CN117079414A - Hospital risk early warning monitoring management platform - Google Patents

Abstract

The application discloses a hospital risk early warning monitoring management platform in the field of medical equipment, which comprises a bracelet, a wireless charger and a service terminal, wherein a controller, a WIFI component, a Bluetooth component, an FNC component, a heart rate and blood pressure pulse detection component, a positioner and a power supply are arranged in the bracelet, a display screen is fixedly connected to the bracelet, an infusion tube heater is fixedly connected to the bracelet, the infusion tube heater is positioned on one side of the display screen, the infusion tube heater is a bent electric heating wire, an SOS key is arranged on the bracelet, the SOS key is positioned on one side of the display screen away from the infusion tube heater, the wireless charger is used for charging the power supply, bluetooth transmitters with different names are arranged in all areas in a hospital, and user information codes are stored in the controller. By adopting the technical scheme of the application, the patient sign can be collected by using the bracelet when the patient goes out of bed to move, and risk early warning can be carried out.

Description

Hospital risk early warning monitoring management platform

Technical Field

The application belongs to the field of medical equipment, and particularly relates to a hospital risk early warning monitoring management platform.

Background

With the refinement and intellectualization of modern hospital management, as an important ring of hospital security risk management, more and more hospitals put attention into the prior management of risks, and it is expected to discover potential risks as early as possible to prevent the potential risks. At present, a medical risk early warning system does not form uniform, complete and standardized management. Most documents are expanded around clinical risk early warning management, and risk early warning discussion on the premise of hospital safety event management is rarely visible, and particularly a related mature early warning model is not found yet. A traditional security risk event refers to an unexpected event that occurs during medical, care, is not planned, unexpected, or is generally undesirable. With the continuous rise of the hospital management level in recent years, the hospital security risk event is gradually widened from a narrow medical and nursing adverse event to a generalized adverse event. The international hospital management guiding wind vane gradually focuses on the hospital risk early warning, because the early warning tool for reasonably using the risk can identify the risk early, problems are prone to be found, and the safety risk event which does not occur is killed in the cradle. Currently, there are drawbacks to the widely used risk assessment tools, such as severity assessment grade matrix, in which there is no well defined specific range of high, medium, low and frequency of occurrence of the risk of injury, typical, and broad, and difficulties in specific use. Therefore, it is very urgent and valuable to develop a series of well-defined hospital security risk event risk early warning tools at the present stage.

In order to solve the problems, patent publication number CN105575056B discloses a comprehensive risk early warning system and an early warning method for a hospital, which comprises a handheld device, a multifunctional sickbed, a nurse station early warning and warning management platform, a doctor station early warning and warning management platform and a data center platform; the handheld device is provided with a first communication module, an electronic tag card reader, a code scanner, an information input module and a first controller; the multifunctional sickbed comprises a sickbed body, an electronic tag, a second communication module, a data input port, a pipeline falling detector, a pressure sensor and a second controller; the nurse station early warning and warning management platform comprises a third controller, a third communication module and a first information prompter; the doctor station early warning and warning management platform comprises a fourth controller, a fourth communication module and a second information prompter; the data center platform comprises a fifth controller, a fifth communication module and a short message sending base station.

According to the comprehensive risk early warning system and the comprehensive risk early warning method for the hospital, the bar code on the wrist strap of the patient is bound with the multifunctional sickbed through the handheld device, the state of the patient is detected, but the patient tends to get down to the sickbed to move, and the system is difficult to obtain physical sign data of the patient when the patient is separated from the sickbed, so that risk early warning is difficult to be carried out on the patient in the moving state.

Disclosure of Invention

In order to solve the problems that in the prior art, patients often get down to move, and the system is difficult to obtain physical sign data of the patients when the patients get away from a sickbed, so that risk early warning is difficult to be carried out on the patients in the movement, the application aims to provide a hospital risk early warning monitoring management platform which can collect physical signs of the patients when the patients get down to move by using a bracelet and carry out risk early warning.

