KR102024011B1 - Medicament delivery system - Google Patents

Abstract

The present invention relates to a drug administration system, and more particularly, to a drug administration system for measuring the flow rate of the drug and detecting whether bubbles are generated.
The present invention is connected to a drug bag (3) in which one end of the drug is to be administered to the patient, and the other end is connected to a catheter (4) for injecting the drug into the patient, which is the passage of the drug to be administered to the patient. A drug tube 1; The drug by controlling the infusion pump 520 and the infusion pump 520 which are installed to adjust the dose of the drug administered to the patient from the drug bag 3 through the pressure applied to the drug tube 1. A drug injector 500 including a control unit 530 for adjusting a dosage of the drug; Disclosed is a drug administration system installed in the drug tube (1) in a position adjacent to the patient, comprising a sensor module (2) for measuring the flow rate of the drug flowing through the drug tube (1), and detects whether bubbles are generated. do.

Description

Drug delivery system comprising a sensor module installed in the catheter fixing band {Medicament delivery system}

The present invention relates to a drug administration system, and more particularly, to a drug administration system for measuring the flow rate of the drug and detecting whether bubbles are generated.

In general, the drug administration device and drug administration system for administering the drug to the patient, since the dosage and time of the drug to be administered for each patient is different, the drug is administered by appropriately adjusting the amount and time of the drug administered according to the target patient.

In particular, in the case of a Patient Controlled Analgesia (PCA) in which a narcotic analgesic is administered to a patient with a few ml of drug per hour, the type of drug to be administered, the amount of the drug and the time of administration of the drug, etc. Care must be taken with careful consideration, which requires precise measurement of the amount of drug administered.

To this end, Korean Patent Laid-Open Publication No. 10-2015-0022230 discloses a flow meter for measuring the flow rate of a drug administered to a patient by using a drop sensor installed at the bottom of the fluid chamber, but as described above Only the drop sensor installed at the bottom has a problem that the distance between the drop sensor and the patient is far from precisely measuring the flow rate of the drug administered to the actual patient.

In particular, it is difficult to determine that the amount of drug simply falling from the fluid chamber is the same as the amount of drug administered to the actual patient, and there is a problem in that an error occurs with the amount of drug administered to the actual patient due to bubbles generated after the drop sensor. .

In the case of adjusting the pumping flow rate of the drug injection pump based on the inaccurate measurement of the drug flow rate, a narcotic analgesic in which several ml of the drug is administered per hour may cause a fatal error in the dose of the patient. have.

In addition, in the prior art, the injection pump of the autonomous pain control device (PCA) was applied to the drug by applying the drive method of the blade through the motor, but the drive through the motor auto-pain that requires precise dosage control according to the mechanical error of the motor There is a problem that causes errors in the drug administration system of the control device (PCA).

(Patent Document 1) KR10-2015-0022230 A1

An object of the present invention, in order to solve the above problems, to measure the flow rate of the drug administered to the actual patient and at the same time to detect the occurrence of bubbles, to provide a drug administration system capable of precise dosage control.

The present invention was created in order to achieve the object of the present invention as described above, the present invention is connected to the drug bag (3) is stored, one end is administered to the patient, the other end for injecting the drug to the patient A drug tube (1) connected to the catheter (4) and serving as a passage for the drug to be administered to the patient; The drug by controlling the infusion pump 520 and the infusion pump 520 which are installed to adjust the dose of the drug administered to the patient from the drug bag 3 through the pressure applied to the drug tube 1. A drug injector 500 including a control unit 530 for adjusting a dosage of the drug; Disclosed is a drug administration system installed in the drug tube (1) in a position adjacent to the patient, comprising a sensor module (2) for measuring the flow rate of the drug flowing through the drug tube (1), and detects whether bubbles are generated. do.

The controller 530 may control the infusion pump 520 based on the flow rate of the drug measured from the sensor module 2 to adjust the dose of the drug.

When it is determined that bubbles are generated in the drug tube 1 from the sensor module 2, the controller 530 may control the injection pump 520 to stop drug administration.

The injection pump 520 may be a piezoelectric pump for administering a drug using the extension of the piezoelectric element according to the potential.

