The present invention relates generally to a system and method for generating acetylene from calcium carbide, and more particularly to a system and method for recovering acetylene gas that would otherwise be lost during the commercial production of acetylene.
It is known to generate acetylene from calcium carbide by the hydrolysis of the calcium carbide at elevated temperatures. Care must be taken to avoid introducing free oxygen into the hydrolysis reaction, so commercial acetylene generators use an inert gas, such as nitrogen, to purge the calcium carbide mixture of air before introducing the calcium carbide to the reaction vessel. After the calcium carbide mixture is purged of air in a purge hopper, the calcium carbide and nitrogen are transferred to a generator where they are mixed with water at an elevated temperature to generate acetylene. The transfer of calcium carbide and nitrogen to the reaction vessel results in the simultaneous transfer of some acetylene gas back into the purge hopper. In prior art acetylene generation methods, this acetylene is vented to the atmosphere during a post-transfer purge step to prepare the purge bin for a subsequent batch of calcium carbide.
A need currently exists for a system and method for recovering at least some of the acetylene that would otherwise be lost to the atmosphere during the post-generation purge. The present invention addresses that need.
Briefly describing one aspect of the present invention, there is provided a method for generating acetylene from calcium carbide and recovering acetylene that would normally be lost during the process. The method comprises providing acetylene gas generation equipment including a batch hopper, a purge hopper, a feed hopper, an acetylene generator, and an acetylene recovery chiller. Solid calcium carbide is provided to the batch hopper, and air filling in around the solid material causes the batch hopper to contain calcium carbide and air. The batch hopper may be purged with a purge gas in a quantity sufficient to purge the batch hopper of air and to cause said batch hopper to contain calcium carbide and purge gas, but to be substantially free of oxygen. The solid calcium carbide and purge gas are transported to the purge hopper to provide a purge hopper containing a mixture comprising calcium carbide and purge gas. The purge hopper is purged with a purge gas to provide a purge hopper containing a mixture comprising calcium carbide and the purge gas. The solid calcium carbide and purge gas are transported to a feed hopper to provide a feed hopper containing a mixture comprising calcium carbide and purge gas. The solid calcium carbide and purge gas are transported from the feed hopper to the acetylene generator, which includes an aqueous bath for generating acetylene gas by the hydrolysis of calcium carbide. Acetylene gas is generated, and some of the generated acetylene gas moves from the acetylene generator into the feed hopper and the purge hopper, where that acetylene gas mixes with the purge gas to form a combined gas. On purging this combined gas from the purge hopper, the combined gas is passed through a chilled absorption liquid to absorb therein at least some of the acetylene gas from the combined gas without substantially absorbing the purge gas. At least some of the absorption water with acetylene absorbed therein is transferred to the aqueous bath of acetylene generation chamber. The aqueous bath comprising absorption water with acetylene absorbed therein is thereafter used to hydrolyze a subsequent batch of calcium carbide. The method reduces the amount of VOC vented to the atmosphere, and increases the amount of acetylene available for recovery.
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to certain preferred embodiments and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, such alterations and further modifications in the illustrated device, and such further applications of the principles of the invention as illustrated therein being contemplated as would normally occur to one skilled in the art to which the invention relates.
As indicated above, one aspect of the present invention relates to a method for generating acetylene from calcium carbide and recovering acetylene that would normally be lost during the process. In this aspect of the invention, bulk solid calcium carbide is put into a batch hopper for an acetylene generation plant. It is understood that the portion of granular carbide introduced into the batch hopper bin will typically include air, which contains oxygen. The air introduced with the solid carbide into the batch hopper is then purged with a purge gas until substantially all of the oxygen is removed from the purge bin. The solid calcium carbide is then transferred to a purge hopper where the resident gas is purged and vented to an acetylene recovery chiller as more fully described below. The calcium carbide is then transferred to a feed hopper before being introduced into a hot aqueous bath in an acetylene generation chamber. Acetylene is generated in the acetylene generation chamber by the hydrolysis of the calcium carbide. The bulk of the acetylene is then recovered by standard methods.
The process is then repeated with a new batch of calcium carbide. The new batch of solid calcium carbide is put into the purge bin of the acetylene generation plant, and the purge bin is purged with a purge gas to remove substantially all of the resident gas from the purge bin. The solid calcium carbide is then transferred to a feed hopper before being introduced to the hot aqueous bath in the acetylene generation chamber. However, when these subsequent charges of solid calcium carbide are transferred into the acetylene generation chamber, a portion of the acetylene gas in the chamber typically moves back into the purge bin where it mixes with the purge gas.