In order to achieve the above object, the technical scheme of the present application is as follows: the hospital risk early warning monitoring management platform comprises a bracelet, a wireless charger and a service terminal, wherein a controller, a WIFI assembly, a Bluetooth assembly, an FNC assembly, a heart rate and blood pressure pulse detection assembly, a positioner and a power supply are arranged in the bracelet, a display screen is fixedly connected to the bracelet, an infusion tube heater is fixedly connected to the bracelet, the infusion tube heater is positioned on one side of the display screen, the infusion tube heater is a curled electric heating wire, an SOS key is arranged on the bracelet, the SOS key is positioned on one side, far away from the infusion tube heater, of the display screen, the wireless charger is used for charging the power supply, bluetooth transmitters with different names are arranged in all areas in the hospital, and user information codes are stored in the controller;

the controller is used for collecting positioning information of the positioner and Bluetooth information connected to the Bluetooth assembly, determining the plane position of the patient according to the positioning information, positioning the floor where the patient is located through the connected Bluetooth name, and transmitting the position information and the sign information of the patient to the service terminal in real time through the WIFI assembly;

the service terminal is used for collecting position information and sign information sent by a patient, judging whether the position of the patient is located in a hospital area, and sending an alarm when the position of the patient exceeds the hospital area; and judging whether the physical sign information of the patient is in a normal range value, and sending out an alarm when the physical sign information of the patient exceeds the normal range value.

After the scheme is adopted, the following beneficial effects are realized: when the patient handles the hospitalization procedure, the user information of the patient is recorded in the bracelet, and the user information code is stored in the controller of the bracelet. The patient can utilize the display screen to show user information code, and the doctor confirms the patient's identity through user information code, reduces the probability that the replacement or impersonation appears in the treatment.

Generally, the patient can keep free walking during hospitalization, so that medical staff is difficult to find the patient in time, and meanwhile, the patient is difficult to detect the sign information of the patient when walking, and sudden illness is easy to occur, so that the patient is in dangerous condition and the medical staff is difficult to find. The wrist ring is worn on the wrist of the patient, so that the physical sign of the patient can be detected at any time, and whether the patient is in danger or not can be known from the data although the detection of the professional instrument is not detailed and accurate. Meanwhile, the locator is arranged in the bracelet, so that whether the patient leaves a hospital privately or not can be detected, and the locator is positioned when the patient cannot move, so that medical staff can conveniently conduct rescue. However, the conventional positioner can only be positioned to a plane position, and a hospital usually has more floors, so that the patient cannot be easily confirmed only by obtaining the plane position of the patient. By setting different Bluetooth transmitters in each area in the hospital, each time a patient arrives in one area, the Bluetooth connected to the patient is switched to the one with the strongest signal due to the different received signal strengths of the different Bluetooth. Through the discernment to bluetooth name can be quick location to the region and the floor that the patient is located, make things convenient for medical staff to search the patient.

However, there is a delay in detecting only the patient's physical sign information to determine whether the patient is in a dangerous state, because significant physical sign information anomalies will occur some time after the patient has developed. When a patient is ill, the SOS key can be used for carrying out rescue call, so that medical staff can learn the condition of the patient more quickly, and the risk of patient deterioration is reduced.

The bracelet obtains the electric quantity through the power supply, but when the power supply is totally exhausted. The patient needs to be infused or treated almost every day during hospitalization, and the patient needs to be on a sickbed when infusing or treating, and at the moment, the electric quantity of the hand ring can be supplemented through the wireless charger. When the patient infuses, the bracelet is because pressing close to infusion position, consequently the transfer line heater can directly heat infusion pipeline, utilizes wireless charger to supplement the electric quantity simultaneously, and the bracelet can generate heat at the charging process, and this partial heat can also act on infusion pipeline, makes the liquid temperature of input more be close to patient's body temperature, reduces the stimulation to the patient to promote patient's comfort level.

Compared with the prior art, through the bracelet, make the patient still can carry out risk detection to patient's state in the activity of getting into bed, through bracelet and bluetooth transmitter, make the bracelet can carry out space location in the hospital, make medical staff can seek patient's position fast, make the patient send the rescue before the sign data descends through the SOS button, reduce the risk that the state of an illness worsens, make the bracelet charge to the bracelet when patient carries out physiotherapy or infusion through wireless charger, and heat infusion pipeline through the transfer line heater, and utilize the temperature that the bracelet produced when charging, improve energy utilization.

Further, a flip cover for accommodating the SOS keys is arranged on the bracelet.

The beneficial effects are that: the patient easily touches SOS button by mistake and leads to medical rescue resource to be wasted, can protect SOS button through flip, reduces the risk of touching by mistake.

