KR101159294B1 - A method controlling for draining of a bodyfluid drainage apparatus - Google Patents

Abstract

Drainage control method of the body fluid drainage device according to the present invention comprises the steps of measuring the internal pressure of the pulmonary pleura; Determining whether the measured internal pressure exceeds a reference sound pressure for the pulmonary pleura; And sucking the fluid and the air from the pulmonary pleura if the measured internal pressure exceeds the reference negative pressure, and if the measured internal pressure does not exceed the reference negative pressure, It is characterized in that the operation of sucking the body fluid and the air is stopped.

Description

A method controlling for draining of a bodyfluid drainage apparatus

The present invention relates to a technique for discharging body fluids and air in the pulmonary pleura, and more particularly, to a method for controlling drainage of a bodily fluid drainage device that enables control of drainage of body fluid and air automatically according to a state in the pulmonary pleura.

In patients with pneumothorax, a type of pulmonary pleural injury, subpleural bubbles located in the apex burst into the pleura, causing air leakage. To treat this, a chest tube is inserted into the pulmonary pleura to drain fluid and air. That is, during or after surgery, the chest tube is inserted into the pulmonary pleura through the chest wall to discharge the body fluid and air that collects around the lungs, thereby discharging the body fluid and air into the drainage bottle. If the drain bottle becomes full of fluid, exchange it for a new drain bottle.

However, the operation of the fluid drainage device, which is a device for releasing fluid and air that accumulates in the body due to pulmonary pleura damage, is caused by the amount of fluid in the drainage bottle or the pressure state in the pulmonary pleura by a doctor or a medical expert In view of this, the driving of the drainage device is controlled. As a result, since it is determined whether drainage of fluid or air to the patient due to pulmonary pleural injury is determined according to the skill of the medical staff, there is a concern that proper treatment for the patient may occur. Therefore, there is a need for an algorithm that can control the body fluid drainage device to properly discharge the fluid and air that accumulate in the pulmonary pleura according to the condition of the patient.

The problem to be solved by the present invention is to control the body fluid drainage device for draining the body fluid and air to automatically drain or stop draining the body fluid and air according to the pressure state inside the pulmonary pleura. The present invention relates to a method for controlling drainage of a bodily fluid drainage device that detects an amount of change in suction, to remove foreign matter that has accumulated on the chest tube for drainage, and to output a warning signal when an abnormality occurs to the bodily drainage device.

In the drainage control method of the bodily fluid drainage device according to the present invention for solving the above problems, in the drainage control method of a bodily fluid drainage device that sucks the body fluid and air in the pulmonary pleura, measuring the internal pressure of the pulmonary pleura; Determining whether the measured internal pressure exceeds a reference sound pressure for the pulmonary pleura; And sucking the fluid and the air from the pulmonary pleura if the measured internal pressure exceeds the reference negative pressure, and if the measured internal pressure does not exceed the reference negative pressure, It is characterized in that the operation of sucking the body fluid and the air is stopped.

Preferably, after stopping the suction of the bodily fluid and the air, the method further comprises switching an on / off valve to prevent the air from flowing back due to the vacuum pump used for the suction of the bodily fluid and the air. do.

Preferably, the method for controlling drainage of the body fluid drainage device further includes detecting whether a predetermined time has elapsed, and if the predetermined time has elapsed, proceeding to measuring the internal pressure of the pulmonary pleura.

Preferably, the drainage control method of the body fluid drainage device, the step of detecting whether the amount of the aspirated body fluid exceeds the critical body fluid volume of the drain container; And outputting a warning signal indicating that the amount of bodily fluid to be sucked is exceeded if the amount of bodily fluid to be sucked exceeds the threshold amount of bodily fluid.

Preferably, the drainage control method of the body fluid drainage device, the step of detecting whether a predetermined time has passed; And if the predetermined time has elapsed, switching a direction change valve for redirecting the sucked air back into the drain collection container.

