CN111631696A - 5G network-based wearable device for hospital - Google Patents

Abstract

The application discloses wearing equipment is used in hospital based on 5G network includes: the wearable device is worn on the body of a patient through the wearable shell; the vital sign detection module is arranged on the wearable shell and used for detecting the vital signs of the patient to obtain the current vital sign data of the patient; the 5G chip is arranged in the wearable shell and electrically connected with the vital sign detection module, and the 5G chip is used for sending the current vital sign data of the patient obtained by the vital sign detection module to the hospital side terminal; the data connector is arranged on the wearable shell and electrically connected with the vital sign detection module, and is used for connecting external equipment with the wearable equipment so that the wearable equipment can acquire patient information of the patient from the external equipment; the 5G chip can be used for rapidly sending the data of the patient to the hospital side terminal, and the hospital side can rapidly treat or nurse the patient, so that the requirements for rapid transmission, rapid response and other works of hospital data, which are convenient for death and support, are met.

Description

5G network-based wearable device for hospital

Technical Field

The application relates to the technical field of communication, concretely relates to wearing equipment for hospital based on 5G network.

Background

The 5G technology (fifth generation mobile communication technology) is a new generation communication technology, and the performance targets of the 5G technology are high data rate, reduced delay, energy saving, cost reduction, increased system capacity and large-scale device connection, and the application range of the 5G technology is gradually widened due to the above-mentioned advantages of the 5G technology.

Since the popularization of the 5G technology is limited by the base station, the coverage area of the current 5G network signal is still small, and therefore, research on equipment based on the 5G network is not enhanced by hardware providers, but research after the 5G technology is popularized cannot meet the market demand.

Based on the advantages of the 5G technology and the requirements of the hospital for the work of saving and killing the hand injury and the like, such as the rapid transmission and the rapid response of data, a device which is applied to the hospital and is based on the 5G network is urgently needed.

Disclosure of Invention

In view of this, the application provides a 5G network-based wearable device for hospital to based on the advantage of 5G technique, satisfy the hospital to the work's of being convenient for such as the rapid transmission of data, quick response, kill and support the wound demand.

The application provides a wearing equipment is used in hospital based on 5G network includes: the wearable device is worn on the body of a patient through the wearable shell; the vital sign detection module is arranged on the wearable shell and used for detecting the vital signs of the patient to obtain the current vital sign data of the patient; the 5G chip is arranged in the wearable shell and electrically connected with the vital sign detection module, and the 5G chip is used for sending the current vital sign data of the patient obtained by the vital sign detection module to the hospital side terminal; the data connector is used for connecting external equipment and the wearable equipment so that the wearable equipment can acquire patient information of a patient from the external equipment.

Wherein the vital sign detection module comprises: the skin sensor is arranged on the wearable shell and used for acquiring current detection data of blood pressure, heart rate and body temperature of the patient by monitoring the skin state of the patient; and the memory is electrically connected with the skin sensor and used for receiving and storing the current detection data generated by the skin sensor as the current vital sign data and storing the patient information acquired by the data connector.

Wherein the skin sensor comprises: the infrared emitter is electrically connected with the 5G chip and is used for emitting infrared light to the skin of the patient; a photodetector electrically connected to the infrared emitter, the photodetector for capturing a reflected wave of the skin reflected according to the infrared light emitted by the infrared emitting subunit; a processor electrically connected to the photodetector, for amplifying the reflected wave captured by the photodetector, and calculating a blood pressure value after calculating a time difference of a peak of the reflected wave and a difference of amplitude of the reflected wave; the pulse sensor is electrically connected with the 5G chip and used for capturing the pulse frequency of the patient and calculating the heart rate according to the pulse frequency; and the temperature sensor is electrically connected with the 5G chip and is used for sensing the temperature of the skin of the patient.

Wherein, wearing the casing includes: a housing; the biological recognizer is arranged on the surface of the shell and used for recognizing the patient according to the biological characteristics of the patient; and the biological lock is arranged on the shell and electrically connected with the biological identifier and is used for locking the wearing equipment on the patient according to the identification result of the biological identifier.

Wherein, dress the casing still includes: and the remote unlocking device is electrically connected with the 5G chip and the biological lock and is used for unlocking the biological lock locked by the patient after the 5G chip receives an unlocking signal in the control signal sent by the hospital side terminal.