Further, the system also comprises ICU physical sign monitoring equipment, wherein the ICU physical sign monitoring equipment is provided with a scanning gun and is used for scanning patient user information codes for binding and uploading physical sign data detected in the ICU to a service terminal;

the service terminal is used for collecting the sign data uploaded by the ICU sign monitoring equipment, and sending out danger early warning when the sign data reach a danger range value.

The beneficial effects are that: ICU wards are often critical patients, unlike ordinary patients, who may be at risk for life at any time, and therefore require additional attention. The ICU physical sign monitoring equipment is bound with the identity of a patient through the user information code, more precise detection equipment is arranged in an ICU ward, more detailed and more precise detection can be realized compared with a bracelet, and when the physical sign of the patient reaches a dangerous range value, dangerous early warning is sent out, and the patient is rescued in time.

Further, the system comprises an outpatient data monitoring device, wherein the outpatient data monitoring device is used for collecting patient diagnosis information filled in when doctors outpatient, the diagnosis information comprises symptoms, disease time, addresses and recent activity content of patients, and when a large number of patients have approximate symptoms and the recent activity and disease time have intersection, early warning of infectious diseases is sent out.

The beneficial effects are that: the clinic is usually a shift, so that it is more difficult for a single doctor to distinguish between infectious diseases and common conditions. Diagnostic information of different doctors in outpatient service is collected through the outpatient service data monitoring equipment, and approximate symptom patients and interaction differences of the approximate symptom patients in the recorded diagnostic information are analyzed.

Further, the outpatient data monitoring device comprises an alarm key and a camera, wherein the alarm key is positioned below a desk of a doctor in an outpatient room, the alarm key is in signal connection with the service terminal, and the camera is positioned on a ceiling of the outpatient room.

The beneficial effects are that: patient families often are noisy with doctors and even collide with limbs due to various events, and security personnel in hospitals are difficult to discover and stop in time. When the family members of the patients do not manage intelligent behaviors, doctors can press the alarm key to timely inform security personnel to process, meanwhile, cameras are arranged in the outpatient service room, and the security personnel can observe the conditions in the outpatient service room through the cameras and actively start to conduct security maintenance.

Further, the system comprises fire monitoring equipment, wherein the fire monitoring equipment comprises a smoke alarm which is in signal connection with the service terminal.

The beneficial effects are that: the patient can cook in the ward privately and lead to the conflagration, can send the police dispatch newspaper through the smog siren when detecting a large amount of smog, in time inform relevant personnel to handle, can in time reduce the conflagration spread speed when the conflagration takes place simultaneously to reduce the probability that the conflagration takes place.

Further, the medical storage data monitoring device is used for recording the medicine taking record of the hospital, calculating the quantity of each medicine in the hospital according to the medicine taking record, and sending out an alarm when the quantity of the medicine is lower than a risk value.

The beneficial effects are that: the medicine storage data monitoring equipment can record the taking and storing conditions of medicines in hospitals, and give an alarm when the medicine reserves are small, so as to remind related personnel of timely supplementing the medicines.

Further, the medicine storage data monitoring device is further used for recording the effective period of medicines when recording the medicine taking and storing records of the hospital, and subtracting the number of medicines close to expiration when calculating the number of medicines and judging the risk value.

The beneficial effects are that: stored medications often have shelf lives and medications that are nearly expired are unusable because they also take a period of time for the patient to take, and are easily expired during the treatment period. And subtracting the number of the medicaments close to expiration from the calculated number of the medicaments, and judging the risk value, so that the medicament storage data is monitored to detect the reserve of the effective medicaments, and the safety of the reserve of the medicaments and the safety of use are ensured.

Further, an inertial sensor is arranged in the bracelet, a small disinfectant storage bottle is arranged on one side of the bracelet away from the display screen, and an electric control nozzle is arranged on the small disinfectant storage bottle;

the controller is used for acquiring acceleration data collected by the inertial sensor, and when the acceleration data rises rapidly from 0 and falls back to 0 for two times in a short time, the electronic control nozzle is started when the acceleration data falls back to 0 for the next time in a short time.