Preferably, the drainage control method of the body fluid drainage device, if the predetermined time elapses, detecting the amount of change over time with respect to the amount of air to be sucked; And determining whether an amount of change in suction with respect to the amount of air to be sucked out of the reference change amount is exceeded, and when the amount of change in suction is out of the reference change amount, the aspirated air is inputted back into the waste collection container. The switching of the directional valve is performed to make it possible.

Preferably, the method further includes outputting a warning signal indicating that the suction change amount is out of the reference change amount, if the suction change amount is out of the reference change amount.

According to the present invention, the body fluid drainage device automatically drains body fluids and air in accordance with the state inside the pulmonary pleura, thereby providing a more appropriate and immediate treatment for the patient.

In addition, by displaying a warning signal to the abnormal situation that may occur in the body fluid drainage device, there is an effect that the medical staff can immediately respond to such an abnormal situation. In addition, in the body drainage device, it is possible to control the removal of foreign matter accumulated on the chest tube and the like, thereby preventing an increase in the risk of the patient due to the breakage of the device and a mechanical defect.

In addition, by automatically discharging the body fluid and air through the body fluid drainage control method, it is possible to provide a more standard medical care in the treatment of patients.

1 is a view illustrating a structure of a body fluid drainage device for explaining the drainage control method of the present invention.
2 is a block diagram showing the main components of the body fluid drainage device shown in FIG.
3 is a schematic diagram showing the internal structure of the body fluid drainage device shown in FIG.
FIG. 4 is a reference diagram showing part A of FIG. 3 in detail.
5 is a reference diagram for explaining a coupling relationship between a case of a body fluid drainage device and a drainage collection container.
6 is a flowchart of an embodiment for explaining a drainage control method of a body fluid drainage apparatus according to the present invention.
7 is a reference diagram for explaining a suction operation mode according to the present invention.
8 is a reference diagram for explaining a flushing operation mode according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In order to explain the drainage control method of the body fluid drainage apparatus according to the present invention, the structure of the body fluid drainage apparatus will be described first.

1 is a diagram illustrating the structure of a bodily fluid drainage device, FIG. 2 is a block diagram showing main components of the bodily fluid drainage device shown in FIG. 1, and FIG. 3 is an internal structure of the bodily fluid drainage device shown in FIG. It is a schematic diagram showing.

The body fluid drainage device includes a case (1), a drainage collection container (3), a vacuum pump (5), an air flow rate sensor (7), an open / close valve (8), a directional valve (9), and a control unit constituting an exterior. 11). In addition, the body fluid drainage device further includes a drainage sensor 13, a pressure sensor 15, a timer 17, an output unit 19, and a data storage unit 21.

The case 1 is provided with a predetermined space inside, and the drainage collection container 3 is detachably coupled to the outside. However, in this case, the coupling method is preferably made by a general locking jaw, a locking groove, or the like, and various other methods may be used.

The drainage collection container 3 is a container in which body fluid discharged from the pulmonary pleura is collected. The drainage container is configured to separate the body fluid from the body fluid and air received from the pulmonary pleura through the chest tube (P1), to store the separated body fluid, and to discharge only the air to the vacuum pump (5) side. A plurality of partitions (not shown) are disposed in the drainage collection container 3, and connection holes are formed between the partition walls to move air through the connection holes.

The drainage sensor 13 measures the amount of the body fluid collected in the drainage collection container 3, and specifically, measures the level of the body fluid and transmits a predetermined signal to the controller 11. That is, the drainage amount sensor 13 detects whether the amount of aspirated body fluid exceeds the threshold fluid amount determined by the drainage collection container 3, and outputs a detected signal to the controller 11. If the drainage detection sensor 13 detects a predetermined level or more, that is, outputs a signal detected as exceeding a threshold fluid level, the control unit 11 is time to replace the drainage collection container 3. It recognizes and outputs a predetermined warning signal through the output unit 19. The warning signal may be transmitted to the display unit 23 and displayed to be confirmed by a medical staff or a patient. The drainage sensor 13 is installed in the case 1, but is installed in a position corresponding to the drainage collection container (3). The drainage sensor 13 is preferably a non-contact capacitive sensor or an infrared sensor, but is not limited thereto, and various sensors may be used, and the detailed description thereof will be omitted.

