TWI512689B - Cloud rescue system - Google Patents

Description

Cloud rescue system

The invention relates to a cloud rescue system, in particular to a cloud rescue system capable of transmitting the location of an automatic external shock device.

Automated External Defibrillator (English: Automated External Defibrillator, abbreviation: AED) or automatic external defibrillator, automatic electric shock, automatic defibrillator, cardiac defibrillator and fool electric shock, etc., is a portable medical device The automatic extracorporeal electric shock device can diagnose specific arrhythmia and give a defibrillation electric shock, specifically for patients with sudden cardiac arrest outside the hospital for emergency treatment (OHCA).

Because the value of the automatic extracorporeal electric shock device is not high (about 1 to 200,000 Taiwan dollars for an automatic external electric shock device), the penetration rate of the automatic extracorporeal electric shock device in the home or community is not high. In order to save more lives, government departments or administrative agencies will usually deploy automatic external electric shock devices in places where there are a large number of people, such as shopping centers, airports, stations, restaurants, stadiums, schools, etc. and emergency medical services. In Asia, there are more countries and regions with dense populations such as Japan and Hong Kong. In Hong Kong, hospitals, police stations (including the stormtroopers) and ambulance stations are equipped with automatic external electric shock devices. In Taiwan, it is only seen at airports, high-speed rail stations, fire brigade ambulance teams and military health teams. Some airline passenger planes are fully installed; from April 2013, all stations and household affairs of Taipei MRT in Taipei City Public places such as schools and schools will be installed Set this up. Since June 13, 2013, Kaohsiung MRT has also begun installation at the Red Orange Line Station. However, even if the government department distributes the automatic external electric shock device to more places, if the patient has a heartbeat stop where there is no automatic external electric shock device (such as home), the first-aid person next to the patient (bystander) is not easy. The location of the auto-in vitro electric shock device closest to the patient's location was known at the first time. In addition, even if the person outside the body knows the location of the auto-external electric shocker, when the patient is alone, the person on the side must continue to give the patient a first aid (CPR), so the person next to him cannot Go and pick up the automatic extracorporeal electric shock. When the above situation occurs, the person on the side must count on the patient and other supporters of the auto-external electric shock device to take help to take the automatic extracorporeal electric shock.

Therefore, how to enable the bystander to know the location of the auto-external electric shock device closest to the patient's location at the first time, and also to promote the supporter (such as the police officer) that is closest to the patient's position and the location of the extracorporeal electric shock device. , volunteers or other voluntary first-aiders to assist in the delivery of automatic extracorporeal electric shocks, it is worth knowing in the field of ordinary knowledge.

The purpose of this creation is to provide a cloud rescue system that enables first responders to know the location of the auto-external electric shock device closest to the patient's location at the first time.

According to empirical medicine research, if the patient who was arrested before the hospital (OUT-OF-HOSPITAL CARDIAC ARREST, OHCA for short) was given an electric shock within 1 minute, the survival rate was as high as 90%. Heart rhythm of patients with cardiopulmonary dysfunction is divided into ventricular fibrillation (VF) and ventricular tachycardia (VT) without pulse electrical activity ( Pulseless electrical activity (PEA) and cardiac arrest (Asystole), in which VT and VF are shock rhythm, and PEA and ASYSTOLE are non-shock rhythm; early VT/VF will be defibrillated without immediate shock, over time Turned into a non-shockable rhythm of PEA and ASYSTOLE. In empirical medicine, the survival rate of VT/VF is much higher than that of PEA and AYSTOLE, so the earlier the electric shock is defibrillated, the more important it is to stop the cardiopulmonary function, that is, the early electric shock is the key to save such patients. .

