TECHNICAL FIELD
[0001] This invention relates to compressors for efficiently compressing various gases,
and more specifically, method(s) for starting gas compressors for stable operation
at supersonic conditions, and to apparatus in which such method(s) are employed.
BACKGROUND
[0002] The development of improved, highly efficient compression processes have become increasingly
important in view of ever-increasing costs for energy. Further, in various power generation
processes, including some of those integrated with fuel synthesis processes, the compression
of residual or byproduct various gases, including carbon dioxide, is expected to become
more important and increasingly prevalent as the call for sequestration of carbon
dioxide becomes more urgent. Thus, a reduction in gas compression costs by providing
a gas compressor having high efficiency would be desirable in a variety of gas compression
applications. When compressing high molecular weight gases, energy reduction and thus
cost reduction become especially important. In general, design methods associated
with prior art supersonic compressors have encountered various difficulties. Some
structures previously suggested have had or would have difficulty, as a practical
matter, in ingesting an oblique leading edge shock pattern, and thus, have not been
suitable for reliable starting in supersonic operation. Most such difficulties are
problematic, since in order to maintain low shock losses at increased relative Mach
numbers, the use of some sort of oblique shock system is generally required. However,
an oblique shock wave system is of value in supersonic gas compression since it ultimately
enables the maintenance of an operational pre-normal shock Mach number that is sufficiently
low so that the total pressure loss at the terminal normal shock wave is minimized,
thus preserving efficiency.
[0003] As a consequence of trying to provide low loss supersonic shock compression while
maintaining a self-starting compressor design, compressor designs have had a practical
compression ratio upper limit. This is because the level of geometric contraction
required to achieve a low loss supersonic compression process upstream of the normal
shock wave results in a throat size, i.e. the cross-sectional flow area of minimum
size of the aerodynamic duct in which supersonic compression occurs, that will not
start at inlet relative Mach numbers required to achieve pressure ratios above about
2.5 to 1. In other words, in prior art designs known to me, the area of the throat
of a compression duct compared to the area of capture at the inlet of such compression
has needed to remain relatively large, roughly in the 85% range or higher, in order
to enable such a design to "self start" with respect to the supersonic shock waves
attendant to such designs.
[0004] Due to the above mentioned limitations inherent in self-starting supersonic compressor
design, a method for the design of a supersonic compressor that enables the simultaneous
provision of high pressure ratios, at least in the range above about 2.5 to 1, and
moreover from that threshold up to a range of about 25 to 1 or more, and with high
adiabatic efficiency, has not heretofore been provided.
[0005] Consequently, there still remains an as yet unmet need for a method of design for
an easily started supersonic compressor that is capable of operating at high compression
ratios in a stable and highly efficient manner under supersonic conditions. In order
to meet such need and achieve and provide a method for the design of supersonic compressors
that can achieve such operations, it has become necessary to address the basic technical
challenges by developing new methods for starting such a supersonic compressor system.
Thus, it would be advantageous to provide supersonic compressors that achieve supersonic
shock capture in a suitably configured apparatus, while providing very high gas compression
efficiencies in normal operation. Moreover, it would be advantageous to accomplish
such goals while providing a compressor with high pressure ratios suitable for a single
stage compressor design.
[0006] The invention is defined in the independent claims which follow. The dependent claims
are directed to optional features and preferred embodiments.
BRIEF EDSCRIPTION OF THE DRAWING
[0007] The present invention will be described by way of exemplary embodiments, illustrated
in the accompanying drawing in which like reference numerals denote like elements,
and in which:
FIG 1 provides a section view of an exemplary aerodynamic duct in which supersonic
compression occurs in a supersonic gas compressor, wherein a converging inlet portion
having a compression ramp is oriented to compress gas at least partially with a radially
outward component, showing within a converging inlet portion the location of a plurality
of oblique shock waves S1, S2. S3. etc. in a gas being compressed, which oblique shocks serve to efficiently reduce
the velocity of the incoming gas while increasing pressure and temperature, as well
as a location of a normal shock wave SN, at a suitable location as the gas passes through the minimum area throat and emerges
into or travels within a divergent outlet portion of the aerodynamic duct.
FIG. 2 provides a section view of the exemplary aerodynamic duct first illustrated
in FIG. 1, but in this FIG. 2 shown in a condition wherein the aerodynamic duct is
in an unstarted condition, with the unstarted supersonic shock wave SU located at or near the entry of the converging inlet portion of the aerodynamic duct,
however, wherein as taught herein a bypass gas flow is removed from the converging
inlet portion of the aerodynamic duct in order to begin the movement of the normal
shock wave through the converging inlet in the direction of gas flow, to a location
downstream of the converging inlet, ultimately to a location such as at an operating
position for a normal shock SN just illustrated in FIG. 1.
FIG. 3 provides a graphic illustration of a suitable range for starting bypass gas
removal requirements (noted on the vertical axis as starting bleed fraction, defined
by mass of bypass gas bleed divided by mass of inlet gas captured) for a aerodynamic
duct for a supersonic compressor operating at a selected inlet relative Mach number.
FIG. 4 provides a graphic illustration of achievable gas compressor pressure ratio
capability of a compressor designed with an aerodynamic duct and starting gas bypass
as taught herein, as a function of a selected inlet relative Mach number.
FIG. 5 provides a conceptual perspective view of key components of an embodiment for
a gas compressor high speed wheel that, together with adjacent structure shown in
other drawing figures (see FIGS. 6 and 7A) is configured for easy starting and efficient
operation, showing a plurality of aerodynamic ducts mounted for rotary motion on a
shaft mounted rotor, configured for utilizing bypass gas exit conduits that cooperate
with adjacent structure to form and provide bypass gas passageways for removing gas
directly from the converging inlet portion of the aerodynamic duct.
FIG. 6 is a partial vertical cross-sectional view of a portion of the gas compressor
wheel first shown in FIG. 5, now showing details of one embodiment for providing bypass
gas exit conduits on the rotor as a part of a bypass gas passageway to achieve starting
of a supersonic gas compressor with high compression ratio, wherein a bypass gas collector
providing at least in part an intermediate gas pressure chamber allows collection
of the bypass gas from the converging inlet and provides a portion of a gas passageway
for a selected quantity of bypass gas during a startup period, as first indicated
in FIG. 2 above, to operation of the aerodynamic duct to move through a trans-sonic
region until a stable oblique shock is established, as seen in FIG. 1 above, whereupon
the flow of bypass gas as indicated in FIGS. 2, 6, and 7A is terminated.
FIG. 7A is a partial vertical cross-sectional view of an upper portion for an embodiment
wherein a stationary supersonic gas compressor is provided using the wheel first shown
in FIG. 5 and using the starting bypass gas arrangement as just shown in FIG. 6 for
the removal of a quantity of bypass gas from the converging inlet portion of an aerodynamic
duct, and now showing an embodiment wherein bypass gas at startup is removed from
along the upper portion or roof of an aerodynamic duct, and wherein the bypass gas
is returned through a passageway and a valve to a low pressure incoming gas supply
stream, and also showing use of a rotor on a rotating shaft journaled in a casing.
FIG. 7 B is a partial vertical cross-sectional view of an upper portion for another
embodiment of a supersonic gas compressor using a starting bypass gas arrangement,
utilizing the method of removal of a quantity of bypass gas from the converging inlet
portion of an aerodynamic duct, now illustrating an embodiment wherein the bypass
gas at startup is removed on the rotor side (or floor) of the converging inlet of
an aerodynamic duct.
FIG. 7 C is a partial vertical cross-sectional view of an upper portion of a supersonic
gas compressor using a starting bypass gas arrangement, utilizing the method of removal
of a quantity of bypass gas from the converging inlet portion of an aerodynamic duct,
now illustrating an embodiment wherein the bypass gas at startup is removed both (a)
on the rotor side (or floor) of the converging inlet of an aerodynamic duct, and (b)
the ceiling (in this embodiment, a radially distal side with respect to the rotor),
and returning the bypass gas through a valve to the incoming gas stream.
FIG. 8 provides a section view of another embodiment for an exemplary aerodynamic
duct operating at supersonic compression conditions in a gas compressor, similar to
the embodiment first illustrated in FIG. 1 above, but now showing an aerodynamic duct
that provides compression using a converging inlet wherein a compression ramp is oriented
to compress gas at least partially radially inward, while utilizing a plurality of
oblique shock waves S1, S2, S3, etc. which serve to efficiently reduce the velocity of the incoming gas while increasing
pressure and temperature.
FIG. 9 provides a section view of yet another embodiment for an exemplary aerodynamic
duct operating at supersonic compression conditions in a gas compressor, similar to
the embodiments illustrated in FIGS. 1 or 8 above, but now showing compression in
an aerodynamic duct that provides compression using a converging inlet wherein compression
ramps are oriented to compress gas at least partially radially inward and at least
partially radially outward, but still showing a plurality of oblique shock waves S1, S2, S3, etc. which serve to efficiently reduce the velocity of the incoming gas while increasing
pressure and temperature.
FIG. 10 provides a graphic illustration of the distinct and significant advantages
in adiabatic efficiency as a function of inlet relative Mach number, for a supersonic
compressor designed according to the principles provided herein, as compared to prior
art self starting supersonic compressors.
FIG. 11 provides a graphic illustration of the distinct and significant advantages
in pressure ratios available at various Mach numbers, and especially at higher Mach
numbers in the range of 2 or greater, and further in the range of 2.5 or greater,
of a supersonic compressor designed according to the principles provided herein, as
compared to prior art self starting supersonic compressors.
FIG. 12 provides a graphic illustration of the distinct and significant advantages
in adiabatic efficiency as a function of gas compression or pressure ratio, for a
supersonic compressor designed according to the principles provided herein, as compared
to prior art self starting supersonic compressors.
[0008] The foregoing figures, being merely exemplary, contain various elements that may
be present or omitted from actual apparatus that may be constructed to practice the
methods taught herein. An attempt has been made to draw the figures in a way that
illustrates at least those elements that are significant for an understanding of the
various methods taught herein for design, construction, and operation of high efficiency
supersonic compressors. However, various other actions in the design of supersonic
compressors using removal of a portion of bypass gas for starting of the compressor
may be utilized in order to provide a versatile gas compressor that minimizes or eliminates
starting difficulties and/or efficiency losses heretofore inherent in supersonic compressor
designs.
[0009] For the sake of completeness, and to satisfy the Examining Division of the European
Patent Office, there follows a statement about the disclosure in
US-B1-6,334,299.
[0010] US-B1-6,334,299 discloses a method for starting a ramjet engine, by raising the rotational speed
of its rotor to compress gas at supersonic inlet conditions, removing bypass gas from
a converging inlet portion of a duct, stabilizing an oblique shock wave at a selected
inlet relative Mach number and compression ration, and then ending the removal of
the bypass gas.
DETAILED DESCRIPTION
[0011] An exemplary method for the design and construction of a high compression ratio and
highly efficient supersonic gas compressor, such as compressor 18 depicted in FIG.
7A, is set forth herein. Throughout this specification, there is discussion of the
term inlet relative Mach number ("M"), as well as of a Mach number in the minimum
cross-sectional passageway or throat of an aerodynamic duct. For purposes of this
specification, unless expressly set forth otherwise, or unless another interpretation
is required by the specific context mentioned, the various Mach numbers as discussed
and described in detail herein are provided as mass averaged values, wherein the term
mass averaged means that the local Mach numbers throughout the flow area of interest
are weighted by the local mass flow and are subsequently averaged by the total flow.
Mathematically this expression can be described by the following equation:

