JP7193063B2 - fluorescence detector - Google Patents

Description

The present invention relates to a fluorescence detection device.

Patent Literature 1 listed below describes an analyzer in which a light receiving element, a light emitting element, and a flow path are integrated. A sample containing a substance that emits fluorescence in response to irradiated light can be flowed through the channel of this analyzer.

Japanese Patent Application Laid-Open No. 2006-084210

In the analysis device of Patent Document 1, the light receiving element, the light emitting element, and the flow path are integrated. Therefore, when the channel becomes dirty with the sample and needs to be replaced, it is necessary to replace the light receiving element and the light emitting element together. This makes maintenance difficult.

SUMMARY OF THE INVENTION An object of the present invention is to provide a fluorescence detection apparatus that is easy to maintain.

The fluorescence detection device according to claim 1 comprises an external channel through which a liquid sample flows, and a cylindrical flow cell that is detachably attached to the external channel and in which a measurement channel formed inside communicates with the external channel. an irradiating unit that is separate from the flow cell and irradiates the liquid sample flowing in the measurement channel with excitation light from the outside of the flow cell; and an irradiation unit that is separate from the flow cell and integrated with the irradiating unit. and a light-receiving portion that receives fluorescence emitted from the liquid sample irradiated with the excitation light outside the flow cell, and the probe in which the irradiation portion and the light-receiving portion are incorporated is the The flow cell is arranged in contact with the end face of the flow cell in the cylinder axis direction, the flow cell is formed in a cylindrical shape, and held in a state of being sandwiched between the probe and a holding member arranged on the end face opposite to the end face. It is

In the fluorescence detection device of claim 1, the flow cell is detachably attached to the external channel. Further, the irradiation section and the light receiving section are separate from the flow cell and provided outside the flow cell. Therefore, the irradiating part and the light receiving part are less likely to be contaminated with the liquid sample. Also, when the flow cell is contaminated with the liquid sample, the flow cell alone can be removed while leaving the irradiation unit and the light receiving unit.

If the flow cell is only slightly soiled, the flow cell can be reused by cleaning the measurement channel. If the flow cell is heavily soiled, the flow cell should be replaced. Therefore, the fluorescence detection apparatus according to claim 1 is easier to maintain than a configuration in which the flow cell, the irradiation section and the light receiving section are integrated.

According to one aspect of the fluorescence detection device, in the fluorescence detection device of claim 1, the irradiation section and the light receiving section are separate members, and the irradiation direction of the excitation light and the light reception direction of the fluorescence intersect.

In one aspect of the fluorescence detection device, the irradiation direction of the excitation light and the light reception direction of the fluorescence intersect. Therefore, compared to the case where the irradiation direction of the excitation light and the light reception direction of the fluorescence match, the excitation light is less likely to enter the light receiving section, and the fluorescence can be easily detected.
One aspect of the fluorescence detection device includes a holder having a through hole that holds the flow cell in a state in which the flow cell is inserted, the flow cell and the through hole have a rectangular cross-sectional shape, and the irradiation unit and the light receiving unit The parts are arranged so as to face two adjacent sides of the flow cell.

In one aspect of the fluorescence detection device, the irradiation section and the light receiving section are integrated.

In one aspect of the fluorescence detection device, the irradiation section and the light receiving section are integrated. Therefore, compared to a configuration in which the irradiation unit and the light receiving unit are separate units, the fluorescence detection device can be downsized as necessary.
According to a second aspect of the present invention, there is provided the fluorescence detection apparatus according to the first aspect, wherein the cylindrical axis direction of the flow cell is inclined with respect to the horizontal plane.
In one aspect of the fluorescence detection device, a probe incorporating the irradiation unit and the light receiving unit is arranged in contact with an end surface of the flow cell in a cylinder axis direction, the flow cell is formed in a cylindrical shape, and the probe and the , and a holding member disposed on the opposite end face to the end face.

The fluorescence detection device according to the present invention is easy to maintain.

