Patent Application
20160047867
1. Technical Field
The present disclosure relates to sample holders including sample holders which may be used in analysis techniques such as magnetic resonance spectroscopy (MRS), magnetic resonance imaging (MRI) (e.g., magic angle spinning (MAS) nuclear magnetic resonance (NMR)), electron paramagnetic resonance (EPR), dynamic nuclear polarization (DNP), electron nuclear double resonance (ENDOR), etc.
2. Description of the Related Art
Both high resolution magic angle spinning (MAS) nuclear magnetic resonance (NMR) and electron paramagnetic resonance (EPR), as well as the combination of these (dynamic nuclear polarization (DNP) and electron-nuclear double resonance (ENDOR) are used for studying molecular structure and dynamics in samples which may be solid, semi-solid, or a heterogeneous mixture containing multiple phases. These are of particular interest in biophysics, such as protein investigations, catalysis analysis, geochemistry experiments, food preservation investigation and various experiments in medicine.
It is desirable to be able to set the pressure for the sample under investigation. This may involve either lower or higher pressures and temperatures than ambient conditions, and it is desirable to be able to investigate samples under a range of conditions without adversely affecting the sample, and being able to alter these conditions easily.
Grooves 14 are machined in rotor sleeve 1 at selected positions along the internal surface at respective ends. Grooves 14 are introduced, e.g., using a diamond mill that creates a rough surface. Bushings 4 and 5 insert into, and screw through, along grooves 14 positioned along the milled surface of rotor sleeve 1. Bushings 4 and 5 are secured in place adjacent the threaded surface, e.g., at respective ends of rotor sleeve 1, in concert with a high-pressure adhesive, which is allowed to cure.
Bushings 4 and 5 form high-pressure seals within rotor sleeve 1 in concert with O-rings 9 positioned above and below bushings 4 and 5 in rotor sleeve 1.
The rotor sleeve 20 has the disadvantage that the O-rings 9 are required to produce a seal at all times during the use of the sleeve. O-rings tend to degrade over time. Since the O-rings of the rotor sleeve 20 are located behind the bushings, it is relatively difficult and expensive to replace the O-rings, and almost impossible to inspect the O-rings to determine when they may require replacement during analysis. Therefore, rotor sleeves of this type tend to fail in an unpredictable manner and their replacement is relatively expensive.
In an embodiment, a pressurizable sample holder is provided, the sample holder comprising a sample cell having an inner surface defining a sample volume and a plug for maintaining the sample volume under pressure, the sample holder further comprising first and second seals for sealing the sample volume, wherein said first and second seals are formed with said plug, the plug further comprising an inlet, wherein the plug engages with the sample cell so that the first seal seals the sample volume during operational use of the sample holder and the second seal forms a seal when the inlet is in use to pressurize the sample volume.
In an embodiment, two separate seals which are formed by a plug, which facilitate maintaining the seals.
In an embodiment, the plug may be moveable between a first position and a second position, wherein the first seal is engaged when the plug is in the first position and the second seal is engaged when the plug is in the second position.
In an embodiment, reliance on conventional use of dual O-rings to provide an active seal while the sample holder is undergoing operational use (e.g., is undergoing MAS NMR or a similar analytical technique) may be avoided, which facilitates sample holders having more efficient and reliable seals. Avoiding the conventional use of dual O-rings facilitates maintaining environments which were previously not possible where their corrosive nature would affect the integrity of the O-rings such as supercritical CO2.
In an embodiment, the inner surface of the sample cell may comprise a threaded portion and wherein an outer surface of the plug comprises a complimentary threaded portion, and wherein movement of the plug comprises rotation.
In an embodiment, the inlet may be formed with an inlet aperture formed upstream of the threaded portion of the outer surface of the plug. Upstream may refer to the direction of fluid escaping the sample holder kept in place by the plug.
In an embodiment, the second seal may be engaged when the plug is in the first position.
In an embodiment, the sample holder may have an escape fluid flow for fluid exiting the sample holder through an aperture filled by the plug, in which case the second seal may be situated downstream from the first seal with respect to the escape fluid flow.
In an embodiment, the first seal may be formed between a surface of the plug and the inner surface of the sample cell.
In an embodiment, the second seal may be an O-ring disposed between the inner surface of the sample cell and the plug.
In an embodiment, a receptacle may be formed in the plug.
In an embodiment, the sample cell may be formed as a single machined part.
In an embodiment, the plug may be formed as a single machined part.
In an embodiment, both the sample cell and the plug are each formed as a single integrated part, which may make the parts easier and cheaper to manufacture.
In an embodiment, the sample cell may have a first aperture filled by the plug.
In an embodiment, the sample cell may have a first aperture and a second aperture wherein the first aperture is filled by said plug.
