CN111195381A

CN111195381A - Intensive care transfusion monitoring system

Info

Publication number: CN111195381A
Application number: CN202010013837.5A
Authority: CN
Inventors: 田惠; 辛鹏; 乔帅华; 赵猛
Original assignee: Affiliated Hospital of University of Qingdao
Current assignee: Affiliated Hospital of University of Qingdao
Priority date: 2020-01-07
Filing date: 2020-01-07
Publication date: 2020-05-26

Abstract

The utility model provides an intensive care infusion monitoring system, relates to medical instrument technical field, including infusion set, the control unit, computer, and display screen, infusion set on be equipped with the sensor that is used for monitoring the infusion process, the sensor pass through the electric wire and the net twine is connected with the control unit, the control unit pass through the electric wire and the net twine is connected with the computer, the computer be connected with the power, the computer on still be equipped with information processing module, information processing module gather real-time supervision's infusion process information to draw a chart curve, the computer still be connected with the display screen, the chart curve pass through display screen real-time display. The invention brings the infusion treatment in the hospital ward into the Internet for overall management, displays the infusion process in real time and provides standardized reference for the infusion work of nurses, thereby improving the working efficiency and reducing the labor intensity.

Description

Intensive care transfusion monitoring system

Technical Field

The invention belongs to the technical field of medical instruments, and particularly relates to an intensive care infusion monitoring system.

Background

Intensive care (intensive care) refers to the intensive treatment and nursing of various critical patients by applying various advanced medical technologies and modern monitoring and rescuing equipment to ensure the survival and the subsequent life quality of the patients to the maximum extent.

The intensive care equipment comprises a multi-parameter monitor, an infusion pump, a micro-injection pump, a breathing machine, a blood filter, a nutrition pump, a medical bed, a mattress, a defibrillator, a blood gas analyzer, an emergency trolley, a sputum excretion machine, bedside B ultrasonic equipment and the like.

With the development of the internet, the networking management of medical services has made an important progress, but in the aspect of infusion treatment, the method still stays in the traditional form, namely whether infusion is finished or not is determined in a manual observation mode, and then a nurse is asked to pull out a needle through an interphone, so that the operation is complex, unified management is lacked, especially for intensive care, because a patient cannot take care of the infusion, extra workload is needed in the aspect of infusion observation, and if human errors occur, the consequences are serious.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention discloses an intensive care infusion monitoring system which can realize the networking centralized management and can monitor the infusion process of a patient in real time.

In order to achieve the purpose, the technical scheme of the invention is as follows:

the utility model provides an intensive care transfusion monitoring system, includes infusion set, the control unit, computer, and display screen, infusion set on be equipped with the sensor that is used for monitoring the infusion process, the sensor pass through the electric wire and the net twine is connected with the control unit, the control unit pass through the electric wire and the net twine is connected with the computer, the computer be connected with the power, the computer on still be equipped with information processing module, information processing module gather real-time supervision's infusion process information to draw a chart curve, the computer still be connected with the display screen, the chart curve pass through display screen real-time display.

Preferably, the control unit is also electrically connected with an alarm device, and the signal of stopping infusion or replacing medicines is fed back through the alarm device.

Preferably, the infusion device comprises a linear slide rail A fixed on the roof above the sickbed and an infusion support connected to the linear slide rail in a sliding manner through a slider A, the infusion support comprises a female rod fixedly connected with the slider at the top end, the female rod is vertically arranged, a sliding cavity penetrating through the bottom end is arranged in the female rod, a sub-rod coaxial with the female rod is connected in the sliding cavity in a sliding manner, a rolling bearing is further in interference fit with the outer wall surface of the lower end of the female rod, an annular limiting block A is further fixedly arranged on the outer wall surface of the female rod at the upper end of the rolling bearing, an annular limiting block B is further fixedly arranged on the outer wall surface of the female rod at the lower end of the rolling bearing, a turntable is fixedly connected to the periphery of the rolling bearing, the bottom end of the turntable is fixedly connected with a nut sleeve coaxial with the female rod through a curved rod, and the sub-rod, the bottom end of the secondary rod is fixedly connected with a fixed disk coaxial with the primary rod, the surface of the side wall of the secondary rod is fixedly connected with a linear slide rail B arranged along the vertical direction, a slide block B is arranged in the linear slide rail B, the end face of the outer side of the slide block B is fixedly connected with a hook arranged along the horizontal direction, the surface of the lower wall of the hook is also fixedly connected with a pressure rod, a groove is also arranged on the upper end face of the fixed disk opposite to the bottom end of the pressure rod, a miniature pressure sensor is fixedly arranged at the bottom end of the groove, and the bottom end of the pressure rod extends into the groove and is connected with the upper surface of the pressure sensor; the pressure sensor is connected with the control unit through an electric wire and a network cable.

