U.S. patent application number 12/126628 was filed with the patent office on 2008-11-27 for system for the transfer and detection of gas dissolved in fluid under pressure ii.
Invention is credited to Bruce Johnson, Craig McNeil.
Application Number | 20080289396 12/126628 |
Document ID | / |
Family ID | 36124280 |
Filed Date | 2008-11-27 |
United States Patent
Application |
20080289396 |
Kind Code |
A1 |
Johnson; Bruce ; et
al. |
November 27, 2008 |
SYSTEM FOR THE TRANSFER AND DETECTION OF GAS DISSOLVED IN FLUID
UNDER PRESSURE II
Abstract
A gas separation system suited for extraction of gas dissolved
in pressurized fluid. The system includes a semi-permeable membrane
in the form of tubing having an inner core volume with an internal
support present within the inner core volume. The internal support
provides multiple cylindrical supporting surfaces which are
presented to the inside tubing wall surface to prevent collapse of
the tubing wall against external pressure. Internal supports may
include a coil of spring-like configuration fitted coaxially within
the tubing; or multiple filaments that form a longitudinal bundle
within the core of the tubing. The response time of the system may
be enhanced by the presence of an outer tubular conduit surrounding
the semi-permeable membrane tubing and providing a flow path for
the external fluid to increase the rate of diffusion of dissolved
gases through the semi-permeable membrane. Gas pressures may be a
sensed, both total and partial, as well as the identity of
respective sampled gases.
Inventors: |
Johnson; Bruce; (Halifax,
CA) ; McNeil; Craig; (Seattle, WA) |
Correspondence
Address: |
Miltons LLP
225 Metcalfe Street, Suite 700
Ottawa
ON
K2P 1P9
CA
|
Family ID: |
36124280 |
Appl. No.: |
12/126628 |
Filed: |
May 23, 2008 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
10954949 |
Oct 1, 2004 |
7434446 |
|
|
12126628 |
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Current U.S.
Class: |
73/19.05 ;
96/6 |
Current CPC
Class: |
B01D 63/065 20130101;
B01D 69/10 20130101; B01D 19/0031 20130101; G01N 1/2214 20130101;
G01N 2001/2217 20130101; G01N 1/2211 20130101; G01N 7/10
20130101 |
Class at
Publication: |
73/19.05 ;
96/6 |
International
Class: |
B01D 19/00 20060101
B01D019/00; G01N 7/10 20060101 G01N007/10 |
Claims
1. A system for effecting the transfer of gas dissolved in fluid
under pressure comprising: a) a semi-permeable membrane admitting
the transfer of gas while substantially excluding the penetration
of fluid, such membrane being in the form of tubing having an
outside surface, a tubing wall, and inside tubing wall surface and
an inner core volume; and b) an internal support present within the
inner core volume, the internal support having multiple cylindrical
supporting surfaces which are presented to the inside tubing wall
surface to provide support for said tubing wall against a pressure
differential existing between the exterior of the tubing wall and
the inner core volume, whereby gas dissolved in the fluid when
present outside the tubing wall may pass through the tubing wall
into the inner core volume.
2. A system as in claim 1 wherein said internal support comprises a
coil of spring-like configuration fitted coaxially within the
tubing.
3. A system as in claim 1 wherein said internal support comprises
multiple filaments that form a longitudinal bundle containing
longitudinal channels that provide interstitial sub-volumes between
adjacent filaments of the longitudinal bundle to constitute said
inner core volume.
4. A system as in any one of claims 1, 2, or 3 in combination with
a sample gas circulation means communicating with the inner core
volume for carrying gas present therein to said gas sensor.
5. A system as in any one of claims 1, 2, 3 or 4 further
comprising: a) an outer tubular conduit surrounding the
semi-permeable membrane tubing and providing a flow path for the
fluid to follow that is adjacent to the outside surface of said
tubing; and, b) external fluid circulating means to cause the fluid
to pass along said flow path and thereby increase the rate of mass
transfer of dissolved gases through the semi-permeable
membrane.