In an embodiment, a system comprises a sample holder as herein described and an injector for delivering a fluid under pressure to the sample volume.
In an embodiment, the plug may include a receptacle at least partially defined by a threaded portion of a surface of the plug and the injector may include a complementary threaded portion for engaging with the threaded portion of the plug.
In at least one embodiments: the sample holders are re-usable; they may be used with high-pressure maintained in the sample volume; alternatively they may be used with low-pressure maintained in the sample volume; they are usable with both low and high temperatures maintained in the sample volume; they may be subjected to microwaves; and may not require a separate loading device; and very little fluid other than that contained in the sample volume need be pressurized or evacuated, which is more efficient than subjecting an additional volume to excess or reduced pressure.
As used herein, “high-pressure” may refer to approximately 150 to 350 bar, or more and “low pressure” may refer to approximately 103 to 10−4 mbar, or less.
In an embodiment, a method of preparing a sample volume, comprises: providing a pressurizable sample holder comprising a sample cell having an inner surface defining a sample volume and a plug for maintaining the sample volume under pressure, further comprising: providing first and second seals in the sample holder for sealing the sample volume, wherein said first and second seals are formed with said plug, providing an inlet in the plug; and engaging the plug with the sample cell so that the first seal seals the sample volume during operational use of the sample holder and the second seal forms a seal when the inlet is in use to pressurize the sample volume. In an embodiment, the method comprises moving the plug between a first position and a second position, wherein the first seal is engaged when the plug is in the first position and the second seal is engaged when the plug is in the second position. In an embodiment, the method comprises providing the inner surface of the sample cell with a threaded portion and an outer surface of the plug with a complimentary threaded portion, and wherein said movement of the plug comprises rotation. In an embodiment, the inlet is formed with an inlet aperture formed upstream of the threaded portion of the outer surface of the plug. In an embodiment, the second seal is engaged when the plug is in the first position. In an embodiment, the sample cell and the plug engage through a bayonet connection. In an embodiment, fluid exiting the sample holder flows in an escape fluid flow, wherein the second seal is provided downstream from the first seal with respect to the escape fluid flow. In an embodiment, the first seal is formed between a surface of the plug and the inner surface of the sample cell. In an embodiment, the second seal is provided as an O-ring disposed between the inner surface of the sample cell and the plug. In an embodiment, a receptacle is provided in the plug. In an embodiment, the method comprises forming the sample cell as a single machined part. In an embodiment, the method comprises forming the plug as a single machined part.
In an embodiment, no external loading device is needed to provide a sample under increased or reduced pressure, which facilitates use in different (multiple) type of Magnetic Resonance spectrometers such as MAS NMR, EPR, Dynamic Nuclear Polarization NMR (DNP NMR), and Electron Nuclear Double Resonance (ENDOR). This may enhance the ability to undertake structural and dynamic investigation of solid/liquid/gas mixtures by facilitating replicating the sample conditions.
In an embodiment, a sample holder comprises: a sample cell having an inner surface defining a sample volume; and a plug configured to couple to the sample cell, the plug including: a pressurization inlet; a first sealing surface configured to mate with the sample cell to form an operational seal of the sample holder; and a second sealing surface configured to mate with the sample cell to form a pressurizing seal of the sample holder. In an embodiment, the plug is configured to move between a first position and a second position; the first sealing surface is configured to sealingly mate with the sample cell when the plug is in the first position; and the second sealing surface is configured to sealingly mate with the sample cell when the plug is in the second position. In an embodiment, the inner surface of the sample cell comprises a threaded portion, an outer surface of the plug comprises a complimentary threaded portion, and movement of the plug comprises rotation. In an embodiment, the pressurization inlet has an inlet aperture upstream of the threaded portion of the outer surface of the plug. In an embodiment, the second sealing surface is configured to sealingly mate with the sample cell when the plug is in the first position. In an embodiment, the sample cell and the plug are configured to couple together through a bayonet connection. In an embodiment, the sample holder has an escape fluid flow for fluid exiting the sample holder through an aperture filled by the plug, wherein the second seal is situated downstream from the first seal with respect to the escape fluid flow. In an embodiment, the first sealing surface is a surface of a body of the plug configured to mate with the inner surface of the sample cell. In an embodiment, the plug comprises a body and the second sealing surface comprises an O-ring positioned on the plug body and configured to mate with the inner surface of the sample cell. In an embodiment, the plug has a receptacle. In an embodiment, the sample cell is formed as a single machined part. In an embodiment, a body of the plug is formed as a single machined part. In an embodiment, the sample cell has a first aperture filled by said plug. In an embodiment, the sample cell has a first aperture and a second aperture wherein the first aperture is filled by said plug.
