KR101359209B1 - Dosage educational injector. - Google Patents

Abstract

The present invention relates to an injector for educating medication and more specifically, to an injector for educating medication which can be utilized for educating dosage by measuring the insertion length of an injector needle, insertion angle of the injector needle, dosage of the injection liquid and dosage speed, and providing the same to the users. According to the present invention, the injector comprises: a displacement measuring tool which is structured to be horizontal with the injector needle; a flow velocity sensor for measuring dosage speed of the injector injected into the human body; a flux sensor for measuring dosage amount of the injector; and a slope measuring tool for measuring the insertion angles of the injector needle. The injector for educating medication includes a control tool which calculates displacement, flow velocity, flux, and slope values by obtaining the sensing signals and displays corresponding values to a user so that the injector for educating medication can accurately educate medication of the injector. [Reference numerals] (500) Control tool

Description

Dosage Educational injector.

The present invention relates to a syringe for administering education, and more particularly, it can be provided to users by measuring the insertion length of the syringe needle, the insertion angle of the syringe needle, the injection amount and the injection speed of the injection solution, and to use it for education about administration. And a dosage instruction syringe.

The purpose of the administration is to inject the correct dose of the drug accurately and safely through the correct administration route according to the use and effect of the drug prescribed by the subject's symptoms and the like.

The route of administration for administration is subdivided into intradermal injection for injecting drugs into the shallowest layer of the human body, subcutaneous injection for subcutaneous fat layer, intramuscular injection for muscle layer, and intravenous injection for vein. The nurse must insert the syringe needle into the patient's body differently with different depths and inclinations to inject the drug accurately and safely into each layer of the body (dermal, subcutaneous, muscle, vein).

Incorrect dosing, such as incorrect dosage and route of administration, can cause rapid and serious medical problems for the subject, so accurate dosing education is essential for safe dosing.

That is, the insertion depth of the syringe needle, the insertion angle of the syringe needle, the injection amount and the injection speed of the syringe needle vary according to the prescribed medication and the administration route to the user. The training is based on the first method of injection (intradermal injection, subcutaneous injection, intramuscular injection, intravenous injection) inserting a general syringe without a device into the human body model and the virtual screen of the computer simulator to move an object different from the actual syringe in the air. Intravenous injection was the second method.

The first method can educate all the dosages according to the administration route, but can be carried out simply by experience value to measure accurate data about the insertion depth of the syringe needle, the insertion angle of the syringe needle, the injection amount and injection speed of the injection solution, and the like. There was a problem that can not be objectively determined about the user's dosage skills, the second method can be used only for intravenous injection, the limitation of difficult movement and the insertion depth of the syringe needle during intravenous injection can be shown on the computer screen. The sensitivity of holding a real syringe is different by moving a similar object having a thickness and shape different from that of a real syringe in a hollow or perforated model that is not a human body model. The insertion depth of the needle and the insertion angle of the syringe needle can be measured Was, I do not have the ability to inject injectable solution had problems with the medication education does not measure the dose and infusion rate of injection solutions.

none.

The inventor of the present invention, a medication education syringe has the following purpose.

That is, the first object of the present invention is a displacement measuring means configured in parallel with the needle, flow rate sensor for measuring the injection speed of the injection solution injected into the human body, flow rate sensor for measuring the injection amount of the injection solution, syringe needle Configure the tilt measuring means for measuring the insertion angle of the syringe in the syringe, and the control means for calculating the displacement value, the flow rate value, the flow rate value, and the slope value by acquiring the detection signal to display the values to the user. It is.

A second object of the present invention is to make the resistance change even if the piston part rotates in the axial direction of the syringe which forms and inserts a spiral-shaped resistor inside the tilt measuring means.

The third object of the present invention is to configure the wireless transmission unit in the control means to provide the detection values to the external display device to monitor the current insertion length of the syringe needle, the insertion angle of the syringe needle, the injection amount and injection speed of the injection solution, etc. from the outside. It is to make it possible.

Means for Solving the Problems In order to achieve the above object, the present invention is as follows.

That is, the cylinder 20, the needle 10 is fixed to the tip,

In the syringe consisting of a piston portion 30 which can inject or outflow the drug while reciprocating the inside of the cylinder,

Displacement measuring means (100) formed outside the cylinder in parallel to the needle for measuring displacement upon contact with the skin;

A flow rate sensor 300 formed at an end of the piston and a cylinder to measure an injection amount of the injection solution injected into the human body by a change in the magnetic field;

A flow rate sensor 200 formed at the end portion of the piston to measure an injection speed of the injection solution injected into the human body;

The piston is formed in a tubular shape, a resistance is formed in the tube, and the conductive liquid metal is filled, so that the inclination measurement for measuring the insertion angle of the syringe needle using the resistance change amount according to the slope of the conductive liquid metal Means 400;

And a control means 500 for obtaining a signal measured by the displacement measuring means, flow rate sensor, flow rate sensor, and tilt measuring means to calculate a displacement value, a flow rate value, a flow rate value, and a slope value.