The beneficial effects are that: the inertial sensor can detect acceleration that brings when patient's hand is thrown, and the patient can be when needs disinfect to palm direction round trip swing arm, and inertial sensor can be after detecting a set of swing, and automatically controlled nozzle can be controlled to spray antiseptic solution fog to patient's hand direction by the controller, and patient's hand can be along with the action of waving the hand and contact with antiseptic solution fog to accomplish the disinfection to the hand. The controller can open inertial sensor detection in areas such as bathroom and dining room according to the location information, and close in other areas, reduces the probability of false triggering.

Drawings

Fig. 1 is a schematic view of a bracelet.

FIG. 2 is a schematic diagram of the present application.

Detailed Description

The following is a further detailed description of the embodiments:

reference numerals in the drawings of the specification include: bracelet 1, controller 2, WIFI subassembly 3, bluetooth subassembly 4, FNC subassembly 5, heart rate blood pressure pulse detection subassembly 6, locator 7, power 8, transfer line heater 9, SOS button 10, flip 11, inertial sensor 12, small-size antiseptic solution storage bottle 13, automatically controlled nozzle 14.

Example 1

An example is substantially as shown in figures 1 and 2:

the hospital risk early warning monitoring management platform comprises a bracelet 1, a wireless charger and a service terminal, wherein the model of the wireless charger is S8Ultra, the model of the service terminal is R750XS, a controller 2, a WIFI component 3, a Bluetooth component 4, an FNC component 5, a heart rate and blood pressure pulse detection component 6, a positioner 7 and a power supply 8 are fixed in the bracelet 1 through screws, the model of the controller 2 is STM32F103C8T6, the model of the WIFI component 3 is ESP32-WROVER-E, the model of the Bluetooth component 4 is E104-BT53A1, the model of the FNC component 5 is PN5180, the model of the heart rate and blood pressure pulse detection component 6 is MAX30102, the model of the positioner 7 is ATK1218-BD, the model of the power supply 8 is PL402025, a display screen is arranged on the bracelet 1, the model of the display screen is RP2040, the infusion tube heater 9 is fixed on the bracelet 1 through screws, the infusion tube heater 9 is positioned on one side of the display screen, the infusion tube heater 9 is a bent electric heating wire, the model of the electric heating wire is that an SOS key 10 is fixed on the bracelet 1 through screws, the SOS key 10 is positioned on one side of the display screen far away from the infusion tube heater 9, a wireless charger is used for charging the power supply 8, bluetooth transmitters of different names are arranged in each area in a hospital, the model of each Bluetooth transmitter is CM403, and a user information code is stored in the controller 2;

the controller 2 is used for collecting positioning information of the positioner 7 and Bluetooth information connected to the Bluetooth module 4, determining the plane position of the patient according to the positioning information, positioning the floor where the patient is located through the connected Bluetooth name, and transmitting the position information and the sign information of the patient to the service terminal in real time through the WIFI module 3;

the service terminal is used for collecting position information and sign information sent by a patient, judging whether the position of the patient is located in a hospital area, and sending an alarm when the position of the patient exceeds the hospital area; and judging whether the physical sign information of the patient is in a normal range value, and sending out an alarm when the physical sign information of the patient exceeds the normal range value.

The specific implementation process is as follows: when the patient handles the hospitalization procedure, the user information of the patient is recorded in the bracelet 1, and the user information code is stored in the controller 2 of the bracelet 1. The patient can utilize the display screen to show user information code, and the doctor confirms the patient's identity through user information code, reduces the probability that the replacement or impersonation appears in the treatment. The bracelet 1 is less prone to losing than the hospitalized card in the prior art, and is convenient to integrate more functions. The FNC component 5 enables the bracelet 1 to have a short-range wireless communication technology, so that the bracelet 1 can rapidly authenticate identity through an inductor.

Usually, the patient can keep free walking during hospitalization, but the patient is difficult to find in time by medical staff, and the patient is difficult to detect the sign information of the patient when walking, so that sudden illness is easy to happen, and the patient is in dangerous condition and is difficult to find by medical staff. The wristband 1 is worn on the wrist of the patient and can detect the physical sign of the patient at any time, and although the detection of the professional instrument is not detailed and accurate, whether the patient is at risk can still be known from the data. Meanwhile, the locator 7 is arranged in the bracelet 1, so that whether a patient leaves a hospital privately or not can be detected, and the locator is positioned when the patient cannot move, so that medical staff can conveniently rescue the patient. However, the conventional positioner 7 can only be positioned to a planar position, and there are usually many floors in a hospital, and it is difficult to confirm the floor on which the patient is located only by obtaining the planar position of the patient. By setting different Bluetooth transmitters in each area in the hospital, each time a patient arrives in one area, the Bluetooth connected to the patient is switched to the one with the strongest signal due to the different received signal strengths of the different Bluetooth. Through the discernment to bluetooth name can be quick location to the region and the floor that the patient is located, make things convenient for medical staff to search the patient.

