KR20160066320A - instrument for measuring weight of Ringer's solution - Google Patents

Abstract

The present invention relates to a device for measuring the weight of an infusion solution. The device for measuring the weight of an infusion solution makes an elastic member of a road cell as a parallelogram shape, interposes the elastic member between suspension strings, and attaches two strain gauges separated at constant intervals to each of the left side and the right side having a line extending the suspension strings from the bottom surface of the lower side to the elastic member therebetween. A wheatstone bridge circuit is formed by using the strain gauges. The voltages outputted from an outputting terminal of the wheatstone bridge circuit is influenced by a low-pass filter.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to an apparatus for measuring the weight of a liquid for a ring gel for performing a ring gel of a correct potion in a patient in a hospital or the like.

A set of fluids for the patient to perform a ring gel on a patient usually applies to the patient as follows.

A nurse hangs a liquid pack containing a predetermined amount of a potion in a cradle, connects the drip chamber to the liquid pack, connects a tube for removing the air mixed with the roller clamp for adjusting the flow rate, , The injection needle is stuck to the patient and the injection of the drug into the patient (the ring gel) is initiated.

Also, at this time, the nurse counts the number of dropping drops of water in the drip chamber within a predetermined time and adjusts the roller clamp so that the flow rate per hour is required while viewing the chart (flow rate calculation table).

Thereafter, when the total amount of the solution injected into the patient does not reach the total amount of injected into the patient, it is necessary to replace it with the next liquid pack. In this case, however, all of them are carried out by an artificial detection of the nurse.

To solve such a problem, the apparatus for measuring the end point of a fluid usually has a strain gauge fixed to a detecting member which is interposed between a set of fluid and a cradle and deformed according to the weight of the fluid pack, and is large when the weight of the fluid pack is heavy, So that a small detection signal is generated to automatically detect the empty liquid contained in the liquid-liquid pack.

However, the above-described liquid end-point measurement apparatus has a problem that the detection member sensitive to the external force is damaged when the patient or the caregiver pulls the liquid-pour pack over the indifferent position, so that the detection member must be frequently replaced.

An apparatus for measuring the end point of a liquid for solving such a problem is disclosed in Japanese Patent No. 1296586, which is patented by the present applicant.

The above-described liquid end-point measurement apparatus can detect the weight of the liquid medicine in the liquid-liquid pack while reducing the load on the load cell by dispersing the weight of the liquid-liquid pack, thereby providing an effect of automatically measuring the end point of the liquid-liquid.

However, the above-mentioned conventional apparatus for measuring the end point of a liquid for ring gel has not only the weight of the liquid by vibration (shaking) of the liquid pack 3 when the patient is moving (walking, wheelchair, automobile, airplane, etc.) There is a problem in accurately measuring the remaining amount of the liquid in the present state.

The present invention has a problem in solving the above-mentioned problems.

The present invention is characterized in that the elastic member of the load cell is made of "? &Quot;, the elastic member is interposed between the suspending lines, and the elastic member is provided with a predetermined interval at each of the left and right sides with a line extending from the bottom of the lower side, The above problem can be solved by adhering two spaced strain gauges, constructing a Wheatstone bridge circuit using the strain gauge, and filtering the voltages output from the output terminal of the Wheatstone bridge circuit by a low-pass filter.

According to the present invention, by the solution of the above-mentioned problem, the liquid receiver is vibrated in the left and right direction or vibrated up and down so that the resistances of the strain gauge are repeatedly increased and decelerated repeatedly so as to be outputted from the output terminal of the Wheatstone bridge circuit Even if the voltages are abruptly changed, the fluctuation of the voltage is attenuated by the low-pass filter, and the remaining amount of the liquid in the liquid-liquid pack is reliably measured regardless of the vibration of the liquid- The present invention is not limited thereto.

1 is a conceptual diagram showing an equilibrium state of a Wheatstone bridge circuit,
Fig. 2 is a conceptual diagram showing the unbalanced state of the circuit of the Wheatstone bridge, Fig.
FIG. 3 is a conceptual diagram showing the apparatus for measuring a liquid weight of the present embodiment,
FIG. 4 is a conceptual diagram showing a wheatstone bridge and an electronic circuit of the load cell of FIG. 3;
Fig. 5 is a graph showing the voltage output from the output of the shiston bridge of Fig. 4 when the fluid pack is vibrated,
Fig. 6 and Fig. 7 are conceptual diagrams showing the apparatus for measuring the liquid sapphire of Fig. 3 when the liquid pack oscillates from side to side, and
Fig. 8 is a conceptual diagram showing the apparatus for measuring the liquid sapphire of Fig. 3 when the liquid pouch vibrates up and down. Fig.

Hereinafter, an apparatus for measuring the weight of a liquid according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 8 attached hereto.

The load cell transforms the physical deformation occurring in the elastic member which generates a structurally stable deformation with respect to the force or the load into a change of the electrical resistance by using a plurality of strain gauges, and by using the plurality of strain gauges, And converts it into a precise electrical signal.

