Title of Invention

A MASS TRANSFER TRAY

Abstract preventing a cylinder section from seizing up and also permits improved sealing A high-pressure fuel supply pump with high performance is capable of securely performance to minimize the chance of fuel leakage. The high-pressure fuel supply pump has: a casing (48) having a cylindrical cavity (48a); a sleeve (40) which has a cylinder section (40a) and a fixing section (40c), one end thereof closer to the fixing section (40c) being abutted against the bottom of the cavity (48a); and a piston (53) which is disposed in the cylinder section (40a). The high-pressure fuel supply pump takes in fuel through an intake passage (36) by the reciprocation of the piston (53) into a fuel pressurizing chamber (52) to pressurize it, then discharges the pressurized fuel through a discharge passage (37) to forcibly feed it into a fuel injector of a cylinder injection engine. A cylindrical slit (40d) is provided between the cylinder section (40a) and the fixing section (40c) of the sleeve (40), and the fixing section (40c) is secured by being fastened toward the bottom of a cavity (48a) by a cylindrical fastening member (64) screwed to the cavity (48a).
Full Text This invention relates to a mass transfer tray in which a liquid is contacted with a counterflow of gas. This may be for a variety of purposes such as stripping a component from the liquid stream or absorbing a component into a liquid stream. More generically this invention relates to equipment designed to facilitate mass and/or heat transfer between phases.
The type of equipment to which this invention specifically relates employs cross-flow fractionation trays connected by downcomers. In such equipment a tower is provided with a plurality of fractionation trays arranged generally horizontally within the tower. Each tower has a perforated deck and at least one channel, called a downcomer, in which a liquid flowing over the deck may be collected and channeled to the tray below. In use a gas or vapor is introduced at the base of the tower and passes upwards through the perforations in the decks of the franctionation trays. Meanwhile a liquid is introduced at the top of the tower and percolates downward passing over the franctionation trays and down the downcomers to the tray below.
Upon reaching the tray, the liquid flows across the tray in what is
described here as the "design flow direction", which indicates the direction the
liquid is intended to flow when the tray is operating in optimum design
conditions. The tray is provided with a plurality of perforations through which
the gas bubbles continuously at a pressure that, under normal operating
conditions, precludes the liquid from passing through the perforation. These
perforations, in conjunction with the associated covers, are referred to as
"valves" and are designed to permit efficient mass transfer contact between the
gas and the liquid. These valves fall into two major groups; fixed and movable.
The fixed valves have no moving

parts and the movable are adapted to respond to the pressure of the up-flowing gas by opening or closing the valve. The present invention relates to fixed valves.
In the ideal process design, the liquid should be prevented from passing through the valves in the trays by the pressure of gas passing through the perforations in the upward direction. This is a finely balanced process since, if the pressure is too great, the gas will have a shorter transit time within the tower and less efficient contact with the liquid as it flows across the trays and down the tower. The high gas velocity may also cause liquid droplets to be carried up to the tray above, thereby reducing the separation efficiency as a result of back-mixing. On the other hand if the gas flow rate is too low the liquid will penetrate through the valves in the trays, (known as "weeping"), and short-circuit the flow patterns which are intended to maximize liquid/gas contacts.
Some movable valve designs actually allow the valve to close if the pressure drops too low. Such valves can however cause problems if they stick closed or only partially open. They are also expensive. Other (fixed) valve designs merely place a cover over a perforation in the tray deck to prevent liquid falling on to the perforation with sufficient velocity to penetrate even when the pressure is at design levels.
In a typical movable valve, a perforation (for example a round hole) is stamped out of the material of the tray. This is then typically covered by the stamped-out shape, (a metal disc in the example), supported on legs or perhaps in a cage where the valve is meant to open and close with the gas pressure. Where the cover is supported on legs that move within the perforation so that the cover is adapted to rise or fall with the pressure, it is often found that, when a pressure surge or excessive vibration occurs, the whole valve pops out of the tray and is thereafter permanently open. Also

problems can readily occur if the valve sticks either open or closed.
In a typical fixed valve construction, the cover is made from the material of the tray. This is usually done by cutting a pair of slits and deforming the surface of the tray upwards so as to create a perforation and a cover for the perforation at the same time. Such a fixed valve construction is described in USPP 5,463,425 and 3,463,464. As will £e seen, in such fixed valve constructions the dimensions or the aperture dictate the dimensions of the cover which, because of the deformations or cutting process, will barely cover, or not completely cover, the aperture. In addition, it is not possible to create apertures with advantageous shapes that are different from those of the cover. It is for example impossible to provide a round aperture by the standard deformation technique or, using the material removed when the aperture is cut, a quadrilateral cover that will completely cover the aperture. It is also impossible to shape the orifice to create a venturi effect by punching through the material of the tray from the top to create a relatively narrow orifice opening at the bottom which opens into a wider channel at the top surface of the tray. It has been found that venturi effects are often desirable features of fixed valves.
The disadvantage of such prior art methods is that the shape of the perforation dictates the shape of the cover-There are therefore limitations that are inherent in the production process. The present invention provides a way of making mass transfer contacting devices in which the shapes of the perforation and cover can both be manipulated to produce the optimum process advantage and efficiency of operation of the device.
The present invention provides a simple mass transfer contacting device that can easily be installed and which provides a highly effective means of contacting liquid flowing