Dosing education syringe according to the present invention,

Displacement measuring means configured to be parallel to the needle, flow rate sensor for measuring the injection speed of the injection solution injected into the human body, flow rate sensor for measuring the injection amount of the injection solution, tilt measurement for measuring the insertion angle of the syringe needle By configuring the means in the syringe, the control means for acquiring the detection signal to calculate the displacement value, flow rate value, flow rate value, and inclination value to display the values to the user, thereby precisely training the syringe administration Will provide the effect.

In addition, even if the piston portion rotates in the axial direction of the syringe inserting a spiral-shaped resistor inside the tilt measuring means, so that the resistance change is measured equally, so that the insertion angle of the syringe needle can be measured irrespective of the axial rotation. It can provide the effect.

In addition, by configuring the wireless transmission unit in the control means to provide the detection value to the external display device to monitor the current insertion length of the syringe needle, the insertion angle of the syringe needle, the injection amount and injection speed of the syringe needle, etc. The provider will be able to confirm that medication is being taken.

1 is a cross-sectional view of a medication teaching syringe according to an embodiment of the present invention.
Figure 2 is an internal cross-sectional view of the inclination measuring means of the syringe needle for medication in accordance with an embodiment of the present invention.
Figure 3 is an exemplary view showing a micro-change amount measurement unit and the tilt measurement unit of the dosage training syringe according to an embodiment of the present invention.
Figure 4 is a conceptual diagram showing the axial rotation of the medication for syringe in accordance with an embodiment of the present invention.
Figure 5 is a block diagram of the control means of the syringe for dosing education according to an embodiment of the present invention.

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

It should be understood, however, that the scope of the present invention is not limited to these embodiments, and all of the technical ideas that fall within the scope of the present invention are within the scope of the present invention.

1 is a cross-sectional view of a medication teaching syringe according to an embodiment of the present invention.

As shown in Figure 1, the dosage training syringe,

The syringe 20 is configured with a syringe 20 fixed to the tip, and a piston unit 30 capable of introducing or discharging the drug while reciprocating the inside of the cylinder.

Here, the displacement measuring means 100 is configured to measure the degree of insertion of the syringe needle into the skin.

That is, the displacement measuring means 100 is formed outside the cylinder in parallel with the needle to measure the displacement upon contact with the skin.

For example, the displacement measuring means may have a bellows shape, and may be a spring or an elastic band.

In addition, it forms a cylindrical shape that can be placed inside the needle.

Then, in order to provide the measured value of the displacement measuring means to the control means is connected to the wire inside the cylinder, or to the outside by a wire.

In addition, the injection rate of the injection solution injected into the human body is measured to check how quickly the injection solution is introduced into the human body (or the human body, hereinafter, defined as the human body). The flow rate sensor 200 is formed to measure the injection rate of the injection solution injected into the human body.

In general, since the rubber packing is formed at the end of the piston, a space for inserting the flow rate sensor may be formed in the rubber packing or may be formed in front of the rubber packing.

In addition, the flow rate sensor 300 is configured at the end of the piston and the cylinder to measure the injection amount of the injection solution injected into the human body by the change of the magnetic field.

In order to provide the measured values to the control means to connect the wire to the flow sensor formed inside the cylinder and to connect the wire to the control means.

Since the technique of measuring the injection amount by the change of the magnetic field is a known technique, a detailed description thereof will be omitted.

In addition, as described above, a space for inserting the flow sensor may be formed in the rubber packing or may be formed in front of the rubber packing.

On the other hand, the tilt measuring means 400 which is the core technology of the present invention is configured in a tubular shape inside the piston part.

In this case, a resistance is formed in the tube, and the conductive liquid metal is filled so that the tilt (insertion angle of the syringe needle) is measured using the resistance change amount according to the slope of the conductive liquid metal.

2 is an internal cross-sectional view of the inclination measuring means of the syringe needle for medication education according to an embodiment of the present invention.

As shown in Figure 2, the inclination measuring means 400,

The first resistor 415 is formed in a spiral form on the inner surface of the tubular shape,

A spiral second resistor 425 formed in parallel with the first resistor,

Is formed on one side of the inner surface of the tubular, the first electrode 410 is connected to the first resistor,

A second electrode 420 formed on the other side of the tubular inner surface and to which the second resistor is connected;

It is configured to include a conductive liquid metal 430 is filled in the tubular shape.