Based on the empirical medical foundation, and in accordance with the above and other objects, the present invention aims to provide a cloud rescue system including a plurality of automatic external shock devices, at least one first portable electronic device, and at least two second portable devices. Type electronic device and a servo host. The extracorporeal automatic shock devices are each distributed in a first region of a different geographic location, and each of the automated external shock devices includes at least one automated external electrical shock (AED). The first portable electronic device includes a first positioning module and a first rescue interactive application. The first positioning module can detect the current geographic location of the portable electronic device and save the geographic location as a first location information. The first rescue interactive application includes a first cloud information receiving module and a first rescue sending module. When the first rescue interactive application is started, the first rescue sending module immediately sends the first location information. Each of the second portable electronic devices includes a second positioning module and a second rescue interactive application, and the second positioning module can detect the current geographic location of the second portable electronic device and Save as a third location information. The second rescue interactive application includes a second cloud information receiving module and a second rescue sending module, and the second rescue sending module will send the third position information every other predetermined time. In addition, the servo host includes an emergency control center, a shock device distribution module, an electronic device information receiving module, and a distance calculation module. The emergency control center is stationed in professional online personnel. The electric shock device distribution module will record each The geographic location of the first area, the electronic device information receiving module mainly receives the first and the third location information sent by the rescue interactive application. The distance calculation module calculates a first area where the location is closest to the first location information, and stores the location of the closest first area as a second location information. The server will transmit the second location information to the cloud information receiving module via the Internet. Then, the distance calculation module calculates the second portable electronic device that is closest to the first location information and the second location information according to each third location information received by the electronic device information receiving module, and is closest to The location of the second portable electronic device of the first location information and the second location information is stored as a fourth location information. The server sends the second location information and the fourth location information to the first cloud information receiving module via the Internet, and the server also transmits the first location information and the second location information to the closest one. a second cloud-type information receiving module of the second portable electronic device of the location information and the second location information.

In the above cloud rescue system, the automatic external shock device further includes an outer box, an outer cover detector, a pair of speaking devices, a first camera, and a warning light. The outer box includes a box body and an outer cover, the box body is for receiving an external automatic electric shock device (AED) and the outer body electric shock device (AED) is closed by using the outer cover. The cover detector is disposed between the box body and the outer cover, and the cover detector is configured to detect whether the outer box is opened. The intercom device is placed on the surface of the cabinet, and the user of the automatic external electric shock (AED) can talk to the online personnel of the emergency control center through the intercom. In addition, the first camera is disposed on the surface of the box and is on the same side of the box as the outer cover, and the warning light is disposed on the box. Wherein, when the cover detector detects that the outer box is opened, the first camera immediately records the image in front.

The above-mentioned cloud rescue system, wherein the first area is an external vicinity of a daily business place, and the business place is a business place with a 24-hour daily business hours.

The above-mentioned cloud rescue system, in which the first area is the external proximity of the police station's substation (send).

The cloud rescue system described above, wherein the business place is a convenience store, a large shopping mall, or other similar convenience store.

In the above cloud rescue system, the server further includes a recording module, and the recording module converts the time of the first location information received by the electronic device information receiving module and the first location information itself into a record barcode.

In the above cloud rescue system, the extracorporeal automatic shock device further includes a clip detector, and the clip detector is abutted by an automatic external electric shock (AED).

In the above cloud rescue system, when the automatic external electric shock (AED) leaves the cabinet, the clip detector immediately sends a warning message to the emergency control center.

In the above cloud rescue system, when the cover detector detects that the outer case is opened, the warning light immediately emits light.

In the above cloud rescue system, the first portable electronic device further includes a second camera, and the first rescue interactive application further includes an audio and video interactive module, and the first audio and video interactive module can capture the image captured by the second camera. Transfer to the emergency control center.

In the above cloud rescue system, the first portable electronic device is a smart phone or a tablet computer, and the second portable electronic device is a smart phone or a tablet computer.