However, there is a delay in detecting only the patient's physical sign information to determine whether the patient is in a dangerous state, because significant physical sign information anomalies will occur some time after the patient has developed. When a patient is ill, the SOS key 10 can be used for carrying out rescue call, so that medical staff can learn the condition of the patient more quickly, and the risk of patient deterioration is reduced. Meanwhile, the calling rescue function is integrated into the key, so that the key can be convenient for old patients to use.

The bracelet 1 obtains the electric quantity through the power supply 8, but when the power supply 8 is totally exhausted. The patient needs to be infused or treated almost every day during the hospitalization period, and the patient needs to be on a sickbed when the infusion or the treatment is carried out, and at the moment, the electric quantity of the hand ring 1 can be supplemented through the wireless charger. When the patient infuses, bracelet 1 is because pressing close to the infusion position, consequently infusion tube heater 9 can directly heat the infusion pipeline, utilizes wireless charger to supplement the electric quantity simultaneously, and bracelet 1 can generate heat at the charging process, and this partial heat can act on the infusion pipeline equally, makes the liquid temperature of input more be close to patient's body temperature, reduces the stimulation to the patient to promote patient's comfort level. And heating element integration makes patient's hand take place when temporarily moving still can utilize the power 8 in the bracelet 1 to supply power and heat on bracelet 1.

According to the application, the risk detection can be carried out on the patient state in the activities of getting out of bed by the bracelet 1, the bracelet 1 and the Bluetooth transmitter can be used for carrying out space positioning in a hospital, medical staff can quickly find the position of the patient, the patient can send rescue before the physical sign data decline by the SOS key 10, the risk of disease deterioration is reduced, the bracelet 1 can be charged by a wireless charger when the patient carries out physiotherapy or transfusion, the transfusion pipeline is heated by the transfusion tube heater 9, the temperature generated by the bracelet 1 during charging is utilized, and the energy utilization rate is improved.

Example two

The difference from the above embodiment is that: the hand ring 1 is rotatably connected with a flip cover 11 for accommodating the SOS key 10.

The specific implementation process is as follows: the patient easily touches SOS button 10 by mistake and leads to medical rescue resource to be wasted, can protect SOS button 10 through flip 11, reduces the risk of touching by mistake.

Example III

The difference from the above embodiment is that: the ICU physical sign monitoring device is connected with a scanning gun in a signal mode, the model of the scanning gun is Aibao 6506, and the ICU physical sign monitoring device is used for scanning patient user information codes to bind and uploading physical sign data detected in the ICU to the service terminal;

the service terminal is used for collecting the sign data uploaded by the ICU sign monitoring equipment, and sending out danger early warning when the sign data reach a danger range value.

The specific implementation process is as follows: ICU wards are often critical patients, unlike ordinary patients, who may be at risk for life at any time, and therefore require additional attention. The ICU physical sign monitoring equipment is bound with the identity of a patient through the user information code, more precise detection equipment is arranged in an ICU ward, more detailed and more precise detection can be realized compared with the bracelet 1, and when the physical sign of the patient reaches a dangerous range value, dangerous early warning is sent out, and the patient is rescued in time.

Example IV

The difference from the above embodiment is that: the system comprises an outpatient data monitoring device, wherein the outpatient data monitoring device is a computer, the model number of the outpatient data monitoring device is 3910-14N6, the outpatient data monitoring device is used for collecting patient diagnosis information filled in during outpatient service of doctors, the diagnosis information comprises symptoms, illness time, address and recent activity content of patients, and when a large number of patients have similar symptoms and the recent activity and illness time have intersection, early warning of infectious diseases is sent.

