JP2007212213A - Automatic sample exchange device for nmr device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an automatic sample exchange device for an NMR device capable of preventing a sample rotor from sinking even when the wind pressure is weak. <P>SOLUTION: This automatic sample exchange device for the NMR device is used for the NMR device equipped with a sample tube raising/lowering mechanism by the air for floating the sample tube to an opening direct upper part of a housing by the wind pressure of the air blown up from a hole of the housing extending vertically downward in the center of SCM, and lowering the sample tube toward an NMR measuring part on the bottom part of the hole of the housing by reducing the wind pressure of the air. The device is equipped with a latch mechanism comprising a hook withdrawing by abutting on a sample rotor mounted on the sample tube when the sample tube is floated by the wind pressure larger than a prescribed wind pressure on the opening direct upper part of the housing, and projecting again for holding the sample rotor on the opening direct upper part of the housing when the sample tube is moved to a position out of the opening direct upper part of the housing. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an automatic sample changer used for an NMR apparatus.

  An NMR device applies a strong static magnetic field (main magnetic field) to a sample to induce a precession around the static magnetic field direction in the magnetic moment of a nucleus having a nuclear spin in the sample, and the direction of the static magnetic field there. A sample of the NMR signal emitted when the precession of the nuclear magnetic moment is excited by applying a high-frequency magnetic field in the direction perpendicular to the axis, and then the nuclear magnetic moment precession returns from the excited state to the ground state. It is a device that observes as a high-frequency magnetic field with a frequency unique to.

  At present, a considerable part of the NMR measurement is routine measurement with a fixed procedure, and an automatic sample that automatically loads and unloads the sample to improve the efficiency of continuous sample setting and removal. An exchange device is used (Patent Documents 1 to 3).

  In the case of an automatic sample changer with a small number of samples that can be set automatically, as shown in Fig. 1, it is possible to attach an automatic sample changer directly to the top of the superconducting magnet (SCM) and perform NMR sample change It is. Such an SCM direct type automatic sample changer employs a chucking plate 2 as a sample holding mechanism (Patent Document 1).

  Eight cylindrical sample sleeves 1 are provided at equal intervals on the circumference of the turntable 3 so as to be fixed on the turntable 3. In each sample sleeve 1, one sample tube with a sample rotor 6 is inserted and installed. The rotation axis of the turntable 3 is placed at a position shifted from immediately above the SCM, and only one of the eight sample sleeves 1 can be fed onto the central axis of the SCM by the rotation of the turntable 3. It has a structure that can be done.

  From directly above the SCM, the cylindrical housing 10 extends vertically downward along the central axis of the SCM, and the sample rotor 6 is slid and dropped along the hole of the housing 10 to measure the sample tube by NMR measurement. It can be transported to the part. Normally, eject air is blown from the bottom direction of the hole of the housing 10 upward, and the sample rotor 6 floats in the sample sleeve 1 located at the upper end opening of the housing 10 by the wind pressure. It is in a state. At this time, if the eject air is throttled, the sample rotor 6 slowly descends due to the decrease in the wind pressure, and the sample tube can be loaded into the NMR measurement section.

  At the position where the sample sleeve 1 is removed from directly above the housing 10 of the SCM, the sample rotor 6 cannot be floated because there is no eject air blown from the housing 10. Therefore, the sample rotor 6 is received by the chucking plate 2 so that the sample rotor 6 does not fall.

  In a position immediately above the housing 10, a notch is provided in the chucking plate 2 in order to allow the sample rotor 6 to be loaded from the sample sleeve 1 to the NMR measurement section in the housing 10. At this position, the sample rotor 6 is not held by the chucking plate 2 due to the presence of the notch, but the sample rotor 6 floats in the sample sleeve 1 due to the wind pressure of the eject air blown from the housing 10. It is in a state and held in the air.

  When another sample rotor 6 passes immediately above the housing 10 when the turntable 3 rotates, the sample roller 6 is not held by the chucking plate 2 because it passes through the notch of the chucking plate 2, but is ejected. Since the sample rotor 6 is lifted by the wind pressure of the air, the sample rotor 6 does not sink and is not sandwiched between the housing 10 and the turntable 3.

  When the sample rotor 6 holding the target sample tube comes to a position immediately above the housing 10, the turntable 3 is stopped and the volume of ejected air is reduced to load the sample rotor 6 onto the measuring section in the housing 10. .

Japanese Patent Laid-Open No. 10-62315 US Pat. No. 5,534,780 U.S. Pat. No. 4,581,583

  By the way, the above-described sample rotor holding mechanism using the chucking plate 2 works when it is disengaged from the position directly above the housing 10 of the SCM, and does not work so that the sample can be loaded / ejected at the position immediately above the housing 10. It has become.