In the prior art, that acetylene would simply be vented to the atmosphere from the purge hopper and lost. According to the present invention though, the acetylene and purge gas mixture is passed from the purge hopper into a cold absorption fluid (which may be water) so that the absorption fluid can absorb some of the acetylene gas. Most preferably, the acetylene and purge gas mixture is passed through cold absorption water by bubbling the mixture through the water. The absorption fluid is selected to be a fluid in which acetylene is more soluble than nitrogen, thus causing the acetylene to be preferentially absorbed into the fluid, leaving the nitrogen substantially not absorbed.
It is to be appreciated that while this description refers to the acetylene (or the nitrogen) as being “absorbed” into the fluid, the gas(es) may more accurately be said to be dissolved into the fluid. For the purposes of this disclosure therefore, the terms may be used interchangeably, with the system and methods of the present invention causing the acetylene to be preferentially absorbed/dissolved into the absorption fluid, while leaving the nitrogen substantially unabsorbed/undissolved.
It is also to be appreciated that while this description refers to the acetylene (or the nitrogen) as being absorbed into an “absorption fluid” or into “water”, those terms are generally used interchangeably to indicate an absorption fluid that may be water. The use of the term “water” is not to be construed to exclude other absorption fluids, and the term “absorption fluid” is not to be construed to exclude water.
The absorption water and dissolved acetylene may then be transferred back to the aqueous bath. The return of absorption water and acetylene into the aqueous bath of the acetylene generation chamber causes less acetylene to be absorbed into the aqueous bath during the acetylene generation process, thus making more acetylene available for recovery. The loss of acetylene into the generator water during the generation process is minimized since the generator water is now richer in acetylene. The acetylene that is provided by the acetylene recovery process offsets acetylene that would otherwise be lost to the generator water, thus allowing that acetylene to be recovered from the generator.
The released acetylene is thereafter recovered by physical separation of the acetylene gas from the aqueous bath, as occurs with newly generated acetylene. In particular, the lighter acetylene gas is piped away from the top while the heavier aqueous bath remains below.
The acetylene generation bath containing recycled acetylene absorption water (and some dissolved acetylene) may subsequently be used to hydrolyze another batch of calcium carbide. The recovery may occur after the aqueous bath has been used to hydrolyze a subsequent batch of calcium carbide, or it may occur before the aqueous bath has been used to hydrolyze a subsequent batch of calcium carbide.
In some embodiments of the inventive system and method the solid calcium carbide is provided to a top, fill bin of a multi-bin carbide feed system of an acetylene generation system before being transferred to the purge bin. As when the calcium carbide is initially provided directly to a purge bin, air typically fills the space around the calcium carbide in the fill bin.
The calcium carbide and air may then be transferred to a middle, purge bin of the carbide feed system. Vibratory or screw feeders may be used to assist the transfer.
Once the calcium carbide has been provided to the purge bin, a purge gas is used to flush acetylene from the purge bin. The purge gas may be substantially any gas that doesn't contain oxygen or another species that would be detrimental to the acetylene generation process or the equipment or personnel, with nitrogen being most preferred due to its effective performance and low cost.
The carbide/nitrogen mixture may then be fed to the acetylene generation chamber. As with the transfer of calcium carbide to the purge bin, vibratory or screw feeders may be used to assist with the transfer. When the acetylene generation chamber has previously been used to generate acetylene, and when some of that acetylene remains in the acetylene generation chamber, the filling action displaces acetylene from the acetylene generation chamber and that acetylene gas enters the purge bin where it mixes with nitrogen. At this point the now “empty” purge bin contains an acetylene/N2 atmosphere.
The acetylene/purge gas mixture must be purged before refilling with more calcium carbide from the fill bin. The method of the present invention accomplishes that purge step with reduced losses of acetylene. In particular, the acetylene and purge gas mixture is passed through cold absorption water that absorbs some of the acetylene gas but leaves the purge gas substantially not absorbed. The absorption water and dissolved acetylene may then be transferred back to the aqueous bath where the temperature of the generator water increases the temperature of the absorption water. The acetylene in the absorption water offsets acetylene that would otherwise be absorbed into the generator water, thus allowing generated acetylene to be recovered with less loss to the generator water. The acetylene generation bath containing recycled acetylene absorption water (and some dissolved acetylene) may subsequently be used to hydrolyze another batch of calcium carbide.
A series of valves is preferably used to control the flow of materials in the system. In particular, the purge bin preferably includes a top (fill) valve and a bottom (feed) valve. In the embodiments in which a fill bin is used, the fill bin also may include a top (fill) valve and a bottom (feed) valve.
As to the function of the valves, and particularly as to the function of the valves in the purge bin, the top (fill) valve is open and the bottom (feed) valve is closed while solid calcium carbide is being loaded into the bin. Then, the top valve is closed while the air in the purge bin is purged and replaced with the purge gas. Once the purge bin is purged, the bottom valve is opened to allow the solid calcium carbide and attendant purge gas to move to the acetylene generation chamber.