The specific implementation process is as follows: the clinic is usually a shift, so that it is more difficult for a single doctor to distinguish between infectious diseases and common conditions. Diagnostic information of different doctors in outpatient service is collected through the outpatient service data monitoring equipment, and approximate symptom patients and interaction differences of the approximate symptom patients in the recorded diagnostic information are analyzed.

Example five

The difference from the above embodiment is that: the outpatient data monitoring equipment comprises an alarm key and a camera, the model of the camera is MJSXJ15CM, the alarm key is positioned below a doctor table in an outpatient room, and the camera is positioned on a ceiling of the outpatient room.

The specific implementation process is as follows: patient families often are noisy with doctors and even collide with limbs due to various events, and security personnel in hospitals are difficult to discover and stop in time. When the family members of the patients do not manage intelligent behaviors, doctors can press the alarm key to timely inform security personnel to process, meanwhile, cameras are arranged in the outpatient service room, and the security personnel can observe the conditions in the outpatient service room through the cameras and actively start to conduct security maintenance.

Example six

The difference from the above embodiment is that: the fire disaster monitoring device comprises a smoke alarm, the model of the smoke alarm is YJ-105, and the smoke alarm is in signal connection with a service terminal.

The specific implementation process is as follows: the patient can cook in the ward privately and lead to the conflagration, can send the police dispatch newspaper through the smog siren when detecting a large amount of smog, in time inform relevant personnel to handle, can in time reduce the conflagration spread speed when the conflagration takes place simultaneously to reduce the probability that the conflagration takes place.

Example seven

The difference from the above embodiment is that: the medicine storage data monitoring device is a computer, the model number of the medicine storage data monitoring device is 3910-14N6, the medicine storage data monitoring device is used for recording medicine taking and storing records of hospitals, calculating the quantity of each medicine in the current hospitals according to the medicine taking and storing records, and sending out an alarm when the quantity of the medicine is lower than a risk value.

The specific implementation process is as follows: the medicine storage data monitoring equipment can record the taking and storing conditions of medicines in hospitals, and give an alarm when the medicine reserves are small, so as to remind related personnel of timely supplementing the medicines.

Example eight

The difference from the above embodiment is that: the medicine storage data monitoring equipment is also used for recording the effective period of medicines when recording the medicine taking and storing records of the hospital, and subtracting the number of medicines close to expiration when calculating the number of medicines and judging the risk value.

The specific implementation process is as follows: stored medications often have shelf lives and medications that are nearly expired are unusable because they also take a period of time for the patient to take, and are easily expired during the treatment period. And subtracting the number of the medicaments close to expiration from the calculated number of the medicaments, and judging the risk value, so that the medicament storage data is monitored to detect the reserve of the effective medicaments, and the safety of the reserve of the medicaments and the safety of use are ensured.

Example nine

The difference from the above embodiment is that: an inertial sensor 12 is fixed in the bracelet 1 through screws, the model of the inertial sensor 12 is RS232, a small disinfectant storage bottle 13 is adhered to one side of the bracelet 1 far away from the display screen, and an electric control nozzle 14 is integrally formed on the small disinfectant storage bottle 13;

the controller 2 is configured to acquire acceleration data collected by the inertial sensor 12, and to turn on the electronically controlled nozzle 14 when the acceleration data is rapidly raised from 0 and lowered back to 0 twice in a short time, and then lowered back to 0 again in a short time.

The specific implementation process is as follows: the inertial sensor 12 can detect acceleration that brings when patient's hand is thrown, and the patient can be when needs disinfect, to palm direction back and forth swing arm, and inertial sensor 12 can be after detecting a set of swing, and the automatically controlled nozzle 14 of controller 2 can control sprays antiseptic solution fog to patient's hand direction, and patient's hand can be along with the action of waving the hand and contact with antiseptic solution fog to accomplish the disinfection to the hand. The controller 2 can turn on the inertial sensor 12 for detection in areas such as a bathroom and a canteen according to the positioning information, and turn off in other areas, so that the probability of false triggering is reduced.