Where:
A = the reference area over which the Mach number is to be averaged
ρ = the local flow density
V = the local flow velocity
MI = the local Mach number
M = the mass Averaged Mach number
[0012] Attention is directed to FIG 1, which provides a section view of an exemplary aerodynamic
duct 20 that provides a bounding passage in which supersonic compression occurs in
a supersonic gas compressor 18 configured according to the design techniques taught
herein. The aerodynamic duct 20 includes a convergence inlet portion 22 having a compression
ramps 24 are oriented to compress an incoming gas as designated by reference arrow
26 in an outward direction as indicated by reference arrow 28, which outward direction
is at least partially with a radially outward with respect to the rotation of compressor.
This can be appreciated by reference to FIG. 7A, as well as to FIG. 5, both of which
have been marked to depict the differential between radius R1 (from a shaft 30 centerline
axis of rotation 32 to a floor 34 of an aerodynamic duct 20 in a position upstream
of compression ramps 24) and radius R2 (from a shaft 30 centerline 32 to a position
35 on a compression ramp 24 after at least some outward compression has been achieved).
[0013] Returning now to FIG. 1, shown within the converging inlet portion 22 is a plurality
of oblique shock waves S
1, S
2 , S
3, etc. resulting from supersonic compression of a gas. The oblique shocks S
1, S
2, S
3, etc., serve to efficiently reduce the velocity of the incoming gas while increasing
its pressure and its temperature. During stable compressor operation at or near design
conditions, a stable normal shock wave S
N, is positioned at a suitable location, usually at or shortly after the gas passes
through the minimum area cross-sectional area (designated as a throat 36 in design
terms used for aerodynamic ducts), or more broadly, as the gas emerges into or travels
within a divergent outlet portion 38 of the aerodynamic duct 20. In any event, the
design of the converging inlet portion 22 of the aerodynamic duct 20 is configured
to produce a series of oblique shock waves (S1, S2, S3, S4, et cetera, to shock wave
Sx, wherein X is a positive integer), which series of shock waves slows the inlet
flow of captured gas in the converging inlet portion 22 from a selected design point
inlet relative Mach number to a Mach number of between about 1.2 and about 1.5 at
a reference location prior to or at the location of a normal shock wave S
N. The selected design point inlet relative Mach number is selected, of course, at
a value above the reduced Mach number at the reference location prior to or at the
normal shock wave. For practical purposes, useful inlet relative Mach numbers may
be considered to be at about Mach 1.8 or higher, or in another embodiment, at about
Mach 2 or higher, or in another embodiment, at about Mach 2.5 or higher. Techniques
for the production of multiple oblique shock waves to accomplish such reduction in
Mach number, with an attendant increase in static pressure and static temperature
is adequately described in various prior art patents and literature; for example,
the techniques set forth in
US Patent 3,777,487 should be more than sufficient to allow one of ordinary skill in the art and to which
this specification is addressed to provide such multiple oblique shock waves in a
suitable apparatus.
[0014] FIG. 2 provides a section view of the exemplary aerodynamic duct 20 first illustrated
in FIG. 1, but in this FIG. 2 shown in a condition wherein the aerodynamic duct 20
is in an unstarted condition, with the unstarted supersonic shock wave S
U located at or near the entry 39 of the converging inlet portion 22 of the aerodynamic
duct 20. However, in this FIG. 2, the method of removal of a quantity of bypass gas
flow from the converging inlet portion 22 of the aerodynamic duct 20 is shown. Removal
of such bypass gas directly from the converging inlet portion 22 eliminates or minimizes
the choking effect of increased capture of gas 26 by the aerodynamic dict 20 at increasing
speed during startup of the compressor, and allows downstream movement of a shock
wave from the unstarted shock wave position noted as S
U, ultimately to the started shock wave position noted as S
N in FIG. 1. However, during a startup sequence, after leaving location indicated as
S
U, the shock may relocate to an intermediate location S
I as indicated in hidden lines at a position further downstream within diverging outlet
portion 38 of the aerodynamic duct 20, which intermediate position may be expected
to vary, depending upon backpressure, instantaneous gas throughput as compared to
design condition capacity, other operating conditions, and the control scheme utilized
for the compressor. Ideally, the normal shock S
N will be located at a position at or near the throat 36 so that losses are held to
a minimum via gas expansion before occurrence of the normal shock S
N operating position, as generally depicted in FIG. 1.
[0015] Further, in FIG. 2, exit conduits 40, as defined by interior sidewalls 42, are shown
penetrating through first bounding portion 44 of aerodynamic duct 20, from a bounding
side 46 to an exit side 48. In other words, a first bounding portion 44 of aerodynamic
duct 20 includes perforations defined by interior sidewalls 42 that provide exit conduits
40. These exit conduits 40 are provided in sufficient size, shape, and quantity, and
consistent with acceptable and manageable aerodynamic loss as further discussed below,
in order to provide a bypass gas quantity within an acceptable range with respect
to a selected design operating envelope, as also further discussed below. For embodiments
of practical commercial attention, the sizing and quantity of such exit conduits 40
provide for removal of a bypass gas quantity, during startup, which increases as the
inlet relative Mach number increases. Further, the bypass gas quantity required to
be removed during starting, as a function of a particular inlet relative Mach number,
is graphically set forth in FIG. 3. By cursory analysis of FIG. 3, it can be appreciated
by those of ordinary skill in the art, to whom this specification is directed, that
the quantities of bypass gas removed for a given design operating envelope, indicated
as "starting bleed fraction," i.e. the ratio of mass of bleed bypass gas to the mass
of captured gas entering aerodynamic duct 20, is in excess (and increasingly so at
increasing inlet relative Mach number) of an amount of bleed that might be used in
an aerodynamic technique for boundary layer control for reducing aerodynamic loss
at high speed operation during operation. More precisely, the quantity of bypass gas
fraction (m
bld/m
cap) used at a selected inlet relative Mach number, at a given design point, in selected
operating envelope may be bounded by:
- (a) an upper limit described by the equation