Preferably, the infusion progress information is pressure value information output by the pressure sensor in real time.

Preferably, the use method of the intensive care infusion monitoring system comprises the steps of transmitting the pressure value of a pressure sensor on the infusion device to a control unit in real time; a second step of filtering the pressure value signal of the infusion needing to be stopped or the medicine needing to be replaced by the control unit and transmitting an action signal to the alarm device; transmitting the real-time monitored pressure value to a computer by the control unit; summarizing the pressure numerical value information monitored in real time through an information processing module on a computer, and drawing a chart curve; and displaying the graph curve in real time through the display screen.

Preferably, in step two, the nurse responds to the alarm signal of the alarm device in time.

Preferably, in the fifth step, the nurse prepares the medicine to be subsequently instilled by observing the graph curve and within the time range of the oblique straight line segment of the graph curve; and in the time range of the curve segment of the graph curve, the drip point is driven to carry out the operation of changing the medicine or stopping the medicine; within the time range of the horizontal straight line segment of the graph curve, the alarm sounds simultaneously, which represents that the liquid is completely instilled and the nurse should go to the instillation point immediately for emergency treatment.

Preferably, in the fourth step, a database of the graph curve of the commonly used medicine at the time of infusion is further established, and comparative analysis is carried out to determine the typical graph curve characteristic of the medicine.

Preferably, the typical graph curve features are used for a nurse to memorize, the infusion process of the medicine represented by the graph curve is rapidly identified according to the graph curve on the display screen, and the work of dispensing, dosing and stopping the medicine is comprehensively arranged according to the infusion process of each medicine.

Preferably, the chart curve also comprises a typical chart curve characteristic used for comparison, and the nurse compares the typical chart curve characteristic with the real-time chart curve characteristic, quickly identifies the infusion process and arranges the infusion work according to the infusion process.

The intensive care transfusion monitoring system has the beneficial effects that:

1. the infusion treatment monitoring system realizes overall monitoring management of infusion treatment, can effectively reduce the workload of nurses, avoids ineffective labor and improves the working efficiency;

2. the invention visually manages the infusion process through the chart curve, and is convenient for nurses to pointedly arrange the infusion work in each time period;

3. according to the infusion set, the typical graph curve characteristics and the real-time graph curve characteristics are integrated in the same graph curve, so that a nurse can visually see the remaining drip time without estimation, and a more accurate reference standard is provided for overall management of infusion work.

4. The invention is also provided with an alarm device which can send a signal to a nurse for the emergency situation of complete transfusion together with the graph curve, thereby avoiding the danger of air bubble entering caused by the empty transfusion of the patient.

Drawings

FIG. 1: the invention has a structure schematic diagram;

FIG. 2: the structural schematic diagram of the infusion device;

FIG. 3: the invention is a graph curve diagram on a display screen;

FIG. 4: schematic of embodiment 3 of the invention;

1: infusion device, 101: linear slide a, 102: slider a, 103: female rod, 104: sliding chamber, 105: a limiting block A, 106: and a limiting block B, 107: rolling bearing, 108: turntable, 109: curved bar, 110: nut bushing, 111: sub-rod, 112: linear slide B, 113: hook, 114: slider B, 115: groove, 116: pressure sensor, 117: fixed disk, 118: pressure lever, 2: control unit, 3: computer, 4: display screen, 401: pressure shaft, 402: time axis, 403: patient bed number identification, 404: diagonal line segment, 405: curve segment, 406: horizontal straight line segment, 5: alarm device, 6: typical graph curve characteristics, 7: real-time chart curve characteristics.

Detailed Description

The following description is only exemplary of the present invention and should not be construed as limiting the scope of the present invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention should be included in the scope of the present invention.