6. A system as in claim 5 wherein the flow path is an annular flow
path and wherein said annular flow path comprises a helically
formed baffle present therein.
7. A system as in claim 6 wherein the helically formed baffle has a
width that occupies the space between the outer tubular conduit and
said tubing
8. A system as in claim 4 wherein said sensor determines the
pressure of the gases present in the sampling inner core
volume.
9. A gas detection system as in claim 4 wherein said sensor
identifies the character of at least one gas present within the
inner core volume.
10. A system for effecting the transfer of gas under pressure
comprising: a) a semi-permeable membrane admitting the transfer of
gas while substantially excluding the penetration of liquid, such
membrane being in the form of tubing having an outside surface, a
tubing wall, and inside tubing wall surface and an inner core
volume; and b) an internal support present within the inner core
volume, the internal support having multiple cylindrical supporting
surfaces which are presented to the inside tubing wall surface to
provide support for said tubing wall against a pressure
differential existing between the exterior of the tubing wall and
the inner core volume, whereby gas present under a given pressure
outside the tubing wall may pass through the tubing wall into the
inner core volume when the inner core volume is at a pressure that
is lower than the given pressure.
11. A system as in claim 8 wherein a fluid is present within the
inner core volume.
Description
FIELD OF THE INVENTION
[0001] This invention relates to the separation of a gas from a
liquid and to the mass transfer of a gas present within a fluid in
a high-pressure environment into a low pressure environment. More
particularly, it relates to the detection of the presence of gas
within a liquid and, in particular to sampling, identifying the
character, and quantifying the amount and/or partial pressure of
gas dissolved in fluids under pressure, such as water at depth in
the water column of the ocean or a river or lake, or of water or
other fluid confined in a pressure vessel in industrial process or
storage application.
[0002] Further, it relates to the use of the pressure-resistant
membrane of the system to achieve the mass transport of a gas into,
or out of, solution with a fluid under pressure.
BACKGROUND TO THE INVENTION
[0003] In the field of oceanography, it is often desired to obtain
a direct measurement of the identity and pressure of dissolved
gases present in seawater or freshwater. A major target gas is
carbon dioxide --CO.sub.2. Known techniques for obtaining such
measurements include the use of semi-permeable membranes that allow
such gases to penetrate into a sampling volume, while resisting the
penetration of the external liquid and sustaining the hydrostatic
pressure so that it does not collapse the sampling volume.
[0004] Samples of prior art techniques for measuring the partial
pressure of gases, and particularly carbon dioxide dissolved in
seawater, are respectively European patents EP-01 04 35 85 A2 and
EP-00 59 26 32 A1. An example of a planar membrane which is
supported in order to resist hydrostatic pressure is described in
U.S. Pat. No. 5,121,627. The support of the planar geometry of a
membrane against substantial hydrostatic pressures, while
preserving structural integrity and semi-permeability of the
membrane, is difficult, and is impracticable in applications where
a relatively large total area of membrane is required for an
acceptably high rate of penetration of the gas under detection into
the sampling volume, with corresponding enhancement of response
time performance.
[0005] Use of semi-permeable membranes in the format of tubing is
described in U.S. Pat. Nos. 3,871,228; 4,563,892, and 4,662,210. An
advantage of the use of tubing is that, particularly in respect of
smaller diameter tubing, the curved walls of semi-permeable
membrane material can be largely self-supporting, at least at lower
pressures. Thus, the area limitations of the planar membrane can be
overcome, in that the surface of the tubular membrane forms the
effective area for penetration of gas into the interior volume, and
may be increased proportionally by the length of the tubing
comprising the membrane.
[0006] However, at higher hydrostatic pressures, the semi-permeable
material forming the tubular membrane does not have sufficient
mechanical strength to resist the external pressure and will
undergo collapse to close the interior space such that the
penetration of the gas and its transfer to the detection
instrumentation is obstructed. It is also known that to create a
optimal system for the detection and measurement of gas by
penetration of the gas from a fluid through a semi-permeable
membrane into a sample space, the volume of the sample space must
be relatively small in relation to the active membrane area to
achieve reasonably rapid equilibration of the gas in the sample
space with the ambient fluid from which it was derived, thereby
shortening the response time of the instrumentation.