10, 30‧‧‧ Cloud Rescue System

11‧‧‧Automatic external shock device

110‧‧‧Automatic external electric shock

111‧‧‧Outer box

112‧‧‧ Cover detector

111A‧‧‧ cabinet

111B‧‧‧ Cover

113‧‧‧ intercom

114‧‧‧First camera

115‧‧‧ warning lights

116‧‧‧Clip type detector

12, 32‧‧‧ first portable electronic device

121‧‧‧First Positioning Module

122, 322‧‧‧ first rescue interactive application

1221‧‧‧The first cloud information receiving module

1222‧‧‧First rescue sending module

13‧‧‧Servo host

131‧‧‧Emergency Control Center

132‧‧‧Electric shock device distribution module

133‧‧‧Electronic device information receiving module

134‧‧‧ Distance calculation module

135‧‧‧recording module

14‧‧‧ Back-end emergency places

15‧‧‧Second portable electronic device

151‧‧‧Second positioning module

152‧‧‧Second Rescue Interactive App

1521‧‧‧Second Cloud Information Receiving Module

1522‧‧‧Second rescue transmission module

3224‧‧‧Video Interactive Module

323‧‧‧second camera

FIG. 1 illustrates the cloud rescue system 10 of the present embodiment.

FIG. 2 is a schematic diagram showing the use of the cloud rescue system 10.

FIG. 3 illustrates the automatic external shock device 11.

Figure 4 shows the extracorporeal automatic electric shock device (AED) 110 moved to the external automatic shock device. A schematic view of the outlet 111A.

FIG. 5 illustrates a cloud rescue system 30 of still another embodiment.

Referring to FIG. 1 , FIG. 1 illustrates a cloud rescue system 10 of the present embodiment. The cloud rescue system 10 includes a plurality of automatic external shock devices 11 , a first portable electronic device 12 , and a plurality of second portable electronic devices. The device 15 and a servo host 13. Each of the extracorporeal automatic shock devices 11 are respectively distributed in a first area of a different geographical position, and the first area is an external vicinity of a general daily business place, that is, an outdoor area close to the business place, and the business place is open 24 hours a day. The nature of the shift is, for example, a convenience store (7-11, a family convenience store) or a large shopping mall (Carrefour). Each of the automatic external shock devices 11 includes an automatic external electrical shock device (AED) 110. The automatic external external shock device 110 is mainly used to defibrillate patients who have stopped the cardiopulmonary function before the hospital. In addition, the first portable electronic device 12 includes a first positioning module 121 and a first rescue interactive application 122. The first portable electronic device 12 is, for example, a smart phone or a tablet. The first positioning module 121 can detect the current geographic location of the first portable electronic device 12 and store the detected geographic location as a first location information. The first rescue interactive application 122 includes a first cloud information receiving. The module 1221 and a first rescue sending module 1222, when the first rescue interactive application 122 is activated, the first rescue sending module 1222 will immediately send out the first location information. In addition, each of the second portable electronic devices includes a second positioning module and a second rescue interactive device, and the second portable electronic device 15 is, for example, a smart phone or a tablet. The second positioning module 151 can detect the current geographic location of the second portable electronic device 15 and store the detected geographic location as a third location information. The second rescue interactive application 152 includes a second cloud information receiving. mold The group 1521 and a second rescue sending module 1522, the second rescue sending module 1522 sends the third position information every predetermined time, for example, 5 minutes or 10 minutes. In the above, the first area is in addition to the external proximity of the general daily business premises, and also includes the external proximity of the police station's sub-resident (sending). The sub-resident (send) also has a 24-hour shift of police officers. .