Wherein, wearing equipment still includes: the setting is on wearing the casing and the little current releaser of being connected with the 5G chip electricity, and little current releaser is used for judging whether normal according to patient's vital sign data is automatic to under the condition that patient's vital sign is abnormal, detect that medical personnel is not present and not receive the control signal of hospital side terminal, release little current and act on to the patient on one's body.

Wherein, wearing equipment still includes: the scheduler integrated module is electrically connected with the micro-current releaser and is used for scheduling the micro-current releaser to release or forbid the release of the micro-current under the condition that a micro-current release signal in a control signal transmitted by a hospital side terminal is received through a 5G chip within preset time, and scheduling the micro-current releaser to automatically release the micro-current under the condition that an operation signal transmitted by the hospital side terminal is not received within preset time; and the model training integrator is used for training a diagnosis model for automatically judging whether the vital signs of the patient are normal or not by the micro-current releaser and deeply learning the diagnosis model to update the diagnosis model.

Wherein, wearing equipment still includes: the alarm emitter is arranged on the wearable shell and electrically connected with the micro-current releaser and the 5G chip, and when the alarm emitter is used for monitoring the micro-current released by the micro-current releaser, the vital signs of a patient are judged to be in an abnormal state, and an alarm signal is emitted to a hospital side terminal through the 5G chip.

Wherein, wearing equipment still includes: the positioner is arranged on the wearing shell and electrically connected with the 5G chip, and is used for sending position data of the patient to the hospital side terminal through the 5G chip after the position of the wearing equipment is positioned; the positioner includes: the electronic map integration module is used for integrating an electronic map; the positioning module is electrically connected with the electronic map integration module and is used for marking the position of the patient on the electronic map integrated by the electronic map integration module; the image making module is electrically connected with the electronic map, the positioning module and the 5G chip and is used for making a current scene map of the electronic map containing the position of the patient into picture data and sending the picture data to the hospital side terminal by using the 5G chip; the map common module is electrically connected with the electronic map and the positioning module, and is used for sharing the map integrated by the electronic map integration module with the hospital side terminal and transmitting the position of the patient to the hospital side terminal in real time by using a 5G chip; and the positioning selection module is electrically connected with the image making module and the map sharing module and is used for monitoring the movement speed of the patient, selecting the image making module or the map sharing module according to the movement speed of the patient and sending the position data of the patient by using the 5G chip.

Wherein, wearing equipment still includes: the life inductor is arranged on the wearable shell and electrically connected with the positioner, and the positioner is opened when the life inductor is used for detecting a life signal of a patient.

The aforesaid wearing equipment for hospital based on 5G network of this application dresses on one's body in the patient, can in time monitor patient's vital sign information, through based on 5G network, can be fast with patient's data transmission to hospital side terminal for hospital side can respond according to patient's vital sign fast, thereby rescues or nurses the patient fast, has consequently satisfied the work of being convenient for to kill and support injuries etc. such as quick transmission, the quick response of hospital data.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic block diagram of a partial structure of a wearable device for a hospital based on a 5G network according to an embodiment of the present application;

fig. 2 is a schematic block diagram of another part of the structure of the wearable device for hospitals based on the 5G network according to the embodiment of the present application;

fig. 3 is a schematic block diagram of a structure of a vital sign detection module of a wearable device for a hospital based on a 5G network according to an embodiment of the present application;

fig. 4 is a schematic block diagram of a structure of a skin sensor of a wearable device for a hospital based on a 5G network according to an embodiment of the present application;

fig. 5 is a block diagram schematically illustrating a structure of a wearable housing of a wearable device for a hospital based on a 5G network according to an embodiment of the present application;

fig. 6 is a block diagram schematically illustrating a structure of a positioner of a wearable device for a hospital based on a 5G network according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application are clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application. The following embodiments and their technical features may be combined with each other without conflict.

Referring to fig. 1, a wearable device for a hospital based on a 5G network includes: the device comprises a wearable shell 1, a vital sign detection module 2, a 5G chip 3 and a data connector 4; the wearable device is worn on the body of a patient through the wearable housing 1; the vital sign detection module 2 is arranged on the wearable shell 1 and used for detecting vital signs of a patient to obtain current vital sign data of the patient; the 5G chip 3 is arranged in the wearable shell 1, is electrically connected with the vital sign detection module 2, and is used for sending the current vital sign data of the patient obtained by the vital sign detection module 2 to a hospital terminal; data connector 4 sets up on wearing casing 1, and is connected with vital sign detection module 2 electricity for plug into external equipment and wearing equipment, so that wearing equipment acquires patient's patient information from external equipment.