Drug administration system according to the present invention, by measuring the flow rate of the drug at the most recent distance of the drug injection catheter administered to the patient, by detecting the occurrence of bubbles, it is possible to precise flow rate measurement, accordingly the dosage actually administered to the patient There is an advantage that can be grasped precisely.

In addition, the drug administration system according to the present invention, the sensor module is configured to be detachably attached to the catheter fixing band for drug administration, can be easily installed, and can further secure the catheter and drug tube at the same time as the drug detection sensing There is an advantage to that.

In addition, the sensor module for drug administration system according to the present invention, by immediately blocking the drug injection at the recent distance of the patient when a similar situation, such as contamination of the drug or incorrect drug administration, it is possible to prevent or minimize medical accidents, etc. There is an advantage to that.

In addition, the drug administration system according to the present invention, by using a piezoelectric pump for drug administration using a conventional motor, there is an advantage that is optimized for the autonomous pain control device (PCA) that requires a small amount and precise drug administration.

1 is a conceptual diagram schematically showing a state of a drug administration system according to the present invention.
2 is a view showing an example of use of the sensor module for drug administration system according to the present invention.
3 is a perspective view showing the state of the sensor module for drug administration system of FIG.
4 is a plan view showing the state of the sensor module for drug administration system of FIG.
Figure 5 is a cross-sectional view showing a coupling of the fixed band of the sensor module for drug administration system of FIG.
6A and 6B are plan views showing the state before and after blocking the drug tube of the drug blocking unit of the drug administration system of the drug administration system of FIG.
7A and 7B are plan views showing the state before and after blocking the drug tube of another embodiment of the drug blocking unit of the drug administration system of the drug administration system of FIG.

Hereinafter, the drug administration system and the sensor module for drug administration system according to the present invention will be described in detail with reference to the accompanying drawings.

Drug administration system according to the present invention, as shown in Figure 1, the drug bag (3) is stored with the drug to be administered to the patient; A drug tube (1), one end of which is connected to the drug bag (3) and the other end of which is connected to a catheter (4) for injecting the drug into the patient, which is a passage of the drug to be administered to the patient; The drug by controlling the infusion pump 520 and the infusion pump 520 which are installed to adjust the dose of the drug administered to the patient from the drug bag 3 through the pressure applied to the drug tube 1. A drug injector 500 including a control unit 530 for adjusting a dosage of the drug; It is installed on the drug tube (1) adjacent to the patient, and comprises a sensor module (2) for measuring the flow rate of the drug flowing through the drug tube (1), and detects whether bubbles are generated.

The drug to be administered to the patient may be any type of drug as long as it is a drug to be administered to the patient in a liquid state, and is not limited to the administration location of the patient.

For example, the drug may be administered by a PCA, which is administered to the patient in a very small amount of several ml per hour, and more specifically, narcotic analgesics may be applied.

The drug bag 3 is a structure in which drugs to be administered to a patient are stored, and any type of drug bag 3 currently used on the market can be used.

The drug tube 1 is a configuration that serves as a passage of a drug to be administered to a patient, and various configurations are possible.

For example, the drug tube 1 is connected to the drug chamber 510, one end of which the drug is stored, and the other end is connected to the catheter 4 for injecting the drug into the patient, thereby the drug tube 510 Drugs can be given to the patient.

That is, the drug tube 1 may be any type of drug tube 1 currently in use on the market, and more preferably, may be a tube made of a transparent silicone material.

The drug injector 500 is configured to control the dose of the drug administered to the patient, and various configurations are possible.

For example, the drug injector 500, the injection pump 520 is installed to adjust the dose of the drug administered to the patient from the drug bag (3) through the pressure applied to the drug tube (1), and the injection By controlling the pump 520, it may include a control unit 530 for adjusting the dosage of the drug.

In addition, the drug injector 500, the housing 510 is formed in the interior space is formed so that the injection pump 520 and the control unit 530, the front of the housing 510, the drug administration information to the user The display unit 540 may be further provided.

The housing 510 is a configuration in which an internal space is formed such that the injection pump 520 and the control unit 530 are installed, and various configurations are possible.

 For example, the housing 510, the inlet and outlet formed for the introduction and discharge of the drug tube (1) on the bottom, and the drug tube (1) in the lower portion for coupling to the injection pump 520 A sliding cover 511 may be included.