[0007] In U.S. Pat. No. 5,763,762, it is suggested that a filler
for the purpose of reducing the internal volume of a tubular
semi-permeable membrane may be provided from the group: thread,
mono-filament, powder, wire, in situ formed polymer, fluid and any
combination of these. However, U.S. Pat. No. 5,763,762, does not
discuss as a design consideration, the utility of a system for the
detection or measurement of a gas dissolved in liquid under
pressure, or the incorporation of the feature of a pressure
resistance membrane as an element of the invention claims.
[0008] Fillers of the type previously proposed will have a tendency
to permit partial or complete collapse of the tubing, the
compression and constriction of the filler substrate, or the
rendering the membrane susceptible to mechanical penetration or
rupture by the forcing of the membrane film into voids in the
filler substrate or projections on filler elements, thereby
increasing the pressure drop occurring when sampled gas is removed
from the core of such tubing or rendering the system
non-functional.
[0009] Further, in order to shorten the response time of such a
system, it is desirable for the gases present in the external fluid
to be exposed to the semi-permeable membrane with minimal
interference from boundary layers that are depleted in such
gases.
[0010] The invention addresses the objects of overcoming the
disadvantages of the prior art and provides for a new form of gas
detection and transfer system that operates with a minimized
response time.
[0011] The invention in its general form will first be described,
and then its implementation in terms of specific embodiments will
be detailed with reference to the drawings following hereafter.
These embodiments are intended to demonstrate the principle of the
invention, and the manner of its implementation. The invention in
its broadest and more specific forms will then be further
described, and defined, in each of the individual claims which
conclude this Specification.
SUMMARY OF THE INVENTION
[0012] According to the present invention, in one aspect an gas
transfer or detection system relies on a semi-permeable membrane in
the format of tubing which contains an internal support. According
to one embodiment, the internal support presents multiple,
generally cylindrical, supporting surfaces to the inside wall of
the tubing. Such multiple cylindrical supporting surfaces may be
provided by a coil of spring-like configuration fitted coaxially
within the tubing. Alternately, such multiple cylindrical
supporting surfaces may be provided by multiple filaments that form
a longitudinal bundle within the core of the tubing.
[0013] Both variants of the invention enable use of a relatively
thinner wall in the tubing which serves as a semi-permeable
membrane. Both variants act by providing support for the inner wall
of such tubing. An advantage of the use of the coil-format variant
is that gas samples may be removed from the inner core of the coil
rapidly with minimum pressure drop. An advantage of the use of the
filament format of the invention is that the sampling volume
present inside the tubing, in the interstitial spaces between the
filaments, is reduced in size.
[0014] In both cases, in the gas detection mode gas circulation
means may be used to pass gas present within the tubing to the gas
sensor or detector present within the instrument. Such sensor may
determine the pressure of the gas in the gas sampling volume. It
may also determine the character of such gas, e.g. identifying the
presence of dissolved oxygen or carbon dioxide. Further, the sensor
may distinguish between the partial pressures of different
categories of gases present in the gas sampling volume,
corresponding to the dissolved gases present in the external
fluid.
[0015] To enhance the response of the instrument to changes in
ambient dissolved gases, the semi-permeable membrane tubing may be
surrounded by an outer, preferably co-axial, tubular conduit or
channel through which the external fluid is forced to follow. By
imposing a flow rate on such external fluid, the boundary layer of
gas-depleted fluid adjacent the semi-permeable membrane is reduced
in thickness. This hastens the mass transfer rate of gas from the
liquid through the semi-permeable membrane, shortening the response
time of the instrument.
[0016] According to a further variant, the fluid in the outer
tubular conduit is forced to follow a spiral path around the
semi-permeable membrane tubing. This spiral path may be imposed,
for example, by placing a spiral baffle on the outer wall of the
membrane or the inner wall of the outer tubular conduit. In a
specific embodiment of this variant, the spiral baffle may be
created by a copper wire in the form of an expanded spring of
diameter approximately equal to the annular space between the outer
tubular conduit and the semi-permeable membrane tubing within such
conduit. Copper is preferred as being toxic to microorganisms that
would otherwise foul the outer surface of the semi-permeable
membrane.
