The present invention relates to the field of conservation.
It is widely recognized that flue gases often contain heat and water. It is known to extract water from flue gas in water-constrained environments, for example, in the context of a desert-situated fossil-fuel-fired power plant. It is also known to extract heat from flue gas, for example, to pre-heat boiler feed make-up water. However, often only relatively modest amounts of heat can be extracted from flue gases using conventional technologies; if excess heat is extracted, condensation can occur, leading in many applications to the possibility of undesirable corrosion. As well, because of the relatively wide availability of water in areas where flue gases are likely to be found, i.e. inhabited areas, the recovery of water from flue gas using known processes is rarely economic.
Forming one aspect of the invention is a process for use with a relatively moist flue gas. The process comprises the steps of:
The process is characterized in that:
In the process:
Forming another aspect of the invention is apparatus for use with a flue gas, a supply of liquid and a flow of brine, the brine being adapted to exothermically absorb moisture from the flue gas to produce heat.
The apparatus comprises: a flue; a vessel which, in use, receives liquid from said supply and which has an interior including a headspace, the vessel being disposed within the flue in spaced relation to define a flow channel between the vessel and the flue and through which the flue gas passes in use; a distributor which, in use, receives the brine and channels same to the flow channel; a plurality of heat pipes each leading between the flow channel and the interior of the vessel, the surfaces of the heat pipes operating in use in the manner of packing in a packed absorption column, thereby to facilitate the absorption of moisture from the flue gas and the generation of heat and weak brine, the heat pipes further withdrawing heat from the flow channel and delivering same to the liquid in the vessel to produce gas; a conduit for venting the gas from the headspace of the vessel; a collector for collecting the weak brine; and a regenerator for receiving the weak brine, regenerating the brine and producing a flow of water.
In the apparatus:
Advantages, features and characteristics of the present invention will become apparent upon review of the following detailing description, with reference to the appended drawings, the latter being briefly described hereinafter.
Reference is now made to
With reference to
The reservoir 20, flue 22, vessel 24, distributor 26, plurality of heat pipes 28 and conduit 30, which collectively define a stripping absorption module 36, are shown in detail in
Herein, it will be seen that this collector 20 takes the form herein of a shallow dish-shaped reservoir having a drain 38.
This flue 22 will be seen to include a stack 40 extending vertically from the collector 20, the stack 40 being defined by an annular wall 42 which forms an extension of the collector 20 and which has a gas inlet 44 defined therethrough adjacent the collector 20 and further has a a brine inlet 46 therethrough adjacent the top of the stack 40.
This vessel 24 is an obround with vertical sides 48 and is disposed in concentric, spaced relation to the stack 40 to define a flow channel 50 between the vessel 24 and the stack 40. Interior of the vessel 24 is a headspace 52. A liquid inlet 54 is provided near the base of the vessel 24, as indicated in
This distributor 26 is defined by a plate 56 and a plurality of chimneys 58. The plate 56 is annular and is disposed proximal to the top of the vessel 24 and beneath the brine inlet 46 to occlude the flow channel 50. The chimneys 58 each extend upwardly from the plate 56, to a height above the brine inlet 46. At the base of each chimney 58 is a gas passage 60 that extends through the plate 56. The surface of the plate 56 between the chimneys 58 is provided with perforations 62, to provide for fluid communication across the plate 56.
The heat pipes 28 are of the conventional type, i.e. each pipe 28 is a partially evacuated tube used for heat transfer and containing a working fluid. At the hot interface within a heat pipe, the working fluid, which is in liquid form, contacts a thermally conductive solid surface and turns into a vapor by absorbing heat from that surface. The vapor flows by one or more of diffusion and convection to a cold interface in the heat pipe, whereat it condenses back into a liquid, releasing the latent heat. The liquid then returns to the hot interface through either capillary action, wicking or gravity action where it evaporates once more and repeats the cycle.
These heat pipes 28 are arranged in layers 64, with each heat pipe 28 leading between the flow channel 50 and the interior of the vessel 24 and having the shape of the ogee, and the heat pipes 28 in each layer collectively defining a grid 66.
As best seen in
Although an onion dome is not shown, the portions of the grids that correspond to the upper part and lower part are indicated, respectively, by reference numerals 68,70 in
The arrangement of the heat pipes 28 is such that the vessel 24 projects above and below the plurality of heat pipes 28.
This conduit 30 extends through the sidewall 42 of the stack 40, proximal to the collector 20, thence upwardly through the base of the vessel 24, and thence interiorly of the vessel 24 to the headspace 52.
It will be understood that this exemplary apparatus can be used with a moist feed gas, such as flue gas, with a supply of liquid and with a flow of strong brine adapted to exothermically absorb moisture from the feed gas to produce heat.
In use:
Reference is now made to
Herein, portions of an ethanol plant are shown.
With initial reference to that portion of
In use, the distillation columns 74, 76 which form part of the ethanol refining system (not shown) are arranged, with the beer column 72, for multiple effect distillation, i.e. positive pressure stream is used to drive the first column 74; vapors from the first column 74 are used to drive the second column 76; and vapors from the second column 76 are used to drive the beer column 72. Whole stillage from the bottom of the beer column 72 is pumped to the dewatering facility 78 and separated into syrup and cake which is transferred to the rotary drier 80, to produce DDGS and offgas. The offgas passes through the oxidizer 82, to remove aromatics. In a conventional facility (not shown), fuel such as natural gas would be used to provide the positive pressure steam to the first column, and a condensing heat exchanger would be used to capture heat from flue gases exiting the thermal oxidizer. In the exemplary embodiment, this functionality is instead provided by the balance of
Whereas specific exemplary embodiments are described and illustrated, it will be appreciated that the invention is not so limited.
Rather, the invention should be understood as advantageous in the context of any application wherein there exists:
The flue gas should have a minimum moisture content of about 12 wt. %; at concentrations significantly below this, the energy associated with the latent heat of the contained water vapor will normally be insufficient to maintain the temperature of the absorber at 220° F., and below this temperature, useful steam heat will not normally be available.
Persons of ordinary skill will readily appreciate the manner in which the invention can be deployed in other applications and accordingly, a detailed description is neither required nor provided. However, it will be appreciated that, at elevated temperatures, absorption capacity of LiBr brine falls off; accordingly, it will be expected that the stripping absorption module will normally be designed to operate in the 220-300° F. range. As well, LiBr brine has a tendency to crystallize at elevated concentrations, which could cause facility damage; for this reason, the strong brine will normally be designed to enter the SAM at no higher than 70 wt. % LiBr.
By adjusting the flow rate of the brine, the equilibrium temperature of the strong brine at the top of the absorber and the equilibrium temperature at the bottom of the absorber can be the same and the temperature of the brine as it passes through the absorber can be substantially constant, i.e. within about 2 F. Without intending to be bound by theory, it is believed that this has advantage in terms of heat exchange efficiency, as heat exchangers in general are most efficient use under constant temperature differential conditions.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CA12/00209 | 3/7/2012 | WO | 00 | 1/17/2014 |
Number | Date | Country | |
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61450405 | Mar 2011 | US | |
61450923 | Mar 2011 | US |