KR102365746B1 - Absorbance measuring apparatus - Google Patents

Abstract

As a disclosed absorbance measuring device comprises a sample flow member, a light source, a detector, a moving member, and a light attenuation filter member, at the zero point measurement position, the amount of light emitted from the light source and directed toward the detector is attenuated by the light attenuation filter member. Since such light attenuation does not occur at a density measurement position, the difference between each measurement voltage value at the zero point measurement position and the density measurement position can be reduced. Thus, there is an advantage in that a decrease in absorbance measurement accuracy due to external temperature change can be prevented.

Description

Absorbance measuring apparatus

The present invention relates to an absorbance measuring device.

The absorbance measuring device is a device for measuring the concentration of a sample by using the property of a material in a solution to absorb light. When the concentration of the sample is high, the absorbance is high, and when the concentration of the sample is low, the absorbance is also decreased.

What can be presented as an example of such an absorbance measuring device is that of the patent document presented below.

Those of the patent documents presented below have been previously registered by the applicant of the present application. The measurement is carried out while moving the light source and detector to the concentration measurement position where concentration measurement is possible.

At this time, the absorbance measurement accuracy using the measured voltage value decreases according to the external temperature change. In particular, the greater the difference between each measured voltage value at the zero point measurement position and the concentration measurement position, the more sensitively it responds to such temperature change, The absorbance measurement accuracy may be significantly reduced.

However, according to the conventional absorbance measuring apparatus, it was not possible to solve the problem that the absorbance measurement accuracy is deteriorated according to the external temperature change.

In addition, according to the conventional absorbance measuring apparatus, air contained in the sample also caused the decrease in absorbance measurement accuracy, but there was a problem in that it was difficult to remove the air contained in the sample.

Registered Patent No. 10-2218313, Registration date: 2021.02.16., Title of the invention: Absorbance measuring device

An object of the present invention is to provide an absorbance measuring apparatus capable of preventing a decrease in absorbance measurement accuracy due to external temperature change.

Another object of the present invention is to provide an absorbance measuring device that allows air contained in a sample to be removed in order to improve absorbance measurement accuracy.

An absorbance measuring device according to an aspect of the present invention comprises: a sample flow member through which a sample, which is a concentration measurement target, flows for concentration measurement; a light source capable of irradiating light for measuring the concentration of the sample; a detector capable of detecting the light irradiated from the light source; a moving member capable of moving the light source and the detector to a zero point measurement position capable of measuring a zero point, which is a reference for measuring the concentration of the sample, and a concentration measurement position capable of measuring the concentration of the sample; and a light attenuation filter member for attenuating the amount of light emitted from the light source at the zero point measurement position and directed toward the detector.

In a state where the light source and the detector are moved to the zero point measurement position by the moving member and the zero point is measured, the light source and the detector are moved to the concentration measurement position by the moving member so that the concentration of the sample is It may be measured based on the zero point, and when the light source and the detector are moved to the zero point measurement position by the moving member and the zero point is measured, the amount of light emitted from the light source and directed toward the detector is the amount of light attenuated by an attenuation filter element,
The sample flow member includes a sample flow body and a predetermined direction in a direction in which light is emitted from the light source toward the detector inside the sample flow body so that the sample can flow in a direction in which light is emitted from the light source toward the detector. A sample flow hole formed long in length, a sample inflow path that is connected to the bottom of one side of the sample flow hole and serves as an inlet through which the sample flows into the inside of the sample flow hole, and the ceiling of the other side of the sample flow hole A sample outlet which is connected and serves as an outlet through which the sample flowing along the inside of the sample flow hole is discharged, a slope collector formed in a taper shape on the ceiling of the sample flow hole, and the highest point among the slope collectors Doedoe formed in, including an air vent hole for communicating the inside of the sample flow hole and the outside of the sample flow body,
The sample flow body is formed in a horizontally long form compared to the vertical, the light source is disposed to face one side of the sample flow body, the detector is disposed to face the other side of the sample flow body, and the sample When the light source and the detector of the fluid body are in the concentration measurement position, on each side portion facing the light source and the detector, the light irradiated from the light source passes through the sample flow hole to reach the detector. A transparent window is formed, and the sample inflow path is connected to the bottom of one side of the sample flow hole and the sample outlet is connected to the ceiling of the other side of the sample flow hole, so that the sample introduced through the sample flow hole is After flowing in the longitudinal direction of the sample flow hole, it can be discharged through the sample flow path, and the inclined collector is formed in a tapered shape that is the highest point at the center of the ceiling of the sample flow hole, so that the sample flow hole passes through the sample flow hole. During the flow of the sample, the air contained in the sample rises from the inside of the sample to reach the inclined collector in the form of a bubble, and then moves along the inclined collector toward the highest point of the inclined collector. and the air moved toward the highest point of the inclined collector can be discharged to the outside through the air vent hole, so that air in the sample can be removed while the sample flows through the sample flow hole characterized in that