1A is a side view showing a fluorescence detection device according to a first embodiment of the present invention, and FIG. 1B is a cross-sectional view taken along line BB in FIG. (A) is a side view showing a modified example in which the connection portion of the flow cell in the fluorescence detection device according to the first embodiment of the present invention is arranged so as to be substantially perpendicular to the axial direction of the main body, and (B) is a main body; FIG. 4C is a side view showing a modification in which the upstream end wall and the downstream end wall of the main body are arranged so as to be substantially orthogonal to the axial direction of the main body, and FIG. FIG. 10 is a side view showing a modified example, and (D) is a cross-sectional view taken along line DD in (C). (A) is a side view showing a fluorescence detection device according to a second embodiment of the present invention, and (B) is a cross-sectional view taken along the line BB in (A). FIG. 6 is a perspective view showing a flow cell and a holder in a fluorescence detection device according to a second embodiment of the present invention; FIG. 11 is a side view showing a state in which the plate on which the holder is installed is moved to replace the flow cell in the fluorescence detection device according to the second embodiment of the present invention.

An example of an embodiment of a fluorescence detection device according to the present invention will be described below with reference to the drawings. Components shown using the same reference numerals in each drawing mean the same components. In addition, description may be abbreviate|omitted about the structure and code|symbol which overlap in each drawing. Moreover, the present invention is not limited to the following embodiments, and can be implemented with appropriate modifications within the scope of the purpose of the present invention.

<First Embodiment>
(Fluorescence detector)
FIG. 1A shows a main part of a fluorescence detection device 10 (hereinafter sometimes referred to as device 10) according to a first embodiment of the present invention. The device 10 is configured with an external channel 20 , a flow cell 30 and a probe 40 .

(external channel)
A liquid sample can flow in the external channel 20 . The external flow path 20 includes an inlet-side flow path 22 through which the liquid sample flows into the flow cell 30 and an outlet-side flow path 24 through which the liquid sample flows out from the flow cell 30 .

One end of the inlet-side channel 22 is connected to a joint member 22A for connecting with the flow cell 30 . On the other hand, the other end (not shown) of the inlet-side channel 22 is connected to a collection source for collecting the liquid sample. Furthermore, a liquid-sending pump (not shown) is connected downstream of the collection source (that is, between the collection source and the flow cell 30). The liquid sample is moved to the flow cell 30 by this liquid-sending pump.

As the liquid sample collection source, the source of the liquid sample (for example, a sampling well formed in the soil to collect groundwater) can be used, as well as a tank in which the liquid sample collected at the source is stored. can also be used as a source.

One end of the outlet-side channel 24 is connected to a joint member 24A for connecting with the flow cell 30 . On the other hand, the other end (not shown) of the outlet-side channel 24 is connected to a drain pipe for discarding the liquid sample. Alternatively, the outlet-side channel 24 itself serves as a drain pipe.

(flow cell)
The flow cell 30 is a container for causing the liquid sample to be analyzed to flow or stay. formed. The higher the transmittance, the better. The flow cell 30 includes a body portion 32 , a connection portion 34 and a connection portion 36 .

The flow cell 30 can be integrally formed not only with the upstream end wall 32A, but also with a permeable material. If only the upstream end wall 32A is made of a permeable material, the manufacturing cost of the flow cell 30 can be reduced.

As shown in FIG. 1(B), the body part 32 is a tubular part having a circular cross section, and is formed with a measurement channel through which the liquid sample flows along the axial direction of the cylinder. A connecting portion 34 is joined to the upstream end of the body portion 32 , and a connecting portion 36 is joined to the downstream end thereof.

The connecting portion 34 is a cylindrical portion that is detachably connected to the joint member 22A and guides the liquid sample from the inlet-side channel 22 to the main body portion 32 . The cross-sectional area of the flow path of the connection portion 34 is smaller than the cross-sectional area of the flow path in the main body portion 32 . The connecting portion 34 is connected to the cylinder axis direction of the main body portion 32 at an angle θ1. This angle θ1 is set to an angle larger than 90°.

