CN111228607A - Drip monitoring system and method - Google Patents

Abstract

The invention discloses a drip monitoring system and a method, wherein the drip monitoring system comprises: the system comprises a first server, a second server, a drip detection device and an electronic device. The second server is in communication connection with the first server and is used for receiving the drip information provided by the first server; the drip detection device is in communication connection with the first server and used for detecting the drip monitoring information and transmitting the drip monitoring information to the first server; the electronic device is in communication connection with the first server and used for receiving the drip information transmitted by the first server. The first server is used for calculating the drip flow rate according to the drip monitoring information, the drip information comprises the drip monitoring information and the drip flow rate, and the first server is further used for transmitting control information to the drip monitoring device. Therefore, the drip monitoring system can achieve the effects of monitoring the drip in real time and reducing the burden of caregivers.

Description

Drip monitoring system and method

Technical Field

The present invention relates to monitoring technology, and more particularly, to a drip monitoring system and method.

Background

Most of medical transfusion is gravity drip, i.e. a liquid bag or a liquid bottle is hung on a fixed frame, so that the liquid drips into blood due to natural gravity. The setting of the bit needs to have the weight of different bits according to different medicaments, different brands, therefore if will monitor the weight of bit will need to adjust to different bits, at present, the monitoring mode of bit process still adopts artifical guardianship, when finding that the bit is ended or bit process is unusual, need manually press alarm button or inform the caregiver to handle.

Furthermore, besides professional medical personnel, it is difficult for general patients or families to know the state of the drip (how much time is left for the drip to drip off, the drip speed, etc.), so that the patients or families are inconvenienced due to the fact that the condition of the drip needs to be noticed all the time, and the workload of caregivers is increased due to the lack of an efficient monitoring mode. Therefore, how to design an intravenous drip monitoring system to solve the above problems is an urgent need in the art.

Disclosure of Invention

The invention mainly aims to provide an infusion monitoring system and method, which mainly improve the effect that the traditional infusion monitoring process adopts a manual monitoring mode, an infusion detection device is used for sensing the weight of an infusion in real time, the weight of the infusion is transmitted to a cloud server in real time, and a patient, family members or a caregiver can know the state of the infusion or further control the infusion through the cloud server, so that the effects of monitoring the infusion in real time and reducing the burden of the caregiver are achieved.

In order to achieve the above object, an embodiment of the present invention provides a droplet monitoring system, including: the system comprises a first server, a second server, a drip detection device and an electronic device. The second server, the drip detection device and the electronic device are all in communication connection with the first server. The second server is used for receiving the drip information provided by the first server, the drip detection device is used for detecting the drip monitoring information and transmitting the drip monitoring information to the first server, and the electronic device is used for receiving the drip information transmitted by the first server. The first server is further used for calculating the drip flow rate according to the drip monitoring information, the drip information comprises the drip monitoring information and the drip flow rate, the electronic device is further used for transmitting the control information to the first server, and the first server can transmit the control information to the drip monitoring device.

According to an embodiment of the present disclosure, the drip monitoring system further comprises: the third server is in communication connection with the first server and used for receiving the drip information provided by the first server and transmitting monitoring information to the first server; the monitoring information comprises blood pressure information, heartbeat information and body temperature information.

According to an embodiment of the present invention, the droplet detecting apparatus further comprises: a processor; the weight sensing unit is electrically connected with the processor and is used for sensing the weight information of the drip and transmitting the weight information to the processor; the communication module is electrically connected with the processor and used for receiving the control information and the alarm value transmitted by the first server; the alarm module is electrically connected with the processor and used for sending out a warning signal; the power supply module is electrically connected with the processor, the weight sensing unit, the communication module and the alarm module and used for providing electric quantity required by the processor, the weight sensing unit, the communication module and the alarm module; the processor is used for judging whether the weight information is smaller than or equal to the alarm value, if so, the alarm module is controlled to send out an alarm signal, and the processor is also used for enabling or disabling the alarm module according to the control information.

According to an embodiment of the present disclosure, the processor is further configured to transmit droplet monitoring information to the first server through the communication module, where the droplet monitoring information includes an identification number of the droplet detection device, a name of the droplet detection device, a status of the droplet detection device, an alarm value, and weight information.