over and around the valve with gas flowing up through the valve. Equally importantly, the design is such that the size and shape of the perforations and the covers can be independently optimized for the specific application. In addition there are no moving parts to the valve that might stick or fail to function appropriately and they can be sized to fit any perforation.
General Description of the Invention
The present invention provides a fractionation tray having at least one perforation therein and a design flow direction in the vicinity of said perforation and, spanning the perforation, a bridge member comprising first and second support legs connected by a cover member oriented in the design flow direction in the vicinity of the perforation and wide enough to completely cover the perforation at all rioints, the legs being adapted to be releasably affixed to the tray so as to span the perforation, the first leg being a solid member located upstream of the perforation in the design flow direction and having a width that is at least 5% wider, and preferably at least 10% or 20% wider, than the greatest width of the perforation transverse to the design flow direction.
The other support leg can also be a solid member though this is not an essential feature. It can for example comprise a plurality of vertical support elements that together constitute the second leg of the bridge member. The overall width of the second leg, however constituted, is preferably at least 10%, and preferably at least 201 narrower than that of the first leg.
The leg of the bridge member that is located downstream in the flow direction is preferably provided with one or more apertures passing through the wall. These may be provided by holes cut in a solid member or they may be created;in effect by having the leg comprise two or more vertical support members separated by a space or spaces which provide the

aperture(s). In use a portion of the gas flowing up through the perforation passes through the apertures to minimize any opportunity for liquid hold-up adjacent the surface of the leg. It is also possible to provide, in place of or in addition to such apertures, that the width of the leg be reduced till it is narrower than the widest dimension of the orifice at right angles to the flow direction. This has the same effect of reducing any liquid holdup in the region of the downstream leg
The legs of the bridge member preferably terminate in tabs that are adapted to cooperate with slots cut into the deck to anchor the bridge member in place. The tabs may then be bent over to prevent ready removal of the bridge member. Alternatively other means of achieving the same objective may be provided. For example the tabs may be provided with aligned holes to accommodate a rod passing through both, or each tab may twisted slightly on the underside of the tray such that the tabs are no longer aligned with the slots through which they pass.
The cover member connecting the legs may be a simple
horizontal, flat plate or it may be provided, at least on the
underside, with a rib member aligned along the design flow
direction. The purpose of the rib would be to direct the flow
of gas arising through the perforation out to the sides. In
other embodiments the cover member can comprises a plurality
of components that together serve to protect the perforation
against access of liquid approaching the perforation from
above. Thus the cover member may for example comprise two
plates that together form a cover with a V shaped, {or
inverted V), cross-section in the design flow direction. It
is preferred that the cover member, at all points, be at least
10% wider than the width of the perforation at the point
directly below it. ;
The cover member can also be provided with an aperture shaped such that a flow of gas through the aperture is

directed essentially horizontally and in the design flow direction. The aperture can be created for example by making a slit in the cover member parallel to plane of the first leg and deforming the side of the slit nearest the first leg upwards. In use such an arrangement is particularly useful if the valve is located under a downcomer such that a liquid flow falls directly on to the cover member. Such a slit aperture helps initiate liquid flow in the desired design flow direction.
The cover member can be horizontal but it is often preferred that it is tilted such that the end adjacent the first leg member, that is the upstream leg in terms of the design flow direction, is higher than the end adjacent the second or downstream leg. This has the effect of creating higher pressure at the upstream end of the valve and lower pressure at the downstream end, thus encouraging and enhancing the flow in the design flow direction. The extent of the tilt is a matter for optimization depending on the desired volume and speed of the liquid flow in the design flow direction. However it is often preferred that the first support leg is at least 5% longer, such as from about 5 to 25% longer, than the second support leg.
The perforation in the tray deck can have any convenient shape and this includes round, elliptical and polygonal. Venturi perforations in which the perforation is made by punching out a suitable shape, usually round, and usually in the downward direction, are particularly advantageous for use. with the bridge members of the present invention.
In use a liquid flowing in the design flow direction across the deck encounters the first leg member. Since this leg is solid, the liquid flow is split and directed to either side of the perforation. As it passes on either side of the perforation it encounters gas flowing at right angles to the direction of flow of the liquid. This makes for very efficient gas/liquid contact. The different flow directions