and
- (b) a lower limit described by the equation

Where:
mbld = mass of bypass gas bleed from the aerodynamic duct,
mcap = mass of gas captured by the aerodynamic duct, and
M = the inlet relative Mach number for the aerodynamic duct.
[0016] Due to the presence of exit conduits 40, when the compressor control system valve
V is open (see FIG. 6), a quantity of bypass gas (indicated by reference arrows 50)
migrates toward the exit conduits 40, and thence through the exit conduits 40 (as
indicated by reference arrows 52 in FIGS. 2 and 6) and into bypass gas collectors
54. Thus, a bypass gas passageway 58 is provided that is of increasing capacity (i.e.,
can conduct more mass, given the conditions of size, gas, temperature, differential
pressure, etc.) as the inlet relative Mach number increases, as generally graphically
depicted in FIG. 3, for example. The bypass gas collectors 54 direct the bypass gas
away from the aerodynamic duct 20, by, in one embodiment as seen in FIGS. 5 and 6,
directing the bypass gas through further bypass gas passageways 58 toward the low
pressure gas inlet 60 of the compressor 18. As indicated in FIGS. 5 and 6, in an embodiment,
the bypass gas collectors 54 are configured in a generally parallelepiped shape, as
defined by (a) a bottom or floor that is provided by exit side 48 of a first bounding
portion 44 of aerodynamic duct 20, (b) opposing collector boards, and more specifically
a flow preventive collector board 62 on one side, and an overflow collector board
64 on the other side (over which bypass gas flows as noted by reference arrow 66 in
FIG 6). (c) opposing ribs 68, and (d) a ceiling provided by a portion of the interior
72 of rotor shroud 74. In an embodiment, the inlet to the bypass gas collectors 54
is defined by exit conduits 40. In an embodiment, the outlet to bypass gas collectors
54 is defined (a) axially along opposing ribs 68 and (b) radially between the upper
end 76 of overflow collector board 64 and an interior roof portion 78 of ceiling of
interior 72 of rotor shroud 74.
[0017] Other structural details of the aerodynamic duct 20 include a second bounding portion
80, shown at the throat 36 and downstream as a roof in the diverging outlet portion
38. in an embodiment, along the diverging outlet portion 38, the use of ribs 68 may
be maintained, for connection to the rotor shroud 74. In an embodiment, opposing the
floor 34 upstream of compression ramp 24, a third bounding portion 82 may be provided,
similarly using opposing ribs 68 and rotor shroud 74.
[0018] Overall, operation of a shrouded wheel supersonic compressor is as shown in FIGS.
5, 6, 7A, 7B, and 7C, is in many respects similar to the unshrouded compressor wheel
design illustrated in
US Patent No. 7,293,955. More specifically, a compressor wheel rotates, in the direction of reference arrow
90 as noted in FIG. 5. As seen in FIG. 5, in an embodiment, one or more helical strakes
K are provided adjacent each of one or more compression ramps 24. In one embodiment,
the one or more helical strakes K extend from leading edge 92. Helical strakes K have
a height K
H have inlet interior walls K
I and outlet interior walls K
O that form lateral bounds of passageway provided by aerodynamic duct 20. Compression
ramp 24 and first bounding portion 44 form radial bounds for a portion of the passageway
provided by aerodynamic duct 20. Similarly, throat 36 and floor 96 of diverging outlet
portion 38 act with second bounding portion 80 to form radial bounds for a portion
of the passageway provided by aerodynamic duct 20.
[0019] Strakes K effectively separate the low pressure inlet gas 100 from high pressure
compressed gas downstream at each one the aerodynamic ducts 20. In an embodiment,
strakes K are provided in a generally helical structure extending radially outward
from an outer surface portion 102 of rotor 104 to an outward bounding region of the
passageways provided by aerodynamic ducts 20. As noted above, in an embodiment, first
bounding portion 44 and second bounding portion 80 form a significant portion of such
outward bounding region. In an embodiment, the third bounding portion 82 may also
provide a portion of such outward bounding region. In an embodiment, the number of
strakes K is equal to the number of compression ramps 24. In an embodiment, a compression
ramp 24 may be provided for each aerodynamic duct 20. The number of aerodynamic ducts
may be selected as appropriate for the required service, gas being compressed, mass
flow, pressure ratio, etc., as most advantageous for a given service. In some embodiments,
the number of aerodynamic ducts 20 provided for rotary motion on a single stage rotor
may be 3, or 5, or 7, or 9.
[0020] As shown in FIGS. 6 and 7A, during starting, compressor 18, via valve V in a compressor
control system, opens a passageway 58 between the aerodynamic duct 20 and the low
pressure gas inlet 60. A selected quantity of bypass gas is thus routed from the aerodynamic
duct 20 to the low pressure gas inlet 60. Once the compressor 18 reaches a stable
operating condition with the oblique shock waves stabilized, then the bypass gas is
reduced and ultimately eliminated, thus enabling the compressor 18 to operate at high
pressure ratios while maintaining high efficiency.
[0021] As earlier noted above, FIG. 3 provides a graphic illustration of a suitable range
for starting bypass gas removal requirements (noted on the vertical axis as starting
bleed fraction, defined by mass of bypass gas bleed divided by mass of inlet gas captured)
for a aerodynamic duct 20 for a supersonic compressor 18 operating at a selected inlet
relative Mach number. Thus, for desired target inlet relative Mach number, the bypass
gas removal passageways, including exit conduits 40 and bypass gas collectors 54,
need to be sized and shaped to receive therethrough the required quantity of bypass
gas. With respect to selection of a desired target inlet relative Mach number, FIG.
4 provides the range of inlet relative Mach numbers achievable by some embodiments
for a compressor 18 configured according to the teachings herein.
[0022] In addition to the embodiment for an aerodynamic duct 20 as noted in FIGS 1 and 2
above, other configurations may be feasible and several additional embodiments are
noted herein for providing advantageous wheel mounted bounding passageways for supersonic
compression.
[0023] FIG. 8 provides a section view of another embodiment for an exemplary aerodynamic
duct 120 operating at supersonic compression conditions in a gas compressor, similar
to the embodiment first illustrated in FIGS. 1 and 2 above, but now showing an aerodynamic
duct 120 that provides compression using a converging inlet 122 wherein a compression
ramp 124 is oriented to compress gas at least partially radially inward, as indicated
by reference arrow 126, while utilizing a plurality of oblique shock waves S
10, S
11, S
12, etc., which serve to efficiently reduce the velocity of the incoming gas while increasing
pressure and temperature. For starting in such an embodiment, exit conduits 40
B are provided, and bypass gas collectors 54
B are provided, each of which functionally and structurally are substantially comparable
to exit conduits 40 and collectors 54 noted above with respect to the structures described
in detail in relation to FIGS. 1 and 2.
[0024] Attention is directed to FIG. 7B, wherein a cross-sectional view of an embodiment
for a compressor utilizing a rotor 104
B that has thereon aerodynamic duct(s) 120 as just described above in the discussion
with respect to FIG. 8. At time of starting (not illustrated functionally in FIG.
8, but rather in FIG. 7B), the exit conduits 40
B positioned in the floor 130 side of aerodynamic duct(s) 120, accept therethrough
an amount of bypass gas as indicated by reference arrow 132. A bypass gas passageway
134 is provided that has a selected design size of increasing gas flow capacity (i.e.,
can conduct more mass, given the conditions of passageway physical size, gas, temperature,
differential pressure, etc.) as the design inlet relative Mach number increases. The
bypass gas sent through exit conduits 40
B in the floor located bypass gas collectors 54
B (see FIG. 8), is directed away from the aerodynamic duct(s) 120 as indicated by reference
arrow 133 and into lower bypass gas passageway 134. In an embodiment as seen in FIG.
7B, the collected bypass gas as indicated by reference arrow 136 passes through further
portions of bypass gas passageways 134, and travels through valve 137, then through
lower bypass gas outlet 138 and on toward the low pressure gas inlet 60 of the compressor
18
B.
[0025] Similarly, in FIG. 9 yet another embodiment for an exemplary aerodynamic duct 140
is provided for use in a supersonic gas compressor such as compressor 18. In this
figure, use of opposing compression ramps 142 and 144 is indicated in converging inlet
146. The compression ramp structure 142 is oriented to compress gas at least partially
radially inward as indicated by reference arrow 148. Compression ramp 144 is oriented
to compress gas at least partially radially outward as indicated by reference arrow
150. Efficient compression is accomplished utilizing a plurality of oblique shock
waves S
20, S
21, S
22, and S
30, S
31, S
32, etc. which serve to efficiently reduce the velocity of the incoming gas while increasing
pressure and temperature. For starting in such an embodiment, exit conduits 40
C and 40
D are provided, and bypass gas collectors 54
C and 54
D are provided; functionally and structurally these are substantially the same as noted
above with respect to the exit conduits 40 and the collectors 54 described in detail
in relation to FIGS. 1 and 2.
[0026] Attention is directed to FIG. 7C, wherein a cross-sectional view of an embodiment
for a compressor utilizing a rotor 104
C that has thereon aerodynamic duct(s) 140 as just described above in the discussion
with respect to FIG. 9. At time of starting (not illustrated functionally in FIG.
9, but rather in FIG. 7C), the exit conduits 40
C and 40
D, positioned in the roof side compression ramp 142 and in the floor side compression
ramp 144, respectively, accept therethrough bypass gas as indicated by reference arrows
52 and 132, respectively. The bypass gas (as indicated by reference arrows 52) sent
through exit conduits 40
C in the roof located bypass gas collectors 54
C, is directed away from the aerodynamic duct 140 and into bypass gas passageway 58.
