JP2010249622A - Liquid chromatograph - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To limit a range where leakage liquid is allowed to leak and propagate from a piping connection part of a joint in a liquid chromatograph apparatus configured such that a sample cell disposed at least in a detection unit is connected to piping of an analysis channel through the joint. <P>SOLUTION: The sample cell of the detection unit is connected to the piping of the analysis channel through the joint. The piping connected to the sample cell through the joint has an up-tilt part which tilts upward in the view from the joint, near the part connected with the joint. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention includes a liquid feeding unit for feeding a mobile phase, an injection unit for injecting a sample into an analysis channel, a separation unit for separating the injected sample for each component, and a detection unit for detecting the separated sample. The present invention relates to a liquid chromatograph apparatus provided with a module.

  As shown in FIG. 1, there is a liquid chromatograph apparatus in which a liquid feeding unit 6, an injection unit 8, a separation unit 10, and a detection unit 12 are connected and integrated by a pipe in this order from the upstream side. In such a liquid chromatograph apparatus, the analysis flow path 2 is configured by connecting each unit with a pipe via a joint.

  For example, the detection unit 12 includes a sample cell 12a. The inlet of the sample cell 12a is connected to the separation column 10a of the separation unit 10 through a pipe 18, and the outlet of the sample cell 12a is drained through the pipe 20. Connected to. The pipe 18 is connected to a pipe connected to the inlet of the sample cell 12a via a joint 14, and the pipe 20 is connected to a pipe connected to the outlet of the sample cell 12a via a joint 16.

Japanese Patent No. 4093099

  The pipes connected to the inlet and outlet of the sample cell 12a, the pipes 18 and 20, are made of resin tubes. High pressure is applied in these pipes, and liquid leakage may occur at the connection ports of the joints 14 and 16. As shown in FIG. 5, the joint is fixed in a horizontal state (see FIG. 5A) or in a vertical state (see FIG. 5B), and the pipe connected thereto Extended horizontally or vertically from the joint.

  In the state of FIG. 5, when a liquid leak occurs at the joint portion of the joint 14, the leaked liquid travels through the pipe 18 and it is impossible to predict where the liquid droplet will fall. Furthermore, it may go out of the detection unit 12 through the pipe 18. The detection unit 12 may be provided with a tray for receiving leaked leak liquid. However, when the leak liquid travels through the tube, the droplet is dropped at a position where the tray is not provided, There is also a risk that it may be contaminated by the module.

  Accordingly, the present invention provides a liquid chromatograph apparatus in which at least a sample cell provided in a detection unit is connected to a pipe of an analysis flow path via a joint, and leaked liquid leaked from a pipe connection portion of the joint is transmitted through the pipe. The purpose is to limit the range.

  The present invention relates to a liquid feeding unit for feeding a mobile phase to an analysis channel, a sample injection unit for injecting a sample into the analysis channel, and a separation unit for separating the sample injected by the sample injection unit into components. And a liquid chromatograph apparatus connected to the downstream side of the separation unit, and having a detection unit for detecting each component by circulating the sample passed through the separation unit in the sample cell, wherein at least the sample cell of the detection unit has a joint The pipe is connected to the pipe of the analysis flow path, and the pipe has an ascending slope portion that is an ascending slope when viewed from the joint in the vicinity of the connection portion with the joint.

  According to the above structure, the pipe of the analysis channel has an upward inclined portion that is upwardly inclined when viewed from the joint in the vicinity of the joint connection portion, so that leaked liquid leaked from the joint pipe connection portion is transmitted through the pipe. The range is limited to the range from the joint connection part of the joint to the upward inclined part.

  Therefore, if the detection unit includes a tray for receiving leaked liquid leaked from the joint at a position immediately below the range from the joint to the upward inclined portion, the leaked liquid leaked from the joint can be reliably received. Since the leaked liquid does not leak to the outside of the detection unit through the pipe, it is possible to prevent contamination of other units.

  It is preferable that the tray is provided with a liquid level sensor that detects that the leaked liquid has accumulated up to a predetermined position at the lowermost part, inclining in a direction in which the liquid flows in a certain direction. If the liquid level sensor detects that the leaked liquid is output by a method such as displaying on the display, the analyst can easily know the occurrence of the liquid leak.

  In the liquid chromatograph apparatus of the present invention, the pipe of the analysis channel connected to the sample cell of the detection unit via the joint has an upward inclined portion that is upwardly inclined when viewed from the joint in the vicinity of the connection portion with the joint. Therefore, the leaked liquid leaking from the joint cannot be transmitted beyond the upward inclined portion of the pipe, and the position where the leaked liquid is limited to a position immediately below the range from the joint to the upward inclined portion of the pipe. As a result, it is possible to prevent the liquid leak from the joint from dropping on the other modules as the liquid leaks from the joint, or from coming out of the detection unit through the pipe.