That is, in order to couple to the injection pump 520 located inside the housing 510 of the drug tube 1, the sliding cover 511 is removed to couple the drug tube 1 to the injection pump 520, and sliding The cover 511 may be recombined.

In addition, the housing 510 may be provided with a handle 550 and a fastening ring (not shown) for mounting on the upper part of the user for easy transportation and infusion hook.

The infusion pump 520 is configured to adjust the dose of the drug administered to the patient from the drug bag 3 through the pressure applied to the drug tube 1, various configurations are possible.

For example, the injection pump 520 may be a piezoelectric pump for administering a drug using the extension of the piezoelectric element according to the potential.

More specifically, the injection pump 520, a plurality of piezoelectric actuators that can be stretched according to the potential is installed along the drug tube (1), by pressing the drug tube (1) through a change in the potential applied to each drug The drug in the tube 1 can be supplied at a precise flow rate.

In this case, the injection pump 520 may further include a pressure pad (not shown) installed between the piezoelectric actuators and the drug tube 1, whereby the pressure delivered from the piezoelectric actuators is a drug tube ( It can be delivered consistently in 1).

Furthermore, the drug tube 1 can be prevented from moving as it is pressed from the injection pump 520 through the pressure pad.

On the other hand, the injection pump 520 is, of course, can be configured to press the drug tube 1 by using a drive of the motor.

The controller 530 is configured to control the dosage of the drug by controlling the infusion pump 520, various configurations are possible.

For example, the controller 530 may be controlled by applying a potential to the injection pump 520, which is a piezoelectric pump using a piezoelectric element, and more specifically, each of the piezoelectric actuators installed along the drug tube 1. By applying different potentials to the piezoelectric actuators, the degree of elongation of the piezoelectric actuators can be adjusted, thereby adjusting the pressure transmitted to the drug tube 1.

In addition, the control unit 530, by controlling the infusion pump 520 based on the flow rate of the drug measured from the sensor module 2 to be described later, it is possible to adjust the dose of the drug.

That is, the dosage of the drug administered to the patient is determined based on the flow rate of the drug measured from the sensor module 2 installed at the closest distance of the patient, and the injection amount of the drug to be administered based on the determined dosage. Can be adjusted by controlling.

In addition, the control unit 530 may stop the drug administration by controlling the injection pump 520 when a bubble is detected in the drug tube 1 from the sensor module 2 to be described later, further known by the user Various warning devices such as alarming or warning through the screen of the display unit 540 may be operated.

The display unit 540 is formed on one surface of the housing 510 and provides various types of information of drugs to be administered to the user, and various configurations are possible.

For example, the display unit 540 may provide a variety of information, such as the type of drug currently administered, the patient's life information, the amount of the drug so far administered, the amount of the drug administered per hour, and the like.

On the other hand, the drug administration system according to the present invention, which relates to a self pain control device (PCA), a very small amount of the drug is administered a few ml per hour, even a small dose error may be fatal to the patient.

Therefore, the sensor module 2 for precisely measuring the dose of the drug administered to the patient is required, with reference to the accompanying drawings will be described in detail with respect to the sensor module.

2 to 5, the sensor module according to the present invention, the sensor body 100 is formed with a fixed portion 110 is fixed to the drug tube (1) flowing through the drug is formed; A flow rate measuring unit (200) installed at a position adjacent to the fixing unit (110) in the sensor body (100) and measuring a flow rate of the drug flowing in the drug tube (1); It is installed in a position adjacent to the fixing unit 110 in the sensor body 100, and includes a bubble detection unit 300 for detecting whether or not bubbles in the drug tube (1).

That is, the sensor module according to the present invention may be installed in the drug tube 1 adjacent to the patient to measure the flow rate of the drug flowing through the drug tube 1 and detect bubbles in the drug tube 1. .

The sensor body 100 is a configuration in which the flow rate measuring unit 200 and the bubble detector 300 are installed therein, and various configurations are possible.

For example, the sensor body 100 may include a fixing part 110 which is formed so that the drug tube (1) through which the drug flows is fitted.

The fixing part 110 is configured to be fixed to the drug tube (1), various configurations are possible.