The collected bypass gas as indicated by reference arrow 66 passes through further
portions of bypass gas passageways 58, and travels toward the low pressure gas inlet
60 of the compressor 18
C. The lower bypass gas passageway 134 is provided that has a selected design size
of increasing gas flow capacity (i.e., can conduct more mass, given the conditions
of passageway physical size, gas, temperature, differential pressure, etc.) as the
design inlet relative Mach number increases. The bypass gas sent through exit conduits
40
B in the floor located bypass gas collectors 54
B (see FIG. 8), is directed away from the aerodynamic duct(s) 120 as indicated by reference
arrow 133 and into lower bypass gas passageway 134. In an embodiment as seen in FIG.
7B, the collected bypass gas as indicated by reference arrow 136 passes through further
portions of bypass gas passageways 134, and travels through valve 137, then through
lower bypass gas outlet 138 and on toward the low pressure gas inlet 60 of the compressor
18
C.
[0027] In any event, once the gas being compressed passes the aerodynamic duct 20, or other
suitable embodiments (such as described in FIGS. 7B and 8, or in FIGS. 7C and 9),
the high speed compressed gas exits the rotor through a passageway as indicated by
reference arrow 150, and then in an embodiment may pass through an array of diffusers
152 and 154, as indicated by reference arrow 155, before entering a volute 156 as
indicated by reference arrows 158, in which the velocity slows and static pressure
is accumulated.
[0028] The compressor 18 described herein may be utilized for compression of various gases.
Benefits using such a compressor design are especially seen with gases in which the
speed of sound at standard aerodynamic conditions (1 atmosphere, 15.5°C or 60°F) is
at or about that of nitrogen or lower. Also, gases with high molecular weight may
be compressed with compressors designed as set forth herein with significant benefit,
especially when handling those gases with a molecular weight of nitrogen or higher.
Some of such gases may include hydrocarbons, such as ethane, propane, butane, pentane,
and hexane, as well as other high molecular weight compounds such as carbon dioxide,
sulfur dioxide, or very high molecular weight compounds such as uranium hexafluoride.
[0029] In short, compressors provided according to the designs provided herein are particularly
well suited to applications involving gases with low sound speeds where high pressure
ratios are required, such as carbon dioxide or propane, where high Mach number compression
designs are advantageous. For example compression of carbon dioxide to a discharge
pressure of from between about 10.34 MPa (1500 psia) to about 15.17 MPa (2200 psia)
can be accomplished in a cost effective manner. Similarity, propane compression for
natural gas liquefaction requires propane compression at pressure ratios of from about
16:1 to about 50:1, depending upon the details of the process selected. The combination
of relatively low speed of sound in propane, and high pressure ratios required, make
such service an ideal candidate for the compressor designs taught herein.
[0030] Attention is directed to FIG. 7A, where a partial vertical cross-sectional view is
provided of a supersonic gas compressor 18. The compressor 18 includes a casing 160
that has a low pressure gas inlet 60 for admitting a main flow of low pressure gas
to be compressed. The casing has a high pressure gas exit, here represented by volute
156, from which a flow of high pressure compressed gas is discharged. Rotor 104 is
journaled via shaft 30 in casing 160, such as with bearings 162. Provided with rotor
104 are aerodynamic ducts 20, which in an embodiment as depicted in FIG. 5, may be
bounded laterally and thus configured in helical fashion between helical strakes K,
along axis of rotation 32. Aerodynamic aspects of duct 20 have been adequately discussed
above; however, in each compressor design, the aerodynamic ducts 20 are provided having
an inlet relative Mach number for operation associated with a design operating point
selected within a design operating envelope for the selected gas composition, gas
quantity, and gas compression ratio. In an embodiment, a plurality of aerodynamic
ducts 20 is mounted on the rotor 104. In an embodiment, wherein bypass gas collectors
54 are co-located for rotary movement with each of the aerodynamic ducts 20. In an
embodiment such as that depicted in FIG. 5, three aerodynamic ducts 20 are provided.
[0031] Bypass gas passageway(s) 58 are provided and configured for placement in an open,
fluid conducting position, such as by opening valve V for bypass gas passage, during
the process of starting of the gas compressor 18. Likewise, the bypass gas passageway(s)
58 are provided and configured for placement in a closed position, such as by closing
valve V, in order to effectively eliminate the removal of bypass gas (such as indicated
by reference arrow 50 in FIG. 6) after startup of the compressor. In such embodiments,
a valve V associated with the bypass gas passageways is configured for opening and
closing the fluid conductivity of the bypass gas passageways.
[0032] In an embodiment the bypass gas passageway(s) 58 are adapted to receive bypass gas
50 from the aerodynamic ducts 20 and return the bypass gas to the low pressure gas
inlet 60. In an embodiment, the bypass gas passageway(s) further include one or more
bypass gas collectors 54, as seen for example in FIGS. 1 and 2, and as may be better
appreciated in FIG. 5. A plurality of exit conduits 40 provide a fluid connection
between the converging inlet portion 22 of the aerodynamic duct 20 and the bypass
gas collectors 54. In an embodiment, the one or more bypass gas collectors 54 are
each co-located with one of the aerodynamic ducts 20, and are mounted for rotary movement
therewith. The bypass gas collectors 54 are shaped and sized to facilitate removal
of a bypass portion of gas as indicated by reference arrow 50 directly from said aerodynamic
ducts via exit conduits 40 defined by sidewalls 46 between an aerodynamic duct third
bounding portion 82 of the converging inlet portion 22, and the exit side (floor 48)
of the bypass gas collectors 54. In an embodiment, a compressor is sized to provide
a quantity of bypass gas within the ranges as depicted in FIG. 3. In an embodiment,
the various components of bypass gas passageway(s) 58, including exit conduits 40,
bypass gas collectors 54, valve V, and associated piping and fluid conduits as may
be necessary in a particular design configuration, are sized and shaped for removal
of a selected quantity of bypass gas that increases as the inlet relative Mach number
increases, wherein a quantity of bypass gas selected from a range of (a) from about
11 % by mass to about 19% by mass of the inlet gas captured by the converging inlet
portion for operation at an inlet relative Mach number of about 1.8, to (b) from about
36% by mass to about 61% by mass of the inlet gas captured by the converging inlet
portion 22 for operation at an inlet relative Mach number of about 2.8.
[0033] In an embodiment, the inlet relative Mach number of the aerodynamic duct(s) is in
excess of 1.8. In an embodiment, the inlet relative Mach number of said aerodynamic
duct is at least 2. In yet another embodiment, the inlet relative Mach number of said
aerodynamic duct is at least 2.5. In a yet further embodiment, the inlet relative
Mach number is in excess of about 2.5. In a still further embodiment, the inlet relative
Mach number the aerodynamic duct(s) is between about 2 and about 2.5, inclusive of
such bounding parameters. In another embodiment, the inlet relative Mach number of
the aerodynamic duct(s) is between about 2.5 and about 2.8, inclusive of such bounding
parameters.
[0034] For most designs, of compressors according to the teachings herein, at the design
operating point, the Mach number before a normal shock at the design position location,
is in a range of from about 1.2 to about 1.5.
[0035] High efficiency at high gas compression ratio is one hallmark of the most advantageous
portions of a design operating envelope achievable by compressors designed as taught
herein. However, compressors may be provided wherein the design operating envelope
comprises a gas compression ratio of at least 3. On an embodiment, the design operating
envelope may include a gas compression ratio of at least 5. Further, in an embodiment,
a gas compression ratio of somewhere from about 3.75 to about 12, inclusive of said
parameters, may be provided. In yet another embodiment of such designs, a design operating
envelope may include a gas compression ratio somewhere in the range of from about
12 to about 30, inclusive of said parameters. With certain designs, a design operating
envelope may be provided wherein the gas compression ratio is in excess of 30.
[0036] As noted in FIGS. 8 and 9, as contrasted to FIGS. 1 and 2, differing variations for
compression ramp portions of an aerodynamic duct may be provided. As noted in FIGS.
1, 2, and 9, an aerodynamic duct may include a converging inlet having a compression
ramp that compresses incoming gas at least partially radially outward, such as shown
by reference arrow 28 in FIGS. 1 and 2, or reference arrow 150 in FIG. 9. As noted
in FIG. 9, a second compression ramp may be provided, wherein the second compression
ramp is oriented to compress an incoming gas at least partially radially inward, as
noted by reference arrow 148 in FIG. 9. In a still further embodiment, as depicted
in FIG. 8, an aerodynamic duct may include a converging inlet that only utilizes a
having a compression ramp that compresses incoming gas at least partially radially
inward, as noted by reference arrow 126 in FIG. 8.
[0037] While the exact design of an aerodynamic duct may vary in various design configurations,
for ease of construction, it may be useful and save materials, weight, and space if
the bypass gas collectors 54 are at least partially defined by a floor (exit side)
48 that is also an exterior portion of a third bounding portion 82 of an aerodynamic
duct 20, as shown in FIG. 1. As better seen in FIGS. 1 and 5, the bypass gas collectors
54 may also be at least partially defined by axially oriented and radially extending
opposing ribs 68. Also, the bypass gas collectors 54 may be at least partially defined