also make unlikely any weeping of liquid through the perforations. Because the cover member is preferably at least 10% larger than the perforation at all points, the gas flow directing effect is increased and the possibility of weeping is reduced.
The valves are usually arranged in staggered arrays such that each row of valves across the flow direction is staggered with respect to the valves in the rows in front and behind such that they lie, (with respect to the flow direction), between pairs of adjacent valves in these rows.
Drawings
Figure 1 is cross-section of a valve according to the
invention.
Figure 2 is a plan view of the valve shown in Figure 1.
Figure 3 is a flat plate than can be bent to provide the valve
cover shown in Figures 1 and 2.
Figure 4 is cross-section of a valve according to the
invention showing legs of different length and a flow
directing aperture in the cover member.
In the Drawings the design flow direction is from right to
left.
Detailed Description of the Invention
The invention is now further described with reference to the Drawings which are intended to illustrate the invention but are not to be understood as implying any essential limitations on the scope of the invention.
The device illustrated in Figures 1 and 2 comprises a bridge member spanning a perforation, 6 in the tray, 5, and comprising first and second legs, 1 and 2 respectively, connected by a cover member, 3. The legs terminate in tabs, 4, which pass through slots, 7, cut in the tray, 5.. The tabs below the level of the tray are bent over to prevent removal of the bridge member.

Figure 3 shows a flat metal plate stamped to provide a bridge member according to the invention when bent along the dotted lines to form first and second legs. The aperture, 8, in the narrower of the two legs, (the downstream leg), is intended to allow a gas flow through the aperture to minimize liquid buildup on the downstream face of the leg.
In Figure 4 leg, 1, is longer than leg, 2, such that the cover member, 3, slopes downward towards the second leg. The cover member also has a directing slot, 8, formed by cutting a slit in the cover member and deforming the side of the slit adjacent the first leg upwards.
In use the first leg of the bridge member is located at right angles to the design flow direction. Thus liquid flowing across the tray encounters the face of the first leg and is deflected sideways and around the perforation. This slows down the flow and ensures that the contact of gas with liquid, other than the gas flowing through the apertures in the second leg, will be essentially at right angles.
The legs shown in the drawings are of equal height but this is not an essential feature and indeed often the cover member is preferred to slope downwards towards the second leg. For example it may be advantageous to provide that the first leg is longer than the second to intercept more of the flow and to minimize the risk of significant amounts of the liquid washing over the bridge member and by-passing the gas contact zones on either side of the bridge member.
In operation a tray has a large number of perforations which are usually circular, though other shapes such as elliptical and even polygonal are usable. The preferred locations of the perforations on the tray is in lines across the design flow direction with adjacent lines staggered such that the perforations in one line are between pairs of perforations in the lines on either side along the. design flow direction. This ensures that the flows are repeatedly split

and combined to ensure that no flow of liquid develops that is not contacted by the up-rising gas.
The performance of the mass transfer contacting device illustrated in Figure 1 of the drawings was compared with a standard single weight movable valve with the same perforation dimensions, in identical tray environments and under identical liquid flow conditions. The prior art movable valve comprised a flat cover larger than the perforation and provided with three peripherally and uniformly spaced legs extending perpendicular to the cover and below the lower surface of the tray with stops at the lower extremities to prevent the cover rising beyond a pre-determined point.
It is found very useful to compare the "flood point" for each device at a range of gas flow rates. The flood point is reached when the integrity of the liquid and gas flows are lost and the tower fills up with liquid. Thus the flood point defines an extremity of the permitted operating range for a tray. The flood point for the device according to the invention was compared with the standard prior art valve at a range of gas flow rates. The measured flood point figures for the two devices are shown in the Table below.
It is also useful to compare the performances at the opposite end of the permitted operating range, that is the required pressure drop across the tray at low gas flow rates before the valves of the prior art close and no longer permit mixing or where excessive weeping makes the device according to the invention ineffective.
In the following Table the ratio of the quoted parameter for the invention device to the same parameter for the prior art movable valve at the same liquid flow rate is given. In general, for AP, smaller is better and for Fp, higher is better. In general it will be seen that the performance of the valve of the invention is as good as, or better than, that of the best prior art valve.