The first resistor 415 and the second resistor 425 are formed parallel to the inner surface of the tubular shape in a spiral shape.

For example, a first resistor and a second resistor of tungsten alloy or metals are formed in a spiral form on the inner surface.

In addition, the conductive liquid metal is filled, preferably about half of the internal space.

The resistors are configured to measure the resistance value according to the slope of the conductive liquid metal.

In addition, the first electrode 410 is formed on one side of the tubular inner surface, one side of the first resistor is connected, and the second electrode 420 is formed on the other side of the tubular inner surface, and One side will be connected.

In this case, the resistor may be a variable resistor.

On the other hand, as shown in Figure 3, the control means 500,

Fine change amount measuring unit 510 for measuring the fine change amount of the resistance according to the slope of the conductive liquid metal,

It comprises a gradient measuring unit 520 for measuring the gradient by obtaining the resistance micro-change amount measured in the fine change amount measuring unit.

That is, the above configuration is for measuring tilt (insertion angle of the syringe needle).

In detail, the micro change amount measuring unit 510 measures the resistance change amount according to the slope of the conductive liquid metal. For example, the micro change amount measuring unit 510 may include a Wheatstone bridge circuit to amplify the resistance change amount. .

That is, there is no change amount in the horizontal state, but when tilted, a minute resistance change (저항 R) occurs.

At this time, the Wheatstone bridge circuit performs the function of amplifying so that the amount of fine change can be measured.

In addition, the inclination measuring unit 520 measures the inclination by obtaining the resistance microvariation amount? R measured by the microvariation measuring unit.

As described above, the reason for measuring the tilt (insertion angle of the syringe needle) depends on the purpose and effect of the injection drug to deliver the drug from the shallowest layer of the human body to the subcutaneous, muscle, and deepest veins below it. Since the injection solution must be injected by inserting the different angles of the needle, it is configured to practice the tilt during correct insertion so that the drug can be accurately delivered to each layer of the human body.

In addition, as described above, the reason for forming a spiral-shaped resistor inside the inclination measuring means is as shown in FIG. 4, so that the resistance change amount is measured equally even if the piston part (syringe) rotates in the axial direction of the syringe to be inserted. This provides the effect of measuring the insertion angle of the syringe needle irrespective of the axial rotation.

Figure 5 is a block diagram of the control means of the medication for syringe in accordance with an embodiment of the present invention.

That is, the control means obtains the signals measured by the displacement measuring means, the flow sensor, the flow rate sensor, and the tilt measuring means to calculate the displacement value, the flow rate value, the flow rate value, the slope value, and display the calculated values on the display panel. Will be.

In addition, the control means,

Displacement measuring means, flow rate sensor, displacement / flow rate / flow rate detection signal acquisition unit 530 for obtaining the detection signal measured by the flow rate sensor,

A digital signal converting unit 540 for converting a sensing signal obtained from the displacement / flow rate / flow sensing signal acquisition unit into a digital signal,

A digital signal calculator 550 for obtaining a digital signal converted by the digital signal converter and calculating a displacement value, a flow rate value, and a flow rate value;

A display output processor 560 for outputting a displacement value, a flow rate value, a flow rate value, and a tilt value measured by the tilt measurement unit to the display panel;

And a display panel 570 for displaying a displacement value, a flow rate value, a flow rate value, and a slope value transmitted by the display output processor.

The displacement / flow rate / flow rate detection signal acquisition unit 530 acquires a detection signal measured by the displacement measuring means, the flow rate sensor, and the flow rate sensor.

In this case, since the obtained sensing signal is an analog signal, a process of converting the signal into a digital signal is required to analyze the same in the central controller (not shown).

Since the central controller is a generally configured element, a detailed description of the operation is omitted.

That is, the digital signal converter 540 converts the sensing signal acquired by the displacement / flow rate / flow rate detection signal acquisition unit into a digital signal.

In this case, the digital signal calculator 550 obtains the digital signal converted by the digital signal converter to calculate the displacement value, the flow rate value, and the flow rate value, and the displacement value and the flow rate calculated by the display output processor 560. A value, a flow rate value, and an inclination value measured by the inclination measuring unit are output to the display panel.

On the other hand, the control means may be configured to include a wireless transmission unit (not shown) for acquiring the calculated (measured) value and wirelessly transmitting it to the external display device.

That is, when the external display device is configured and the wireless transmission unit is configured, two-way wireless communication is possible, so that the calculated displacement value, flow rate value, flow rate value, and slope value can be transmitted using the same.