According to the absorbance measuring device according to an aspect of the present invention, since the absorbance measuring device includes a sample flow member, a light source, a detector, a moving member, and a light attenuation filter member, the light attenuation filter at the zero point measurement position The amount of light irradiated from the light source and directed to the detector is attenuated by the member, and such light attenuation does not occur at the concentration measurement position, so that the difference between each measured voltage value at the zero point measurement position and the concentration measurement position is It can be reduced, and there is an effect that a decrease in absorbance measurement accuracy due to external temperature change can be prevented.

In addition, the absorbance measuring device further includes an external air removing member, the sample flow member includes an inclined collector and an air vent hole, and the sample flow hole constituting the sample flow member emits light from the light source toward the detector. By forming a long predetermined length in the direction in which light is irradiated from the light source to the detector in the inside of the sample flow body so that the sample can flow in the irradiated direction, the air contained in the sample can be removed, Accordingly, there is an effect that the absorbance measurement accuracy can be improved.

1 is a perspective view showing a state in which an absorbance measuring apparatus according to an embodiment of the present invention is in a concentration measuring position together with a partial cross-section;
Figure 2 is a cross-sectional view of the absorbance measuring apparatus according to an embodiment of the present invention in a position measuring the concentration from the front.
3 is a perspective view showing a state in which the absorbance measuring apparatus according to an embodiment of the present invention is in a zero-point measurement position.
4 is a cross-sectional view of the external air removing member constituting the absorbance measuring device according to an embodiment of the present invention from the front.

Hereinafter, an absorbance measuring apparatus according to an embodiment of the present invention will be described with reference to the drawings.

1 is a perspective view showing a state in which an absorbance measuring device according to an embodiment of the present invention is in a concentration measuring position with a partial cross-section, and FIG. 2 is an absorbance measuring device according to an embodiment of the present invention in a concentration measuring position It is a cross-sectional view seen from the front, FIG. 3 is a perspective view showing the absorbance measuring device according to an embodiment of the present invention in a zero-point measurement position, and FIG. 4 is an absorbance measuring device according to an embodiment of the present invention. It is a cross-sectional view viewed from the front of the external air removing member.

1 to 4 , the absorbance measuring apparatus 100 according to the present embodiment includes a sample flow member 110 , a light source 130 , a detector 140 , a moving member 150 , and a light quantity. and an attenuation filter element 170 .

In addition, the absorbance measuring apparatus 100 may further include an external air removing member 160 .

In addition, the absorbance measuring apparatus 100 may further include a collimated light forming lens member 180 and a condensing lens member 185 .

In the sample flow member 110 , a sample, which is a concentration measurement target, flows for concentration measurement, and includes a sample flow body 111 , a sample flow hole 112 , a sample inlet passage 113 , and a sample outlet passage 114 . ), and an inclined collector 115 and an air vent hole 116 .

The sample flow body 111 is formed in a rectangular parallelepiped shape, and therein the sample flow hole 112 , the sample inlet 113 , the sample outlet 114 , the inclined collector 115 and The air vent hole 116 is formed.

The sample flow body 111 is formed in a horizontally long shape compared to the vertical, and the light source 130 is disposed to face one side of the sample flow body 111 , and the other side of the sample flow body 111 is disposed to face the sample flow body 111 . The detector 140 is disposed to face the side surface.