According to an embodiment of the disclosure, the first server is further configured to record the weight information, and calculate a weight difference between the current weight information and the previous weight information to determine whether the weight difference is greater than a threshold value.

According to an embodiment of the disclosure, the processor is further configured to detect an electric quantity of the power supply module and transmit electric quantity information to the first server through the communication module.

According to an embodiment of the present disclosure, the drip detection device further includes an identification barcode, and the electronic device is configured to check the drip information and the power information according to the identification barcode.

According to an embodiment of the present disclosure, the electronic device is further configured to transmit control information to the droplet detecting device through the first server.

Another embodiment of the present invention provides a method for droplet monitoring, comprising: detecting drip monitoring information through a drip detection device, and transmitting the drip monitoring information to a first server; calculating the drip flow rate according to the drip monitoring information; transmitting the drip information to a second server and the electronic device; wherein the drip information comprises drip monitoring information and drip flow rate; receiving control information transmitted by the electronic device; and transmitting control information to the droplet detecting device.

According to an embodiment of the present invention, the drop monitoring method further comprises: receiving monitoring information transmitted by a third server, and transmitting drip information to the third server; the monitoring information comprises blood pressure information, heartbeat information and body temperature information.

According to an embodiment of the present invention, the droplet detecting device is further configured to: receiving control information and an alarm value transmitted by the first server; detecting the weight information of the drip; and judging whether the weight information is less than or equal to the alarm value, and if so, sending out an alarm signal.

According to an embodiment of the present invention, the droplet detecting device is further configured to transmit the droplet monitoring information to the first server, wherein the droplet monitoring information includes an identification number of the droplet detecting device, a name of the droplet detecting device, a status of the droplet detecting device, an alarm value, and weight information.

According to an embodiment of the disclosure, the first server is further configured to record the weight information, and calculate a weight difference between the current weight information and the previous weight information to determine whether the weight difference is greater than a threshold value.

According to an embodiment of the present invention, the droplet detecting device is further configured to transmit the power information to the first server.

According to an embodiment of the present disclosure, the drip detection device includes an identification barcode, and the electronic device is configured to check the drip information and the power information according to the identification barcode.

According to an embodiment of the present invention, the drop monitoring method further comprises: the electronic device transmits control information to the droplet detection device through the first server.

The invention relates to a drip monitoring system and a method, which mainly improve the effect that the prior drip monitoring process adopts a manual monitoring mode, a drip detection device is utilized to sense the weight of a drip in real time, the weight of the drip is transmitted to a cloud server in real time, a patient or a caregiver can know the state of the drip through the cloud server or further control the drip, and the effects of monitoring the drip in real time and reducing the burden of the caregiver are achieved.

Drawings

FIG. 1 is a schematic diagram of a drop monitoring system according to some embodiments of the present invention;

fig. 2 is a schematic diagram of a droplet detection apparatus according to some embodiments of the present invention; and

fig. 3 is a flow chart of a method of drop monitoring according to some embodiments of the invention.

Detailed Description

The following disclosure provides many different embodiments or illustrations for implementing different features of the invention. The elements and configurations of the specific examples are used in the following discussion to simplify the present invention. Any examples discussed are intended for illustrative purposes only and do not limit the scope or meaning of the invention or its illustrations in any way. Furthermore, the present invention may repeat reference numerals and/or letters in the various examples, which are included for simplicity and clarity and do not in themselves dictate a relationship between the various embodiments and/or configurations discussed below.

The term (terms) used throughout the specification and claims has the ordinary meaning as commonly understood in each term used in the art, in the disclosure herein, and in the specific context, unless otherwise indicated. Certain terms used to describe the invention are discussed below or elsewhere in this specification to provide additional guidance to those skilled in the art in describing the invention.

As used herein, coupled or connected may mean that two or more elements are in direct physical or electrical contact with each other, or in indirect physical or electrical contact with each other, and coupled or connected may mean that two or more elements operate or act in conjunction with each other.