  Therefore, when the wind pressure of the eject air is weak for some reason, the turntable 3 transports the target sample rotor to a position directly above the SCM when another sample rotor exists in front of the target sample rotor. Therefore, when another sample rotor passes through the position immediately above the housing 10 during rotation, the sample rotor may sink and be sandwiched between the housing 10 and the turntable 3 to break the sample tube. It was.

  In view of the above points, an object of the present invention is to provide an automatic sample changer for an NMR apparatus in which a sample rotor does not sink even when the wind pressure of eject air is weak.

In order to achieve this object, an automatic sample changer for an NMR apparatus according to the present invention comprises:
The sample tube is levitated directly above the opening of the housing by the air pressure of the air blown up from the hole of the housing extending vertically downward from the center of the SCM, and the air pressure of the air is throttled toward the NMR measurement section at the bottom of the hole of the housing An automatic sample changer for an NMR apparatus used in an NMR apparatus equipped with a sample tube up-and-down mechanism by air for lowering the sample tube,
When the sample tube is floating above the opening of the housing at a wind pressure higher than the specified wind pressure, it retracts in contact with the sample rotor attached to the sample tube, and the sample tube moves to a position off the housing opening In this case, it is characterized in that a latch mechanism comprising a hook protruding again to hold the sample rotor directly above the opening of the housing is provided.

  Further, the hook is driven by a cam that rotates integrally with a turntable on which the sample tube is placed.

According to the automatic sample changer for an NMR apparatus of the present invention,
The sample tube is lifted directly above the opening of the housing by the air pressure of the air blown up from the hole in the housing extending vertically downward from the center of the SCM, and directed to the NMR measurement section at the bottom of the hole in the housing by reducing the air pressure. An automatic sample changer for an NMR apparatus used in an NMR apparatus equipped with a sample tube up-and-down mechanism by air for lowering the sample tube,
When the sample tube is floating above the opening of the housing at a wind pressure higher than the specified wind pressure, it retracts in contact with the sample rotor attached to the sample tube, and the sample tube moves to a position off the top of the opening of the housing. When equipped with a latch mechanism consisting of a hook that protrudes again to hold the sample rotor just above the opening of the housing,
It is possible to provide an automatic sample exchange device for an NMR apparatus that prevents the sample rotor from sinking even when the wind pressure of air is weak.

  FIG. 2 shows an embodiment of an automatic sample changer for an NMR apparatus according to the present invention. The same members as those in FIG. 1 are denoted by the same reference numerals as those in FIG.

  Eight cylindrical sample sleeves 1 are provided at equal intervals on the circumference of the turntable 3 so as to be fixed on the turntable 3. In each sample sleeve 1, one sample tube with a sample rotor 6 is inserted and installed. The rotation axis of the turntable 3 is placed at a position shifted from immediately above the SCM, and only one of the eight sample sleeves 1 can be fed onto the central axis of the SCM by the rotation of the turntable 3. It has a structure that can be done.

  From directly above the SCM, the cylindrical housing 10 extends vertically downward along the central axis of the SCM, and the sample rotor 6 is slid and dropped along the hole of the housing 10 to measure the sample tube by NMR measurement. It can be transported to the part. Normally, eject air is blown from the bottom direction of the hole of the housing 10 upward, and the sample rotor 6 floats in the sample sleeve 1 located at the upper end opening of the housing 10 by the wind pressure. It is in a state. At this time, when the eject air is throttled, the sample rotor 6 descends slowly due to the decrease in the wind pressure, and the sample tube can be loaded into the NMR measuring section.

  At the position where the sample sleeve 1 is removed from directly above the housing 10 of the SCM, the sample rotor 6 cannot be floated because there is no eject air blown from the housing 10. Therefore, the sample rotor 6 is received by the chucking plate 2 so that the sample rotor 6 does not fall.

  In a position immediately above the housing 10, a notch is provided in the chucking plate 2 in order to allow the sample rotor 6 to be loaded from the sample sleeve 1 to the NMR measurement section in the housing 10. At this position, the sample rotor 6 is not held by the chucking plate 2 due to the presence of the notch, but the sample rotor 6 floats in the sample sleeve 1 due to the wind pressure of the eject air blown from the housing 10. It is in a state and held in the air.

  In such a configuration, a latch-type sample holding mechanism is provided at a position immediately above the housing 10 separately from the chucking plate 2 which is a conventional sample rotor holding mechanism. The latch-type sample holding mechanism includes a hook 7 that holds the sample rotor 6 at a position directly above the housing 10, and a cam that pushes the hook 7 directly above the housing 10 when the sample rotor 6 moves laterally from directly above the housing 10. I have 8. The cam 8 has a protruding portion that comes into contact with the hook 7 in order to push the hook 7 directly upward of the housing 10. One abutment portion is provided at each intermediate angular position between the sample sleeves 1 arranged at equal intervals on the circumference of the turntable 3, and rotates together with the sample sleeve 1.