In addition, the server 13 includes an emergency control center 131, a shock device distribution module 132, an electronic device information receiving module 133, and a distance calculation module 134. The Emergency Control Center 131 has professional online personnel stationed 24 hours a day, and each online staff can teach the public to use the Automatic External Electromagnetic Torque (AED) 110 correctly. The electric shock device distribution module 132 records the geographic location of each of the first regions. Moreover, at intervals, the electric shock device distribution module 132 updates the geographical position of the first region according to the variation of the distribution of the automatic external shock device 11 (when there is a new automatic external shock device 11 added, if it is to be The geographic location of the first region is removed within the shock device distribution module 132 when the automatic external shock device 11 is removed. The electronic device information receiving module 133 mainly receives the first location information sent by the first rescue interactive application 122 and the third location information sent by the second rescue interactive application 152. The distance calculation module 134 mainly calculates the automatic external shock device 11 located closest to the first position information, and stores the position of the closest automatic external shock device 11 as a second position information. Then, the distance calculation module 134 calculates the second portable electronic device 15 that is closest to the first location information and the second location information according to each third location information received by the electronic device information receiving module 133, and The location of the second portable electronic device 15 closest to the first location information and the second location information is stored as a fourth location information. Then, the server 13 immediately transmits the second location information and the fourth location information to the first cloud information receiving module 1221 of the first rescue interactive application 122 via the Internet. and, The server also transmits the first location information and the second location information to the second cloud information receiving module 1521 of the second portable electronic device 15 that is closest to the first location information and the second location information. In the above, the server 13 further includes a recording module 135. The recording module 135 converts the time of the first location information and the first location information received by the electronic device information receiving module 133 into a recording barcode. The record barcode is, for example, a QR code. Moreover, the servo host 13 also immediately transmits the recorded barcode (using the network transmission) to a back-end emergency site 14, such as a hospital emergency room or an emergency fire brigade.

Please refer to FIG. 2 , which is a schematic diagram of using the cloud rescue system 10 . When the patient suddenly stops heartbeat in the home (the patient's home does not have an automatic external electric shock device 110), the family (beside the person) next to the patient can immediately use the smart phone (first portable electronic device) The first rescue interaction module 122 in the first rescue interactive application 122 transmits the current location (first location information) of the first portable electronic device 12 to The servo host 13, the distance calculation module 134 in the servo host 13 will immediately calculate the automatic external shock device 11 closest to the first position information (assuming that the nearest automatic external shock device 11 is placed near the patient's home 7- The external proximity of 11 , that is, the second position information), the servo host 13 will immediately transmit the position (second position information) set by the automatic external shock device 11 to the smart phone of the person (the first carrying) In the electronic device 12), the person in front of the body can obtain the automatic external electrical shock device (AED) 110 in the shortest time to assist the patient. In this way, life-threatening patients can improve their survival rate.

In addition, when the patient is only alone, the person on the side must continue to give the patient a first aid (CPR), so the person outside the body can not personally take the automatic external electric shock device. At the moment, it also holds the smart phone (second portable electronic device 15) Supporters (such as police, volunteers, or other voluntary first-aiders, who have more than one supporter and are located in different areas) can assist in the rescue, and the supporters can assist in the rescue. The reason for the effect is as follows: the second rescue sending module 1522 of the supporter's smart phone transmits the third location information (the current location of the second portable electronic device 15) to the server 13 every 10 minutes, because the supporter is not only 1 person, so the servo host 13 will receive the third position information from each area. Then, the distance calculation module 132 further calculates the second portable electronic device 15 that is closest to the first location information and the second location information according to each third location information received by the server host 13 (closest to the The first location information and the location of the second portable electronic device 15 of the second location information are the fourth location information). Then, the server 13 transmits the fourth location information to the smart phone (the first portable electronic device 12) of the person on the side via the Internet. In addition, the servo host 13 also transmits the current position of the first portable electronic device 12 and the position (second position information) set by the automatic external shock device 11 through the Internet to the first position information and the first The smart phone held by the supporter of the two-position information. In this way, the person who is on the side can not only obtain the automatic external electrical shock (AED) 110 for emergency patients in the shortest time, but also a redundant, voluntary first responder to assist the automatic external shock before the emergency personnel arrive. The device 11 delivers or shocks the first aid, so that patients whose life is at risk can improve their survival rate. In the above, according to the development experience of the countries, in addition to the public emergency organizations such as police and volunteers, the supporters for the voluntary participation in first aid have no budgetary expenditure, so they quickly increase the first-aid coverage rate in the city. . In addition, the automatic external shock device 11 of the present embodiment is provided at a police station adjacent to 7-11 which is open 24 hours a day or has a 24-hour shift station of a police officer, so when the person in the side needs other people to help, Can turn to the service staff on the 7-11 shift or the police officer stationed at the station, so in the majority You can also get help at night.