[0017] The foregoing summarizes the principal features of the
invention and some of its optional aspects. The invention may be
further understood by the description of the preferred embodiments,
in conjunction with the drawings, which now follow.
BRIEF DESCRIPTION OF THE DRAWINGS
[0018] FIG. 1 is a schematic diagram of the sensor package and
cylindrical membrane interface.
[0019] FIG. 2 is a perspective view of the cylindrical membrane
with detail of the wire coil spring internal support.
[0020] FIG. 3 is a perspective view of the cylindrical membrane
with detail of the longitudinal filament bundle internal support
having interstitial spaces between adjacent filaments.
[0021] FIG. 4 is a diagram of the connection between the
cylindrical membrane interface and the tubing from the sensor
package.
[0022] FIG. 5 is a diagram of the spiral baffle between the
cylindrical membrane interface and the outer conduit tubing.
DESCRIPTION OF THE PREFERRED EMBODIMENT
[0023] FIG. 1 is a schematic depiction of the sensor package 1 and
tubular membrane interface 2 which has been inserted into a fluid
phase 3 containing dissolved gas 4. Connecting tubing 5 extends
between the membrane interface 2 and the sensor package 1. The
sensor package 1 may include any means of measuring a component or
property of the gas that is sampled by the membrane interface 2.
For example, the entire system may be submerged as in an underwater
instrument or the sensor package 1 may be above water or in a
laboratory.
[0024] The membrane interface 2 may be attached to the sensor
package 1 at only one end, relying on diffusion to communicate with
the sensor package 1. Alternately, for flow-through applications,
the tubular membrane interface 2 may be coupled at both ends to the
sensor package 1. Further, the tubular membrane interface 2 may be
in the form of multiple tubings which are interconnected or
connected at a manifold. In the case of a flow-through
configuration, both ends may be closed during equilibration whereby
the membrane interface 2 acts as a known volume sample loop.
[0025] Examples for sensor packages 2 are a pressure sensor, a gas
chromatograph, a mass spectrometer, an optical cell or any other
sensor that measures a property of the enclosed fluid. The sensor
elements of the sensor package 1 may also be incorporated into the
actual tubular membrane interface 2, as in the case where the
system comprises an optical cell.
[0026] Substances to be sampled will typically be gases that will
equilibrate across or pass through the interface between fluid
phase and the inner core volume 6 of the tubular membrane interface
2. The system applies to any substance that can be made to pass
through the interface that serves as a barrier for other
substances, and equilibrate, or otherwise be detected or measured,
even if not equilibrated.
[0027] FIG. 2 depicts a tubular membrane interface 2 supported by a
support member 7 in the form of a spiral coil 8. The spiral coil 8
may be made of wire or any equivalent material. The wire in such
spiral coil 8 need not be necessarily round, but could be of any
cross-section, e.g. square or spiral in cross-section, which is
effective for the application. It is in this most generalized sense
that such support members are "cylindrical". The spiral should be
wound sufficiently tightly as to preclude the collapse of the
tubular membrane 2 into gaps between consecutive coils.
[0028] FIG. 3 depicts a tubular membrane interface 2 supported by
an alternate support in the form of a wire bundle 9. While referred
to as "wire", these elements need not be made of metal, and any
equivalent functioning form of filament may be employed. The wire
bundle 9 will typically be composed of large numbers of fine wires.
The wires may be in patterned in groups, i.e., twisted bundles of
multiple wires, or may be packed individually. The wires in such
bundles 9, as with the wires of the spiral coil 8, need not be
necessarily round, but may be of any cross-section, e.g. square or
spiral, which is effective for the application. Again, generally,
such wires are "cylindrical" in character.