The case 1 is provided with connection parts 23a, 23b, 23c, and 23d into which the chest tube P1 connected to the pulmonary pleura of the human body is fitted. FIG. 4 is a reference diagram showing part A of FIG. 3 in detail. As shown in FIG. 4, the connecting portions 23a, 23b, 23c, and 23d include an inflow pipe 23a and a return pipe 23b each having partitions formed by partition walls or different pipes adjacent to each other. do. The inlet pipe 23a and the return pipe 23b have a constant length and the upper part is open and in communication with each other. The inflow pipe 23a and the return pipe 23b are fitted together in the chest tube P1 described above.

Inlet pipe (23a) is provided with a first passage (23c) is coupled to the waste collection container (3). That is, the inlet pipe 23a guides the body fluid and air passing through the chest tube P1 to be moved to the drainage collection container 3 side.

The return pipe 23b has a second passage 23d through which air discharged from the vacuum pump 5 side can flow. The second passage 23d is preferably connected to the direction switching valve 9 and the sixth conduit P6 connected to the discharge side of the vacuum pump 5.

And the case 1 is provided with the 3rd channel connected to the waste collection container 3. As shown in FIG. 5 is a reference diagram for explaining a coupling relationship between the case 1 of the body fluid drainage device and the drainage collection container 3. Reference numeral 23e illustrated in FIG. 5 corresponds to a third passage, and the third passage 23e is disposed at a position spaced apart from the first passage 23c by a predetermined distance. The third passage 23e is connected to the air flow rate measuring sensor 7 through another pipe line P2 (shown in FIG. 3).

One side of the air flow rate measuring sensor 7 is connected to the drainage collection container 3 by the second pipe P2, and the other side thereof is connected to the vacuum pump 5 by the third pipe P3. Specifically, the air flow rate measuring sensor 7 is disposed in the case 1, and is installed between the drainage collection vessel 3 and the vacuum pump 5, and the amount of air from the drainage collection vessel 3 It can be detected periodically over time. The air flow rate measurement sensor 7 may be differential pressure, area, volume, rotational speed detection, electronic, ultrasonic, vortex, thermal, etc., most preferably temperature independent and can be corrected with nitrogen. Sensors can be used. However, the present invention is not limited thereto, and any thing that can guarantee linearity at a small flow rate is of course possible. The air flow rate measuring sensor 7 is electrically connected to the control unit 11 to transmit a signal for the measured air amount to the control unit 11.

The pressure sensor 15 is disposed inside the case 1, and is a sensor for measuring the pressure inside the pulmonary pleura of the patient. In this embodiment, the pressure sensor 15 is installed between the drainage collection container 3 and the air flow rate sensor 7, that is, the second pipe P2, but the present invention is not limited thereto. If it is between the container 3 and the vacuum pump 5 may be installed in the third pipe (P3). However, if the on-off valve 8 is installed on the inlet side of the vacuum pump 5, it should be installed between the on-off valve 8 and the drainage collection container (3). The pressure sensor 15 is electrically connected to the control unit 11 to transmit the measured pressure signal to the control unit 11.