The upstream end wall 32A of the main body 32 is formed at an angle .theta.1 with respect to the cylinder axis direction of the main body 32. As shown in FIG. Furthermore, the inner surface of the upstream end wall 32A is formed so as to be continuous with the inner surface of the connecting portion 34 (linearly). As a result, the liquid sample flows from the connection portion 34 along the upstream end wall 32A and into the main body portion 32 .

Similarly, the connecting portion 36 is a cylindrical portion detachably connected to the joint member 24A, and guides the liquid sample from the main body portion 32 to the outlet side channel 24. As shown in FIG. The cross-sectional area of the flow path of the connecting portion 36 is smaller than the cross-sectional area of the flow path in the main body portion 32 . The connection portion 36 is connected to the cylinder axis direction of the body portion 32 at an angle θ2. This angle θ2 is set to an angle larger than 90°. Also, the angle θ2 is substantially the same as the angle θ1.

In addition, as shown in FIG. 1A, the cylinder axis direction of the main body portion 32 is inclined with respect to the horizontal plane. As a result, air bubbles generated inside the flow cell 30 easily escape from the connecting portion 34 to the main body portion 32 and then from the main body portion 32 to the connecting portion 36 along with the flow of the liquid sample. Therefore, measurement of fluorescence in a liquid sample is less likely to be affected by air bubbles.

Further, the downstream end wall 32B of the body portion 32 is formed so as to form an angle θ2 with respect to the cylinder axis direction of the body portion 32 . Furthermore, the inner surface of the downstream end wall 32B is formed so as to be continuous (linearly) with the inner surface of the connecting portion 36 . As a result, the liquid sample flows from the body portion 32 along the downstream end wall 32</b>B and out to the connecting portion 36 .

The cross-sectional areas of the flow paths in the connecting portions 34 and 36 are both smaller than the cross-sectional area of the flow paths in the main body portion 32, but the embodiment of the present invention is not limited to this. For example, the cross-sectional area of the flow path in at least one of the connecting portions 34 and 36 may be approximately the same as the cross-sectional area of the flow path in the main body portion 32 . Thereby, the flow velocity of the liquid sample can be stabilized.

(probe)
The probe 40 has an irradiation unit 42 that irradiates excitation light onto the liquid sample flowing through the measurement channel of the main body 32, and a light reception unit 44 that receives fluorescence emitted from the liquid sample irradiated with the excitation light. It is a device that has been The probe 40 is detachably fixed to a holder 48 .

It should be noted that "integrated" means that the irradiation unit 42 and the light receiving unit 44 are incorporated in the same housing 46, and the excitation light is irradiated from the same surface (end surface 46A of the housing 46) to emit fluorescence. Refers to the state of receiving light.

The end surface 46A of the housing 46 is arranged in contact with the outer surface of the upstream end wall 32A of the body portion 32 of the flow cell 30 . In this state, the excitation light P1 is emitted from the irradiation unit 42 along the axial direction of the main body 32 (that is, the flow direction of the liquid sample). Further, the component of the fluorescence P2 along the axial direction of the main body portion 32 is received by the light receiving portion 44 . Since the end surface 46A of the housing 46 and the outer surface of the upstream end wall 32A of the main body 32 are arranged in close contact with each other without a gap, stray light is suppressed from entering the light receiving unit 44. FIG. Note that the end surface 46A and the outer surface of the upstream end wall 32A of the main body 32 do not necessarily need to be in close contact as long as the fluorescence measurement is not hindered. You may have

On the opposite side of the probe 40 in the main body 32 of the flow cell 30, a holding member 86 is installed in contact with the outer surface of the downstream end wall 32B. The flow cell 30 is held by being sandwiched between the probe 40 and the holding member 86 .

The spacing between probe 40 and holding member 86 can be adjusted by moving at least one of probe 40 and holding member 86 . The flow cell 30 can be fixed by moving these in a direction in which they are relatively in contact with each other. Further, the fixation of the flow cell 30 is released by moving these in a direction in which they are relatively separated from each other.

With the flow cell 30 unlocked, the flow cell 30 can be removed from the apparatus 10 by removing the connecting portions 34 and 36 from the joint members 22A and 24A, respectively.