Examples 1,

Referring to fig. 1, an intensive care infusion monitoring system comprises an infusion device 1, a control unit 2, a computer 3 and a display screen 4, wherein a sensor for monitoring an infusion process is arranged on the infusion device 1, the sensor is connected with the control unit 2 through an electric wire and a network cable, the control unit 2 is connected with the computer 3 through an electric wire and a network cable, the computer 3 is connected with a power supply, an information processing module is further arranged on the computer 3, the information processing module collects infusion process information monitored in real time and draws a chart curve, the computer 3 is further connected with the display screen 4, and the chart curve is displayed in real time through the display screen 4;

referring to fig. 1, the control unit 2 is further electrically connected to an alarm device 5, and the alarm device 5 feeds back a signal indicating that the infusion is to be stopped or the medicine is to be replaced;

referring to fig. 2, the infusion device comprises a linear slide rail a101 fixed on the roof above the hospital bed, and an infusion support slidably connected to the linear slide rail 101 through a slider a102, the infusion support comprises a female rod 103 fixedly connected with the slider at the top end, the female rod 103 is vertically arranged, a sliding cavity 104 penetrating through the bottom end is arranged in the female rod 103, a sub-rod 111 coaxial with the female rod 103 is slidably connected in the sliding cavity 104, a rolling bearing 107 is further in interference fit with the outer wall surface of the lower end of the female rod 103, an annular stop block a105 is further fixedly arranged on the outer wall surface of the female rod 103 at the upper end of the rolling bearing 107, an annular stop block B106 is further fixedly arranged on the outer wall surface of the female rod 103 at the lower end of the rolling bearing 107, a rotary table 108 is fixedly connected with the periphery of the rolling bearing 107, and a nut sleeve 110 coaxial with the female rod is fixedly connected to the bottom end, the screw thread of said son pole 111 connects to the nut set 110 and connects with the sliding of mother pole 103, the bottom of said son pole 111 also fixedly connects with the coaxial fixed disk 117 of mother pole, the surface of sidewall of said son pole 111 also fixedly connects with the linear slideway B112 set up along vertical direction, there are sliders B114 in the said linear slideway B112, the end surface of outside of the said slider B114 fixedly connects with the hook 113 set up along horizontal direction, the lower wall surface of the said hook also fixedly connects with the pressure lever 118, there are grooves 115 on the upper end of the fixed disk 117 opposite to bottom of the pressure lever 118, there are miniature pressure sensors 116 fixedly at the bottom of the groove 115, the bottom of the said pressure lever 118 extends into groove 115 and connects with upper surface of the pressure sensor 116; the pressure sensor is connected with the control unit through an electric wire and a network cable;

the infusion process information is pressure value information output by the pressure sensor 116 in real time;

as shown in fig. 2, the pressure sensed by the pressure sensor 116 includes the weight of the vial (including the infusion tube) and the weight of the liquid in the vial; the weight is applied to the pressure sensor, the pressure sensor transmits a pressure value to the control unit, the control unit 2 transmits real-time pressure information to the computer 3 besides performing alarm information sorting, and then the pressure value is plotted into a graph curve through an information processing module in the computer 3 (as shown in fig. 3, the graph curve includes a time axis 402, a pressure axis 401, and a real-time graph curve feature 7 located between the time axis and the pressure axis, and the real-time graph curve feature 7 includes an inclined straight line segment 404, a curve segment 405, and a horizontal straight line segment 406).

Examples 2,

The embodiment is a further improvement on the basis of embodiment 1, and specifically includes:

a method for using an intensive care infusion monitoring system comprises a first step of transmitting a pressure value of a pressure sensor on an infusion device 1 to a control unit 2 in real time; a second step of filtering the pressure value signal of the infusion needing to be stopped or the medicine needing to be replaced by the control unit 2 and transmitting an action signal to the alarm device 5; step three, the control unit 2 transmits the pressure value monitored in real time to the computer 3; summarizing the pressure numerical value information monitored in real time through an information processing module on the computer 3, and drawing a chart curve; displaying the graph curve in real time through the display screen 4;

in the second step, the nurse responds to the alarm signal of the alarm device 5 in time;