The vacuum pump 5 is connected to the direction change valve 9 through the fourth pipe line P4. The vacuum pump 5 is disposed inside the case 1, and is connected to a chest tube and a conduit inserted into a pulmonary pleura part of a patient to suck up fluid and air inside the pulmonary pleura. Various types of vacuum pumps may be used, so detailed description thereof will be omitted. However, the vacuum pump 5 has a third pipe line P3 connected to the air flow rate sensor 7 at one end thereof, and a fourth pipe line P4 connected to the direction switching valve 9 at the other end side thereof. ), Air or other fluid flowing through the third conduit P3 can flow to the directional valve 9 through the fourth conduit P4. On the other hand, as the vacuum pump 5 operates, the negative pressure (pressure state lower than atmospheric pressure) can be formed inside the drainage collection container 3 and the lung chest tube.

One side of the directional valve 9 is connected to the vacuum pump 5 through the fourth pipe (P4), the other side is connected to the atmosphere through the fifth pipe (P5) and at the same time the sixth pipe (P6) It is connected to the connecting portion (23a, 23b, 23c, 23d) through. Specifically, the sixth conduit P6 may be connected to the waste collection container 3 through the connecting portions 23a, 23b, 23c, and 23d as described above. That is, the direction switching valve 9 is electrically connected to the control unit 11 as a three-way valve, and according to the control of the control unit 11, the air flow is controlled by the fifth conduit P5 and the sixth conduit P6. Allows selective flow to either side. The directional valve 9 is preferably a solenoid valve that can operate by an electrical signal, but is not limited to this, of course, various types of valves can be used. However, in the exemplary embodiment of the present invention, an example in which the sixth pipe P6 is connected to the drainage collection container 3 through the connecting parts 23a, 23b, 23c, and 23d is illustrated, but is not limited thereto. It is also possible to be made in communication with the atmosphere.

The on-off valve 8 is provided on the third pipe line P3. Specifically, the on-off valve 8 is provided on the third pipe line P3 provided on one end side of the vacuum pump 5, and the vacuum pump 5 and It is installed between the air flow rate measuring sensors (7). However, when the pressure sensor 15 is disposed between the vacuum pump 5 and the air flow rate sensor 7, the third pipe line P3 between the vacuum pump 5 and the pressure sensor 15. It is installed on. The on-off valve 8 is a valve for opening and closing the flow of air, and when the vacuum pump 5 is operated, the passage is opened to enable the flow of air, and when the pump device is stopped, the flow of air. It is to close the passage to prevent it. The on-off valve 8 is electrically connected by the control unit 11, the operation is controlled by the control unit (11). On the other hand, the on-off valve 8 is preferably a solenoid valve capable of opening and closing the valve by an electrical signal, but is not limited to this, of course, various valves can be used.

On the other hand, the timer 17 is preferably electrically connected to the control unit (11). The data storage unit 21 is electrically connected to transmit and receive data to and from the control unit 11 by storing the data measured by the air flow rate sensor 7 and the drainage sensor 13.

The output unit 19 includes a display unit 23 and a wireless communication module 25 provided at the front of the case 1. When the output unit 19 receives a control signal for outputting a warning signal from the controller 11, the output unit 19 displays the corresponding warning signal on the display unit 23 or outputs the wireless communication module 25.

The display unit 23 may output an image or the like so that the necessary data can be easily viewed by the controller 11. The display unit 23 is formed on the upper surface side of the case 1 to display a predetermined operating state. For example, when the amount of body fluid drawn into the drainage collection container 3 exceeds the threshold amount of body fluid, a warning signal indicating that the amount of body fluid being sucked is exceeded is displayed. A warning signal is displayed to indicate that foreign matter is stuck. On the other hand, the display unit 23 may display a warning signal that the power of the battery (not shown) for driving the body fluid drainage device is almost consumed under the control of the controller 11.

The wireless communication module 25 is a portable operation device (control such as an iPod) that can wirelessly control and operate the main computer device of the hospital and its body fluid discharging device where the medical staff can view data stored in the data storage unit 21 in real time. Device) and near field communication means (e.g., Wi-Fi communication, Radio Frequency (RF) communication, Bluetooth communication, Wireless LAN communication, Ultra Wide Band system (UWB) communication). Connected via one short range wireless communication means. According to this configuration, the body fluid discharge device performs a predetermined operation by the portable operation device, and the data in the body fluid discharge device can be transmitted to the main computer device.