Note that the holding mechanism for holding the flow cell 30 is not limited to a mode in which the flow cell 30 is sandwiched between the probe 40 and the holding member 86 . For example, two halved (substantially C-shaped) annular members may be used to sandwich and hold the outer peripheral surface of the main body 32 of the flow cell 30 .

(action/effect)
In the fluorescence detection device 10 of the first embodiment, the flow cell 30 is detachably attached to the external channel 20 (both the inlet-side channel 22 and the outlet-side channel 24) via joint members 22A and 24A. there is A probe 40 in which an irradiation unit 42 and a light receiving unit 44 are integrated is separate from the flow cell 30 and provided outside the flow cell 30 .

Therefore, it is possible to prevent the irradiating part 42 and the light receiving part 44 of the probe 40 from contacting the liquid sample and becoming dirty, or from being soiled to reduce the measurement accuracy. In addition, when the flow cell 30 becomes dirty with the liquid sample, the flow cell 30 alone can be removed leaving the probe 40 in place.

If the flow cell 30 is only slightly soiled, the flow cell 30 can be reused by cleaning the measurement channel of the main body 32 . If the flow cell 30 is heavily soiled, the flow cell 30 should be replaced. Therefore, the apparatus 10 is easier to maintain than a configuration in which the flow cell 30 is integrated with the irradiation section and the light receiving section.

Further, the probe 40 in the device 10 has an irradiation section 42 and a light receiving section 44 integrated. Therefore, the size can be reduced as compared with a fluorescence detection device in which the irradiation section and the light receiving section are separate bodies.

Further, in the device 10, the inner surface of the upstream end wall 32A of the main body 32 of the flow cell 30 is formed so as to be continuous (linearly) with the inner surface of the connecting portion 34. As shown in FIG. Further, the upstream end wall 32A is formed so as to form an angle θ1 with respect to the cylinder axis direction of the body portion 32 . This angle θ1 is set to be greater than 90°.

As a result, the liquid sample flowing along the upstream end wall 32A from the connecting portion 34 is prevented from colliding with the outer peripheral wall 32C of the main body 32, disturbing the flow, and generating air bubbles and stagnation. That is, compared with the case where θ1 is 90° or less, the change in the flow direction of the liquid sample is slowed and rectified.

By suppressing the generation of air bubbles, the diffused reflection of excitation light is suppressed, and the diffusion of fluorescence is suppressed. In addition, the inside of the flow cell 30 is less likely to become dirty by suppressing the occurrence of stagnation. The main body 32 of the flow cell 30 is cylindrical and has no corners. Therefore, the effect of suppressing contamination of the flow cell 30 is further enhanced as compared with the case where the flow cell 30 is formed in a rectangular tubular shape.

In addition, in the device 10 , the inner surface of the downstream end wall 32</b>B of the main body 32 of the flow cell 30 is formed so as to be continuous (linearly) with the inner surface of the connecting portion 36 . Further, the downstream end wall 32B is formed so as to form an angle θ2 with respect to the cylinder axis direction of the body portion 32 . This angle θ2 is set to be greater than 90°. With this configuration as well, the liquid sample flowing out from the main body portion 32 to the connection portion 36 is rectified, so that the generation of air bubbles and stagnation as described above is suppressed.

(Modification)
In the present embodiment, the inner surface of the upstream end wall 32A of the main body 32 of the flow cell 30 is formed so as to be continuous (linearly) with the inner surface of the connecting portion 34. The form is not limited to this.

For example, as shown in FIG. 2A, the inner surface of the upstream end wall 32A of the main body 32 and the inner surface of the connecting portion 34 may be connected at an angle. In such an embodiment as well, the formation of the upstream end wall 32A inclined with respect to the axial direction of the main body 32 suppresses the occurrence of air bubbles and stagnation. The same applies to the relationship between the inner surface of the downstream end wall 32B and the inner surface of the connecting portion 36. As shown in FIG.

In the present embodiment, the upstream end wall 32A of the main body 32 of the flow cell 30 is formed so that the angle θ1 with respect to the cylinder axis direction of the main body 32 is greater than 90 degrees. Embodiments of the invention are not limited to this.