In an embodiment, a system comprises: a sample holder having: a sample cell having an inner surface defining a sample volume; and a plug configured to couple to the sample cell, the plug including: a pressurization inlet; a first sealing surface configured to mate with the sample cell to form an operational seal of the sample holder; and a second sealing surface configured to mate with the sample cell to form a pressurizing seal of the sample holder; and an injector configured to deliver a fluid under pressure to the sample volume via the pressurization inlet. In an embodiment, the plug includes a receptacle at least partially defined by a threaded portion of a surface of the plug, and the injector includes a complementary threaded portion to engaging with the threaded portion of the plug.
In an embodiment, a method comprises: forming a pressurization seal between a pressurization-seal surface of a plug and a sample cell of a sample holder, an inner surface of the sample cell defining a sample volume; pressurizing the sample cell via an inlet in the plug; and forming an operational seal between an operational-seal surface of the plug and the sample cell. In an embodiment, the method comprises moving the plug between a first position and a second position, wherein the operational seal is formed when the plug is in the first position and the pressurization seal is formed when the plug is in the second position. In an embodiment, the method comprising providing the inner surface of the sample cell with a threaded portion and an outer surface of the plug with a complimentary threaded portion, wherein the moving of the plug comprises rotation. In an embodiment, the inlet is formed with an inlet aperture upstream of the threaded portion of the outer surface of the plug. In an embodiment, the pressurization seal is formed when the plug is in the first position. In an embodiment, the sample cell and the plug are coupled together through a bayonet connection. In an embodiment, fluid exiting the sample holder flows in an escape fluid flow, wherein the second seal is provided downstream from the first seal with respect to the escape fluid flow. In an embodiment, the operational seal is formed between a surface of a body of the plug and the inner surface of the sample cell. In an embodiment, the plug comprises a plug body and an O-ring positioned on the body of the plug, and the pressurization seal is formed between the O-ring and the inner surface of the sample cell. In an embodiment, the plug includes a receptacle. In an embodiment, the method comprises forming the sample cell as a single machined part. In an embodiment, the method comprising forming a body of the plug as a single machined part.
Embodiments are herein described with reference to the accompanying diagrams in which:
As illustrated in greater detail in
a) and (b) illustrated the sample holder 30 inserted in the sealing cell 40. As illustrated in
As illustrated in
It is to be realized that the provision of a top cap (in the manner illustrated in
In the orientation illustrated in
The direction of fluid flow when a pressurized fluid is introduced via an injector is shown in
During this loading of the sample holder (e.g., through the introduction of pressurized fluid to the sample holder), the flow of fluid in the direction of arrow 154 and 156 is prevented by the O-ring 82.
The difference between the orientation shown in
The seal formed between the plug and the sample cell 90 lies upstream of the seal formed by the O-rings 82 in the sense that fluid escaping from the sample volume must first pass the seal formed between the outer extremity 170 of the plug 50 and the tapered portion 162 of the sample cell 90 (the first seal) before passing the seal formed by the O-ring (the second seal).
The first seal serves to maintain the operating environment in the sample volume and this does not depend on the O-ring. Furthermore, the first seal is provided by the edge to surface engagement, which facilitates forming a more efficient and reliable seal. Since the second seal, involving the O-ring, is only in use during loading of the sample volume, it is relatively easy to tell when the seal has degraded and needs replacing. Since the O-ring is easily accessible, it is easy to replace.
In an embodiment, the sample cell 90 is made of Rexolite® (C-Lec Plastics Inc., Philadelphia, Pa., USA) a microwave compatible plastic, but other materials, such as other high compatibility plastic materials may be used. In an embodiment, the plug 50 is made of Torlon® (Solvay Plastics), but other materials such as other plastics may also be used. In an embodiment, the sealing cell 40 is made from nonmagnetic stainless steel, but other materials may be used, such as other nonmagnetic metallic alloys.
As illustrated, both the sample cell 90 and the plug 50 are constructed as single body components, machined from solid materials. In alternate embodiments, the parts may be molded as a single integral whole.
As a safety feature, the turbine blades 52 and the thread 58 (
It is to be realized that depending on the target working pressure and temperature, active volume requirements, MAS spinning frequency range and material's strength a trade between the wall thickness (of the various components illustrated), sample active volume and the maximum spinning frequency can be made.
In an embodiment pressure in excess of 5.0 MPa (100 bar) may be achieved for a 7.0 mm diameter rotor type sample holder while the spinning frequency reaches 5.0 kHz or more.
The various embodiments described above can be combined to provide further embodiments. Aspects of the embodiments can be modified, if necessary to employ concepts of the various patents, applications and publications to provide yet further embodiments.
These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