It will be understood that the terms first, second, third, etc. may be used herein to describe various elements, components, regions, layers and/or sections. These elements, components, regions, layers and/or regions should not be limited by these terms. These terms are only used to distinguish one element, component, region, layer or section from another. Thus, a first element, component, region, layer or section discussed below could be termed a second element, component, region, layer or section without departing from the teachings of the present invention. As used herein, the vocabulary and/or includes any combination of one or more of the associated listed items. Where in this document reference is made to and/or is intended to refer to any one, all or any combination of at least one of the listed elements.

Please refer to fig. 1. Fig. 1 is a schematic diagram of a drip monitoring system 100 according to some embodiments of the disclosure. As shown in fig. 1, the drip monitoring system 100 includes a first server 110, a second server 120, a third server 130, a drip detection device 140, and an electronic device 150, wherein the first server 110 is communicatively connected to the second server 120, the third server 130, the drip detection device 140, and the electronic device 150, respectively. The droplet detecting device 140 is used for detecting the droplet monitoring information and transmitting the droplet monitoring information to the first server 110. The first server 110 transmits the spot information to the second server 120, the third server 130, and the electronic device 150. The third server 130 is used for transmitting the monitoring information to the first server 110. The first server 110 is configured to calculate a droplet flow rate according to the droplet monitoring information, and the droplet information includes the droplet monitoring information and the droplet flow rate. The electronic device 150 is configured to transmit control information to the first server 110, and the first server 110 transmits the control information to the drip monitoring device 140.

In this embodiment, the second server 120 may be implemented as a server inside a hospital, the third server 130 may be implemented as a medical cloud server of another business, and the electronic device 150 may be implemented as a smart phone, a tablet computer or a wearable device used by a patient, a family member or medical staff.

Please refer to fig. 2. Fig. 2 is a schematic diagram of a droplet detection device 140 according to some embodiments of the disclosure. As shown in fig. 2, the drip detection device 140 includes a processor 141, a weight sensing unit 142, a communication module 143, an alarm module 144, and a power supply module 145. The processor 141 is electrically connected to the weight sensing unit 142, the communication module 143, the alarm module 144 and the power supply module 145, and the power supply module 145 is electrically connected to the weight sensing unit 142, the communication module 143 and the alarm module 144. The weight sensing unit 142 is used for detecting the weight information of the drip and transmitting the weight information to the processor 141. The communication module 143 is configured to receive the control information and the alarm value transmitted by the first server 110, the alarm module 144 is configured to send an alarm signal, and the power supply module 145 is configured to provide the power required by the processor 141, the weight sensing unit 142, the communication module 143, and the alarm module 144. The processor 141 is configured to determine whether the weight information is less than or equal to the warning value, and if so, control the alarm module 144 to send a warning signal, and enable or disable the alarm module 144 according to the control information.

In one embodiment, the processing unit 141 may be implemented as an integrated circuit such as a micro control unit (microcontroller), a microprocessor (microprocessor), a digital signal processor (digital signal processor), an Application Specific Integrated Circuit (ASIC), a logic circuit, or other similar components or combinations thereof. The communication module 143 may be implemented as global system for mobile communication (GSM), personal handy-phone system (PHS), Long Term Evolution (LTE), Worldwide Interoperability for Microwave Access (WiMAX), wireless fidelity (Wi-Fi), bluetooth wireless technology (bluetooth), etc. The alarm module 144 may be implemented as a buzzer, a light emitting element, a combination thereof, or the like, which may emit a warning sound or a flashing light. The power supply module 145 may be implemented as a battery or a power supply line.

The operation of drip monitoring system 100 will be described in detail below with reference to fig. 1-3. Please refer to fig. 3. Fig. 3 is a flow chart of a method 300 of drop monitoring according to some embodiments of the disclosure. The droplet monitoring method 300 can be applied to the droplet monitoring system 100 of fig. 1 and the droplet detecting device 140 of fig. 2. The method 300 for real-time droplet monitoring comprises the following steps (it should be understood that the steps mentioned in this embodiment, except the sequence specifically mentioned, can be performed simultaneously or partially simultaneously according to the actual requirement.