The sample flow hole 112 is formed inside the sample flow body 111 from the light source 130 so that the sample can flow in a direction in which light is irradiated from the light source 130 toward the detector 140 . It is formed to have a predetermined length in a direction in which light is irradiated toward the detector 140 .

When the light source 130 and the detector 140 of the sample flow body 111 are at the concentration measurement position, on each side portion facing the light source 130 and the detector 140, the light source 130 Transparent windows are formed so that the irradiated light can pass through the sample flow hole 112 and reach the detector 140 .

The sample inflow path 113 is connected to the bottom of one side of the sample flow hole 112 so that the sample passing through the external air removing member 160 is introduced into the sample flow hole 112 . will be the entrance.

The sample outlet path 114 is connected to the ceiling of the other side of the sample flow hole 112 , and becomes an outlet through which the sample flowing along the inside of the sample flow hole 112 is discharged.

As described above, as the sample inlet 113 and the sample outlet 114 are formed, the sample introduced through the sample inlet 113 flows in the longitudinal direction of the sample flow hole 112 . Then, it can be discharged through the sample outlet path 114 .

The inclined collector 115 is formed in a tapered shape on the ceiling of the sample flow hole 112 .

In this embodiment, the inclined collector 115 is formed in a tapered shape that becomes the highest point at the center of the ceiling of the sample flow hole 112 , so that during the process of flowing the sample through the sample flow hole 112 , the The air contained in the sample rises from the inside of the sample to reach the inclined collector 115 in the form of a bubble, and then moves along the inclined collector 115 toward the highest point of the inclined collector 115. be able to

The air vent hole 116 is formed in the form of a fine hole at the highest point of the inclined collector 115 to communicate the inside of the sample flow hole 112 and the outside of the sample flow body 111 .

The air moved toward the highest point of the inclined collector 115 can be discharged to the outside through the air vent hole 116, so that while the sample flows through the sample flow hole 112, the Air can be removed.

The sample, from which air is primarily removed while passing through the external air removal member 160 , is introduced into the sample flow hole 112 through the sample inflow path 113 , and is transmitted from the light source 130 to the detector. During the process of flowing in the direction in which light is irradiated toward 140, the air remaining in the sample floats to the top of the sample flow hole 112 and then flows along the inclined collector 115 to flow through the air vent hole ( 116) and then removed to the outside of the sample flow body 111 through the air vent hole 116.

Here, the sample passes through the external air removal member 160 primarily, and then passes through the inclined collector 115 and the air vent hole 116 of the sample flow member 110 and secondarily through the air has been suggested to be removed, but is not limited thereto, and the sample is not directly passed through the external air removal member 160 but the inclined collector 115 and the air vent hole of the sample flow member 110 ( 116) can also be used.

The light source 130 may irradiate light for measuring the concentration of the sample, and an LED light source 130 may be presented as an example.

The detector 140 may detect the light irradiated from the light source 130 , and a photodiode may be presented as an example.

The moving member 150 moves the light source 130 and the detector 140 to a zero point measurement position capable of measuring a zero point, which is a reference for measuring the concentration of the sample, and a concentration measurement position capable of measuring the concentration of the sample. that can be moved

Here, the zero point measurement position means that the light source 130 and the detector 140 move away from the sample flow member 110 and directly face each other, so that the light irradiated from the light source 130 is directed to the detector 140 . It refers to a direct inflow position, and the concentration measurement position refers to a position where the light source 130 and the detector 140 indirectly face each other with the sample flow member 110 interposed therebetween. Refers to a position where light passes through the sample flow hole 112 of the sample flow member 110 and then flows into the detector 140 .

In a state in which the light source 130 and the detector 140 are moved to the zero point measurement position by the moving member 150 and the zero point is measured, the light source 130 and the detector 140 are moved to the zero point by the moving member 150 . The detector 140 is moved to the concentration measurement position, so that the concentration of the sample flowing through the sample flow hole 112 can be measured based on the zero point.

In detail, the moving member 150 includes a light source mounting body 151 , a detector mounting body 156 , a body connecting body 158 , and a driving means 154 .

The light source mounting body 151 is to which the light source 130 is mounted.