For example, the fixing part 110 is a recess formed in a concave upper surface of the sensor body 100, may be formed to cross the sensor body 100, the vertical section of the 'U' shape It may be shaped.

In addition, the fixing unit 110 may be formed smaller than the outer diameter of the drug tube (1), so that the drug tube (1) can be fitted and fixed by pressing, the drug tube (1) of the deformable material It can be deformed and fitted.

On the other hand, as another example, the sensor body 100 may be provided with a plastic material in the recess formed in the upper surface of the coupling groove 112 is formed to the left and right so that the drug tube (1) can be fitted.

That is, the coupling groove 112 is provided with a thin thickness in the groove formed in the sensor body 100, it may be deformed so as to spread left and right as the drug tube (1) is fitted.

In this case, the coupling groove 112 is a material through which light from the photosensor for bubble detection in the drug tube 1 of the bubble detection unit 300 to be described later is transmitted, or an opening for light transmission at a position where the photosensor is located. The hole 113 may be formed.

On the other hand, the fixing unit 110 and the coupling groove 112 may be formed together in the sensor body 100, for example, the fixing unit 110 is formed in the sensor body 100, the bubble detection unit ( The coupling groove 112 may be further provided at a portion where the 300 is located.

The fixing part 110 and the coupling groove 112 is preferably formed on the upper surface of the sensor body 100, but may also be formed on the side or the like.

In addition, the sensor body 100 may be further provided with a cover (not shown) to prevent the exposure of the drug tube (1) on the upper surface.

The cover part is configured to cover the upper surface of the sensor body 100 to prevent exposure of the drug tube (1), various configurations are possible.

For example, the cover part is hinged to one side of the upper surface of the sensor body 100, the sensing part of the drug tube (1) by covering the fixed drug tube (1) is fitted to the fixed part 110 through the hinge rotation Exposure can be prevented.

The flow rate measuring unit 200 is installed at a position adjacent to the fixing unit 110 in the housing 100 and measures a flow rate of the drug flowing through the drug tube 1, and various configurations are possible.

That is, the flow rate measuring unit 200 is provided to be adjacent to the drug tube 1 in the housing 100, and any configuration can be used as long as it is configured to measure the amount of drug flowing through the drug tube 1. .

For example, the flow rate measuring unit 200, before passing through the temperature change unit 210 for changing the temperature of the drug flowing in the drug tube 1, and the temperature change unit 210 of the drug The first and second temperature sensors 220 and 230 may respectively measure the drug temperature before and after passing through the temperature change unit 210 to determine the flow rate of the drug through the temperature difference therebetween.

More specifically, the flow rate measuring unit 200, the first temperature sensor 220, the temperature change unit 210 and the second temperature sensor 230 along the drug tube 1 so as to be parallel to the movement direction of the drug. Can be installed.

Through this, the flow rate of the drug may be measured through a difference between the temperature of the drug measured by the first temperature sensor 220 and the temperature of the drug measured by the second temperature sensor 230.

Meanwhile, in this case, the temperature change unit 210 is installed between the first temperature sensor 220 and the second temperature sensor 230, and each of the first temperature sensor 220 and the second temperature sensor 230, respectively. The separation distance may be different.

The temperature change unit 210 is configured to change the temperature of the drug flowing in the drug tube 1, various configurations are possible.

For example, the temperature change unit 210, as a heater, may heat the drug flowing in the drug tube 1 to cause a temperature change of the drug, and in another way, cool the drug flowing in the drug tube 1. This can change the temperature of the drug before and after passage.

The temperature change unit 210, the first temperature sensor 220 and the second temperature sensor 230 can be used as a product currently used in the market, a detailed description thereof will be omitted.

The bubble detection unit 300 is installed at a position adjacent to the fixing unit 110 in the housing 100 and detects whether bubbles are generated in the drug tube 1, and various configurations are possible.

For example, the bubble detector 300 is a photosensor for detecting bubbles in the drug tube 1, and more specifically, is installed on one side adjacent to the fixing part 110 in the housing 100 to irradiate light. The light emitting unit 310 and the light emitting unit 310 may be provided on the other side adjacent to the fixing unit 110, the light receiving unit 320 for receiving the light emitted from the light emitting unit 310.