For example, as shown in FIG. 2B, the angle θ1 may be approximately 90 degrees. Even with such a configuration, the flow cell 30 can be easily attached and detached from the apparatus 10 (see FIG. 1), so the maintainability of the apparatus 10 is high.

Further, in the present embodiment, as shown in FIG. 1, the excitation light P1 is irradiated along the axial direction of the main body 32 (that is, the flow direction of the liquid sample), and the fluorescence P2 is emitted along the axial direction of the main body 32. Although the probe 40 is arranged so that the component along the line is received, embodiments of the present invention are not limited to this.

For example, as shown in FIG. 2C, the probe 40 may be arranged along the outer peripheral wall 32C of the main body 32 of the flow cell 30. As shown in FIG. By doing so, the excitation light P1 is irradiated along a direction substantially orthogonal to the axial direction of the main body 32 (that is, the flow direction of the liquid sample), and the fluorescence P2 is substantially orthogonal to the axial direction of the main body 32. A component along a direction is received.

In the embodiment shown in FIG. 2C, the end surface 46A of the probe 40 can be formed so as to be substantially perpendicular to the irradiation direction of the excitation light P1 in order to arrange the probe 40 and the outer peripheral wall 32C in contact with each other. It is preferable, and in addition, as shown in FIG. 2(D), it is more preferable to form the outer peripheral wall 32C of the flow cell 30 into a rectangular tubular shape.

In this manner, the flow cell 30 may have a rectangular tubular shape as well as a circular tubular shape, or may have a polygonal tubular shape other than a rectangular shape. Moreover, such a polygonal flow cell 30 can also be applied to an embodiment in which the excitation light P1 is emitted along the cylinder axis direction of the main body 32 .

<Second embodiment>
(Fluorescence detector)
FIG. 3A shows a main part of a fluorescence detection device 50 (hereinafter sometimes referred to as device 50) according to a second embodiment of the present invention. The device 50 comprises an external channel 20 , a flow cell 60 and a holder 70 .

(external channel)
The configurations of the external flow path 20 (the inlet-side flow path 22 and the outlet-side flow path 24) and the joint members 22A and 24A are the same as those of the first embodiment, and description thereof will be omitted.

(flow cell)
The flow cell 60 is a container for flowing or retaining a liquid sample to be analyzed, and is made of a light-transmitting material (such as quartz glass, for example). The flow cell 60 includes a main body portion 62, connecting portions 64 and 66, and reduced diameter portions 64A and 66A.

The body portion 62 is a tubular portion having a rectangular cross section as shown in FIG. 3(B), and as shown in FIG. a road is formed. The inner diameter (the length of one side of the rectangle) of this measurement channel is, for example, about 10 mm. A connecting portion 64 is joined to the upstream end of the body portion 62 via a reduced diameter portion 64A, and a connecting portion 66 is connected to the downstream end via a reduced diameter portion 66A.

The connecting portion 64 is a tubular portion having a circular cross section that is detachably connected to the joint member 22A and guides the liquid sample from the inlet-side channel 22 to the main body portion 62 . The connection portion 64 has an inner diameter of, for example, about 6 mm, and the cross-sectional area of the channel is smaller than the cross-sectional area of the channel (measurement channel) in the main body portion 62 . Also, the connecting portion 64 is connected along the cylinder axis direction of the main body portion 62 .

The reduced diameter portion 64A is a portion that gradually reduces the inner diameter of the body portion 62 to the inner diameter of the connection portion 64, and is a portion that gradually transforms the rectangular shape of the body portion 62 into the circular shape of the connection portion 64. As shown in FIG.

Similarly, the connecting portion 66 is a tubular portion having a circular cross section that is detachably connected to the joint member 24A, and guides the liquid sample from the main body portion 62 to the outlet side channel 24. As shown in FIG. The cross-sectional area of the flow path of the connecting portion 66 is smaller than the cross-sectional area of the flow path in the main body portion 62 . Also, the connection portion 66 is connected along the cylinder axis direction of the main body portion 62 .