"LFR" means the normalized, liquid flow rate in. liters per
minute per centimeter of weir. The "LFR RATIO" is the ratio
of the actual flow rate to the lowest flow rate used.
"AP" means the pressure drop across the tray in cm of water.
"Fp" means the normalized gas flow rate in cm/second based on
the active bubbling area.
"Lowest" and "Highest" refer to the indicated performance
parameters at the opposed ends of the permitted range of gas
flow rate and pressure drop for a given liquid flow rate in
the standardized test tower used in the evaluations.
From the above data it can be seen that at lowest gas and liquid flow rates, the device according to the invention performed rather more efficiently than the conventional closable valve since lower pressure drops and gas flow rates were possible for efficient operation.
Perhaps more importantly the device according to the invention operates at higher rates and with much lower pressure drops before reaching the flood point.
In a second series of tests the same fixed valves of the invention used in the first series of comparisons were compared with fixed valves made by deformation of the tray

material to form a trapezoidal bridge member of essentially the same dimensions as the bridge member in the present invention as illustrated in the drawings. This valve is described in USP 3,463,464. The difference is that the shape of the perforation in the prior art valve is dictated by the shape of the bridge member. As in the previous comparisons, the orientation and spacing of the valves on the tray were the same and the materials used, and the gases and liquids contacted were also the same. The results obtained were as follows:

The above performance advantages were obtained in tests in which the devices performed in trouble-free mode. However in the real world the prior art movable valves frequently cause problems by sticking either open or closed. The absence of moving parts together with the retention of an equivalent normal operating range is a great advantage for the devices of the invention in that such problems with sticking valves are totally eliminated.


WE CLAIM:
1. A mass transfer tray (5) having at least one perforation (6) therein and a design flow direction in the vicinity of said perforation and, spanning the perforation, a bridge member comprising first and second support legs (1, 2) connected by a solid cover member (3) oriented in the design flow direction in the vicinity of the perforation and completely covering the perforation (6), the legs (1, 2) of said bridge member capable of being attached to the tray so as to span the perforation (6), the first leg (1) being a solid member located upstream of the perforation in the design flow direction and having a width that is at least 5% wider than the greatest width of the perforation (6) transverse to the design flow direction.
2. The mass transfer tray as claimed in claim 1, wherein the first leg (1) is at least 10% wider than the greatest width of the perforation (6) in the design flow direction.
3. The mass transfer tray as claimed in claim 1, wherein the support leg (1) is longer than the second support leg (2) such that the cover member slopes downward in the design flow direction.
4. The mass transfer tray as claimed in claim 1, wherein the support legs (1, 2) of the bridge member are provided with tab extensions (4) cooperating with openings in the tray to provide attachment means for holding the bridge member in place over the perforation.

5. The mass transfer tray as claimed in claim 1, wherein the second support
leg (2) is provided with apertures (8) passing through the leg.
6. The mass transfer tray as claimed in claim 1, wherein the first and second
support legs (1, 2) are of equal length.
7. The mass transfer tray as claimed in claim 1, wherein the perforations (6)
are Venturis.
8. The mass transfer tray (5) as claimed in claim 1, wherein the perforation has a different shape from the cover member (3) and the first support leg (1) is at least 5% wider than the perforation (6) at any point transverse to the design flow direction and at least 5% longer than the second support leg (2).
9. The mass transfer tray (5) as claimed in claim 1 or 8, wherein the cover member (3) is provided with an aperture (8) designed to direct a gas flowing therethrough horizontally in the design flow direction.

Documents:

201-mas-1998 abstract-duplicate.pdf

201-mas-1998 abstract.pdf

201-mas-1998 assignment.pdf

201-mas-1998 claims-duplicate.pdf

201-mas-1998 claims.pdf

201-mas-1998 correspondence-others.pdf

201-mas-1998 correspondence-po.pdf

201-mas-1998 description (complete)-duplicate.pdf

201-mas-1998 description (complete).pdf

201-mas-1998 drawings.pdf

201-mas-1998 form-19.pdf

201-mas-1998 form-2.pdf

201-mas-1998 form-26.pdf

201-mas-1998 form-4.pdf

201-mas-1998 form-6.pdf

201-mas-1998 petition.pdf


Patent Number 208461
Indian Patent Application Number 201/MAS/1998
PG Journal Number 39/2007
Publication Date 28-Sep-2007
Grant Date 31-Jul-2007
Date of Filing 02-Feb-1998
Name of Patentee M/S. KOCH-GLITSCH,LP
Applicant Address 4111 EAST 37TH STREET , WICHITA,KANSAS 67220.
Inventors:
# Inventor's Name Inventor's Address
1 RICHARD P HAUSER BRUCE TAYLOR 4111 EAST 37TH STREET , WICHITA,KANSAS 67220.
PCT International Classification Number B 01 D 03/22
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 08/792,348 1997-02-05 U.S.A.