Through this, the bubble detector 300 may detect bubbles that may be generated in the drug tube 1.

On the other hand, the bubble detection unit 300, not only the above-described transmission type may be used, but also the direct reflection type, mirror reflection type, etc., in which both the light emitting unit 310 and the light receiving unit 320 are installed on one side, may also be applied. Of course.

That is, the bubble detection unit 300 may be any configuration as long as it is possible to confirm whether bubbles are generated in the drug tube 1.

On the other hand, the flow rate measuring unit 200 and the bubble detection unit 300, may be installed along the drug tube (1) to be fitted and fixed to the sensor body 100, there is no limitation on the arrangement order.

That is, with respect to the drug advancing direction of the drug tube 1, the flow rate measuring unit 200 may be installed first, the bubble detection unit 300 may be installed sequentially, on the contrary, the bubble detection unit 300 is installed first, The flow rate measuring unit 200 may be installed.

Further, the flow rate measuring unit 200 and the bubble detector 300 may be installed on one side of the drug tube 1, but is not limited thereto, and the bubble detector 300 and the flow rate detector 200 are opposite to each other. It may be installed or face to face.

In addition, the first temperature sensor 220 and the temperature change unit 210 of the flow measurement unit 200 is installed first, the bubble detection unit 300 is installed in the middle, the second temperature sensor after the bubble detection unit 300 By installing the 230, the flow rate measuring unit and the bubble detecting unit 300 may be installed together.

On the other hand, the sensor module, it can be installed at the closest distance of the patient for precise flow rate measurement of the drug administered to the patient.

For example, the sensor module may be installed by being fitted to the fixing part 110 at the end of the catheter 4 side of the drug tube 1 is administered to the patient.

More specifically, the drug tube 1 may be installed in the fixing part 110 at the end of the catheter 4 side of the drug tube 1 coupled to the catheter 4 inserted into the vein of the patient.

On the other hand, in this case, because the sensor module itself can not be shaken or separated from the drug tube (1) by an external impact, the sensor module is fixed to the fixing band 400 is attached to the patient to fix the catheter (4) Can be installed.

The fixing band 400, which is attached to the body of the patient to secure the catheter 4, various configurations are possible.

For example, the fixing band 400 may include a body portion 410 attached to the body of the patient, and a holding portion 420 for wrapping and fixing the catheter 4 inserted into the body of the patient.

In addition, as an example, the fixing band 400, as shown in Figure 3 and 4, in addition to the coupling guide portion 430 provided on one surface of the body portion 410 in order to fix the sensor module It may include.

The coupling guide part 430 is coupled to the coupling part 120 of the sensor body 100 to be described later, and is configured to fix the sensor module to the fixing band 400, and various configurations are possible.

For example, the coupling guide part 430 may be configured as a pair of parallel members so that the sensor module is fixedly coupled to the fixing band 400 by guiding the coupling part 120 to be described later.

That is, the coupling guide portion 430, a pair of parallel guide grooves 431 is formed, can guide the coupling portion 121 of the coupling portion 120, the locking portion 122 is caught by the sensor The module can be fixed.

In this case, the sensor body 100 may include a coupling part 120 coupled to the coupling guide part 430 in order to be fixed to the fixing band 400.

The coupling part 120 is configured to be fixed to the fixing band 400, and various configurations are possible.

For example, the coupling part 120 may protrude from both side surfaces of the sensor main body 100, and may be formed to be elongated in the horizontal direction.

More specifically, the coupling part 120 is formed at both ends of the protruding portion 123 protruding from both side lower sides of the sensor body 100 and the end of the protruding portion 123, the coupling guide portion ( The coupling portion 121 coupled along the guide groove 431 of the 430, and the coupling portion 121 protrudes from both ends of the coupling portion 121 so that the coupling portion 121 is caught and fixed to the guide groove 431 of the coupling guide portion 430 It may include a locking portion 122 extending in the direction.

Meanwhile, the coupling part 120 may protrude from both side surfaces of the sensor body 100 and may be formed in parallel with the drug tube 1, but is not limited thereto.

The protruding portion 123 is configured to protrude from both side lower sides of the sensor body 100, and various configurations are possible.