Please refer to FIG. 3 , which is illustrated as an automatic external shock device 11 . The automatic external shock device 11 further includes an outer box 111, an outer cover detector 112, a pair of speaking devices 113, a first camera 114 and a warning light 115. The outer box 111 includes a box body 111A for accommodating an extracorporeal automatic electric shock device (AED) 110 and an outer cover 111B for closing the auto-in vitro electric shock device (AED) 110. The cover detector 112 is disposed between the casing 111A and the outer cover 111B, and the cover detector 112 can detect whether the outer casing 111 is opened. Further, the intercom device 113 is disposed on the surface of the casing 111A. When the emergency responder who takes the automatic external electrical shock (AED) 110 has problems in operation or first aid, the first-aider can talk to the online personnel of the emergency control center through the intercom device 113 (please refer to FIG. 1). The patient can get the correct rescue procedure and increase the survival rate of the patient. Further, the first camera 114 is disposed on the surface of the casing 111A and is on the same side of the casing 111A as the outer cover 111B, and the warning light 115 is disposed on the top surface of the casing 111A. When the outer cover detector 112 detects that the outer box 111 is turned on, the first camera 114 immediately records the image in front, and the warning light 115 also immediately emits light. The first camera 114 can detect the person who removed the extracorporeal automatic electric shock device (AED) 110 against the front video, effectively preventing the theft of the external automatic electric shock device (AED) 110. In addition, the presence of the warning light 115 can also alert the service personnel in the convenience store that the extracorporeal automatic electric shock (AED) 110 will be extracted.

Please refer to FIG. 4. FIG. 4 is a schematic diagram showing the extracorporeal automatic electric shock device (AED) 110 of the extracorporeal automatic shock device being removed from the casing 111A. The extracorporeal automatic shock device (AED) 110 further includes a clip detector 116. The clip detector 116 is on one side of the housing 111A, and the clip detector 116 is an external external electric shock (AED). 110 is leaning against it. When the auto-in vitro electric shock (AED) 110 is removed from the cabinet, the clip detector 116 senses that the auto-external electric shock (AED) 110 has left the original position. Clip detection The device 116 will immediately send a warning message to the emergency control center 131. In this way, the emergency control center 131 can know that there may be an emergency of the patient, and the emergency control center 131 can immediately notify the back-end emergency site 14 to let the back-end emergency site 14 dispatch the rescue at the first time.

Referring to FIG. 5, FIG. 5 illustrates a cloud rescue system 30 of another embodiment. The first portable electronic device 32 of the cloud rescue system 30 further includes a second camera 323, and the first rescue interactive application 322 further includes Including an audio and video interaction module 3224. After the audio-visual interaction module 3224 is enabled, the video-audio interaction module 3224 immediately transmits the image captured by the second camera 323 to the emergency control center 131. In this way, the online personnel of the emergency control center 131 can use the second camera 323 to view the state of the patient after the fainting, and the online personnel can correctly judge the patient's first-time emergency for the external electric shock. In particular, some patients with sudden death (when the patient is very critical), patients with sudden death may have shortness of breath when they are fainting, and the family members around the patient will think that they do not need to be in vitro. Electric shock, so missed the golden time of patient rescue, so the use of audio and video interactive module 3224 can help patients get the most correct first aid.

The present invention has been described above by way of examples, and is not intended to limit the scope of the claims. The scope of patent protection is subject to the scope of the patent application and its equivalent fields. Modifications or modifications made by those skilled in the art, without departing from the spirit or scope of the invention, are equivalent to the equivalents or modifications made in the spirit of the invention and should be included in the following claims. Inside.