by opposing collector boards, said opposing collector boards provided in pairs, wherein
an upstream collector board 62 substantially prevents flow of bypass gas thereby,
and wherein a downstream collector board 64 defines at least a portion of a bypass
gas outlet from the bypass gas collector 54. Further, a rotor shroud 74 (hoop shroud)
may be provided, extending circumferentially about the rotor 104 to provide a bypass
gas flow restrictive interior roof portion 78 above the bypass gas collectors 54.
In an embodiment, an outer surface 79 of the rotor shroud 74 may be provided with
a grooved portion 81 providing a labyrinth seal with respect to casing 160.
[0038] As seen in FIG. 7A, the compressor 18 may include an interconnecting a conduit 170
between the diverging outlet portion of the aerodynamic duct and the high pressure
outlet volute 156 of the casing 160. With such a conduit 170, there may be located
one or more outlet diffusers, such as diffusers 152 and 154. Such outlet diffusers
152 and 154 are adapted to slow high speed gas escaping the diverging outlet portion,
to convert kinetic energy to static pressure in the high pressure outlet volute 156
of the casing 160.
[0039] In a method for starting a supersonic gas compressor, a compressor is provided including
a rotor having one or more aerodynamic ducts mounted for rotary movement, wherein
the aerodynamic ducts 20 have converging inlet portions and diverging outlet portions.
The aerodynamic ducts include one or more structures that at supersonic inflow conditions
generate oblique shock waves in a gas within the converging inlet portion and a normal
shock wave in a gas as said gas enters or passes through the diverging outlet portion.
The aerodynamic duct provided has an inlet relative Mach number for operation associated
with a design operating point selected within a design operating envelope for a selected
gas composition, gas quantity, and gas compression ratio. A method of starting includes
initiating engagement of the converging inlet portion of the aerodynamic ducts with
an inlet gas stream to be compressed. Then, a selected quantity of bypass gas is removed
from the converging inlet portion as the aerodynamic duct increases in velocity while
the gas therein transforms from a subsonic inflow condition to a supersonic condition
at an inlet relative Mach number associated with a design operating point. The selected
quantity of bypass gas removed increases as the inlet relative Mach number increases
as selected for the desired design operating point. Generally, the quantity of bypass
gas removed is selected from a range of (a) from about 11 % by mass to about 19% by
mass of the inlet gas captured by the converging inlet portion for operation at an
inlet relative Mach number of about 1.8, to (b) from about 36% by mass to about 61%
by mass of the inlet gas captured by the converging inlet portion for operation at
an inlet relative Mach number of about 2.8. Exemplary operating conditions for such
bypass gas removal amounts are suggested in FIG. 3. When the oblique shock waves are
effectively stabilized within the design operating envelope of the supersonic gas
compressor, the removal of a quantity of bypass gas from the converging inlet portion
is effectively eliminated. In an embodiment, the removal of said bypass gas is completely
terminated after the aerodynamic duct has reached a selected inlet relative Mach number
for the design operating point. Thereafter, normal operation of the compressor occurs
without removal of bypass gas.
[0040] In one aspect, the compressor startup method taught herein may be practiced in a
compressor configuration wherein one of the converging inlet portions comprise exit
conduits therein, and wherein removal of the bypass flow is conducted by removing
gas through such exit conduits 40.
[0041] In short, the novel supersonic gas compressor described and claimed herein, and the
method and apparatus for starting the same, can provide a significant benefit in compressor
designs for high efficiency operation. The supersonic gas compressor described and
claimed herein may be utilized to compress a variety of suitable gases. In an embodiment,
such a compressor may be utilized to compress carbon dioxide. In another embodiment,
the compressor may be utilized to compress propane.
[0042] In summary, whether for application for carbon dioxide sequestration, air separation,
hydrocarbon processing, or other gas compression operation, and especially for gases
having low sonic velocities and or high molecular weights, a novel supersonic gas
compressor design has now been developed. Initial calculations have indicated that
significant improvements in efficiency may be attained in such a design. And, an important
consideration is that efficiency is increased since after starting using a significant
bleed fraction, the bleed amount is reduced to little or nothing, i.e. essentially
zero, as the compressor design, and especially the rotor design, is able to achieve
stable operation in a desired very high compression ratio design range without ongoing
removal of bypass bleed gas.
[0043] In the foregoing description, numerous details have been set forth in order to provide
a thorough understanding of the disclosed exemplary embodiments for a novel supersonic
gas compressor. However, certain of the described details may not be required in order
to provide useful embodiments, or to practice a selected or other disclosed embodiments.
Further, the description includes, for descriptive purposes, various relative terms
such as adjacent, proximity, near, on, onto, on top, underneath, underlying, downward,
lateral, base, floor, shroud, roof, ceiling, and the like. Such usage should not be
construed as limiting. Terms that are relative only to a point of reference are not
meant to be interpreted as absolute limitations, but are instead included in the foregoing
description to facilitate understanding of the various aspects of the disclosed embodiments.
Various steps or operations in method(s) described herein may have been described
as multiple discrete operations, in turn, in a manner that is most helpful in understanding
the method(s). However, the order of description should not be construed as to imply
that such operations are necessarily order dependent. In particular, certain operations
may not need to be performed in the order of presentation. And, in different embodiments,
one or more operations may be performed simultaneously, or eliminated in part or in
whole while other operations may be added. Also, the reader will note that the phrase
"in one embodiment" has been used repeatedly. This phrase generally does not refer
to the same embodiment; however, it may. Finally, the terms "comprising", "having"
and "including" should be considered synonymous, unless the context dictates otherwise.
Various aspects and embodiments described and claimed herein may be modified from
those shown without materially departing from the novel teachings and advantages provided
by this invention, and may be embodied in other specific forms without departing from
the spirit or essential characteristics thereof. Embodiments presented herein are
to be considered in all respects as illustrative and not restrictive or limiting.
This disclosure is intended to cover methods and apparatus described herein, and not
only structural equivalents thereof, but also equivalent structures. Modifications
and variations are possible in light of the above teachings.
1. A method of starting a supersonic gas compressor for compressing a selected gas, said
compressor comprising
a casing (160), said casing further comprising a low pressure gas inlet (60) for admitting
a main flow of a selected gas (26) to be compressed, and a high pressure gas exit
(156) for discharging a compressed flow of said selected compressed gas,
a rotor (104) journaled in said casing, said rotor comprising one or more aerodynamic
ducts (20) having a converging inlet portion (22) and a diverging outlet portion (38),
said aerodynamic ducts comprising one or more structures that at supersonic inflow
conditions generate a plurality of oblique shock waves (S
1 to S
x) in a gas within said converging inlet portion and a normal shock wave (S
N) in a gas as said gas enters or passes through said diverging outlet portion, said
aerodynamic ducts having an inlet relative Mach number for operation associated with
a design operating point selected within a design operating envelope for a selected
gas composition, gas quantity, and gas compression ratio,
a bypass passageway (58) adapted to receive bypass gas from said aerodynamic ducts,
said bypass gas passageway further comprising one or more bypass gas collectors (54),
said one or more bypass gas collectors each co-located with one of said aerodynamic
ducts and shaped and sized to facilitate removal of a bypass portion of gas directly
from said aerodynamic ducts;
said method comprising:
raising the rotating speed of said rotor to compress said selected gas at supersonic
inlet conditions;
removing a selected quantity of bypass gas from said converging inlet portion of said
aerodynamic duct through said bypass gas collectors and returning it to said low pressure
gas inlet;
stabilizing said oblique shock wave at a selected inlet relative Mach number and compression
ratio; and then
effectively ending removal of said bypass gas.
2. The method as claimed in claim 1, wherein said rotor comprises a plurality of leading
edges (92), and wherein each one of said plurality of said leading edges corresponds
to, and lies upstream from, one of said one or one or more aerodynamic ducts.
3. The method as claimed in claim 1, wherein each one of said converging inlet portions
comprise exit conduits (40) therein, and wherein removal of bypass gas comprises exit
of said bypass gas through said exit conduits.
4. The method as claimed in claim 3, wherein bypass gas removed through said exit conduits
comprises a quantity of (a) from about 11% by mass to about 19% by mass of the inlet
gas captured by said converging inlet portion for operation at an inlet relative Mach
number of about 1.8, to (b) from about 36% by mass to about 61% by mass of the inlet
gas captured by said converging inlet portion for operation at an inlet relative Mach
number of about 2.8.
5. The method as claimed in claim 1 or in claim 3, wherein the quantity of said bypass
gas removed is between an upper limit described by the equation