The detector mounting body 156 is to which the detector 140 is mounted.

A light source holder 155 protrudes from the outer surface of the light source holder body 151 , the light source 130 is installed on the light source holder 155 , and a detector holder 157 is installed on the outer surface of the detector holder body 156 . ) protrudes, and the detector 140 may be installed on the detector holder 157 .

The light source 130 and the detector 140 are disposed so as to directly face each other on the surfaces of the light source mounting body 151 and the detector mounting body 156 that face each other. That is, the light source 130 and the detector 140 may be directly disposed on the surfaces of the light source mounting body 151 and the detector mounting body 156 facing each other, and the light source mounting body 151 and The light source 130 and the detector 140 are respectively disposed on the outside of the detector mounting body 156, and the light source mounting body 151 so that the light source 130 and the detector 140 directly face each other. And the detector mounting body 156 may be formed to have a hole portion through each.

The body connecting body 158 connects the light source mounting body 151 and the detector mounting body 156 to move integrally.

The body connecting body 158 is formed in the form of a shaft, and may be rotatably connected to the sample flow body 111 .

The driving means 154 provides a driving force for moving the light source 130 and the detector 140 to the zero point measurement position and the concentration measurement position.

In this embodiment, the driving means 154 rotates any one of the light source mounting body 151 , the detector mounting body 156 and the body connecting body 158 , and the light source mounting body 151 and As the detector mounting body 156 is sequentially moved to the zero point measurement position and the concentration measurement position, the light source 130 and the detector 140 can be sequentially moved to the zero point measurement position and the concentration measurement position is to make it

Illustratively, an electric motor may be provided as the driving means 154 .

When the light source mounting body 151, the detector mounting body 156, and the body connecting body 158 are rotated in one direction by the driving means 154, the light source mounting body 151 and the detector mounting body As 156 is moved to the zero point measurement position, the light source 130 and the detector 140 are moved to the zero point measurement position, and the light source mounting body 151 and the detector by the driving means 154 . When the mounting body 156 and the body connecting body 158 are rotated in other directions, the light source mounting body 151 and the detector mounting body 156 are moved to the concentration measurement position, so that the light source 130 and The detector 140 may be moved to the concentration measurement position.

In this embodiment, the light source mounting body 151 and the detector mounting body 156 are each formed in a sector shape of a predetermined size, and the light source mounting body 151 and the detector mounting body 156 are the sample flow. It is disposed to face each other with the member 110 interposed therebetween, and the body connecting body 158 connects the vertices of the light source mounting body 151 and the detector mounting body 156 to each other. A rack gear 152 is formed on the arc portion of the light source mounting body 151 , and a pinion gear 153 meshing with the rack gear 152 is formed on the rotation shaft of the driving means 154 .

When configured as described above, when the driving means 154 is operated and the pinion gear 153 is rotated in the other direction, the light source mounting body 151 engaged with the pinion gear 153 moves in one direction. By rotating, the body connecting body 158 and the detector mounting body 156 connected to the light source mounting body 151 are also rotated in one direction, so that the light source 130 and the detector 140 are connected to the sample flow member. It comes to the zero point measurement position facing away from 110, and the light irradiated from the light source 130 is directly received by the detector 140, so that the amount of light irradiated from the light source 130 can be detected. there is.

Then, when the driving means 154 is operated and the pinion gear 153 is rotated in one direction, the light source mounting body 151 engaged with the pinion gear 153 is rotated in the other direction, The body connecting body 158 and the detector mounting body 156 connected to the light source mounting body 151 are also rotated in other directions, so that the light source 130 and the detector 140 are connected to the sample flow member 110 . It comes to the concentration measurement position indirectly facing with the interposed therebetween, and the light irradiated from the light source 130 passes through the sample flowing through the sample flow member 110 and then to the detector 140 . By being received, the absorbance of the sample using the light amount of the light source 130 detected at the zero point measurement position as the zero point can be measured, and accordingly, the use time of the absorbance measuring device 100 is accumulated and the light source Even if the light amount of 130 is reduced or the detector 140 is deteriorated, the detected value according to the reduction in the light amount of the light source 130 or the deterioration of the detector 140 can be automatically corrected.