  The hook 7 includes a protrusion B for holding the sample rotor 6 and a protrusion A that receives pressure from the head of the sample rotor 6, and is configured to slide on the slide guide 9. As the cam 8 rotates, the protruding portion of the cam 8 abuts on the hook 7, and when the hook 7 is pushed out directly above the housing 10 by the protruding portion, the protrusion B protrudes to the inner hole side of the sample sleeve 1, and the sample The rotor 6 is held (FIGS. 2 and 3). When the sample rotor 6 is pushed up by the eject air and the head of the sample rotor 6 comes into contact with the protrusion A, the hook 7 slides on the slide guide 9 and the holding of the sample rotor 6 is released. (FIG. 4). The slide guide 9 is fixed on the chucking plate 2 by appropriate means (FIG. 5).

  Therefore, as long as the sample rotor 6 is not lifted by eject air, the sample rotor 6 cannot come into contact with the protrusion A, and the sample rotor 6 is not released from being held by the protrusion B. Thereby, even if the wind pressure of the eject air decreases for some reason, the sample rotor 6 is held in its original position and does not sink toward the housing 10, so that the sample rotor is positioned immediately above the housing 10. When passing, there is no possibility that the sample rotor will sink and be sandwiched between the housing 10 and the turntable 3 and break the sample tube.

  On the other hand, when the ejected air has an air volume that exceeds a predetermined air volume sufficient to float the sample rotor 6, the sample rotor 6 floats when the sample rotor 6 passes the position immediately above the housing 10. Then, the hook 7 is retracted by coming into contact with the projection A, and the holding of the sample rotor 6 by the projection B is released. However, the sample rotor 6 does not sink toward the housing 10 because of sufficient wind pressure. When the rotor passes the position immediately above the housing 10, the sample rotor sinks and is sandwiched between the housing 10 and the turntable 3, and there is no possibility of damaging the sample tube.

  When the target sample rotor 6 has come to a position just above the housing 10, the sample rotor 6 can be lifted and brought into contact with the protrusion A to release the holding of the sample rotor 6 by the protrusion B. The formed sample rotor 6 can be slowly lowered toward the hole of the housing 10 by restricting the eject air, and the sample tube can be loaded into the NMR measuring section.

  When the NMR measurement is completed, the sample rotor 6 loaded in the NMR measurement section is ejected by eject air, and when the turntable 3 rotates to the next sample position, the cam 8 also rotates integrally therewith, and the hook 7 Is pushed out again, and the sample rotor 6 is held by the projection B at a position directly above the housing 10. If the ejected air is weak for some reason, the protrusion A of the hook 7 does not come into contact with the sample rotor 6, so the hook 7 does not retreat, and the sample rotor 6 is held by the protrusion B at a position directly above the housing 10. Is maintained. Therefore, even if there is another sample rotor 6 in the middle of rotation of the turntable, the sample rotor 6 will not sink into the housing 10 and be sandwiched between the housing 10 and the turntable 3.

  In this embodiment, the rotary type automatic sample changer for NMR apparatus has been described. However, the present invention can also be applied to a linear movement type automatic sample changer for NMR apparatus. In that case, instead of the cam 8, a rectangular hook pressing plate that is provided with one protruding portion at an intermediate position between the sample sleeves arranged in series and moves linearly integrally with the sample sleeve can be used. good.

  It can be widely used for routine measurement using an NMR apparatus.

It is a figure which shows an example of the conventional automatic sample change apparatus for NMR apparatuses. It is a figure which shows one Example of the automatic sample change apparatus for NMR apparatuses concerning this invention. It is a figure which shows operation | movement of the automatic sample change apparatus for NMR apparatuses concerning this invention. It is a figure which shows operation | movement of the automatic sample change apparatus for NMR apparatuses concerning this invention. It is the elements on larger scale of the automatic sample change apparatus for NMR apparatuses concerning this invention.

Explanation of symbols

1: sample sleeve, 2: chucking plate, 3: turntable, 6: sample rotor, 7: hook, 8: cam, 9: slide guide, 10: housing, 11: protrusion A

Claims (2)

The sample tube is levitated directly above the opening of the housing by the air pressure of the air blown up from the hole of the housing extending vertically downward from the center of the SCM, and the air pressure of the air is throttled toward the NMR measurement section at the bottom of the hole of the housing An automatic sample changer for an NMR apparatus used in an NMR apparatus equipped with a sample tube up-and-down mechanism by air for lowering the sample tube,
When the sample tube is floating above the opening of the housing at a wind pressure higher than the specified wind pressure, it retracts in contact with the sample rotor attached to the sample tube, and the sample tube moves to a position off the housing opening An automatic sample changer for an NMR apparatus, comprising a latch mechanism comprising a hook protruding again to hold the sample rotor directly above the opening of the housing. 2. The automatic sample changer for an NMR apparatus according to claim 1, wherein the hook is driven by a cam that rotates integrally with a turntable on which the sample tube is placed.

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