In step S310, the droplet detecting device 140 detects droplet monitoring information and transmits the droplet monitoring information to the first server 110. In one embodiment, the weight sensing unit 142 of the droplet detection device 140 detects the weight information of the droplet, the processor 141 determines whether the weight information is less than or equal to the alarm value, and if not, the state of the droplet detection device 140 is under monitoring; if yes, the state of the drip detection device 140 is switched to alarm, and the processor 141 controls the alarm module 144 to send out an alarm signal, which may be a warning sound or a warning light, but the invention is not limited thereto.

In one embodiment, if the drip detection device 140 automatically detects whether the weight of the drip is the same as the previous drip after the drip is replaced by the caregiver, if the weight of the drip is the same as the previous drip, the alarm value is not set, and if the weight of the drip is not the same as the previous drip, the alarm value is input again. In another embodiment, if the alarm value needs to be adjusted to replace a drip of a different item, the caregiver may reset the alarm value.

In view of the above, the processor 141 is configured to transmit the drip monitoring information to the first server 110 through the communication module 143, where the drip monitoring information includes information such as the identification number of the drip detection device, the name of the drip detection device, the status of the drip detection device, the alarm value, and the weight information. The droplet detection device name can be a name set by a user, such as dad's droplet, and the droplet detection device status is the current status of the droplet detection device, such as monitoring, alarming, pausing, waiting, clearing, and the like. The weight information is the information sensed by the weight sensing unit 142, and is described in the previous paragraphs, which is not repeated herein.

In step S320, a droplet flow rate is calculated based on the droplet monitoring information. In one embodiment, first server 110 is further configured to calculate a droplet flow rate based on droplet monitoring information, the droplet monitoring information including a droplet detection device identification number, a droplet detection device name, a droplet detection device status, an alarm value, and weight information. For example, the first server 110 may calculate the flow rate (weight information/time) of the drip within a period of time, which may be 20 seconds or 30 seconds, but the invention is not limited thereto. In another embodiment, the first server 110 is further configured to calculate the remaining time of the drip based on the weight information, for example, the first server 110 may calculate that the drip has run out of 50 minutes. As can be seen from the above, the droplet flow rate and the remaining time are calculated by the server 110, and the droplet information includes the droplet monitoring information, the droplet flow rate and the remaining time from the droplet detecting device 140.

In view of the above, the processor 141 is further configured to detect the power of the power supply module 145, and transmit power information to the first server 110 through the communication module 143. For example, when the power supply module 145 is implemented as a battery, the processor 141 may detect a remaining power level, and transmit power level information to the first server 110 together with the drip information, wherein the power level information is used to remind the patient or the caregiver of the battery status of the drip detection device 140, so as to remind the relevant person to replace the battery before the battery is used up.

In an embodiment, the first server 110 is further configured to record weight information within a period of time, and calculate a weight difference between the current weight information and the previous weight information to determine whether the weight difference is greater than a threshold value. For example, the initial weight of the droplet is 500 g, the weight of the droplet after 3 minutes is 480 g, and the weight of the droplet after 5 minutes is 10 g, at which time the processor 141 detects that the weight of the droplet changes to-470 g, and the weight change is greater than the threshold value, so the first server 110 determines that the condition is an abnormal condition. The abnormal condition may be that the weight of the drip drops is changed too much by a person pulling the drip drop detecting device 140, or the drip drop tube is blocked, so that the weight of the drip drops is not changed for a period of time. If the abnormal condition is released, the first server 110 notifies the processor 141 to control the alarm module 144 not to send the alarm signal, but if the abnormal condition is not released within a period of time, the first server 110 notifies the processor 141 to control the alarm module 144 to send the alarm signal, so as to alert the relevant person of the occurrence of the abnormal condition of the drip detection device 140.