and a lower limit described by the equation

wherein
mbld = mass of bypass gas removed from said aerodynamic ducts,
mcap = mass of gas captured by said aerodynamic ducts,
M = the inlet relative Mach number for the aerodynamic ducts.
6. The method as claimed in claim 5, wherein removal of bypass gas comprises discharging
gas from said converging inlet portion through exit conduits (40) in a bounding portion
(44) of said converging inlet portion.
7. The method according to any one of the preceding claims, wherein said selected gas
has a molecular weight of at least that of nitrogen.
8. The method as claimed in any one of the preceding claims, wherein said selected gas
comprises a hydrocarbon gas.
9. The method as claimed in any one of the preceding claims, wherein said selected gas
comprises carbon dioxide.
10. A supersonic gas compressor, comprising:
a casing (160), said casing further comprising a low pressure gas inlet (60) for admitting
a main flow of a selected gas to be compressed, and a high pressure gas exit (156)
for discharging a compressed flow of said selected compressed gas,
a rotor (104) journaled in said casing, said rotor comprising one or more aerodynamic
ducts (20) having a converging inlet portion (22) and a diverging outlet portion (38),
said aerodynamic ducts comprising one or more structures that at supersonic inflow
conditions generate a plurality of oblique shock waves (S1 to Sx) in a gas within said converging inlet portion and a normal shock wave (SN) in a gas as said gas enters or passes through said diverging outlet portion, said
aerodynamic ducts having an inlet relative Mach number for operation associated with
a design operating point selected within a design operating envelope for a selected
gas composition, gas quantity, and gas compression ratio,
a bypass gas passageway (58), said bypass gas passageway having an open position,
for use during bypass gas passage during starting of said gas compressor, and a closed
position where gas bypass passage is effectively eliminated, for use after stabilizing
said oblique shocks;
said bypass gas passageway adapted to receive bypass gas from said aerodynamic ducts
and return it to said low pressure inlet, said bypass gas passageway further comprising
one or more bypass gas collectors (54), and a plurality of exit conduits (40), said
one or more bypass gas collectors each co-located with one of said aerodynamic ducts
and mounted for rotary movement therewith, said bypass gas collectors shaped and sized
to facilitate removal of a bypass portion of gas from said aerodynamic ducts via exit
conduits defined by sidewalls (42) between an aerodynamic duct bounding portion (44)
of said converging inlet portion and said bypass gas collectors.
11. The compressor as claimed in claim 10, wherein said bypass gas passageway is sized
for increased capacity for removal of a selected quantity of bypass gas as said inlet
relative Mach number increases, wherein the selected quantity of said bypass gas removed
is between an upper limit described by the equation

and a lower limit described by the equation

wherein
mbld = mass of bypass gas removed from said aerodynamic duct(s),
mcap = mass of gas captured by said aerodynamic ducts,
M = the inlet relative Mach number for the aerodynamic duct(s).
12. The compressor as claimed in claim 10, wherein said bypass gas collectors comprise
chambers at least partially defined by a floor (48) comprising an exterior portion
of a bounding portion of said aerodynamic duct.
13. The compressor as claimed in claim 12, wherein said bypass gas collectors comprise
chambers at least partially defined by axially oriented and radially extending opposing
ribs (68).
14. The compressor as claimed in claim 12, wherein said bypass gas collectors comprise
chambers at least partially defined by opposing collector boards, said opposing collector
boards provided in pairs, wherein an upstream collector board (62) substantially prevents
flow of bypass gas thereby, and wherein a downstream collector board (64) defines
at least a portion of a bypass gas outlet from said bypass gas collector.
15. The compressor as claimed in claim 10, further comprising an interconnecting conduit
(170) between said diverging outlet portion of said aerodynamic duct and said high
pressure gas exit (156) of said casing, and further comprising outlet diffusers (152,
154), said outlet diffusers adapted to slow high speed gas escaping said diverging
outlet portion to convert kinetic energy to pressure in said high pressure gas exit
of said casing.
1. Verfahren zum Starten eines Überschallverdichters zum Verdichten eines ausgewählten
Gases, der Verdichter aufweisend
ein Gehäuse (160), wobei das Gehäuse des Weiteren einen Niedrigdruckgaseinlass (60)
zum Einlassen eines Hauptstroms eines zu verdichtenden ausgewählten Gases (26) und
einen Hochdruckgasausgang (156) zum Entladen eines verdichteten Stroms des ausgewählten
verdichteten Gases aufweist,
einen in dem Gehäuse gelagerten Rotor (104), wobei der Rotor einen oder mehrere aerodynamische
Kanäle (20) umfasst, die einen zusammenlaufenden Einlassabschnitt (22) und einen auseinanderlaufenden
Auslassabschnitt (38) aufweisen, die aerodynamischen Kanäle eine oder mehrere Anordungen
umfassend, die bei Überschall-Einlassbedingungen eine Vielzahl von schrägen Stoßwellen
(S
1 bis S
x) in einem Gas innerhalb des zusammenlaufenden Einlassabschnitts und eine senkrechte
Stoßwelle (S
N) in einem Gas erzeugen, während das Gas in den auseinanderlaufenden Auslassabschnitt
eintritt oder hindurchströmt, die aerodynamischen Kanäle eine relative Einlass-Machzahl
für den zu einem vorgesehenen Betriebspunkt zugehörigem Betrieb aufweisend, der innerhalb
eines vorgesehenen Betriebsbereichs für eine ausgewählte Gaszusammensetzung, Gasmenge
und Verdichtungsverhältnis ausgewählt ist,
einen Nebenstromdurchgang (58), der angepasst ist, um Nebenstromgas von den aerodynamischen
Kanälen zu empfangen, der Nebenstromgasdurchgang des Weiteren einen oder mehrere Nebenstromgassammler
(54) aufweisend, wobei jeder der einen oder mehreren Nebenstromgassammler zusammen
mit einem der aerodynamischen Kanäle angeordnet und geformt und dimensioniert ist,
um eine Entnahme einer Nebenstromgasmenge direkt von den aerodynamischen Kanälen zu
ermöglichen;
das Verfahren umfassend:
Erhöhen der Rotationsgeschwindigkeit des Rotors, um das ausgewählte Gas bei Überschalleinlassbedingungen
zu verdichten;
Entnehmen einer ausgewählten Menge von Nebenstromgas des zusammenlaufenden Einlassabschnitts
des aerodynamischen Kanals durch die Nebenstromgassammler und Zurückführen des Gases
zu dem Niedriggaseinlass;
Stabilisieren der schrägen Stoßwelle bei einer ausgewählten relativen Machzahl und
einem ausgewählten Verdichtungsverhältnis; und dann
effektives Beenden der Entnahme des Nebenstromgases.
2. Verfahren gemäß Anspruch 1, bei dem der Rotor eine Vielzahl von Vorderkanten (92)
umfasst und wobei jede der Vielzahl von Vorderkanten korrespondiert zu und stromabwärts
liegt von einem der einen oder mehreren aerodynamischen Kanäle.
3. Verfahren gemäß Anspruch 1, bei dem jeder der zusammenlaufenden Einlassabschnitte
darin Ausgangskanäle (40) aufweist und wobei die Entnahme von Nebenstromgas die Abgabe
des Nebenstromgases durch die Ausgangskanäle umfasst.
4. Verfahren gemäß Anspruch 3, bei dem durch den Ausgangskanal entnommenes Nebenstromgas
eine Menge (a) von in etwa 11% Massenanteil bis in etwa 19% Massenanteil des Einlassgases,
das durch den zusammenlaufenden Einlassabschnitt für den Betrieb bei einer relativen
Einlass-Machzahl von in etwa 1,8 eingefangen wurde, umfasst, bis zu (b) von in etwa
36% Massenanteil bis in etwa 61% Massenanteil des Einlassgases, das durch den zusammenlaufenden
Einlassabschnitt für den Betrieb bei einer relativen Einlass-Machzahl von in etwa
2,8 eingefangen wurde.
5. Verfahren gemäß Anspruch 1 oder Anspruch 3, bei dem die Menge des entfernten Nebenstromgases
zwischen einem oberen Limit, beschrieben durch die Gleichung