In the present embodiment, the light attenuation filter member 170 attenuates the amount of light emitted from the light source 130 and directed toward the detector 140 at the zero point measurement position by a preset value.

Although not shown, the light attenuation filter member 170 may be fixed to the outside of the sample flow member 110 using a fixing frame or the like.

In a state in which the light source 130 and the detector 140 are moved to the zero point measurement position by the moving member 150 and the zero point is measured, the light source 130 and the detector 140 are moved to the zero point by the moving member 150 . The detector 140 is moved to the concentration measurement position so that the concentration of the sample can be measured based on the zero point, and the light source 130 and the detector 140 are moved by the moving member 150 When the zero point is measured by moving to the zero point measurement position, the amount of light emitted from the light source 130 and directed toward the detector 140 is attenuated by the light amount attenuation filter member 170 .

As described above, as the light attenuation filter member 170 is applied, the amount of light emitted from the light source 130 by the light attenuation filter member 170 at the zero point measurement position and directed toward the detector 140 is is attenuated, and such light quantity attenuation does not occur at the concentration measurement position, so that the difference between each measured voltage value at the zero point measurement position and the concentration measurement position can be reduced, so that the absorbance measurement accuracy according to the external temperature change degradation can be prevented.

The collimated light forming lens member 180 directs the light irradiated from the light source 130 toward the detector 140 in the form of parallel light, and a lens in which a surface facing the sample flow member 110 is convex. can be formed in the form.

The condensing lens member 185 condenses the light directed toward the detector 140 in the form of parallel light via the collimated light forming lens member 180 toward the detector 140 , and the sample flow member 110 ) may be formed in the form of a lens having a convex surface.

When configured as described above, the light irradiated from the light source 130 and spread is aligned in the form of parallel light while passing through the collimated light forming lens member 180 , and passes through the sample flow member 110 to pass through the detector 140 . ), the light passing through the sample flow member 110 and directed toward the detector 140 may be condensed to the detector 140 while passing through the condensing lens member 185 .

The external air removal member 160 is disposed outside the sample flow member 110 to remove air contained in the sample flowing from the outside to the sample flow member 110 .

In this embodiment, the external air removing member 160 is disposed between the external source of the sample (not shown) and the sample inflow path 113 , and flows from the external source toward the sample inflow path 113 . It is possible to primarily remove air in the sample.

In detail, the external air removing member 160 includes an external air removing body 161, an external air removing flow hole 162 formed by a predetermined length vertically along the inside of the external air removing body 161, and the external air An external air removal inlet 163 passing through the upper portion of one side of the removal body 161 to communicate the external supply source and the external air removal flow hole 162, and the external air removal flow hole 162 from the bottom of the An external air removal outlet passage 164 extending through the external air removal body 161 and the external air removal flow hole 162 are formed in the form of fine holes in the upper portion of the external air removal flow hole 162 . and an air discharge hole 165 for communicating the inside of the outer air removing body 161 with the outside.

When configured as described above, the sample supplied from the external source flows into the external air removal flow hole 162 through the external air removal inflow path 163 and then fills the external air removal flow hole 162 . while descending to the lower side of the external air removal flow hole 162 , it flows out through the external air removal outlet path 164 , and then flows into the sample inflow path 113 .

At this time, while the sample is descending through the external air removal flow hole 162, the air contained in the sample rises in the form of a bubble, collects in the air discharge hole 165, and then the air discharge hole 165. It can be removed from the sample while being discharged to the outside through the.

As described above, the absorbance measuring device 100 includes the sample flow member 110 , the light source 130 , the detector 140 , the movable member 150 , and the light quantity attenuation filter member 170 . ), at the zero point measurement position, the amount of light emitted from the light source 130 by the light attenuation filter member 170 and directed toward the detector 140 is attenuated, and at the concentration measurement position, the amount of light is attenuated By not being generated, the difference between each measurement voltage value at the zero point measurement position and the concentration measurement position can be reduced, so that a decrease in absorbance measurement accuracy due to external temperature change can be prevented.