in the fifth step, the nurse prepares the medicine to be subsequently instilled by observing the graph curve and within the time range of the inclined straight line section 404 of the graph curve; and in the time range of the curve segment 405 of the graph curve, the drip point is driven to carry out the operation of changing the medicine or stopping the medicine; within the time range of the horizontal straight line segment 406 of the graph curve, the alarm sounds simultaneously, which represents that the liquid is completely instilled and a nurse needs to go to an instillation point immediately for emergency treatment;

in the fourth step, a database is established for a graph curve of the commonly used medicine during instillation, and comparative analysis is carried out to determine the characteristic 6 of the typical graph curve of the medicine;

the typical graph curve characteristic 6 is used for the nurses to memorize, the infusion process of the medicine represented by the graph curve is quickly identified according to the graph curve on the display screen 4, and the work of dispensing, dosing and stopping the medicine is comprehensively arranged according to the infusion process of each medicine.

When the infusion device in the prior art performs infusion, at the beginning, the sum of the air pressure in the liquid and the air pressure in the medicine bottle is atmospheric pressure due to the high position of the liquid in the medicine bottle, and the constant-speed infusion can be maintained due to the stable pressure, as shown in fig. 3, which is a constant-speed infusion stage represented by an inclined straight line segment 404; when the liquid in the medicine bottle is less and less, and the inner end of the air inlet pipe is exposed, the air in the bottle is directly communicated with the outside air, so that the liquid drips by the gravity of the liquid, and the dripping by the gravity of the liquid follows the rule of first quick and then slow (the liquid is less and less, the gravity is less and less, and the dripping speed is gradually reduced), so that a curve section 405 is formed at the stage, and the curve section 405 just represents the signal that the liquid is about to drip off and needs to be replaced or the medicine is stopped because the inner end of the air inlet pipe is close to the bottle opening; when the liquid is completely dripped, the pressure value on the pressure sensor tends to be constant, and a horizontal straight line segment 406 is displayed on a graph curve, which clearly displays a signal needing to be processed immediately, and meanwhile, the pressure value at the stage is constant and is a value which is sorted out by the control unit 2 and needs to be informed to the alarm device 5 for alarming.

According to the above description, the infusion process of each infusion bottle of each sickbed can be quickly identified through the graph curve, so that the internet overall management of the infusion operation can be realized, once the infusion process in a ward can be uniformly managed, the time can be properly arranged according to the infusion process, and the infusion work can be orderly.

Specifically, when the graph curve shows a diagonal line segment 404, the representative liquid level is high, and the nurse has sufficient time to dispense subsequent medicines; when the patient enters the curve segment 405, the liquid is about to drip off, and the nurse can change the medicine or stop the medicine for the patient in time in the time period; when entering the horizontal line segment 406, the nurse should go to the drip point immediately for emergency treatment, which is the stage when the alarm device 5 sends out the alarm signal.

Further, according to the typical graph curve characteristics, the nurse can quickly identify the progress of the infusion in the inclined straight line segment 404 and the curve segment 405, for example, when the straight line segment 404 goes to 1/3, which represents that the liquid is still remaining 2/3 at the normal infusion speed, and the nurse can quickly estimate the remaining infusion time.

Examples 3,

On the basis of the embodiment 1 and the embodiment 2, the embodiment is further improved, and specifically includes:

as shown in fig. 4, the graph curve also comprises a typical graph curve characteristic 6 for comparison, and a nurse compares the typical graph curve characteristic 6 with a real-time graph curve characteristic 7, quickly identifies the infusion progress and arranges infusion work according to the infusion progress.

On the premise of the same medicine and the same infusion speed, theoretically, the typical graph curve characteristic and the real-time graph curve characteristic are completely overlapped, but only tend to be overlapped due to the influence of accidental factors, but even if the characteristic and the real-time graph curve characteristic are enough for a nurse to accurately judge the infusion process.

The horizontal axis of the graph is the time axis 402, so that when the typical graph curve feature 6 and the real-time graph curve feature 7 appear in the same graph, a nurse can visually see the remaining drip-infusion time without estimation, thereby providing a more accurate reference standard for overall management of infusion work.