und einem unteren Limit, beschrieben durch die Gleichung

ist, wobei
mbld = die Masse des von dem aerodynamischen Kanal entnommenen Nebenstromgases ist,
mcap= die Masse des durch die aerodynamischen Kanäle eingefangenen Gases ist,
M = gleich die relative Einlass-Machzahl für die aerodynamischen Kanäle ist.
6. Verfahren gemäß Anspruch 5, bei dem die Entnahme von Nebenstromgas das Entladen von
Gas von dem zusammenlaufenden Einlassabschnitt durch Ausgangskanäle (40) in einem
Randabschnitt (44) des zusammenlaufenden Einlassabschnitts umfasst.
7. Verfahren gemäß einem der vorstehenden Ansprüche, bei dem das ausgewählte Gas mindestens
das Molekulargewicht von Stickstoff aufweist.
8. Verfahren gemäß einem der vorstehenden Ansprüche, bei dem das ausgewählte Gas ein
Kohlenwasserstoffgas umfasst.
9. Verfahren gemäß einem der vorstehenden Ansprüche, bei dem das ausgewählte Gas Kohlenstoffdioxid
umfasst.
10. Überschallverdichter, aufweisend:
ein Gehäuse (160), wobei das Gehäuse des Weiteren einen Niedrigdruckgaseinlass (60)
zum Einlassen eines Hauptstroms eines ausgewählten zu verdichtenden Gases umfasst
und einen Hochdruckgasausgang (156) zum Entladen eines verdichteten Stroms des ausgewählten
verdichteten Gases,
einen in dem Gehäuse gelagerten Rotor (104), wobei der Rotor einen oder mehrere aerodynamische
Kanäle (20) umfasst, die einen zusammenlaufenden Einlassabschnitt (22) und einen auseinanderlaufenden
Auslassabschnitt (38) aufweisen, die aerodynamischen Kanäle eine oder mehrere Anordnungen
umfassend, die bei Überschalleinlassbedingungen eine Vielzahl von schrägen Stoßwellen
(S1 bis SX) in einem Gas innerhalb des zusammenlaufenden Einlassabschnitts und eine senkrechte
Stoßwelle (SN) in einem Gas erzeugen, während das Gas durch den auseinanderlaufenden Auslassabschnitt
eintritt oder hindurchströmt, die aerodynamischen Kanäle eine relative Einlass-Machzahl
für den zu einem vorgesehenen Betriebspunkt zugehörigem Betrieb aufweisend, der innerhalb
eines vorgesehenen Betriebsbereichs für eine ausgewählte Gaszusammensetzung, Gasmenge
und Gasverdichtungsverhältnis ausgewählt ist,
einen Nebenstromgasdurchgang (58), wobei der Nebenstromgasdurchgang eine offene Position
zur Verwendung während des Nebenstromgasdurchgangs während des Startens des Gasverdichters
aufweist und eine geschlossene Position, bei der ein Durchgang von Nebenstromgas zur
Verwendung nach Stabilisierung der schrägen Stöße effektiv ausgeschlossen ist;
wobei der Nebenstromgasdurchgang angepasst ist, um Nebenstromgas von den aerodynamischen
Kanälen zu empfangen und zu dem Niedrigdruckgaseinlass zurückzuführen, der Nebenstromgasdurchgang
des Weiteren einen oder mehrere Nebenstromgassammler (54) und eine Vielzahl von Ausgangskanälen
(40) aufweisend, wobei der eine oder mehrere Nebenstromgassammler jeweils zusammen
mit einem der aerodynamischen Kanäle angeordnet ist und für eine Rotationsbewegung
damit montiert ist, wobei der Nebenstromgassammler geformt und dimensioniert ist,
um eine Entnahme einer Nebenstromgasmenge von den aerodynamischen Kanälen über Ausgangskanäle
zu ermöglichen, die durch Seitenwände (42) zwischen einem Randbereich (44) eines zusammenlaufenden
Einlassabschnitts des aerodynamischen Kanals und der Nebenstromgassammler definiert
ist.
11. Verdichter gemäß Anspruch 10, bei dem der Nebenstromgasdurchgang für eine erhöhte
Kapazität zum Entnehmen einer ausgewählten Menge von Nebenstromgas, wenn die relative
Einlass-Machzahl ansteigt, dimensioniert ist, wobei die ausgewählte Menge des entnommenen
Nebenstromgases zwischen einem oberen Limit, beschrieben durch die Gleichung

und einem unteren Limit, beschrieben durch die Gleichung

ist, wobei
mbld = die Masse des von dem aerodynamischen Kanal entnommenen Nebenstromgases ist,
mcap= die Masse des durch die aerodynamischen Kanäle eingefangenen Gases ist,
M = gleich die relative Einlass-Machzahl für die aerodynamischen Kanäle ist.
12. Verdichter gemäß Anspruch 10, bei dem die Nebenstromgassammler Kammern umfassen, die
zumindest teilweise durch einen Boden (48) definiert sind, der einen äußeren Abschnitt
des Randabschnitts des aerodynamischen Kanals umfasst.
13. Verdichter gemäß Anspruch 12, bei dem die Nebenstromgassammler Kammern umfassen, die
zumindest teilweise durch axial ausgerichtete und sich radial erstreckende gegenüberliegende
Rippen (68) definiert sind.
14. Verdichter gemäß Anspruch 12, bei dem die Nebenstromgassammler Kammern umfassen, die
zumindest teilweise durch gegenüberliegende Sammelplatten definiert sind, wobei die
gegenüberliegenden Sammelplatten paarweise bereitgestellt sind, wobei eine stromaufwärts
liegende Sammelplatte (62) im Wesentlichen das Vorbeiströmen von Nebenstromgas verhindert
und wobei eine stromabwärts liegende Sammelplatte (64) zumindest einen Abschnitt eines
Nebenstromgasauslasses von dem Nebenstromgassammler definiert.
15. Verdichter gemäß Anspruch 10, des Weiteren einen Verbindungskanal (170) zwischen dem
auseinanderlaufenden Auslassabschnitt des aerodynamischen Kanals und dem Hochdruckgasausgang
(156) des Gehäuses aufweisend und des Weiteren Auslassdiffusoren (152, 154) umfassend,
wobei die Auslassdiffusoren angepasst sind, um das Entweichen von Hochgeschwindigkeitsgas
des auseinanderlaufenden Auslassabschnitts zu verlangsamen, um kinetische Energie
zu Druck in dem Hochdruckgasausgang des Gehäuses umzuwandeln.
1. Procédé de démarrage d'un compresseur supersonique à gaz destiné à comprimer un gaz
sélectionné, ledit compresseur comprenant
un carter (160), ledit carter comprenant en outre une entrée (60) pour gaz à basse
pression destinée à l'admission d'un écoulement principal d'un gaz sélectionné (26)
devant être comprimé, et une sortie (156) pour gaz à haute pression destinée à décharger
un écoulement comprimé dudit gaz comprimé sélectionné,
un rotor (104) monté rotatif par le biais d'un arbre dans ledit carter, ledit rotor
comprenant une ou plusieurs canalisation aérodynamiques (20) comprenant une partie
d'entrée convergente (22) et une partie de refoulement divergente (38), lesdites canalisations
aérodynamiques comprenant une ou plusieurs structures qui, en conditions d'écoulement
rentrant supersonique, génèrent une pluralité d'ondes de choc obliques (S
1 à S
x) dans un gaz dans ladite partie d'entrée convergente et une onde de choc normale
(S
N) dans un gaz lorsque ledit gaz rentre ou passe à travers ladite partie de refoulement
divergente, lesdites canalisations aérodynamiques présentant un nombre de Mach relatif
en entrée pour un fonctionnement associé à un point de fonctionnement de conception
sélectionné à l'intérieur d'une enveloppe de fonctionnement de conception pour une
composition de gaz, une quantité de gaz et un taux de compression de gaz sélectionnés,
une voie de passage de contournement (58) adaptée pour recevoir un gaz de contournement
à partir desdites canalisations, ladite voie de passage de contournement comprenant
en outre un ou plusieurs collecteurs de gaz de contournement (54), chacun desdits
un ou plusieurs collecteurs de gaz de contournement étant colocalisé avec l'une desdites
canalisations aérodynamiques et conformé et dimensionné de sorte à faciliter le retrait
d'une partie de contournement du gaz directement depuis lesdites canalisations aérodynamiques
;
ledit procédé comprenant le fait :
d'élever la vitesse de rotation dudit rotor pour comprimer ledit gaz sélectionné en
conditions d'entrée supersoniques ;
de retirer une quantité sélectionnée de gaz de contournement de ladite partie d'entrée
convergente de ladite canalisation aérodynamique à travers lesdits collecteurs de
gaz de contournement et de la renvoyer à ladite entrée pour gaz à basse pression ;
de stabiliser ladite onde de choc oblique à un nombre de Mach relatif en entrée et
à un taux de compression sélectionnés ; et ensuite
de mettre effectivement fin au retrait dudit gaz de contournement.
2. Procédé tel que revendiqué dans la revendication 1, dans lequel ledit rotor comprend
une pluralité de bords d'attaque (92), et dans lequel chacun de ladite pluralité desdits
bords d'attaque correspond à et s'étend en amont de l'une desdites une ou plusieurs
canalisations aérodynamiques.
3. Procédé tel que revendiqué dans la revendication 1, dans lequel chacune desdites parties
d'entrée convergentes comprend des conduites de sortie (40) dedans, et dans lequel
le retrait de gaz de contournement comprend la sortie dudit gaz de contournement à
travers lesdites conduites de sortie.
4. Procédé tel que revendiqué dans la revendication 3, dans lequel le gaz de contournement
retiré à travers lesdites conduites de sortie comprend une quantité (a) allant d'environ
11% en masse jusqu'à environ 19% en masse du gaz en entrée capturé par ladite partie
d'entrée convergente pour un fonctionnement à un nombre de Mach relatif en entrée
d'environ 1,8, à (b) d'environ 36% en masse jusqu'à environ 61% en masse du gaz en
entrée capturé par ladite partie d'entrée convergente pour un fonctionnement à un
nombre de Mach relatif en entrée d'environ 2,8.
5. Procédé tel que revendiqué dans la revendication 1 ou dans la revendication 3, dans
lequel la quantité dudit gaz de contournement retiré se trouve entre une limite supérieure
décrite par l'équation