In addition, the absorbance measuring device 100 further includes the external air removal member 160, the sample flow member 110 includes the inclined collector 115 and the air vent hole 116, The sample flow body 111 so that the sample flows in the direction in which the sample flow hole 112 constituting the sample flow member 110 is irradiated with light from the light source 130 toward the detector 140 . By being elongated to a predetermined length in the direction in which light is irradiated from the light source 130 to the detector 140 inside of there will be

In the above, the present invention has been shown and described with respect to specific embodiments, but those skilled in the art can variously modify the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the claims below. and may be changed. However, it is intended to clearly state that all such modifications and variations are included within the scope of the present invention.

According to the absorbance measuring apparatus according to an aspect of the present invention, it is possible to prevent a decrease in absorbance measurement accuracy due to external temperature change, and to remove air contained in the sample to improve absorbance measurement accuracy. Therefore, it can be said that the industrial applicability is high.

100: absorbance measuring device
110: sample flow member
130: light source
140: detector
150: moving member
160: external air removal member
170: light attenuation filter member

Claims (4)

a sample flow member through which the sample to be measured for concentration is flowed to measure the concentration;
a light source capable of irradiating light for measuring the concentration of the sample;
a detector capable of detecting the light irradiated from the light source;
a moving member capable of moving the light source and the detector to a zero point measurement position capable of measuring a zero point, which is a reference for measuring the concentration of the sample, and a concentration measurement position capable of measuring the concentration of the sample; and
Including; and a light attenuation filter member for attenuating the amount of light emitted from the light source at the zero point measurement position and directed toward the detector.
In a state where the light source and the detector are moved to the zero point measurement position by the moving member and the zero point is measured, the light source and the detector are moved to the concentration measurement position by the moving member so that the concentration of the sample is It can be measured based on the zero point,
When the zero point is measured by moving the light source and the detector to the zero point measurement position by the moving member, the amount of light emitted from the light source and directed toward the detector is attenuated by the light amount attenuation filter member,
The sample flow member is
a sample flow body;
a sample flow hole elongated by a predetermined length in a direction in which light is irradiated from the light source toward the detector inside the sample flow body so that the sample can flow in a direction in which light is irradiated from the light source to the detector;
a sample inflow path that is connected to the bottom of one side of the sample flow hole and serves as an inlet through which the sample flows into the sample flow hole;
a sample outlet passage that is connected to the ceiling of the other side of the sample flow hole and serves as an outlet through which the sample flowing along the inside of the sample flow hole is discharged;
an inclined collector formed in a tapered shape on the ceiling of the sample flow hole;
an air vent hole formed at the highest point of the inclined collector and communicating the inside of the sample flow hole and the outside of the sample flow body;
The sample flow body is formed in a horizontally long form compared to the vertical, the light source is disposed to face one side of the sample flow body, the detector is disposed to face the other side of the sample flow body,
When the light source and the detector of the sample flow body are in the concentration measurement position, on each side portion facing the light source and the detector, the light irradiated from the light source passes through the sample flow hole to reach the detector Each transparent window is formed so that
The sample inflow path is connected to the bottom of one side of the sample flow hole and the sample outflow path is connected to the ceiling of the other side of the sample flow hole, so that the sample introduced through the sample flow hole is the length of the sample flow hole flow in the direction and then be able to be discharged through the sample outlet,
The inclined collector is formed in a tapered shape that becomes the highest point at the center of the ceiling of the sample flow hole, so that air contained in the sample rises inside the sample while the sample flows through the sample flow hole and bubbles in the form of being able to move toward the highest point of the gradient collector along the gradient collector after reaching the gradient collector,
Air moved toward the highest point of the inclined collector can be discharged to the outside through the air vent hole, so that air in the sample can be removed while the sample flows through the sample flow hole Absorbance measuring device with The method of claim 1,
The absorbance measuring device is
and an external air removal member disposed outside the sample flow member to remove air contained in the sample flowing from the outside to the sample flow member. delete The method of claim 1,
The absorbance measuring device is
a collimated light forming lens member for directing the light irradiated from the light source toward the detector in the form of parallel light; and
and a condensing lens member for condensing the light directed toward the detector in the form of parallel light through the collimated light forming lens member toward the detector.

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