When wearing equipment to on one's body at the patient through wearing casing 1, can open vital sign detection module 2 by oneself to detect patient's vital sign, when opening and detecting vital sign detection module 2, can use 5G chip 3 to send to hospital side terminal with patient's current vital sign data voluntarily, thereby can make hospital side grasp patient's health fast, thereby salvage or nurse the patient fast. Therefore, the hospital data transmission system meets the requirements of quick transmission, quick response and the like of hospital data, and is convenient for rescuing the patient with the injury. In addition, it can be understood that the wearing device provided by the present embodiment includes, but is not limited to, a watch or a bracelet.

In addition, in other embodiments, when the patient wears the wearing device to the body through wearing the shell 1, the hospital side can also transmit a control signal, so that the vital sign detection module 2 receives the control signal through the 5G chip 3, the vital sign detection module 2 is turned on, and then the current vital sign data of the patient is automatically sent to the hospital side terminal through the 5G chip 3, so that the hospital side can quickly grasp the physical condition of the patient, and the patient can be quickly treated or nursed. Therefore, the hospital data transmission system meets the requirements of quick transmission, quick response and the like of hospital data, and is convenient for rescuing the patient with the injury.

Referring to fig. 3, the vital sign detection module 2 includes: a skin sensor 21 and a memory 22; the skin sensor 21 is arranged on the wearable shell 1, and the skin sensor 21 is used for acquiring current detection data of blood pressure, heart rate and body temperature of a patient by monitoring the skin state of the patient; the memory 22 is electrically connected with the skin sensor 21, and the memory 22 is used for receiving and storing the current detection data generated by the skin sensor 21 as the current vital sign data and storing the patient information acquired by the data connector 4.

When the vital signs of a patient are detected, the blood pressure, the heart rate and the body temperature of the patient can be detected through the skin sensor 21, and external equipment such as a breathing machine and the like can be connected through the data connector 4 to obtain data of the external equipment for detecting other vital signs of the patient, so that the specific vital signs of the patient can be detected according to needs, and after the current vital signs of the patient are detected, the data of the current vital signs of the patient are stored in the memory 22, so that the current vital sign data of the patient can be conveniently checked by a backup and hospital side through a hospital side terminal; in addition, the data connector 4 may also receive information of the patient from the hospital-side terminal, such as the patient urine volume, other laboratory indexes, and the like, as well as the inpatient, the number of hospitalization, and the like, through data lines or wirelessly, and then store the information in the memory 22 for the hospital-side terminal to view, and the like.

Referring to fig. 4, the skin sensor 21 includes: an infrared emitter 211, a photodetector 212, a processor 213, a pulse sensor 214, and a temperature sensor 215; the infrared emitter 211 is electrically connected with the 5G chip 3, and the infrared emitter 211 is used for emitting infrared light to the skin of the patient; a photodetector 212 electrically connected to the infrared emitter 211, the photodetector 212 for capturing a reflected wave of the skin reflected according to the infrared light emitted from the infrared emitting subunit; the processor 213 is electrically connected to the photodetector 212, and the processor 213 amplifies the reflected wave captured by the photodetector 212, calculates the time difference of the peak of the reflected wave and the difference of the amplitude of the reflected wave, and then calculates the blood pressure value; the pulse sensor 214 is electrically connected with the 5G chip 3, and the pulse sensor 214 is used for capturing the pulse frequency of the patient and calculating the heart rate according to the pulse frequency; the temperature sensor 215 is electrically connected to the 5G chip 3, and the temperature sensor 215 is used for sensing the temperature of the skin of the patient.

When the heart rate of a patient is detected, the infrared emitter 211 is turned on, the infrared emitter 211 emits near infrared rays, the near infrared rays are absorbed by hemoglobin in blood, ordered blood flow changes along with blood pressure changes, the waveform of reflected waves also changes, the reflected waves are captured by the photoelectric detector 212, the difference of the waveforms can be detected, the waveform is amplified, the time difference of formed wave peaks and the difference of wave amplitude are analyzed, and the blood pressure value is calculated. When measuring the heart rate, only the pulse sensor 214 is needed to measure the pulse of the patient, and then the heart rate of the patient is calculated through the conversion relation between the pulse and the heart rate; when measuring the body temperature, the body temperature of the patient can be measured by directly using the temperature sensor 215.