et une limite inférieure décrite par l'équation

où:
mbld = masse de gaz de contournement retiré desdites canalisations aérodynamiques,
mcap = masse de gaz capturé par lesdites canalisations aérodynamiques,
M = nombre de Mach relatif en entrée pour les canalisations aérodynamiques.
6. Procédé tel que revendiqué dans la revendication 5, dans lequel le retrait du gaz
de contournement comprend le fait de décharger du gaz de ladite partie d'entrée convergente
à travers des conduites de sortie (40) dans une partie de délimitation (44) de ladite
partie d'entrée convergente.
7. Procédé selon l'une quelconque des revendications précédentes, dans lequel ledit gaz
sélectionné présente un poids moléculaire au moins égal à celui de l'azote.
8. Procédé tel que revendiqué dans l'une quelconque des revendications précédentes, dans
lequel ledit gaz sélectionné comprend un gaz d'hydrocarbures.
9. Procédé tel que revendiqué dans l'une quelconque des revendications précédentes, dans
lequel ledit gaz sélectionné comprend du dioxyde de carbone.
10. Compresseur supersonique à gaz, comprenant :
un carter (160), ledit carter comprenant en outre une entrée (60) pour gaz à basse
pression destinée à l'admission d'un écoulement principal d'un gaz sélectionné devant
être comprimé, et une sortie (156) pour gaz à haute pression destinée à décharger
un écoulement comprimé dudit gaz comprimé sélectionné,
un rotor (104) monté rotatif par le biais d'un arbre dans ledit carter, ledit rotor
comprenant une ou plusieurs canalisations aérodynamiques (20) comprenant une partie
d'entrée convergente (22) et une partie de refoulement divergente (38), lesdites canalisations
aérodynamiques comprenant une ou plusieurs structures qui, en conditions d'écoulement
rentrant supersonique, génèrent une pluralité d'ondes de choc obliques (S1 à Sx) dans un gaz dans ladite partie d'entrée convergente et une onde de choc normale
(SN) dans un gaz lorsque ledit gaz rentre ou passe à travers ladite partie de refoulement
divergente, lesdites canalisations aérodynamiques présentant un nombre de Mach relatif
en entrée pour un fonctionnement associé à un point de fonctionnement de conception
sélectionné à l'intérieur d'une enveloppe de fonctionnement de conception pour une
composition de gaz, une quantité de gaz et un taux de compression de gaz sélectionnés,
une voie de passage de contournement (58), ladite voie de passage de gaz de contournement
présentant une position ouverte, à utiliser pendant le passage du gaz de contournement
lors du démarrage dudit compresseur à gaz, et une position fermée dans laquelle le
passage de gaz de contournement est effectivement éliminé, à utiliser après la stabilisation
desdits chocs obliques ;
ladite voie de passage de gaz de contournement est adaptée pour recevoir un gaz de
contournement provenant desdites canalisations aérodynamiques et le renvoyer à ladite
entrée à basse pression, ladite voie de passage de gaz de contournement comprenant
en outre un ou plusieurs collecteurs (54) de gaz de contournement, et une pluralité
de conduites de sortie (40), chacun desdits un ou plusieurs collecteurs de gaz de
contournement étant colocalisé avec l'une desdites canalisations aérodynamiques et
monté pour avoir un mouvement de rotation avec celle-ci, lesdits collecteurs de gaz
de contournement étant conformés et dimensionnés en vue de faciliter le retrait d'une
partie de contournement de gaz depuis lesdites canalisations aérodynamiques à travers
des conduites de sortie définies par des parois latérales (42) entre une partie (44)
de délimitation des canalisations de ladite partie d'entrée convergente et lesdits
collecteurs de gaz de contournement.
11. Compresseur tel que revendiqué dans la revendication 10, dans lequel ladite voie de
passage de gaz de contournement est dimensionnée pour que sa capacité augmente pour
le retrait d'une quantité sélectionnée de gaz de contournement à mesure que ledit
nombre de Mach relatif en entrée augmente, dans lequel la quantité sélectionnée dudit
gaz de contournement retiré se trouve entre une limite supérieure décrite par l'équation

et une limite inférieure décrite par l'équation

où:
mbld = masse de gaz de contournement retiré de ladite/desdites canalisation(s) aérodynamique(s),
mcap = masse de gaz capturé par lesdites canalisations aérodynamiques,
M = nombre de Mach relatif en entrée pour la/les canalisation(s) aérodynamique(s).
12. Compresseur tel que revendiqué dans la revendication 10, dans lequel lesdits collecteurs
de gaz de contournement comprennent des chambres au moins en partie définies par un
plancher (48) comprenant une partie extérieure d'une partie de délimitation de ladite
canalisation aérodynamique.
13. Compresseur tel que revendiqué dans la revendication 12, dans lequel lesdits collecteurs
de gaz de contournement comprennent des chambres définies au moins en partie par des
nervures (68) en regard orientées axialement et s'étendant radialement.
14. Compresseur tel que revendiqué dans la revendication 12, dans lequel lesdits collecteurs
de gaz de contournement comprennent des chambres définies au moins en partie par des
panneaux de collecteur en regard, lesdits panneaux de collecteurs en regard étant
prévus par paires, dans lequel un panneau de collecteur amont (62) empêche ainsi sensiblement
tout écoulement de gaz de contournement, et dans lequel un panneau de collecteur aval
(64) définit au moins une partie d'un refoulement de gaz de contournement dudit collecteur
de gaz de contournement.
15. Compresseur tel que revendiqué dans la revendication 10, comprenant en outre une conduite
d'interconnexion (170) entre ladite partie de refoulement divergente de ladite canalisation
aérodynamique et ladite sortie (156) pour gaz à haute pression dudit carter, et comprenant
en outre des diffuseurs de refoulement (152, 154), lesdits diffuseurs de refoulement
étant adaptés pour ralentir le gaz à haute vitesse s'échappant de ladite partie de
refoulement divergente pour convertir l'énergie cinétique en pression dans ladite
sortie pour gaz à haute pression dudit carter.