In steps S330 and S340, the first server 110 transmits the drip information to the second server 120, the third server 130 and the electronic device 150, and the first server 110 receives the monitoring information transmitted by the third server 130. In one embodiment, the first server 110 receives the droplet information and then transmits the droplet information to the second server 120, the third server 130 and the electronic device 150. The third server 130 also transmits monitoring information to the first server 110, wherein the monitoring information may be blood pressure information, heartbeat information, and body temperature information. For example, the first server 110 and the third server 130 may transmit information to each other, and the third server 130 may be a cloud server that collects information such as heart beat, blood pressure or body temperature, so as to exchange data with the first server 110. In another embodiment, the first server 110 sends the drip information to the third server 130, and the third server 130 can use the drip information for subsequent operations, for example, to provide the drip information to the user served by the third server 130. The second server 120 is a server inside the hospital, and because the personal data of the patient is kept secret, the second server 120 cannot necessarily transmit the information with the personal information of the patient to the first server 110, but only receives the drip information from the first server 110.

In another embodiment, the first server 110 can transmit the power information to the electronic device 150 when transmitting the drip information, so as to remind the patient or the caregiver of the current power of the battery of the drip detection device 140.

In steps S350 and S360, the control information transmitted by the electronic device 150 is received, and the first server 110 transmits the control information to the droplet detecting device 140. In one embodiment, the electronic device 150 is configured to transmit control information to the first server 110, the first server 110 transmits the control information to the drip monitor 140, and the drip monitor 140 is configured to enable or disable the alarm module 144 according to the control information. For example, the first server 110 may open the right to the caregiver, so that the caregiver uses the electronic device 150 to transmit the control information to the first server 110, thereby controlling the droplet detecting device 140 to enable or disable the alarm module 144 at a specific time, so as to control the plurality of droplet detecting devices 140, thereby reducing the burden of the caregiver in setting the droplet detecting device 140.

For example, a caregiver can use the electronic device 150 to set a rest time of 0 to 6 am, and the alarm module 144 is kept in the off state, so that when the weight of the drip is less than or equal to the alarm value, the alarm module 144 will not sound or light to prompt the caregiver, but the drip detection device 140 will still transmit the alarm information to the electronic device 150 to remind the caregiver to check the drip.

In light of the above, the drip detection device 140 may have an identification bar code thereon, and the electronic device 150 is used for checking the drip information and the power information according to the identification bar code. The identification barcode may be implemented as a one-dimensional barcode or a two-dimensional barcode, but the invention is not limited thereto. For example, a patient or a caregiver can directly use the electronic device 150 to scan the identification barcode and then view the drip information and the power information of the drip detection device 140, so that the relevant personnel can more quickly know the current status of the drip (the remaining time of the drip, the flow rate of the drip, the current weight, etc.). The caregiver may have a higher authority to modify the drip information of the drip detection device 140, such as modifying an alarm value.

In view of the above, after the electronic device 150 has utilized the identification barcode to check the droplet information and the power information, the first server 110 records the identification information of the electronic device 150 and the checked identification number of the droplet detection device 140, and the first server 110 automatically transmits the droplet information and the power information of the droplet detection device 140 to the electronic device 150 without rescanning the identification barcode. For example, a caregiver has 3 patients to care, the drops of the 3 patients are respectively the drop detection device a, the drop detection device B, and the drop detection device C, and after the electronic device 150 of the caregiver scans the identification barcodes corresponding to the drop detection device a, the drop detection device B, and the drop detection device C, the electronic device 150 of the caregiver can automatically receive the drop information and the power information of the drop detection device a, the drop detection device B, and the drop detection device C.

The above embodiments of the present invention mainly improve the prior art that the drip monitoring process adopts a manual monitoring mode, the drip detection device is used for sensing the weight of the drip in real time, and the weight of the drip is transmitted to the cloud server in real time, so that a patient or a caregiver can know the state of the drip or further control the drip through the cloud server, and can detect abnormal conditions, thereby achieving the effects of monitoring the drip in real time and reducing the burden of the caregiver and the caregiver.

Additionally, the above illustration includes exemplary steps in sequential order, but the steps need not be performed in the order shown. It is within the contemplation of the invention that the steps are performed in a different order. Steps may be added, substituted, changed in order, and/or omitted as appropriate within the spirit and scope of embodiments of the present disclosure.

Although the present invention has been described with reference to the above embodiments, it should be understood that various changes and modifications can be made therein by those skilled in the art without departing from the spirit and scope of the invention.