The reduced diameter portion 66A is a portion that gradually reduces the inner diameter of the body portion 62 to the inner diameter of the connection portion 66, and is a portion that gradually transforms the rectangular shape of the body portion 62 into the circular shape of the connection portion 66. Note that the connecting portions 64 and 66 may have a rectangular shape similar to that of the main body portion 62 instead of the circular shape. In this case, the cross-sectional shape of the reduced diameter portions 64A and 66A gradually decreases in inner diameter from the main body portion 62 toward the connection portions 64 and 66 while maintaining a rectangular shape.

(holder)
The holder 70 is a substantially rectangular parallelepiped holding member as shown in FIG. A rectangular through hole 72 is formed in the holder 70 so as to penetrate from the upper end surface to the lower end surface. The shape of the through hole 72 is slightly larger than the shape of the flow cell 60 , and the flow cell 60 can be inserted through the through hole 72 . An elastic member such as rubber is appropriately interposed in the gap between the through-hole 72 and the flow cell 60 to hold the flow cell 60 .

Through-holes 74 and 76 are formed in two adjacent side surfaces of the holder 70 so as to pass through the through-hole 72 from the side surface. The irradiation section 42 and the light receiving section 44 can be attached to the through holes 74 and 76, respectively. The configurations of the irradiation unit 42, the light receiving unit 44, and the light source and fluorescence spectrometer connected thereto are the same as in the first embodiment. are placed in

The excitation light P1 is emitted from the irradiation unit 42 in a direction substantially perpendicular to the axial direction of the main body 62 of the flow cell 60 (that is, the flow direction of the liquid sample), and the liquid sample emits fluorescence P2. Further, the light receiving section 44 receives the component of the fluorescence P2 along the direction substantially orthogonal to the axial direction of the main body 62 and substantially orthogonal to the excitation light P1. That is, the irradiation direction of the excitation light P1 and the light receiving direction of the fluorescence P2 are substantially orthogonal.

A lower end surface of the holder 70 is fixed to the support plate 80 via a plate 82 . Plate 82 comprises two plates 82A, 82B that are hinged 84 together. The plate 82A is fixed to the support plate 80. As shown in FIG. The plate 82B closes the through hole 80A formed in the support plate 80 from above, and as shown in FIG. 5, is rotatable about a hinge 84 as a rotation axis in the direction of opening and closing the through hole 80A. This makes it easy to remove the flow cell 60 from the holder 70 when exchanging the flow cell 60 .

(action/effect)
In the fluorescence detection device 50 of the second embodiment, as shown in FIG. 3A, the flow cell 60 is connected to the external channel 20 (that is, both the inlet-side channel 22 and the outlet-side channel 24), joint members 22A, 24A is detachably attached. The irradiation unit 42 and the light receiving unit 44 are both separated from the flow cell 60 and attached to a holder 70 that holds the flow cell 60 .

Therefore, it is possible to prevent the irradiating part 42 and the light receiving part 44 from being soiled by the liquid sample. Further, when the flow cell 60 is contaminated with the liquid sample, the flow cell 60 alone can be removed while leaving the holder 70, the irradiation unit 42 and the light receiving unit 44.

If the flow cell 60 is only slightly soiled, the flow cell 60 can be reused by removing the flow cell 60 from the holder 70 and cleaning the measurement channel of the main body 62 . At this time, since the inner diameter of the joint portion is about 6 mm, it is easier to insert the cleaning tool than in the case of 6 mm or less. Also, if the flow cell 60 is heavily soiled, the flow cell 60 may be replaced. Therefore, the apparatus 50 is easier to maintain than a configuration in which the flow cell 60, irradiation section and light receiving section are integrated.

It should be noted that it is not always necessary to remove the flow cell 60 from the holder 70 in order to wash the flow cell 60 . For example, the flow cell 60 may be automatically cleaned by injecting the drug from the external channel 20 into the flow cell 60 without removing the flow cell 60 . Also, the inner diameter of the junction in the flow cell 60 is not limited to about 6 mm, and can be changed as appropriate.