Hereinafter, the drainage control method which concerns on this invention is demonstrated using the above-mentioned body fluid drainage apparatus.

6 is a flowchart of an embodiment for explaining a drainage control method of a body fluid drainage apparatus according to the present invention. FIG. 7 is a reference view for explaining a suction operation mode according to the present invention, and FIG. 8 is a reference view for explaining a flushing operation mode according to the present invention.

First, the internal pressure of the pulmonary pleura is measured (step 100). The pressure sensor 15 is used to measure the pressure inside the pulmonary pleura. The pressure sensor 15 transmits the pressure detection signal measured in real time to the controller 11.

After step 100, it is determined whether the measured internal pressure exceeds a reference sound pressure for the pulmonary pleura (step 102). The control unit 11 compares the pressure detection signal for the inside of the pulmonary pleura transmitted from the pressure sensor 15 with a preset reference sound pressure. Here, the reference sound pressure is a pressure that the internal pulmonary pleura has a normal state, and generally the pressure inside the pulmonary pleura maintains a negative pressure lower than the reference atmospheric pressure. Therefore, the sound pressure that appears when the pulmonary pleura is normal is set to the value of the reference sound pressure.

If the measured internal pressure exceeds the reference negative pressure, the body fluid and the air are sucked from the lung pleura (step 104). If the measured internal pressure exceeds the reference negative pressure, it means that the internal pressure of the pulmonary pleura is higher than the normal negative pressure. The high pressure is caused by the accumulation or inflow of fluid or air into the pulmonary pleura. At this time, it is necessary to discharge the fluid or air flowing into the pulmonary pleura to the outside. Therefore, a process of draining the body fluid or air accumulated in the pulmonary pleura into the drainage collection container, that is, the suction process, is performed. To this end, the control unit 11 outputs a signal instructing the discharge of body fluid and air to the vacuum pump (5). Accordingly, the vacuum pump 5 is connected to the chest tube and the conduit inserted into the pulmonary pleura portion of the patient to suck the body fluid and air inside the pulmonary pleura into the drainage collection container 3. As the vacuum pump 5 operates, as the body fluid and air accumulated in the lung pleura are discharged, the pressure inside the lung pleura becomes low, so that a negative pressure in a normal state can be formed. The process of sucking the body fluid and air as the above-described internal pressure of the pulmonary pleura exceeds the reference negative pressure is called a suction operation mode.

After step 104, it is detected whether a predetermined time has elapsed (step 106). The timer 17 described above timings how much time has elapsed, and outputs the timing signal to the control unit 11. The controller 11 detects whether the time for draining the body fluid and the air has elapsed for a predetermined time according to the timing result of the timer 17. If the predetermined time has not elapsed, the operation of sucking the fluid and air from the pulmonary pleura described above is continued.

If a predetermined time has elapsed, it is detected whether the amount of bodily fluid to be drawn exceeds the critical bodily fluid amount of the drainage collection container (step 108). When a predetermined time elapses, the controller 110 requests the drainage amount sensor 13 for a detection result of whether the amount of the body fluid filled in the drainage collection container exceeds the threshold amount of the body fluid. Drainage sensor 13 is a device for measuring the amount of body fluid collected in the drainage collection container (3), and measures whether the amount of the body fluid filled in the container reaches a predetermined threshold amount of fluid, for example, a certain level of the container When the body fluid reaches a certain level, a signal corresponding thereto is transmitted to the control unit 11.

If the amount of body fluid to be sucked exceeds the threshold amount of body fluid, a warning signal indicating that the amount of body fluid to be sucked has been exceeded is output (step 110). If the detection signal indicating that the amount of body fluid drawn into the drainage collection container 3 exceeds the threshold body fluid amount is received from the drainage amount sensor 13, the control unit 11 outputs a predetermined warning signal through the output unit 19. To control. In particular, a warning signal may be displayed on the display unit 23 in order to be recognized by medical staff.