It is a channel lineblock diagram showing roughly an example of composition of a liquid chromatograph device. (A) is the perspective view which shows concretely the panel with piping of the detection unit of the Example, (B) is the perspective view seen from the further diagonal direction. It is a figure which shows simply the joint part of the detection unit of the Example. It is a figure which shows simply the other example of the joint part of a detection unit. It is a figure which shows the example of the conventional joint part simply.

  An embodiment of the liquid chromatograph apparatus will be described below. FIG. 1 is a flow path configuration diagram schematically showing an example of the configuration of a liquid chromatograph apparatus, and FIGS. 2A and 2B specifically show a panel having a detection unit pipe of the same embodiment. It is a perspective view. 2A and 2B show a state where the front cover that can be opened and closed is removed.

  The liquid chromatograph apparatus includes a liquid feeding unit 6, an injection unit 8, a separation unit 10, and a detection unit 12. A module for circulating the liquid provided in each unit is connected to the pipe of the analysis flow path 2 via a joint.

  The liquid feeding unit 6 includes a liquid feeding pump 6a. The pump head inlet of the liquid feed pump 6a is connected to the mobile phase container 4 by piping, and the pump head outlet is connected to the injection port 8a of the injection unit 8 by piping. In addition to the liquid feed pump 6a, the liquid feed unit 6 is a flow meter such as a pressure sensor that monitors the liquid feed amount of the liquid feed pump 6a, a controller that controls the drive of the liquid feed pump 6a based on the measured value of the flow meter, and the like. And the liquid-feeding flow rate of the mobile phase in the analysis flow path 2 can be adjusted to the set flow rate.

  The inlet of the injection port 8a of the injection unit 8 is connected to the pump head outlet of the liquid feeding pump 6a by piping, and the outlet of the liquid feeding pump 6a is connected to the inlet of the separation column 10a of the separation unit 10 by piping. In addition to the injection port 8a, the injection unit 8 includes an autosampler that automatically sucks a sample from a sample container previously set by an analyst and injects the sample into the injection port 8a.

  The inlet of the separation column 10 a of the separation unit 10 is connected to the outlet of the injection port 8 a by piping, and the outlet of the separation column 10 a is connected to the inlet of the sample cell 12 a of the detection unit 12 by piping 18. In addition to the separation column 10a, the separation unit 10 also includes a temperature control unit that adjusts the temperature of the separation column 10a to a constant temperature. The separation column 10a separates the sample injected from the injection port 8a for each component.

  The inlet of the sample cell 12a of the detection unit 12 is connected to the outlet of the separation column 10a by a pipe 18, and the outlet of the sample cell 12a is connected to, for example, a drain or a mass spectrometer by a pipe 20. The pipes 18 and 20 are made of resin tubes, for example, and are connected to the inlet or outlet of the sample cell 12a by joints 14 and 16, respectively. In addition to the sample cell 12a, the detection unit 12 includes a light source that irradiates measurement light such as ultraviolet rays to the sample cell 12a, a photodetector that detects transmitted light or reflected light from the sample cell 12a, and the like. Each component of the sample flowing through the sample cell 12a is detected by a change in the light detection signal.

  The flow path connection in the detection unit 12 will be described. As shown in FIG. 2, the pipe 12b is led to the inlet of the sample cell 12a of the detection unit 12, and the pipe 12c is led to the outlet of the sample cell 12a. In addition, what is shown as 12a in this figure is the board | substrate which attached the sample cell to the panel, and the actual sample cell is attached to the back side of this board | substrate. The pipes 12b and 12c are resin tubes, and both the pipes 12b and 12c are led to the sample cell 12a through one hole provided in the substrate to which the sample cell 12a is attached. The pipe 12 b is connected to the pipe 18 by a joint 14. The pipe 12 c is connected to the pipe 20 by a joint 16. The pipe 18 is connected to the outlet of the separation column 10 a of the separation unit 10.

  In this embodiment, the separation unit 10 is disposed below the detection unit 12, and the pipe 18 is drawn into the detection unit 12 from below and connected to the joint 14. Further, the pipe 20 is drawn out from the upper part of the detection unit 12.

  The joints 14 and 16 are fixed horizontally and vertically by a fixture 17 at positions below the holes through which the pipes 12b and 12c of the substrate to which the sample cell 12a is attached are passed. The joint 14 is inclined so that the connection port with the pipe 18 is diagonally upward and the connection port with the pipe 12b is diagonally downward. The joint 16 is inclined so that the connection port with the pipe 20 is diagonally upward and the connection port with the pipe 12c is diagonally downward.

  Due to the inclination of the joints 14 and 16, the pipe 18 is connected to the joint 14 from an obliquely upward direction, and the pipe 20 is also connected to the joint 16 from an obliquely upward direction. As a result, an upward inclined portion that is upwardly inclined as viewed from the connection portion is formed in the vicinity of the connection portion between the pipes 18 and 20 and the joints 14 and 16. An upward inclined portion is also formed in the vicinity of the connection portion between the joints 14 and 16 of the pipes 12b and 12c.