For example, the protruding portion 123 may protrude from the lower side of both sides of the sensor body 100, and may be formed to have a horizontal length so that the coupling portion 121 may be horizontally maintained. As a plurality may be formed at the same height to support the coupling portion 121.

The coupling portion 121 is formed to extend in the horizontal direction in the protruding portion 123, and is configured to be coupled to the coupling guide portion 430, various configurations are possible.

For example, the coupling portion 121 is formed long in the horizontal direction from the lower side of the sensor body 100, may be coupled in a sliding manner along the guide groove 431 of the coupling guide portion 430, One of the catching portions 122 of the catching portions 122 extending in the protruding direction at both ends may be formed to be deformable according to pressure so as to pass through the guide groove 431 at the time of coupling.

That is, the plastic material may be manufactured by injection, and furthermore, it is preferable to extend from the protrusion 123 in the vertical direction in the protrusion direction for ease of pressure deformation.

The locking portion 122 is formed to extend in the protruding direction at each end of the coupling portion 121, so that the coupling portion 121 is engaged after being engaged along the guide groove 431, various configurations are possible Do.

For example, the locking portion 122 is formed to extend in the protruding direction at both ends of the coupling portion 121, after the locking portion 122 of the one end is deformed through the pressing to move along the guide groove 431, When passing through the guide groove 431, the other end of the engaging portion 122 is caught by the guide groove 431 and at the same time the one end of the engaging portion 122 is caught by the guide groove 431 by the restoring force, the sensor main body 100 Can be fixed

Accordingly, the coupling relationship between the sensor module and the fixed band 400 according to the present embodiment will be described.

First, the pair of guide grooves of the coupling guide part 430 provided in the fixing band 400 is deformed by the user's pressing portion 121 and one end of the protruding portion 122 of the sensor body 100 ( The coupling part 120 is positioned between the 431.

Thereafter, when the sensor module is moved by pushing along the guide grooves 431 in the horizontal direction, one end of the protrusion 122 passes through the guide grooves 431 of the coupling guide part 430, and before pressing by the restoring force. Restored to the sensor module is fixed to the engaging guide portion 430 is fixed.

As a result, the sensor module may be fixedly coupled to the fixed band 400.

On the other hand, as another embodiment for coupling with the fixing band 400 of the sensor module, a velcro tape may be used.

That is, by attaching the velcro tape to the fixing band 400 corresponding to the bottom of the sensor body 100 and the coupling position of the sensor module, it is possible to attach and detach the sensor module to the fixing band 400.

Meanwhile, the sensor module according to the present invention is used in a drug administration system to be administered to a patient, and it is necessary to confirm whether the drug to be administered to the patient is smoothly administered as the intended drug.

To this end, the sensor module according to the present invention, as shown in Figures 6a to 7b, may include a drug determination unit 600 to confirm whether the intended drug is smoothly administered.

The drug determination unit 600 is a sensor for determining whether the drug to be administered is the intended drug, the presence of a foreign substance in the drug, whether the drug is smoothly administered, and the like.

For example, the drug determination unit 600 is provided on one side with respect to the drug tube 1, the drug determination light emitting unit 610 for irradiating light passing through the drug tube (1) and the other side is provided The drug judgment light emitting unit 610 may include a drug judgment light receiving unit 620 for receiving the irradiation light.

More specifically, the drug determination light emitting unit 610, and irradiates light toward the drug tube 1, the irradiated light is scattered while passing through the drug in the drug tube 1 is received by the drug judgment light receiving unit 620 Can be.

On the other hand, the drug determination unit 600, by having a separate control unit (not shown), it is determined whether the foreign matter and the like in the drug in the drug tube (1) through the scattering degree of the light received by the drug determination light receiving unit 620 can do.

Further, the drug determination unit 600, through the degree of scattering of the light received by the drug determination light receiving unit 620, as well as whether or not foreign substances are present in the drug in the drug tube 1, the drug administration period, drug The type and the like can be determined.

More specifically, the drug determination unit 600 may analyze the scattering degree of the light received by the drug determination light receiving unit 620, and determine the type of drug by comparing the scattering degree data of the light according to the type of drug, As another example, a constant change cycle of light scattering degree may be determined according to drug administration, and if the distortion of the change cycle exceeds an error range, it may be detected and judged as an abnormal administration situation of a foreign substance or drug.