[0029] Both wire bundle-supported and coil spring-supported
supports may be of any length, but have been found to provide
useful sampling interfaces in lengths of a few centimeters to
several meters. Both coiled spring supported and wire bundle
supported types of interfaces have been shown to provide proof
against pressures in excess of 600 PSI, maintaining resistance
against this pressure for periods of weeks.
[0030] Use of supported semi-permeable interfaces of the invention
is not limited to applications involving high external fluid
pressures, but may also find application in cases where the
interior of the interface has been evacuated. Further, interfaces
according to the invention may be employed where the object is to
introduce a high-pressure gas into a liquid under lower pressure.
In such case, the liquid flows through the central core volume of
the tubular membrane interface, and the gas is present in the
exterior environment.
[0031] Difficulty may attend the covering of the coiled spring
support 8 with the tubular semi-permeable membrane 2. The tubular
membrane 2 will need to be stretched over the coil spring support 8
in order to avoid excessive pressure increases inside the interface
when the fluid pressure increases outside. The coiled spring 8 may
be forced inside of the tubular membrane 2 by sliding, and this can
be assisted with addition of lubricant such as soap or even water.
However, this approach to fabrication may often result in a damaged
membrane. Other methods of inserting the coiled spring 8 may also
include pressurizing the inside of the tubular membrane 2 with air
or water to increase the internal diameter of the membrane so that
the coiled spring 8 can be inserted therein.
[0032] One particularly effective means of fabricating the coiled
spring supported interface involves inserting the coiled spring 8
into a tubular membrane interface 2 made of elastically resilient
material that, in its relaxed condition has an inside diameter
which is larger than the outside diameter of the coiled spring 8.
Then, by stretching the over-sized tubular membrane 2
longitudinally, the diameter of the oversized tubular membrane 2
will decrease and can be made to fit tightly against the outside
diameter of the spring. An added advantage of this method of
assembly is that the thinning of the membrane wall of the tubular
membrane 2 will enhance the rate of mass transfer of gases through
such membrane wall.
[0033] Using this technique, a typical fabrication might include
stretching silicone tubing of size 0.055'' ID over a spring of
0.039'' OD. With this particular interface the starting silicone
tube length is chosen to be 1/2 to 2/3 of the spring length.
Stretching the tubing longitudinally to the length of the spring
then causes the inside diameter of the tubing to conform to the
outside diameter of the spring. The thinning of the wall is
illustrated by one assembly in which a silicone tube with a wall
thickness of 0.030'' was stretched to two times its relaxed length
and in so doing decreased in wall thickness to 0.013''.
[0034] Terminations on the ends of the tubular membrane interfaces
2 are intended to provide the same strength and resistance against
compression as the supported membrane, and without introducing
significant impediment to gas flow. One method for providing this
termination, as depicted in FIG. 3, is to drill rigid (usually
metal although may be plastic, or other material) tubing and insert
the end of the coil spring about 1 centimeter into this drilled
hole. Then, the semi-permeable membrane tubing 2 is pushed at least
one centimeter over the outside of the drilled metal or plastic
tubing. Another piece of silicone-type or other flexible tubing
(here called the "flexible termination tubing") with inside
diameter smaller than the outside diameter of the interface tubing
is stretched to slip over the joint such that this piece of
flexible termination tubing covers at least one centimeter of the
coiled spring supported interface on one end.
[0035] This flexible termination tubing spans the joint at one end
and then, at the other end, covers several centimeters of the rigid
metal or plastic tube. Wire or a similar filament is then wrapped
around this outer, flexible termination tubing where it covers the
rigid tubing. A final layer of heat-shrink tubing (not shown in
FIG. 3 above) is applied over the termination such that the heat
shrink tubing completely covers and overlaps the wire or similar
filament, and the ends of the flexible termination tubing. Both
ends of the interface are treated in the same manner. The result is
a supported interface with rigid tubing at the ends for connection
via e.g., Swagelok or other means to an appropriation sensor
package 1.
[0036] In order to improve the rate of equilibration across the
fluid/gas interface, it has been found useful to force the external
fluid e.g. water, to flow adjacent to the tubular semi-permeable
membrane interface 2 in intimate contact with its outside surface.