The foregoing is merely an embodiment of the present application, and a specific structure and characteristics of common knowledge in the art, which are well known in the scheme, are not described herein, so that a person of ordinary skill in the art knows all the prior art in the application date or before the priority date, can know all the prior art in the field, and has the capability of applying the conventional experimental means before the date, and a person of ordinary skill in the art can complete and implement the present embodiment in combination with his own capability in the light of the present application, and some typical known structures or known methods should not be an obstacle for a person of ordinary skill in the art to implement the present application. It should be noted that modifications and improvements can be made by those skilled in the art without departing from the structure of the present application, and these should also be considered as the scope of the present application, which does not affect the effect of the implementation of the present application and the utility of the patent. The protection scope of the present application is subject to the content of the claims, and the description of the specific embodiments and the like in the specification can be used for explaining the content of the claims.

Claims (9)

1. Hospital risk early warning monitoring management platform, its characterized in that: the intelligent charging device comprises a bracelet, a wireless charger and a service terminal, wherein a controller, a WIFI assembly, a Bluetooth assembly, an FNC assembly, a heart rate, blood pressure and pulse detection assembly, a positioner and a power supply are arranged in the bracelet, a display screen is fixedly connected to the bracelet, an infusion tube heater is fixedly connected to the bracelet, the infusion tube heater is positioned on one side of the display screen, the infusion tube heater is a curled electric heating wire, an SOS key is arranged on the bracelet, the SOS key is positioned on one side of the display screen away from the infusion tube heater, the wireless charger is used for charging the power supply, bluetooth transmitters with different names are arranged in each area in a hospital, and user information codes are stored in the controller;

the controller is used for collecting positioning information of the positioner and Bluetooth information connected to the Bluetooth assembly, determining the plane position of the patient according to the positioning information, positioning the floor where the patient is located through the connected Bluetooth name, and transmitting the position information and the sign information of the patient to the service terminal in real time through the WIFI assembly;

the service terminal is used for collecting position information and sign information sent by a patient, judging whether the position of the patient is located in a hospital area, and sending an alarm when the position of the patient exceeds the hospital area; and judging whether the physical sign information of the patient is in a normal range value, and sending out an alarm when the physical sign information of the patient exceeds the normal range value.

2. The hospital risk early warning monitoring management platform according to claim 1, wherein: the hand ring is provided with a flip cover for accommodating SOS keys.

3. The hospital risk early warning monitoring management platform according to claim 2, wherein: the ICU physical sign monitoring device is provided with a scanning gun and is used for scanning patient user information codes for binding and uploading physical sign data detected in the ICU to the service terminal;

the service terminal is used for collecting the sign data uploaded by the ICU sign monitoring equipment, and sending out danger early warning when the sign data reach a danger range value.

4. The hospital risk early warning monitoring management platform according to claim 3, wherein: the system comprises an outpatient data monitoring device, wherein the outpatient data monitoring device is used for collecting patient diagnosis information filled in when doctors outpatient, the diagnosis information comprises symptoms, disease time, address and recent activity content of patients, and when a large number of patients have similar symptoms and the recent activity and disease time have intersection, the infectious disease early warning is sent out.

5. The hospital risk early warning monitoring management platform according to claim 4, wherein: the outpatient data monitoring equipment comprises an alarm key and a camera, wherein the alarm key is positioned below a desk of a doctor in an outpatient room, the alarm key is in signal connection with the service terminal, and the camera is positioned on a ceiling of the outpatient room.

6. The hospital risk early warning monitoring management platform according to claim 5, wherein: the fire disaster monitoring device comprises a smoke alarm which is connected with a service terminal through signals.

7. The hospital risk early warning monitoring management platform according to claim 6, wherein: the medical storage data monitoring device is used for recording the medicine taking record of the hospital, calculating the quantity of each medicine in the hospital according to the medicine taking record, and sending out an alarm when the quantity of the medicine is lower than a risk value.

8. The hospital risk early warning monitoring management platform according to claim 7, wherein: the medicine storage data monitoring equipment is also used for recording the effective period of medicines when recording the medicine taking and storing records of the hospital, and subtracting the number of medicines close to expiration when calculating the number of medicines and judging the risk value.

9. The hospital risk early warning monitoring management platform according to claim 8, wherein: an inertial sensor is arranged in the bracelet, a small disinfectant storage bottle is arranged on one side of the bracelet away from the display screen, and an electric control nozzle is arranged on the small disinfectant storage bottle;

the controller is used for acquiring acceleration data collected by the inertial sensor, and when the acceleration data rises rapidly from 0 and falls back to 0 for two times in a short time, the electronic control nozzle is started when the acceleration data falls back to 0 for the next time in a short time.