Referring to fig. 5, the wearable housing 1 includes: a housing 11, a biometric identifier 12 and a biometric lock 13; a biological recognizer 12 is arranged on the surface of the shell 11, and the biological recognizer 12 is used for recognizing the patient according to the biological characteristics of the patient; a biological lock 13 is provided on the housing 11 and electrically connected to the biometric identifier 12, the biological lock 13 being used to lock the wearable device on the patient according to the result of the identification by the biometric identifier 12.

After wearing equipment on one's body, biological recognizer 12 automatic identification person's identity starts biological lock 13 afterwards, binds wearing equipment and patient's health to realized the function that wearing equipment's wearing was bound, consequently simplified the flow of binding between patient and the wearing equipment, thereby promoted hospital side's work efficiency.

The wearable housing 1 further includes: a remote unlocker 14; the remote unlocking device 14 is electrically connected with the 5G chip 3 and the biological lock 13, and the remote unlocking device 14 is used for unlocking the biological lock 13 locked by the patient after the 5G chip 3 receives an unlocking signal in the control signal sent by the hospital side terminal.

Through using remote unlocking ware 14, can carry out the unblock for wearing equipment in hospital side terminal is long-range to make the patient take off wearing equipment fast, consequently simplified the flow of binding between patient and the wearing equipment, thereby promoted hospital side's work efficiency.

Referring to fig. 2, the wearable device further includes: a micro-current releaser 5; little current releaser 5 sets up on wearing casing 1 and be connected with 5G chip 3 electricity, and little current releaser 5 is used for judging whether normal according to patient's vital sign data is automatic to the vital sign of patient to under the condition that the vital sign of patient is unusual, detect that medical personnel is not present and not receive the control signal of hospital side terminal, release little current and act on to the patient on one's body.

Through using little electric current releaser 5, can be in patient's vital sign abnormal, medical personnel not be present and do not receive the condition of the control signal of hospital side terminal, release little electric current to the patient to the vital sign of stimulation patient is resumeed, increases patient's survival probability.

In the present embodiment, the memory 22 also stores normal vital sign data of the human body in a normal state.

The micro-current releaser 5 comprises: a comparison unit, an abnormality diagnosis unit and a current release unit; the normal data storage unit is used for storing normal vital sign data of a human body;

the comparison unit is electrically connected with the normal data storage unit and the memory 22 and is used for comparing the current vital sign data and the normal vital sign data stored in the memory 22 to obtain abnormal vital sign data of the patient; the abnormality diagnosis unit is electrically connected with the comparison unit and the 5G chip 3 and is used for matching response data from a preset diagnosis library to diagnose abnormal physical sign data of a patient to obtain a diagnosis result, and the 5G chip 3 is used for sending the diagnosis result and the abnormal physical sign data obtained by the comparison unit to a hospital side terminal; the current release unit is electrically connected with the 5G chip 3 and the abnormity diagnosis unit and is used for automatically releasing micro-current according to the diagnosis result obtained by the abnormity diagnosis unit or responding to a micro-current release signal in an operation signal sent by a hospital side terminal through the 5G chip 3 to release micro-current.

After the vital signs of the patient are detected, the current vital signs of the patient are compared with the data of the normal vital signs of the human body through a comparison unit, so that the abnormal vital signs of the patient are judged, the abnormal vital signs of the patient are input into a pre-trained diagnosis model, so that the illness state diagnosis result of the patient is obtained, a 5G chip 3 is used for sending the diagnosis result to a hospital terminal, finally, a current release unit responds to a micro-current release signal in an operation signal sent by the hospital terminal to release micro-current or automatically releases micro-current according to the illness state diagnosis result, so that the micro-current acts on the patient to stimulate the resuscitation of the vital signs of the patient, and strives for time for rescuing the patient for the arrival of a doctor, so that the survival probability of the patient is increased, wherein the micro-current strength required to be released by different abnormal vital signs of the patient is different, so as to release micro-current with different intensities for different abnormal conditions of the patient.