Claims

1. An intensive care transfusion monitoring system is characterized in that: including infusion set, the control unit, computer, and display screen, infusion set on be equipped with the sensor that is used for monitoring the infusion process, the sensor pass through the electric wire and the net twine is connected with the control unit, the control unit pass through the electric wire and the net twine is connected with the computer, the computer be connected with the power, the computer on still be equipped with information processing module, information processing module gather real-time supervision's infusion process information to draw into the chart curve, the computer still be connected with the display screen, the chart curve pass through display screen real-time display.

2. An intensive care infusion monitoring system as set forth in claim 1, characterized in that: the control unit is also electrically connected with an alarm device, and the signal of stopping transfusion or replacing medicine is fed back through the alarm device.

3. An intensive care infusion monitoring system as claimed in any one of claims 1 and 2, characterized in that: the infusion device comprises a linear slide rail A fixed on the roof above a sickbed and an infusion support connected to the linear slide rail in a sliding manner through a slide block A, the infusion support comprises a female rod fixedly connected with the slide block at the top end, the female rod is vertically arranged, a sliding cavity penetrating through the bottom end is arranged in the female rod, a sub-rod coaxial with the female rod is connected in the sliding cavity in a sliding manner, a rolling bearing is further in interference fit with the outer wall surface of the lower end of the female rod, an annular limiting block A is further fixedly arranged on the outer wall surface of the female rod at the upper end of the rolling bearing, an annular limiting block B is further fixedly arranged on the outer wall surface of the female rod at the lower end of the rolling bearing, a turntable is fixedly connected to the periphery of the rolling bearing, a nut sleeve coaxial with the female rod is fixedly connected to the bottom end of the turntable through a curved rod, and the, the bottom end of the secondary rod is fixedly connected with a fixed disk coaxial with the primary rod, the surface of the side wall of the secondary rod is fixedly connected with a linear slide rail B arranged along the vertical direction, a slide block B is arranged in the linear slide rail B, the end face of the outer side of the slide block B is fixedly connected with a hook arranged along the horizontal direction, the surface of the lower wall of the hook is also fixedly connected with a pressure rod, a groove is also arranged on the upper end face of the fixed disk opposite to the bottom end of the pressure rod, a miniature pressure sensor is fixedly arranged at the bottom end of the groove, and the bottom end of the pressure rod extends into the groove and is connected with the upper surface of the pressure sensor; the pressure sensor is connected with the control unit through an electric wire and a network cable.

4. An intensive care infusion monitoring system as claimed in claim 3, characterized by: the infusion process information is pressure numerical value information output by the pressure sensor in real time.

5. The method of claim 4, wherein the method comprises: the method comprises the steps of transmitting a pressure value of a pressure sensor on the infusion device to a control unit in real time; a second step of filtering the pressure value signal of the infusion needing to be stopped or the medicine needing to be replaced by the control unit and transmitting an action signal to the alarm device; transmitting the real-time monitored pressure value to a computer by the control unit; summarizing the pressure numerical value information monitored in real time through an information processing module on a computer, and drawing a chart curve; and displaying the graph curve in real time through the display screen.

6. The method of claim 5, wherein the method comprises: in step two, the nurse responds to the alarm signal of the alarm device in time.

7. The method of claim 5, wherein the method comprises: in the fifth step, the nurse observes the graph curve and prepares the follow-up medicine to be instilled within the time range of the oblique straight line segment of the graph curve; and in the time range of the curve segment of the graph curve, the drip point is driven to carry out the operation of changing the medicine or stopping the medicine; within the time range of the horizontal straight line segment of the graph curve, the alarm sounds simultaneously, which represents that the liquid is completely instilled and the nurse should go to the instillation point immediately for emergency treatment.

8. The method of claim 5, wherein the method comprises: in the fourth step, a database is established for the graph curve of the common medicine at the time of infusion, and comparative analysis is carried out to determine the characteristic of the graph curve of the medicine.

9. The method of claim 8, wherein the method comprises: the typical graph curve features are used for the nurses to memorize, the infusion process of the medicine represented by the graph curve is rapidly identified according to the graph curve on the display screen, and the work of dispensing, dosing and stopping the medicine is comprehensively arranged according to the infusion process of each medicine.

10. The method of claim 8, wherein the method comprises: the chart curve also comprises a typical chart curve characteristic used for comparison, and a nurse compares the typical chart curve characteristic with the real-time chart curve characteristic, quickly identifies the infusion process and arranges the infusion work according to the infusion process.