1, when a power source is applied to the Wheatstone bridge, a current flows from the resistor R1 to the resistor R3, and an equivalent current flows from the resistor R2 to the resistor R4 Flows. This is based on the premise that all resistances are the same. Therefore, since there is no voltage difference between the point P1 and the point P2, there is no current flowing through the ammeter A. This indicates that the Wheatstone bridge is in equilibrium.

As shown in Fig. 2, when the resistors R1 and R4 are increased and the resistors R2 and R3 are decreased, the Wheatstone bridge is unbalanced and a three-way current flow is generated in this circuit do.

The first path is a path through which the current flows from the negative electrode to the positive electrode through the resistor R2 through the resistor R2 and the second path from the negative electrode to the positive electrode through the resistor R1 and the resistor R3, And the third path is a path through which current flows from the negative electrode to the positive electrode through the resistor R2 and through the ammeter A to the positive electrode R3.

The current flow through the ammeter A appears as a result of the potential difference between the point P1 and the point P2 and the larger the potential difference is, the larger the current flowing through the ammeter A is.

When four strain gauges are attached to each pole of the iron rod, and the weight is placed on the pole, the pole is reduced in length and is fattened sideways.

Two strain gauges respond proportionally to changes in length on the other opposite side. Two other gauges are located on the side corresponding to the swelling of the column. Therefore, the pair of strain gauges have their wire length shortened, the diameter increased, and the resistance value decreased. The other pair of strain gauges lengthen their wires and thus decrease in diameter and increase the resistance value. If the same weight is attached to the bottom of the column, the column receives tension instead of compression. The columns and strain gage wires behave in opposite directions, but the amount due to tension and compression is the same.

A description will be made of a sapphire weight measuring apparatus of this embodiment with the basic configuration of such a load cell as follows.

In Fig. 3, reference numeral 100 denotes the apparatus for measuring the liquid weight of the present embodiment.

The liquid weighing apparatus 100 includes a substrate B fixed to a bar F of a cradle, a temperature measurement sensor 4 mounted on the substrate B to measure the temperature around the patient, An LED illumination unit 3 mounted on the substrate B and illuminating the liquid infusion pack 50 at night, a display unit 26 mounted on the display unit 26, 26 and an electronic circuit unit 10 connected to the LED illumination unit 3, a load cell 12 mounted on the substrate B, one end fixed to the load cell 12 and the other end extended vertically downward, 50 are suspended in a suspended manner.

An elastic member 111 which is a parallelepiped elastic body and whose upper middle upper surface is fixed to the substrate B and is deformed according to the weight of the liquid infusion pack 30; And four strain gages (61, 62, 63, 64) adhered to four deformed portions (61, 62, 63, 64) on the underside of the lower side of the elastic member (111) causing compression strain and tensile strain in accordance with the load of the solution pack 56, 57, 58, 59).

The four deformed portions 61, 62, 63 and 64 are positioned on both sides of the lower side of the lower side of the elastic member 111 with the vertical direction line of the suspending jig 40 at the center, The strain gauges 56, 57, 58, 59 of the four strain gauges 56, 57, 58, 59 bonded to the four strain portions 61, 62, 63, 64 when the liquid pack 50 is caught in the line 40, 59 are in the compression posture and the strain gauges 57, 58 are in the tension posture.

In the load cell 12, a bridge circuit 80 is constituted by strain gages 56, 57, 58 and 59 as shown in Fig.

In the bridge circuit 80, the applied voltage Ei is applied between the terminal a and the terminal b by the constant voltage source 84.

A load of the liquid bag 50 is applied to the elastic member 111 when the liquid bag 50 is hooked on the hanging string 40 and the four deformation portions 61, 62, 63, The strain gages 56, 57, 58, and 59 change resistance. The output voltage Eo at the terminals c and d of the bridge circuit 80 varies in proportion to the magnitude of the load load. The magnitude of the load load can be measured in measuring the change amount of the output voltage (Eo).

When the load is applied, the load cell 12 outputs an analog load signal of a voltage according to the magnitude of the applied load. 4, the analog load signal is subjected to amplification processing by the amplification circuit 14 of the electronic circuit section 10 and then inputted to the A / D conversion circuit 16 through the low-pass filter 17 .

In the low-pass filter 17, as shown in FIG. 5, the analog load signals amplified by the amplifier circuit 14 due to the vibration occurring in the liquid receiver 50 pass a low frequency portion when swinging, And gives a large attenuation to the frequency.

The A / D conversion circuit 16 converts the input analog load signal into a digital load signal by sampling at a predetermined sampling period. The sampling period is several seconds (ms: 1/1000 second). The digital load signal converted by the A / D conversion circuit 16 is input to the CPU 20 via the input / output interface circuit 18. [

The CPU 20 calculates the magnitude of the load applied to the load cell 12 based on the digital load signal input via the input / output interface circuit 18. Then, the calculation result is displayed on the display 26 as display means. The display 26 is connected to the CPU 20 via the input / output interface circuit 18. The CPU 20 is also connected to an operation key 24 as an instruction input means through the input / output interface circuit 18. [ A memory circuit 22 as a storage means is also connected to the CPU 20. A control program for controlling the operation of the CPU 20 is stored in the memory circuit 22. [

The apparatus for measuring weights of the liquids configured as described above operates as follows.