The wearing equipment still includes: a scheduler integration module 6 and a model training integrator 7; the scheduler integration module 6 is electrically connected with the micro-current releaser 5, and the scheduler integration module 6 is used for scheduling the micro-current releaser 5 to release or forbid the release of the micro-current under the condition that a micro-current release signal in a control signal transmitted by a hospital side terminal is received through the 5G chip 3 within preset time, and scheduling the micro-current releaser 5 to automatically release the micro-current under the condition that an operation signal transmitted by the hospital side terminal is not received within preset time; the model training integrator 7 is electrically connected with the micro-current releaser 5, and the model training integrator 7 is used for training a diagnosis model for automatically judging whether the vital signs of the patient are normal or not by the micro-current releaser 5 and deeply learning the diagnosis model to update the diagnosis model.

In a preset time, the scheduler integration module 6 schedules the current release unit to release or prohibit the micro-current only in response to the micro-current release signal in the control signal sent by the hospital side terminal, so that the probability that the abnormal diagnosis unit diagnoses errors and releases the micro-current which is not suitable for the intensity of the current patient is reduced; and under the condition that the control signal sent by the hospital side terminal is not received within the preset time, the scheduler integration module 6 calls the micro-current releaser 5 to automatically release the micro-current, so that the vital signs of the patient are automatically revived, the time is won for the arrival of the doctor, and the survival probability of the patient is increased.

The method for training the diagnostic model by the model training integrator 7 is as follows: training a convolutional neural network by taking the existing data pair corresponding to the vital sign abnormity and the disease symptoms of a hospital as initial data, and inputting the vital sign abnormity data of the current patient into the convolutional neural network by an abnormity diagnosis unit, so that the convolutional neural network outputs the disease symptoms matched with the vital signs of the patient according to the data pair; when the micro-current released by the micro-current release signal in the control signal sent by the hospital side terminal based on the 5G network is different from the micro-current automatically released, the new data pair appears, and the new data pair is input into the convolutional neural network, so that deep learning of the convolutional neural network is realized, the diagnosis library can be updated in real time, and the disease matched with the vital sign of the patient can be more accurately diagnosed.

The wearing equipment still includes: an alarm transmitter 8; alarm emitter 8 sets up on wearing casing 1 and is connected with little current releaser 5 and 5G chip 3 electricity, and alarm emitter 8 is used for monitoring when little current releaser 5 releases little current, judges that patient's vital sign is abnormal state, transmits alarm signal to hospital side terminal through 5G chip 3.

In the process of detecting the micro-current releaser 5, if the abnormal diagnosis unit 63 of the micro-current releaser 5 obtains the diagnosis result of the patient and the vital signs of the patient are in an abnormal state, the alarm emitter 8 calls the 5G chip 3 to send an alarm signal to the hospital side terminal, so that the hospital side is reminded, the hospital side can perform treatment or nursing on the patient as soon as possible, and the survival probability or nursing experience of the patient is increased.

The wearing equipment still includes: a positioner 9; locator 9 sets up on wearing casing 1 and be connected with 5G chip 3 electricity, and locator 9 is used for after the position of location wearing equipment, sends patient's position data to hospital side terminal through 5G chip 3.

Through using locator 9, can fix a position patient's position fast to promoted the efficiency of hospital side location patient, can look for or rescue the patient fast.

Referring to fig. 6, the positioner 9 includes: the map display system comprises an electronic map integration module 91, a positioning module 92, an image making module 93, a map sharing module 94 and a positioning selection module 95; the electronic map integration module 91 is used for integrating an electronic map; the positioning module 92 is electrically connected with the electronic map integration module 91, and the positioning module 92 is used for identifying the position of the patient on the electronic map integrated by the electronic map integration module 91; the image making module 93 is electrically connected with the electronic map, the positioning module 92 and the 5G chip 3, the image making module 93 is used for making a current scene map of the electronic map containing the position of the patient into picture data, and the 5G chip 3 is used for sending the picture data to the hospital side terminal; the map common module 94 is electrically connected with the electronic map and positioning module 92, and the map common module 94 is used for sharing the map integrated by the electronic map integration module 91 with the hospital terminal and transmitting the position of the patient to the hospital terminal in real time by using the 5G chip 3; the positioning selection module 95 is electrically connected to the image creation module 93 and the map sharing module 94, and the positioning selection module 95 is configured to monitor a movement speed of the patient, and select the image creation module 93 or the map sharing module 94 according to the movement speed of the patient to send the position data of the patient using the 5G chip 3.

