch 20 is attached to the human body 90, and the first physiological sensing patch 20a is attached to the first human body 91, and the second physiological sensing is performed. The patch 20b is attached to the second human body 92 for respectively acquiring at least one physiological parameter about the human body 90, the first human body 91, and the second human body 92, and about the human body 90, the first human body 91, and the second Converting the at least one physiological parameter of the human body 92 into a first transmission signal 3a, a fourth transmission signal 3b, and a fifth transmission signal 3c for the first communication protocol, the transmission device 21 and the at least one physiological sensing sticker The first 20th sensing signal 20a and the second physiological sensing patch 20b are connected to each other for receiving the first transmission signal 3a, the fourth transmission signal 3b and the fifth transmission signal 3c, and the transmission device 21 further Processing the first transmission signal 3a, the fourth transmission signal 3b, and the fifth transmission signal 3c to form an output of the second transmission signal 4a, the sixth transmission signal 4b, and the seventh transmission signal 4c of the second communication protocol. The cloud server 22 receives the second transmission No. 4a, a sixth transmission signal 4b, and a seventh transmission signal 4c, and converting the second transmission signal 4a, the sixth transmission signal 4b, and the seventh transmission signal 4c signal into the human body 90, the first human body 91, and the second The at least one physiological parameter of the human body 92 is stored in the database.

In FIG. 1 , the cloud care system 2 further has a terminal device, such as a smart handheld device 24 or an arithmetic processing device 25 , wherein the smart handheld device 24 can be a smart phone and a touch tablet computer, and the like. 25 can be a desktop or a notebook. The smart handheld device 24 or the computing processing device 25 can be installed with an application for connecting to the cloud server, and acquiring the physiological parameter data or the image through the application. The application can be a web browser or a software program or app customized by the service provider.

Please refer to FIG. 2 , which is a block diagram of another embodiment of each component of the cloud care system of the present invention. In this embodiment, each physiological sensing patch 20 further has at least one sensor 200 and a wireless transmission unit 201. The sensor 200 is configured to obtain the at least one physiological parameter about the human body. The wireless transmission unit 201 is electrically connected to the at least one sensor 200 for converting the at least one physiological parameter into a first transmission signal related to the first communication protocol. In one embodiment, the sensor 200 is disposed inside the physiological sensing patch 20 or, in an embodiment, one side of the sensor 200 is directly pasted with a patch to utilize the patch. Attached to the human body or attached to the human body.

The transmission device 21 further includes a receiving unit 210, a processing unit 211, a transmitting unit 212, a memory unit 213, and an image capturing unit 23. The receiving unit 210 receives the first transmission signal. The processing unit 211 is electrically connected to the receiving unit 210 for converting the first transmission signal into a second transmission signal about the second communication protocol. The transmitting unit 212 is electrically connected to the processing unit 211 for outputting the second transmission signal. The memory unit 213 is configured to temporarily store information required for the arithmetic processing. The image capturing unit 23 is in telecommunication connection with the processing unit. The image capturing unit 23 generates a dynamic image about an environment. The processing unit 211 receives the dynamic image and converts the dynamic image into the second image. The third transmission signal of the communication protocol, the cloud server 22 receives the third transmission signal, and converts the third transmission signal into the dynamic image and stores the dynamic image in the database.

The cloud server 22 has a processor 220, a data receiving and transmitting unit 221, a database 222, and a warning unit 223. The processor 220 performs signal processing on the second transmission signal or the third transmission signal received by the data receiving and transmitting unit 221 to restore the second transmission signal to physiological parameter information, and restore the third transmission signal to a motion image. The signal is stored in the database 222. The processor 220 further has an artificial intelligence calculation program for calculating and monitoring the stored physiological parameters. When an abnormality occurs, the processor 220 can control the warning unit 223 to generate a voice or a warning message of the short message, and then The terminal device transmitted to the user terminal via the data receiving and transmitting unit 221 is the smart handheld device 24. In addition, an application is installed in the smart handheld device 24, and the smart handheld device 24 is connected to the cloud server 22 by executing the application. The smart handheld device 24 obtains the physiological condition by using the application. Parameters and/or motion images are displayed on display 240 of smart handheld device 24. It should be noted that the motion image captured by the image capturing unit 23 may include the environmental condition of the caregiver and its surroundings. In an embodiment, when the cloud server 22 further has an image determining unit for determining whether the caretaker in the image is still in the field of view of the image capturing unit 23, if the scope of the field of view is exceeded, the caretaker is absent. In the dynamic image, the cloud server 22 also activates the alert unit 223 to send a voice or a short message to the caregiver, or a person holding the terminal device, to achieve the effect of instant notification.

However, the specific embodiments described above are only used to illustrate the features and functions of the present invention, and are not intended to limit the scope of implementation of the present invention, without departing from the spirit and technology of the present invention. The equivalent changes and modifications made by the present disclosure are still covered by the scope of the following patent application.