  For example, when a liquid leak occurs in the joint 14, the pipe 18 has an upward inclined portion, so that the leaked liquid falls as a droplet from the lower surface of the joint 14 without being transmitted upward through the upward inclined portion of the pipe 18. Further, since the pipe 12b also has an ascending slope in the vicinity of the connection portion with the joint 14, the range in which the leaked liquid travels through the pipe 12b is limited to the range from the joint 14 to the ascending slope. Therefore, as shown in FIG. 3, even if a liquid leak occurs in the joint 14, the range in which the leaked liquid falls downward is from the upward inclined portion of the pipe 12 b to the end of the joint 14 on the pipe 18 connection side. Limited until. The same applies when a liquid leak occurs in the joint 16.

  The pipe 18 drawn into the detection unit 12 from below is arranged so as to avoid a position immediately below in the same plane as the above-described range where the leaked liquid falls. This is because if there is a pipe at a position directly below the range where the leaked liquid falls, the leaked leaked liquid is applied to the pipe and travels through the pipe.

  The range in which the leaked liquid can be limited without tilting the joint. For example, as shown in FIG. 4 (A), the joint 14 may be fixed in a horizontal state, and an upward inclined portion may be formed in the vicinity of the connection portion between the pipe 18 and the joint 14. Further, as shown in FIG. 4B, the joint 14 is fixed in a vertical state, and the pipe 18 drawn from below is connected to the upper connection portion of the joint 14 and drawn out upward from the joint 14. If 12b is connected to the lower connection portion of the joint 14, the vicinity of the joint 14 connection portion of the pipes 12b and 18 becomes an upward inclined portion. In short, an ascending slope may be formed in the vicinity of the connection portion with the joint of the pipe.

  A tray 22 for receiving the leaked leak liquid is provided at a position just below the range where the leaked liquid falls below the detection unit 12. Further, a liquid stopper 19 is provided at a position between the joints 14 and 16 and the sample cell 12a to guide the leaked liquid leaked from the pipe 12b connection portion of the joint 14 or the pipe 12c connection portion of the joint 16 to the tray 22. Yes. The pipes 12 b and 12 c are passed through narrow grooves provided in the liquid stopper 19, and the leaked liquid transmitted through these pipes 12 b and 12 c is also guided to the tray 22 by the liquid stopper 19.

  The tray 22 is inclined so that the leaked liquid flows in one direction, and a liquid reservoir 22a for storing the leaked liquid up to a certain amount and a leaked liquid accumulated until it overflows in the liquid reservoir 22a are detected at the bottom thereof. A liquid level sensor 24 is provided. The liquid level sensor 24 includes a temperature sensor provided at a height that comes into contact with the leaked liquid when the leaked liquid has accumulated until it overflows to the bottom of the tray, and a temperature sensor provided at a height that does not contact the leaked liquid. It has. The liquid level sensor 24 detects the presence of leaked liquid based on the difference in temperature detected by these temperature sensors. Such a liquid level sensor 24 is, for example, a liquid leak detection device disclosed in Patent Document 1. The leaked liquid overflowing from the liquid reservoir 22a at the bottom of the tray 22 is discharged to the outside of the detection unit 12.

  In the above embodiment, the structure of the joint portion for connecting the module mounted on the unit to the analysis flow path of the liquid chromatograph has been described as a representative example, but the detection unit 12 is not necessarily described. Not only have the above structure, but units other than the detection unit 12 may have the same structure.

2 analysis flow path 4 mobile phase 6 liquid feeding unit 6a liquid feeding pump 8 injection unit 8a injection port 10 separation unit 10a separation column 12 detection unit 12a sample cell 12b, 12c, 18, 20 piping 14, 16 joint 19 liquid stopper 22 tray 22a Liquid reservoir 24 Liquid level sensor

Claims (3)

A liquid feeding unit for feeding a mobile phase to the analysis channel, a sample injection unit for injecting a sample into the analysis channel, a separation unit for separating the sample injected by the sample injection unit for each component, and In a liquid chromatograph apparatus provided with a detection unit connected to the downstream side of the separation unit and detecting each component by circulating the sample that has passed through the separation unit in the sample cell,
At least the sample cell of the detection unit is connected to the pipe of the analysis flow path via a joint,
The liquid chromatograph apparatus according to claim 1, wherein the pipe has an ascending slope portion that is ascending as seen from the joint in the vicinity of a connection portion with the joint.   2. The liquid chromatograph according to claim 1, wherein the detection unit includes a tray for receiving a leaked liquid leaking from the joint at a position immediately below the section from the joint to the upward inclined portion.   The liquid chromatograph according to claim 2, wherein the tray is inclined in a direction in which the liquid flows in a certain direction, and a liquid level sensor is provided at the bottom of the tray to detect that a leaked liquid has accumulated.

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