Meanwhile, the drug determination unit 600 may determine the drug by the above-described independent control unit, but scatter the light received by the drug determination light receiving unit 620 in the above-described control unit 530 in order to construct a more effective drug system. The extent data can be sent to determine the drug.

In addition, the drug determination unit 600, any position of the sensor body 100, as long as it is located on both sides of the drug tube (1), such as the above-described flow measurement unit 200 and bubble detection unit 300 It may be located at.

Further, the drug determination unit 600, the drug determination light emitting unit 610 and the drug determination light receiving unit 620 may be integrally located on one side of the drug tube (1), for receiving light irradiated Of course, it may also be a configuration provided with a reflective member for reflecting light at a position opposite the drug tube (1).

On the other hand, the sensor module according to the present invention, as shown in Figure 6a to 7b, may further include a drug blocking unit 500 for the urgent blocking of drugs administered to the patient in case of emergency.

The drug blocking unit 500 is a recent distance of the patient, is installed in the sensor module to block the drug administered to the patient, it is possible to various configurations.

For example, the drug blocking unit 500, as shown in Figure 6a and 6b, is installed on one side of the drug tube (1), the side of the drug tube (1) through rotation in accordance with an external electrical signal Rotation blocking portion 510 to block by pressing in, and may be installed on the opposite side of the rotation blocking portion 510 based on the drug tube (1), and may include a support portion (530) for supporting the drug tube (1). .

The rotation blocking unit 510 is configured to press and block the drug tube 1 from the side through rotation in accordance with an external electrical signal, and various configurations are possible.

For example, the rotation blocking unit 510, the blocking cam 511 for pressing and blocking the drug tube 1 from the side through the rotation, and drives the blocking cam 511 to rotate in accordance with an external electrical signal. Rotation driving unit (not shown), and may include a shaft portion 512 provided between the rotation driving unit and the blocking cam 511.

For example, the blocking cam 511 may be an elliptical shape on a plane, and may be blocked and opened by the drug tube 1 through rotation along the rotation driving part and the shaft part 512.

Meanwhile, as another example, the shaft portion 512 is provided eccentrically from the center of the blocking cam 511, thereby blocking the drug tube 1 through the rotation of the blocking cam 511 along the rotation driving portion and the shaft portion 512. Opening can be done.

As another example, as shown in FIGS. 7A and 7B, the drug blocking unit 500 blocks and opens the drug tube 1 in a reciprocating linear motion according to the above-described rotation of the rotation blocking unit 510. It may include a linear blocking unit 520.

The linear blocker 520 is installed between the drug tube 1 and the rotary blocker 510 to press the side surface of the drug tube 1 in a reciprocating linear motion according to the rotational movement of the rotary blocker 510. As a configuration to block drug administration, various configurations are possible.

For example, the linear blocking unit 520 may move linearly toward the drug tube 1 side according to the rotation of the blocking cam 511 to block drug administration by directly pressing the side surface of the drug tube 1 ( 522 and the blocking plate 521 which is installed between the blocking unit 522 and the blocking cam 511 to move in accordance with the pressure contact of the rotating blocking cam 511 to linearly move the blocking unit 522. It is fixed to the blocking plate 521, the other end is fixed to the lower portion of the blocking cam 511 at least to move the blocking plate 521 and the blocking portion 522 to the original position through the restoring force according to the rotation of the blocking cam 511. One or more elastic members 524 may be included.

Furthermore, the linear blocking portion 520 may further include a plate 523 installed below the blocking cam 511 to stably install the ends of the plurality of elastic members 524.

Through this, the linear blocking portion 520, the blocking plate 521 and the blocking portion 522 by the linear movement of the drug tube (1) in accordance with the rotation of the blocking cam 511 of the rotation blocking portion 510 in the original position , Drug tube (1) can be blocked.

Further, when the blocking cam 511 of the rotation blocking portion 510 is further rotated or rotated in the reverse direction to open the drug tube 1, the blocking plate 521 through the restoring force according to the elasticity of the elastic member 524. ) And the blocking portion 522 to the original position, the drug tube 1 can be opened.