The image making module 93 and the map sharing module 94 can send the position of the patient to the hospital side terminal, but both have advantages and disadvantages, the image making module 93 sends image data, so that the memory occupied by transmission data is reduced, the transmission is easier, and the defect is that the position of the patient cannot be shared in real time; the map sharing module 94 can share the location of the patient in real time, but increases the memory occupied by data transmission and the burden of network transmission. Therefore, the movement speed of the patient is monitored by the positioning selection module 95, when the movement speed of the patient is slow or the patient is immobile, the position of the patient is sent to the hospital by the image making module 93, and under the condition that the movement speed of the patient is fast, the position of the patient is transmitted by the map sharing module 94, so that the position of the patient can be positioned more quickly.

The wearing equipment still includes: a life sensor 10; the life sensor 10 is disposed on the wearable housing 1 and electrically connected to the positioner 9, and the positioner 9 is turned on when the life sensor 10 detects a life signal of the patient (i.e., when the wearable housing 1 is positioned on the patient).

In the present embodiment, the life sensor 10 is a body temperature detector or a pulse detector, and it should be understood that the life sensor 10 described in the present application is suitable as long as it can detect that the wearable device is worn on the patient.

Through using the life inductor 10, can judge whether wearing equipment is dressed on one's body on the patient to under the condition on one's body on the patient based on wearing equipment, use locator 9 to fix a position the patient or use vital sign detection module 2 to detect patient's vital sign.

In this embodiment, hospital side terminal is the receiver, and the receiver matches with wearing equipment, and the attending physician of patient holds the receiver with wearing equipment assorted of patient, is integrated with the 5G chip in the receiver to realize the receiver and wearing equipment's 5G communication, thereby make the attending physician of patient can receive patient's vital sign fast, and respond to according to patient's vital sign fast enough, thereby carry out treatment or nursing to the patient fast.

The application provides a 5G network-based hospital uses wearing equipment, its theory of operation or process are as follows: through being based on the 5G network, can be fast with patient's data transmission to hospital side terminal for hospital side can respond according to patient's vital sign fast, thereby carries out treatment or nursing to the patient fast, has consequently satisfied the work of being convenient for such as the quick transmission of hospital data, quick response and kill off the support wound.

Although the application has been shown and described with respect to one or more implementations, equivalent alterations and modifications will occur to others skilled in the art based upon a reading and understanding of this specification and the annexed drawings. This application is intended to embrace all such modifications and variations and is limited only by the scope of the appended claims. In particular regard to the various functions performed by the above described components, the terms used to describe such components are intended to correspond, unless otherwise indicated, to any component which performs the specified function of the described component (e.g., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary implementations of the specification.

That is, the above description is only an embodiment of the present application, and not intended to limit the scope of the present application, and all equivalent structures or equivalent flow transformations made by using the contents of the specification and the drawings, such as mutual combination of technical features between various embodiments, or direct or indirect application to other related technical fields, are included in the scope of the present application.

In addition, structural elements having the same or similar characteristics may be identified by the same or different reference numerals. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more features. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In this application, the word "exemplary" is used to mean "serving as an example, instance, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments. The previous description is provided to enable any person skilled in the art to make and use the present application. In the foregoing description, various details have been set forth for the purpose of explanation. It will be apparent to one of ordinary skill in the art that the present application may be practiced without these specific details. In other instances, well-known structures and processes are not shown in detail to avoid obscuring the description of the present application with unnecessary detail. Thus, the present application is not intended to be limited to the embodiments shown, but is to be accorded the widest scope consistent with the principles and features disclosed herein.

Claims (10)

1. The utility model provides a wearing equipment is used in hospital based on 5G network which characterized in that includes:

the wearable device is worn on the body of a patient through the wearable shell;

the vital sign detection module is arranged on the wearable shell and used for detecting the vital signs of the patient to obtain the current vital sign data of the patient;

the 5G chip is arranged in the wearable shell and electrically connected with the vital sign detection module, and the 5G chip is used for sending the current vital sign data of the patient obtained by the vital sign detection module to the hospital side terminal;

the data connector is used for connecting external equipment and the wearable equipment so that the wearable equipment can acquire patient information of a patient from the external equipment.

2. The 5G network-based wearable device for hospitals according to claim 1,

the vital sign detection module comprises:

the skin sensor is arranged on the wearable shell and used for acquiring current detection data of blood pressure, heart rate and body temperature of the patient by monitoring the skin state of the patient;

and the memory is electrically connected with the skin sensor and used for receiving and storing the current detection data generated by the skin sensor as the current vital sign data and storing the patient information acquired by the data connector.