Equilibration of one such interface improved from a time constant
of 2 minutes to a time constant of 15 seconds when such a flow was
imposed. One method of imposing intimate flow adjacent the outside
surface of the tubular membrane interface is to place such
interface tubing inside a larger diameter flow-control cylinder or
flow confinement structure, and then pump fluid to be sampled
through the annular space so formed. The flow path for the fluid
induced by this cylinder can be formed within any solid body.
[0037] One challenge arising in this method is keeping the tubular
membrane interface near the center of the flow channel. This can be
done by placing a helical baffle (for example a copper wire) on the
inside wall of the flow tube. This feature is shown in FIG. 5. As
depicted, the helical baffle fills the width of the annular space.
Such a helical baffle need not fill the entire width of the annular
space, although this would be preferable. It is sufficient for it
to induce a spiral flow path in the fluid. By this means pumped
fluid is then forced to swirl around the annular gap and provide a
highly efficient mass transfer. Further, effective mass transfer of
the gas through the cylindrical membrane interface 2 can be
achieved by forming a channel in the flow confinement structure to
receive the helical baffle. Thus, such channel can be cut into the
surface of a supporting body whereby the fluid is confined within
such channel.
[0038] It is desirable to maintain the flow conduit generally
co-axial with the cylindrical semi-permeable membrane. Where the
helical baffle is not of sufficient depth to maintain such
generally co-axial position of the flow conduit, it may be
necessary to provide spacing lugs on the inside surface of the flow
conduit to preserve the co-axial position of the cylindrical
membrane.
[0039] It has been found useful to coil the resulting assembly
around a forming spool to create a larger spiral, increasing the
density of the assembly in a manner similar to that present in DNA.
Increased compactness for the assembly can also be achieved by
inserting it into a channel that is fabricated as part of the
instrument housing. The radius of curvature of the assembly should
be kept large enough to avoid spreading the internal supporting
coiled spring and thereby weakening the support provided to the
tubular membrane interface 2. For a tubular membrane interface 2
supported by a 0.039'' diameter spring, a radius of curvature of
about 3'' appears sufficient to avoid this problem.
[0040] It is also possible to reduce the inner core volume within a
spirally supported tubular membrane interface 2 by insertion of a
monofilament filler within such inner core. A filled-core system is
more appropriate for measurements of gas pressure. Flow-through
systems, e.g., for measuring other parameters of specific gases,
are usually better served when the dead volume is unobstructed.
Typical results for employment of a monofilament filler in a
spring-supported tubular membrane interface in a system that
directed to measuring partial gas pressure are reported as
follows:
[0041] A 0.039'' OD spring with ID 0.019'' was covered with a
silicone tube of 0.059'' ID with 0.010'' thick wall. The tubing was
then stretched in length to tighten in diameter around the spring.
A pressure sensor with dead volume of 0.3 cm.sup.3 was attached to
the interface at one end and the other end of the interface was
closed off. Eight feet of the supported tubular membrane interface
2 was then placed inside a 5/16'' ID external plastic tube and
water pumped at the rate of 1 gallon per minute through the annular
space around the interface. At time zero, one liter of degassed
water was mixed into the tank of air-saturated water. The time
constant for equilibration of the interface/pressure sensor was
measured to be 3.5 minutes without monofilament inside the spring
interface. With 0.013'' monofilament occupying dead volume within
the inner core volume the time constant was 1.8 minutes.
[0042] However, filling the interface with a larger diameter filler
(e.g. 0.016'' monofilament) actually resulted in a longer time
constant for equilibration. This effect may arise because the
resistance to gas flow through the interface increased.
CONCLUSION
[0043] The foregoing has constituted a description of specific
embodiments showing how the invention may be applied and put into
use. These embodiments are only exemplary. The invention in its
broadest, and more specific aspects, is further described and
defined in the claims which now follow.
[0044] These claims, and the language used therein, are to be
understood in terms of the variants of the invention which have
been described. They are not to be restricted to such variants, but
are to be read as covering the full scope of the invention as is
implicit within the invention and the disclosure that has been
provided herein.
* * * * *