10‧‧‧Cloud Rescue System

11‧‧‧Automatic external shock device

110‧‧‧Automatic external electric shock

12‧‧‧First portable electronic device

121‧‧‧First Positioning Module

122‧‧‧First Rescue Interactive App

1221‧‧‧The first cloud information receiving module

1222‧‧‧First rescue sending module

13‧‧‧Servo host

131‧‧‧Emergency Control Center

132‧‧‧Electric shock device distribution module

133‧‧‧Electronic device information receiving module

134‧‧‧ Distance calculation module

135‧‧‧recording module

14‧‧‧ Back-end emergency places

15‧‧‧Second portable electronic device

151‧‧‧Second positioning module

152‧‧‧Second Rescue Interactive App

1521‧‧‧Second Cloud Information Receiving Module

1522‧‧‧Second rescue transmission module

Claims (8)

A cloud rescue system includes: a plurality of automatic external shock devices, each of which is distributed in a first region of different geographical locations, each of the automatic external shock devices including at least one automatic external shock device (AED) a first portable electronic device, the first portable electronic device includes: at least one first positioning module, the first positioning module can detect a current geographic location of the portable electronic device, and the geographic location The first rescue interactive application includes a first cloud information receiving module and a first rescue sending module, and the first rescue interactive application is activated. The first rescue interactive application includes a first cloud information receiving module and a first rescue sending module. The first rescue transmitting module immediately sends the first location information; at least two second portable electronic devices, each of the second portable electronic devices includes: a second positioning module, the second positioning The module can detect the current geographic location of the second portable electronic device and save the geographic location as a third location information; An interactive application, the second rescue interactive application includes a second cloud information receiving module and a second rescue sending module, and the second rescue sending module sends the third location information every other booking time; a servo host, the servo host includes: an emergency control center; a shock device distribution module, the electric shock device distribution module records each first area Geographical location of the domain; an electronic device information receiving module, the electronic device information receiving module mainly receives the first location information and the third location information; a distance calculation module, the distance calculation module calculates and calculates Positioning the first area closest to the first location information, and storing the location of the closest first area as a second location information, and then the distance calculation module according to the electronic device information receiving mode Each third location information received by the group is used to calculate a second portable electronic device that is closest to the first location information and the second location information, and is closest to the first location information and the second location information The location of the second portable electronic device is stored as a fourth location information; wherein the server sends the second location information and the fourth location information to the first cloud information receiving module via the Internet. And the server host transmits the first location information and the second location information to the second portable electronic device that is closest to the first location information and the second location information. Drive built second information receiver module. The cloud rescue system of claim 1, wherein the automatic external shock device further comprises: an outer box, the outer box comprising a box body and an outer cover, the box body for accommodating the extracorporeal automatic electric shock device (AED) and using the outer cover to close the automatic external electric shock device (AED); an outer cover detector, the outer cover detector is disposed between the box and the outer cover, and the outer cover detector is used To detect whether the outer box is opened; a pair of speaking devices, the intercom device is disposed on the surface of the box, and the user of the automatic external electric shock (AED) can communicate with the emergency control center through the intercom device; a first camera disposed on the surface of the case and in the same housing as the cover On the same side; and a warning light, the warning light is disposed on the box; wherein, when the cover detector detects that the outer box is opened, the first camera immediately records the image in front. The cloud rescue system of claim 1, wherein the server further includes a recording module, and the recording module displays the time and the first location of the first location information received by the electronic device information receiving module. The information itself is converted into a record barcode. The cloud rescue system of claim 2, wherein the extracorporeal automatic shock device further comprises a clip detector, the clip detector being abutted by the automatic external electric shock (AED). The cloud rescue system of claim 4, wherein when the automatic external electrical shock (AED) leaves the cabinet, the clip detector immediately sends a warning message to the emergency control center. The cloud rescue system of claim 2, wherein the warning light is immediately illuminated when the cover detector detects that the outer case is opened. The cloud rescue system of the first aspect of the invention, wherein the first portable electronic device further comprises a second camera, and the first rescue interactive application further comprises an audio-visual interactive module, wherein the audio-visual interactive module can The image captured by the second camera is transmitted to the emergency control center. The cloud rescue system according to any one of the preceding claims, wherein the first portable electronic device is a smart phone or a tablet, and the second portable electronic device is a smart phone or a tablet. .