3. The 5G network-based wearable device for hospitals according to claim 2,

the skin sensor includes:

the infrared emitter is electrically connected with the 5G chip and is used for emitting infrared light to the skin of the patient;

a photodetector electrically connected to the infrared emitter, the photodetector for capturing a reflected wave of the skin reflected according to the infrared light emitted by the infrared emitting subunit;

a processor electrically connected to the photodetector, for amplifying the reflected wave captured by the photodetector, and calculating a blood pressure value after calculating a time difference of a peak of the reflected wave and a difference of amplitude of the reflected wave;

the pulse sensor is electrically connected with the 5G chip and used for capturing the pulse frequency of the patient and calculating the heart rate according to the pulse frequency;

and the temperature sensor is electrically connected with the 5G chip and is used for sensing the temperature of the skin of the patient.

4. The 5G network-based wearable device for hospitals according to claim 1,

the wearing case includes:

a housing;

the biological recognizer is arranged on the surface of the shell and used for recognizing the patient according to the biological characteristics of the patient;

and the biological lock is arranged on the shell and electrically connected with the biological identifier and is used for locking the wearing equipment on the patient according to the identification result of the biological identifier.

5. The 5G network-based wearable device for hospitals according to claim 4, wherein said wearable housing further comprises:

and the remote unlocking device is electrically connected with the 5G chip and the biological lock and is used for unlocking the biological lock locked by the patient after the 5G chip receives an unlocking signal in the control signal sent by the hospital side terminal.

6. The 5G network-based wearable device for hospitals according to claim 1,

the wearing apparatus further includes:

the setting is on wearing the casing and the little current releaser of being connected with the 5G chip electricity, and little current releaser is used for judging whether normal according to patient's vital sign data is automatic to under the condition that patient's vital sign is abnormal, detect that medical personnel is not present and not receive the control signal of hospital side terminal, release little current and act on to the patient on one's body.

7. The 5G network-based wearable device for hospitals according to claim 6,

the wearing apparatus further includes:

the scheduler integrated module is electrically connected with the micro-current releaser and is used for scheduling the micro-current releaser to release or forbid the release of the micro-current under the condition that a micro-current release signal in a control signal transmitted by a hospital side terminal is received through a 5G chip within preset time, and scheduling the micro-current releaser to automatically release the micro-current under the condition that an operation signal transmitted by the hospital side terminal is not received within preset time;

and the model training integrator is used for training a diagnosis model for automatically judging whether the vital signs of the patient are normal or not by the micro-current releaser and deeply learning the diagnosis model to update the diagnosis model.

8. The 5G network-based wearable device for hospitals according to claim 6,

the wearing apparatus further includes:

the alarm emitter is arranged on the wearable shell and electrically connected with the micro-current releaser and the 5G chip, and when the alarm emitter is used for monitoring the micro-current released by the micro-current releaser, the vital signs of a patient are judged to be in an abnormal state, and an alarm signal is emitted to a hospital side terminal through the 5G chip.

9. The 5G network-based wearable device for hospitals according to claim 1,

the wearing apparatus further includes:

the positioner is arranged on the wearing shell and electrically connected with the 5G chip, and is used for sending position data of the patient to the hospital side terminal through the 5G chip after the position of the wearing equipment is positioned;

the positioner includes:

the electronic map integration module is used for integrating an electronic map;

the positioning module is electrically connected with the electronic map integration module and is used for marking the position of the patient on the electronic map integrated by the electronic map integration module;

the image making module is electrically connected with the electronic map, the positioning module and the 5G chip and is used for making a current scene map of the electronic map containing the position of the patient into picture data and sending the picture data to the hospital side terminal by using the 5G chip;

the map common module is electrically connected with the electronic map and the positioning module, and is used for sharing the map integrated by the electronic map integration module with the hospital side terminal and transmitting the position of the patient to the hospital side terminal in real time by using a 5G chip;

and the positioning selection module is electrically connected with the image making module and the map sharing module and is used for monitoring the movement speed of the patient, selecting the image making module or the map sharing module according to the movement speed of the patient and sending the position data of the patient by using the 5G chip.

10. The 5G network-based wearable device for hospitals according to claim 9,

the wearing apparatus further includes:

the life inductor is arranged on the wearable shell and electrically connected with the positioner, and the positioner is opened when the life inductor is used for detecting a life signal of a patient.

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