As shown in FIG. 3, when no vibration occurs in the fluid pack 50, the strain gauges 56 and 59 always have a compression posture, and the strain gauges 57 and 58 always transmit the tensile posture So that the output voltage Eo at the terminal c and the terminal d is lowered in accordance with the decrease in the liquid level of the liquid bag 50 and is displayed on the display 26 by the CPU 20 in accordance with the actual weight change of the liquid bag 50. [ The actual weight is displayed.

6 and 7, when the liquid bag 50 vibrates horizontally as shown in Figs. 6 and 7, particularly when the liquid bag 50 has a vertical direction and a non-parallel state, the load of the liquid bag 50 is horizontal The strain gages 56 and 59 have a compression posture and the strain gauges 57 and 58 have a tensioning attitude at the vertical component of the load of the fluid pack 50. At this time, The output voltage Eo is output from the terminal c and the terminal d of the bridge circuit 80 and the strain gauges 56 and 57 are connected alternately to the compressing and tensile postures in the horizontal component of the load of the liquid- So that the strain gauges 58 and 59 alternately repeat the tension posture and the compression posture so that the output voltage Eo can not be output from the c terminal and the d terminal of the bridge circuit 80.

Therefore, when the liquid bag 50 vibrates to the left and right, the horizontal component of the load of the liquid bag is removed from the Wheatstone bridge circuit, and only the vertical component of the load of the liquid bag is left and output as the output voltage Eo. The output voltage Eo at the terminal c and the output voltage Eo at the terminal d are increased and decreased so that the low frequency filter 17 passes the low frequency portion and attenuates the high frequency. The actual weight is displayed on the display 26 by the CPU 20 in accordance with the actual weight change of the liquid pack 50. [

8, the strain gauges 56 and 59 alternately repeat the compression attitude and the tensile attitude, and the strain gages 57 and 58 are alternately repeated. The output voltage Eo is repeatedly increased and decreased at the terminal c and the terminal d while the load of the liquid filter is increased and decreased repeatedly alternately with the tension attitude and the compression attitude alternately. The output voltage Eo at the c terminal and the d terminal is lowered in accordance with the decrease in the liquid level of the liquid bag 50 and the output voltage Eo of the liquid crystal panel 50 is lowered in accordance with the actual weight change of the liquid bag 50, (20) displays the actual weight on the display (26).

When the electronic circuit unit 10 is wired or wirelessly connected to an environment monitor and a control management server (not shown), the annular monitor and the control management server allow the nurse or doctor to check the remaining amount of the liquid in the actual liquid- It is preferable from the viewpoint of being able to notify.

12; Load cell, 50; Sap pack

Claims (3)

A substrate B fixed to a bar F of a cradle,
A display unit 26 mounted on the substrate B for displaying the amount of remaining liquid,
An electronic circuit unit 10 connected to the display unit 26,
A load cell 12 mounted on the substrate B,
And a hanging string (40) having one end fixed to the load cell (12) and the other end extended vertically downward to be suspended so as to suspend the fluid pack (50)
An elastic member 111 which is a parallelepiped elastic body and whose upper middle upper surface is fixed to the substrate B and is deformed according to the weight of the liquid infusion pack 30; And four strain gages (61, 62, 63, 64) adhered to four deformed portions (61, 62, 63, 64) on the undersurface of the lower side of the elastic member (111) causing compression strain and tensile strain in accordance with the load of the solution pack 56, 57, 58, and 59,
In the load cell 12, the bridge circuit 80 is constituted by the strain gauges 56, 57, 58, and 59.
The c terminal and the d terminal of the bridge circuit 80 are sequentially connected to the amplifying circuit 14 of the electronic circuit portion 10, the low pass filter 17 and the A / D converting circuit 16,
The A / D conversion circuit 16 is connected to the CPU 20 through an input / output interface circuit 18,
The display 26 is connected to the CPU 20 via an input / output interface circuit 18,
The CPU 20 is also connected to an operation key 24 as an instruction input means through the input / output interface circuit 18 and to a memory circuit 22 as a storage means,
A control program for controlling the operation of the CPU 20 is stored in the memory circuit 22,
The four deformed portions 61, 62, 63 and 64 are positioned on both sides of the lower side of the lower side of the elastic member 111 with the vertical direction line of the suspending jig 40 at the center, The strain gauges 56, 57, 58, 59 of the four strain gauges 56, 57, 58, 59 bonded to the four strain portions 61, 62, 63, 64 when the liquid pack 50 is caught in the line 40, 59 are in a compression posture and the strain gauges (57, 58) have a tension attitude. The method according to claim 1,
A temperature measurement sensor 4 mounted on the substrate B for measuring the temperature around the patient,
And an LED illuminating unit (3) mounted on the substrate (1) and illuminating the sap pack (50) at night,
Wherein the electronic circuit unit (10) is connected to the temperature measurement sensor (4) and the LED illumination unit (3). The method according to claim 1,
Wherein the electronic circuit unit (10) is connected to an environmental monitor and a control management server by wire or wirelessly.

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