Claims (16)

1. A drip monitoring system, comprising:

a first server;

the second server is in communication connection with the first server and is used for receiving the drip information provided by the first server;

the drip detection device is in communication connection with the first server and used for detecting drip monitoring information and transmitting the drip monitoring information to the first server; and

electronic means, communicatively coupled to the first server, for receiving the drip information transmitted by the first server;

wherein the first server is configured to calculate a droplet flow rate based on the droplet monitoring information, the droplet information including the droplet monitoring information and the droplet flow rate, and the first server is further configured to transmit control information to the droplet monitoring device.

2. A drop monitoring system as in claim 1, further comprising:

a third server, communicatively connected to the first server, for receiving the drip information provided by the first server and transmitting monitoring information to the first server;

the monitoring information comprises blood pressure information, heartbeat information and body temperature information.

3. The drop monitoring system of claim 1, wherein the drop detection device further comprises:

a processor;

the weight sensing unit is electrically connected with the processor and is used for detecting the weight information of the drip and transmitting the weight information to the processor;

the communication module is electrically connected with the processor and used for receiving the control information and the alarm value transmitted by the first server;

the alarm module is electrically connected with the processor and used for sending out a warning signal; and

the power supply module is electrically connected with the processor, the weight sensing unit, the communication module and the alarm module and used for providing electric quantity required by the processor, the weight sensing unit, the communication module and the alarm module;

the processor is used for judging whether the weight information is smaller than or equal to the alarm value, if so, the alarm module is controlled to send out the alarm signal, and the processor is also used for enabling or disabling the alarm module according to the control information.

4. A drop monitoring system as claimed in claim 3, wherein said processor is further configured to transmit said drop monitoring information to said first server via said communication module, said drop monitoring information including a drop detection device identification number, a drop detection device name, a drop detection device status, said alarm value, and said weight information.

5. A drop monitoring system as in claim 3 wherein said first server is further configured to record said weight information and calculate a weight difference between current weight information and previous weight information to determine if said weight difference is greater than a threshold.

6. The drip monitoring system of claim 3 wherein the processor is further configured to detect a charge level of the power module and transmit charge level information to the first server via the communication module.

7. The drop monitoring system of claim 6, wherein the drop detection device further comprises an identification barcode, and the electronic device is configured to view the drop information and the charge information according to the identification barcode.

8. A drop monitoring system as claimed in claim 1, wherein said electronic device is further configured to transmit said control information to said drop detection device via said first server.

9. A method of drop monitoring, comprising:

detecting drip monitoring information through a drip detection device, and transmitting the drip monitoring information to a first server;

calculating a drip flow rate according to the drip monitoring information;

transmitting the drip information to a second server and the electronic device; wherein the droplet information comprises the droplet monitoring information and the droplet flow rate; and

and transmitting control information to the drip detection device.

10. A drop monitoring method as in claim 9, further comprising:

receiving monitoring information transmitted by a third server, and transmitting the drip information to the third server;

the monitoring information comprises blood pressure information, heartbeat information and body temperature information.

11. A drop monitoring method as claimed in claim 9, wherein said drop detection device is further configured to:

receiving the control information and the alarm value transmitted by the first server;

detecting the weight information of the drip; and

and judging whether the weight information is less than or equal to the alarm value, and if so, sending an alarm signal.

12. A drop monitoring method as in claim 11, wherein said drop detection device is further configured to transmit said drop monitoring information to said first server, said drop monitoring information comprising a drop detection device identification number, a drop detection device name, a drop detection device status, said alarm value, and said weight information.

13. A drop monitoring method as in claim 11, wherein said first server is further configured to record said weight information and calculate a weight difference between a current weight information and a previous weight information to determine whether said weight difference is greater than a threshold.

14. A drop monitoring method as in claim 11, wherein said drop detection device is further configured to send power information to said first server.

15. The drop monitoring method of claim 14, wherein the drop detection device comprises an identification barcode, and the electronic device is configured to view the drop information and the charge information according to the identification barcode.

16. A drop monitoring method as in claim 9, further comprising:

the electronic device transmits the control information to the drip detection device through the first server.

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