2, 2a‧‧ ‧ cloud care system
20‧‧‧Physical sensing patch
20a‧‧‧First physiological sensing patch
20b‧‧‧Second physiological sensing patch
200‧‧‧ sensor
201‧‧‧Wireless transmission unit
21‧‧‧Transportation device
210‧‧‧ Receiving unit
211‧‧‧Processing unit
212‧‧‧Transfer unit
213‧‧‧ memory unit
22‧‧‧Cloud Server
220‧‧‧ processor
221‧‧‧ Data receiving and transmission unit
222‧‧‧Database
223‧‧‧Warning unit
23‧‧‧Image capture unit
24‧‧‧Smart handheld device
240‧‧‧ display
25‧‧‧Operation processing device
3a‧‧‧First outgoing signal
3b‧‧‧fourth transmission signal
3c‧‧‧ fifth transmission signal
4a‧‧‧Second outgoing signal
4b‧‧‧ sixth transmission signal
4c‧‧‧ seventh transmission signal
90‧‧‧ Human body
91‧‧‧ First human body
92‧‧‧Second human body

FIG. 1A is a schematic diagram of an embodiment of a physiological parameter cloud care system according to the present invention. FIG. 1B is a schematic diagram of an embodiment of a physiological parameter cloud care system according to the present invention. FIG. 2 is a block diagram showing an embodiment of various components of the physiological parameter cloud care system of the present invention.

Claims (12)

A physiological parameter cloud care system includes: at least one physiological sensing patch attached to a human body for acquiring at least one physiological parameter of the human body, and converting the at least one physiological parameter into a first a first transmission signal of the communication protocol; a transmission device electrically connected to the at least one physiological sensing patch for receiving the first transmission signal, the transmission device further processing the first transmission signal to form a first a second communication signal output of the second communication protocol; and a cloud server connected to the transmission device, the cloud server has a database, the cloud server receives the second transmission signal, and the The second transmission signal is converted into the at least one physiological parameter and stored in the database. The physiological parameter cloud care system according to claim 1, wherein each physiological sensing patch further comprises: at least one sensor for obtaining the at least one physiological parameter about the human body; and a wireless transmission unit And electrically connected to the at least one sensor for converting the at least one physiological parameter into a first transmission signal related to the first communication protocol. The physiological parameter cloud care system of claim 1, wherein the transmission device further comprises: a receiving unit that receives the first transmission signal; and a processing unit that is electrically connected to the receiving unit for Converting the first transmission signal into a second transmission signal for the second communication protocol; and a transmitting unit electrically connected to the processing unit for outputting the second transmission signal. The physiological parameter cloud care system according to claim 3, wherein the transmission device further has an image capturing unit electrically connected to the processing unit, and the image capturing unit generates a dynamic image about an environment. Receiving, by the processing unit, the dynamic image, and converting the dynamic image into a third transmission signal about the second communication protocol, the cloud server receiving the third transmission signal, and converting the third transmission signal into the dynamic The image is stored in the database. The physiological parameter cloud care system according to claim 1, wherein the first communication protocol is a Bluetooth communication protocol, a wireless network communication protocol, a wireless RF communication, a broadband network communication, a Zigbee, a Thread, a 3G communication protocol, or One of the 4G communication protocols. The physiological parameter cloud care system according to claim 1, wherein the second communication protocol is one of a wireless network communication protocol, a 3G communication protocol, and a 4G communication protocol. The physiological parameter cloud care system according to claim 1, wherein the terminal device has an application device, and the application device is configured to enable the terminal device to communicate with the cloud server. The terminal device obtains the physiological parameter and/or the motion image by the application and displays it on the display of the terminal device. The physiological parameter cloud care system according to claim 1, wherein the physiological parameter comprises one of a heartbeat, a body temperature, a blood pressure, a pulse, an electrocardiogram, a respiratory rate, a blood oxygen concentration, and a combination of at least two of the foregoing. . The cloud parameter server of the physiological parameter described in claim 1, wherein the cloud server further has a warning unit for generating a warning message according to a control signal generated by a controller of the cloud server. The physiological parameter cloud care system according to claim 1, wherein the first communication protocol and the second communication protocol are the same communication protocol. The physiological parameter cloud care system according to claim 1, wherein each physiological sensing patch further has a sensor disposed inside the physiological sensing patch, or the sensor is pasted with a patch. Attached to the human body or attached to the human body. The physiological parameter cloud care system according to claim 1, further comprising at least one first physiological sensing patch and at least one second physiological sensing patch respectively attached to the first human body and the first And the second human body is configured to obtain at least one physiological parameter about the first human body and at least one physiological parameter of the second human body, and convert the at least one physiological parameter about the first human body into the first communication protocol a fourth transmission signal and converting the at least one physiological parameter relating to the second human body into a fifth transmission signal relating to the first communication protocol, the transmission device and the at least one first physiological sensing patch and the At least one second physiological sensing patch telecommunications connection for receiving the fourth transmission signal and the fifth transmission signal, the transmission device further processing the fourth transmission signal and the fifth transmission signal to form a second communication protocol a sixth transmission signal and a seventh transmission signal output, the cloud server receiving the sixth and seventh transmission signals, and converting the sixth and seventh transmission signals into the first The at least one physiological parameter of a human body and the second human body is stored in the database.