In general, the wireless transmission unit may use a short range communication method such as a Wi-Fi communication method and a Bluetooth communication method.

For example, configuring the syringe of the present invention in a practice room and configuring the external display device in a teaching room located at a short distance may monitor the detection values transmitted from each control means.

To this end, each control means is assigned a unique identification number so that it is possible to determine which detection value is transmitted from which syringe.

Therefore, the student through the display panel configured in the syringe can check his syringe injection status in real time, and through the external display device configured in a short distance, the professor can monitor the syringe injection status of the students.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: displacement measuring means
200: flow rate sensor
300: flow sensor
400: tilt measurement means
500: control means

Claims (8)

Cylinder 20, the needle 10 is fixed to the tip,
In the syringe consisting of a piston portion 30 which can inject or outflow the injection solution while reciprocating inside the cylinder,
Displacement measuring means 100 is formed on the outside of the cylinder in parallel to the needle to measure the displacement when in contact with the skin;
A flow rate sensor 300 formed at an end of the piston and a cylinder to measure an injection amount of the injection solution injected into the human body by a change in the magnetic field;
A flow rate sensor 200 formed at the end portion of the piston to measure an injection speed of the injection solution injected into the human body;
Consists of a tubular shape inside the piston portion, forming a resistor in the tube, and is filled with conductive liquid metal to measure the slope (insertion angle of the syringe needle) using the resistance change amount according to the slope of the conductive liquid metal Tilt measuring means for 400;
Dosage education syringe comprising a; control means for obtaining a signal measured in the displacement measuring means, flow sensor, flow rate sensor, inclination measuring means (500) to calculate the displacement value, flow rate value, flow rate value, slope value .
The method of claim 1,
The inclination measuring means 400,
The first resistor 415 is formed in a spiral form on the inner surface of the tubular shape,
A spiral second resistor 425 formed in parallel with the first resistor,
Is formed on one side of the inner surface of the tubular, the first electrode 410 is connected to the first resistor,
A second electrode 420 formed on the other side of the tubular inner surface and to which the second resistor is connected;
Dosage education syringe comprising a conductive liquid metal 430 is filled in the tubular shape.
The method of claim 1,
The control means 500,
Fine change amount measuring unit 510 for measuring the fine change amount of the resistance according to the slope of the conductive liquid metal,
Dosing education syringe comprising a tilt measuring unit for measuring the slope by obtaining the resistance micro-change amount measured in the micro-change amount measuring unit.
The method of claim 1,
The control means 500,
Displacement measuring means, flow rate sensor, displacement / flow rate / flow rate detection signal acquisition unit 530 for obtaining the detection signal measured by the flow rate sensor,
A digital signal converting unit 540 for converting a sensing signal obtained from the displacement / flow rate / flow sensing signal acquisition unit into a digital signal,
A digital signal calculator 550 for obtaining a digital signal converted by the digital signal converter and calculating a displacement value, a flow rate value, and a flow rate value;
A display output processor 560 for outputting values calculated by the digital signal calculator to a display panel;
And a display panel (570) for displaying the displacement value, the flow rate value, and the flow rate values delivered by the display output processor.
The method of claim 1,
The control means 500,
Fine change amount measuring unit 510 for measuring the fine change amount of the resistance according to the slope of the conductive liquid metal,
Gradient measuring unit 520 for measuring the gradient by obtaining the resistance micro-change amount measured in the fine change amount measurement unit,
Displacement measuring means, flow rate sensor, displacement / flow rate / flow rate detection signal acquisition unit 530 for obtaining the detection signal measured by the flow rate sensor,
A digital signal converting unit 540 for converting a sensing signal obtained from the displacement / flow rate / flow sensing signal acquisition unit into a digital signal,
A digital signal calculator 550 for obtaining a digital signal converted by the digital signal converter and calculating a displacement value, a flow rate value, and a flow rate value;
A display output processor 560 for outputting a displacement value, a flow rate value, a flow rate value, and a tilt value measured by the tilt measurement unit to the display panel;
And a display panel 570 for displaying a displacement value, a flow rate value, a flow rate value, and a slope value transmitted by the display output processor.
The method according to claim 3 or 5,
The fine change measuring unit 510,
A dosing training syringe comprising a Wheatstone bridge circuit to amplify the resistance micro-change amount.
6. The method according to any one of claims 3 to 5,
The control means 500,
And a wireless transmitter (not shown) for acquiring a calculated (measured) value and wirelessly transmitting it to an external display device.
The method of claim 1,
The inclination measuring means 400,
Dosage training syringe, characterized in that the resistance change is measured equally even if the piston rotates in the axial direction.

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