On the other hand, in the above-described step 108 and 110, the determination as to whether the amount of body fluid sucked exceeds the threshold body fluid volume of the drain collection container is illustrated as being determined only when a predetermined time has elapsed in Figure 6, the control unit 110 Without a request for the detection result of the), if the amount of liquid sensor 13 independently detects that the amount of body fluid exceeds a predetermined level of the waste collection container, it can transmit a detection signal for this to the control unit 110. Accordingly, the control unit 11 may control to immediately output a predetermined warning signal upon receiving a detection signal that the amount of the body fluid exceeds the threshold body fluid amount even when a predetermined time has not elapsed.

After operation 110, a change amount of time with respect to the amount of air to be sucked is detected (operation 112). The amount of air discharged from the pulmonary pleura through the drainage collection container 3 is periodically detected. The above-described air flow rate measuring sensor 7 is installed between the drainage collection container 3 and the vacuum pump 5 and detects the amount of air discharged from the drainage collection container 3 over time. The air flow rate measuring sensor 7 periodically transmits a signal for the detected air amount to the controller 11. When periodically receiving the amount of air sucked from the air flow rate measurement sensor 7, the control unit 11 detects how the amount of air changes over time.

After operation 112, it is determined whether the amount of change in suction with respect to the amount of air to be sucked out of the reference change amount (step 114). The control unit 11 determines whether the suction change amount of the air with time passes the predetermined change amount, that is, the reference change amount. The reference change amount corresponds to a threshold value for determining whether the air flow changes rapidly. If the amount of change of air to be sucked does not deviate from the reference change amount, it is determined that the duct for sucking the body fluid and the air is functioning normally, and the process proceeds to step 100 and repeats the above-described process.

However, if the suction change amount is out of the reference change amount, a warning signal indicating that the suction change amount is out of the reference change amount is output (step 116). The drastic change in the amount of air coming out of the pulmonary pleura means that foreign matter is trapped in each conduit that draws fluid and air. At this time, since these foreign matters may interfere with the flow of body fluids or air flowing through the pipeline, it is necessary to remove the foreign matters. As a premise of such a task, the controller 110 outputs a warning signal indicating that the foreign matter is stuck through the output unit 19.

After step 116, the divert valve is switched to allow air to be sucked back into the drain collection container (step 118). When it is determined that the amount of change in the amount of air to be sucked out of the standard change amount, the control unit 11 determines that foreign matter is trapped in the conduit, and switches the direction switching valve for inputting the sucked air back into the drainage collection container. The directional valve 9 is a three-way valve electrically connected to the controller 11, and under the control of the controller 11, the air flow is controlled by any of the fifth pipe line P5 and the sixth pipe line P6. Allow selective flow to one side. Therefore, according to the switching control of the control part 11, the direction switching valve 9 closes the 5th bureau P5 and opens the 6th piping P6. As a result, the sucked air is forcedly circulated back to the drainage collection container 3, whereby foreign substances trapped in the conduit can be removed. This operation is called a flushing operation mode. After the flushing operation, the flow returns to step 104 to repeat the above-described process.

On the other hand, the process of performing the above-described flushing operation of step 118 is determined to be performed only when it is determined that the amount of change of the aspirated air is out of the reference change amount, and is determined to be out of the reference change amount. Irrespective of whether the amount of change in the air deviates from the reference change amount, the flushing operation may be performed periodically after a predetermined time. For example, the flushing operation may be repeated for 10 seconds every 5 minutes while the above suction operation mode is in progress.