In this case, the drug tube 1 side end of the blocking portion 522 may be treated with a curved surface, or a rubber member may be added to prevent the drug tube 1 from being torn.

The drug blocking unit 500 should immediately stop drug administration according to the determination of the control unit 530 according to the sensing of the above-described flow rate measuring unit 200, bubble detection unit 300, and drug determination unit 600. If it is determined that the electric signal is received from the control unit 530, it may be driven to immediately block the drug tube (1).

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1: drug tube 100: sensor housing
200: flow rate measurement unit 300: bubble detection unit
400: fixed band 500: drug administration

Claims (4)

A drug tube (1), one end of which is connected to a stored drug bag (3), the other end of which is connected to a catheter (4) for injecting the drug into the patient, which is the passage of the drug to be administered to the patient (1). )Wow;
An infusion pump installed to adjust the dose of the drug administered to the patient from the drug bag 3 through the pressure applied to the drug tube 1, and the dose of the drug is controlled by controlling the infusion pump. A drug injector including a control unit;
It is installed in the drug tube (1) adjacent to the patient, to measure the flow rate of the drug flowing through the drug tube (1), and detects the bubble generation includes a sensor module (2) installed in the catheter fixing band ,
The sensor module 2,
A sensor body (100) having a fixed portion (110) into which a drug tube (1) through which drugs flow is inserted and fixed; A flow rate measuring part 200 installed at a position adjacent to the fixing part 110 to measure a flow rate of the drug flowing through the drug tube 1; It is installed in a position adjacent to the fixed portion 110, and includes a bubble detector 300 for detecting a bubble in the drug tube (1),
At the end of the catheter side of the drug tube 1 to which the drug is administered to the patient, the drug tube 1 is fitted to the fixed part 110,
The sensor body 100 is installed in the fixing band 400 which is attached to the patient in order to fix the catheter (4),
Is installed on one side of the drug tube (1), the drug for urgently blocking the drug to be administered, including a rotation blocking unit 510 for pressing and blocking the drug tube (1) from the side by rotation in accordance with an external electrical signal It includes a blocking unit 500,
The drug determination light emitting unit 610 is installed on one side of the drug tube (1) to irradiate light passing through the drug tube (1), and the other side is provided from the drug determination light emitting unit (610) Including the drug judgment light receiving unit 620 for receiving the irradiation light, the drug judgment unit 600 for determining whether the drug contained in the drug tube (1) through the degree of scattering of the light received by the drug judgment light receiving unit 620 Including;
The sensor body 100,
It includes a coupling portion 120 is formed to protrude from each side lower side,
The coupling part 120 is guided to the coupling guide part 430 provided in the fixing band 400 corresponding to the coupling part 120 to be coupled to the fixing band 400.
The coupling part 120 is formed at both ends of the protruding portions 123 protruding from both side lower sides of the sensor body 100, and at the ends of the protruding portions 123, and the coupling guide portion 430 in the horizontal direction. Coupling portion 121 is coupled along the guide groove 431 of the), and the coupling portion 121 of the coupling portion 121 to be fixed to the guide groove 431 of the coupling guide portion 430 It includes a locking portion 122 extending in the protruding direction at both ends,
The drug blocking unit 500,
And a sensor module installed in the catheter fixing band, wherein the catheter 4 is installed at the end of the catheter 4 in which the drug is administered to the patient among the sensor bodies 100 installed in the fixing band 400 attached to the patient. Drug administration system. The method according to claim 1,
The control unit,
Drug injection system comprising a sensor module installed in the catheter fixing band, characterized in that for controlling the dose of the drug by controlling the infusion pump based on the flow rate of the drug measured from the sensor module (2). The method according to claim 1,
The control unit,
If it is determined that the bubble is generated in the drug tube (1) from the sensor module (2), the drug comprising a sensor module installed in the catheter fixing band, characterized in that to stop the drug administration by controlling the injection pump Dosing system. The method according to claim 1,
The injection pump,
Drug administration system comprising a sensor module installed in the catheter fixing band, characterized in that the piezoelectric pump for administering the drug using the extension of the piezoelectric element according to the potential.

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