When a fill bin is used, the top (fill) valve of the purge bin is opened (the bottom valve was closed before purging) and carbide is allowed to drop from the top (fill) bin filling the purge bin. This displaces N2 from the purge bin into the top (fill) bin. Once the top (fill) bin is empty, the purge bin top (fill) valve is closed and the purge bin is now ready for the next bottom (feed) bin fill cycle. The top bin is now empty and ready for filling from the carbide storage silo (which is also N2 purged). This is done using a similar cycle to that described for the purge bin except that now there is no acetylene.
Referring now to the Figures,
The absorption water and dissolved acetylene is then transferred back to the aqueous bath where the temperature of the absorption water increases by contact with the hot acetylene generation bath. Since the hot acetylene generation bath will typically hold less than about 1 g of acetylene per kg of water, this releases at least some of the acetylene that was dissolved in the absorption water. The released acetylene provides additional acetylene to the acetylene generation bath, and thus provides an acetylene generation bath that will thereafter hold less acetylene that it would hold if additional acetylene were not recycled back into the bath. This reduces the amount of generated acetylene that will be absorbed into the acetylene generation bath, thus making more of the generated acetylene available for recovery.
In the most preferred embodiments, the acetylene generation bath containing recycled acetylene absorption water is thereafter used to hydrolyze a subsequent batch of calcium carbide. The recovery of acetylene may occur before or after the subsequent acetylene generation.
The carbide/nitrogen mixture is then fed to the acetylene generation chamber using either vibratory or screw feeders. The filling action displaces acetylene from the bottom bin which mixes with the nitrogen from the purge bin so that the now empty purge bin contains an acetylene/N2 atmosphere. This must be purged before refilling with carbide from the top bin. The method of the present invention accomplishes that purge step with reduced losses of acetylene.
Once purged, the top (fill) valve of the purge bin is opened (the bottom valve was closed before purging) and carbide is allowed to drop from the top (fill) bin filling the purge bin. This displaces N2 from the purge bin into the top (fill) bin. Once the top (fill) bin is empty, the purge bin top (fill) valve is closed and the purge bin is now ready for the next bottom (feed) bin fill cycle. The top bin is now empty and ready for filling from the carbide silo (which is also N2 purged). This is done using a similar cycle to that described for the purge bin except that now there is no acetylene.
Screw feed 105 delivers the carbide, nitrogen and air material to batch hopper 110. Batch hopper 110 is under a continuous nitrogen purge through dry nitrogen purge inlet 111. Batch hopper 110 vents to the atmosphere through vent 112. When batch hopper 110 contains a full batch of nitrogen-purged carbide, screw feed 105 is turned off and batch hopper discharge valve 115 is in its ‘closed’ position.
As this point the purge hopper 120 preferably contains a partial batch of carbide and purge hopper discharge valve 125 is open. Purge hopper 120 is under a continuous nitrogen purge through dry nitrogen purge inlet 121, and vents to the chiller/water tank 40 (see
Feed hopper 130 preferably contains a full batch of carbide and is choked with carbide from the purge hopper through open discharge valve 125. Discharge valve 135 of feed hopper 130 is also open, allowing carbide to be drawn out and discharged into the generator.
The batch and purge bins continue to be kept under a nitrogen purge. It is to be appreciated that during the removal of carbide from the purge and feed hoppers the continuous nitrogen purge allows for make-up of the displaced carbide volume thus minimizing the tendency for acetylene feed-back from the generator.
The refilling portion of the purge hopper discharge and refilling cycle begins as batch hopper discharge valve 115 opens and nitrogen purged carbide drops from batch hopper 110 into purge hopper 120. As with the discharge portion of the purge hopper discharge and refilling cycle, when the carbide level in batch hopper 110 reaches a lower batch hopper level detector it starts a timer. After an appropriate time (e.g., after 60 seconds) the batch hopper is deemed to be empty and ready for refilling. Batch hopper discharge valve 115 now closes and its refilling cycle initiates.
Purge hopper discharge valve 125 now opens and carbide again chokes back into feed hopper 130. Batch hopper 110 simultaneously begins a refill cycle so that the batch hopper and the feed hopper refilling cycles take place at the same time.
The batch hopper and purge hopper are still under a continuous nitrogen purge. The generator “RUN” cycle may then repeat.
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiment has been shown and described and that all changes and modifications that come within the spirit of the invention are desired to be protected. Moreover, the invention encompasses embodiments both comprising and consisting of any or all of elements described with reference to the illustrative embodiments.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/782,538, filed Mar. 14, 2013, which is hereby incorporated herein by reference.
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1918479 | Milne | Jul 1933 | A |
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2293160 | Miller | Aug 1942 | A |
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Number | Date | Country | |
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20140275682 A1 | Sep 2014 | US |
Number | Date | Country | |
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61782538 | Mar 2013 | US |