Further, in the device 50, as shown in FIG. 3B, the irradiation direction of the excitation light P1 and the light receiving direction of the fluorescence P2 intersect (substantially orthogonal). For this reason, compared to the case where the excitation light irradiation direction and the fluorescence reception direction match, the excitation light is less likely to enter the light receiving unit, so fluorescence can be detected with high accuracy.

Further, in the device 50, a reduced diameter portion 64A is formed between the body portion 62 and the connecting portion 64. As shown in FIG. In this reduced diameter portion 64A, the inner diameter gradually decreases from the body portion 62 toward the connecting portion 64. As shown in FIG. In other words, the flow passage area gradually increases from the connection portion 64 toward the main body portion 62 .

Here, although the flow velocity decreases as the channel area increases, the flow velocity difference between the central portion and the peripheral portion of the main body portion 62 increases when the channel area increases rapidly. In this case, there is a possibility that the flow will be disturbed in the main body portion 62 and that bubbles and stagnation will occur. On the other hand, since the flow cell 60 is provided with the diameter-reduced portion 64A, the flow velocity difference between the central portion and the peripheral portion of the main body portion 62 is less likely to increase, and air bubbles and stagnation are less likely to occur. Therefore, compared to the case where the diameter-reduced portion 64A is not formed, the measurement accuracy is less likely to decrease, and the flow cell 60 is less likely to become dirty.

(Modification)
In the second embodiment, the excitation light P1 is applied from only one direction, but the embodiment of the present invention is not limited to this. For example, as indicated by the dashed line in FIG. 3B, in addition to the excitation light P1, the excitation light P3 may be applied from a different surface of the main body 62 of the flow cell 60 . Thereby, the fluorescence P4 different from the fluorescence P2 can be detected. By doing so, for example, when two types of fluorescent substances are contained in the liquid sample, each fluorescent substance can be detected.

Further, the flow cell 60 is formed with diameter-reduced portions 64A and 66A, and the cross-sectional areas of the flow paths at the connection portions 64 and 66 are both smaller than the cross-sectional area of the flow paths at the main body portion 62. Embodiments are not limited to this. For example, the body portion 62 and the connection portions 64 and 66 may have the same diameter without forming the reduced diameter portions 64A and 66A in the flow cell 60 .

In addition, in the device 50 of the present embodiment, the plate 82B is rotated as shown in FIG. 5 when the flow cell 60 is removed from the holder 70, but the embodiment of the present invention is not limited to this. For example, the plate 82B that fixes the holder 70 does not necessarily have to have a rotation mechanism such as the hinge 84, and may be fixed to the support plate 80. FIG. Even if the plate 82B is fixed to the support plate 80, the flow cell 60 can be removed from the holder 70 by moving the external channel 20 or moving the joint members 22A and 24A. Thus, the present invention can be implemented in various modes. Moreover, these aspects can be used in combination as appropriate.

10 fluorescence detection device 20 external channel 22 inlet side channel (external channel)
24 outlet side channel (external channel)
30 flow cell 42 irradiation unit 44 light receiving unit 50 fluorescence detection device 60 flow cell P1 excitation light P2 fluorescence

Claims (2)

an external channel through which the liquid sample flows;
a cylindrical flow cell that is detachably attached to the external flow channel and has a measurement flow channel formed therein communicating with the external flow channel;
an irradiation unit that is separate from the flow cell and that irradiates the liquid sample flowing in the measurement channel with excitation light from the outside of the flow cell;
a light-receiving unit that is separate from the flow cell and integrated with the irradiation unit and receives fluorescence emitted from the liquid sample irradiated with the excitation light outside the flow cell;
has
a probe incorporating the irradiation unit and the light receiving unit is arranged in contact with the end surface of the flow cell in the cylinder axis direction,
The flow cell is formed in a cylindrical shape and held in a state of being sandwiched between the probe and a holding member arranged on the end face opposite to the end face,
Fluorescence detector. 2. The fluorescence detection device according to claim 1 , wherein the flow cell is provided so that the cylindrical axis direction thereof is inclined with respect to the horizontal plane.

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