On the other hand, in step 102, if the measured internal pressure does not exceed the reference sound pressure, after stopping the operation of sucking the body fluid and air from the pulmonary pleura, the switching valve is switched (step 120). The fact that the measured internal pressure of the pulmonary pleura does not exceed the reference negative pressure means that the inside of the pulmonary pleura forms normal negative pressure. At this time, no drainage of body fluids or air is required. Therefore, the control part 11 stops the suction work of body fluid and air. At the same time, the control unit 11 controls the switching valve 8 to close the conduit disposed between the vacuum pump 5 and the pressure sensor 15. The on-off valve 8 is a valve for opening and closing the flow of air. When the vacuum pump 5 is operated, the opening and closing valve is opened to enable the flow of air, and when the vacuum pump 5 stops, Close the passage to block the flow. The reason for blocking the flow of air is to prevent backflow of the air by the vacuum pump.

Meanwhile, the method inventions of the present invention described above can be implemented as computer readable codes / instructions / programs. For example, it may be implemented in a general-purpose digital computer for operating the code / instructions / program using a computer-readable recording medium. The computer-readable recording medium includes storage media such as magnetic storage media (eg, ROM, floppy disk, hard disk, magnetic tape, etc.), optical reading media (eg, CD-ROM, DVD, etc.) .

The drainage control method of the body fluid drainage device of the present invention has been described with reference to the embodiment shown in the drawings for clarity, but this is merely illustrative, and those skilled in the art have various modifications and equivalents therefrom. It will be appreciated that other embodiments are possible. Accordingly, the true scope of the present invention should be determined by the appended claims.

1: case
3: drainage collection vessel
5: vacuum pump
7: Air flow rate sensor
8: on-off valve
9: directional valve
11: control unit
13: Drainage sensor
15: pressure sensor
17: timer
19: output unit
21: data storage
23: display unit
25: wireless communication module

Claims (7)

In the drainage control method of a body fluid drainage device that sucks body fluid and air inside the pulmonary pleura,
Measuring the internal pressure of the pulmonary pleura;
Determining whether the measured internal pressure exceeds a reference sound pressure for the pulmonary pleura; And
If the measured internal pressure exceeds the reference negative pressure, sucking the body fluid and the air from the pulmonary pleura;
If the measured internal pressure does not exceed the reference negative pressure, stopping the suction of the bodily fluid and the air from the pulmonary pleura. According to claim 1, wherein the drainage control method of the body fluid drainage device
After stopping the suction operation of the bodily fluid and the air, switching an on / off valve to prevent the air from flowing back due to the vacuum pump used for the suction of the bodily fluid and the air; A drainage control method of a body fluid drainage device. According to claim 1, wherein the drainage control method of the body fluid drainage device
Detecting whether a predetermined time has elapsed,
And if the predetermined time has elapsed, proceeding to measuring the internal pressure of the pulmonary pleura. According to claim 1, wherein the drainage control method of the body fluid drainage device
After aspirating the bodily fluid from the pulmonary pleura, detecting whether the amount of the bodily fluid to be drawn exceeds the critical bodily fluid volume of the drain container; And
And outputting a warning signal indicating that the amount of the bodily fluid to be sucked is exceeded if the amount of the bodily fluid to be sucked exceeds the threshold amount of the bodily fluid. According to claim 1, wherein the drainage control method of the body fluid drainage device
After aspirating the air from the pulmonary pleura, detecting whether a predetermined time has elapsed; And
And if the predetermined time has elapsed, switching a direction change valve for changing the direction such that the sucked air is inputted back into the drainage collection container. The method for controlling drainage of the body fluid drainage device according to claim 5
If the predetermined time has elapsed, detecting an amount of change over time with respect to the amount of air drawn in; And
Determining whether the amount of change in suction with respect to the amount of air to be sucked is out of a reference amount of change;
And if the suction change amount is out of the reference change amount, switching to the direction change valve so that the suctioned air is inputted back into the drain collection container. The method of claim 6,
And outputting a warning signal indicating that the suction change amount is out of the reference change amount, if the suction change amount is out of the reference change amount.

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