REF IGERANT RECYCLING SYSTEM
Background of the Invention
The collection or capture of gaseous refrigerants to be evacuated from refrigeration systems is often not practiced due to the lack of suitable available commercial equipment or convenient methods. Although the use of fluorocarbon or CFC refrigerants are intended to be gradually phased out because of atmospheric and environmental pollution, even with the use of other gaseous refrigerants including hydrogen, nitrogen or polarized gaseous refrigerants such as ammonia, water, methanol, methylamine, sulfur dioxide, and the like, release of such materials into the atmosphere is environmentally and economically undesirable and may be prohibited by law. Similarly, the temporary evacuation or purging of toxic gases from chemical systems to avoid atmospheric pollution, or to prevent the loss of valuable or expensive gases, are of substantial interest, but practical systems for such uses are not presently available. Summary of the Invention
The system of the present invention is directed to an apparatus for being permanently or selectively installed with a refrigeration or chemical system whereby a gas may be evacuated from the system and adsorbed on a solid adsorbent material, and later- desorbed and returned to the system, if and when desired. In one embodiment, the invention comprises a portable system incorporating a pressure holding vessel for adsorbing the gas therein and includes means for selectively desorbing the gas for return to the refrigeration or chemical system. In another embodiment, the invention comprises a vessel having the gas adsorbing and desorbing capability which may be permanently installed with a system for selectively capturing the gas and for returning it to the system when desired. The advantages of a system and apparatus of the present invention include providing means for evacuating the gas from a refrigeration or chemical system, for example, when a leak
is detected or during repair or modification of the system during which removal of the gas is desired. Such evacuation may be initiated automatically utilizing suitable monitoring and valve engaging means, or accomplished manually. These, as well as other features and advantages of the invention, will be evident from the following detailed description. Brief Description of the Drawings
Figure 1 is a schematic view of the interior of an apparatus according to the invention illustrating components and features thereof; and
Figure 2 is a partial view of an example of a heat exchange conduit as used in the apparatus with solid adsorbent disposed in heat exchange relationship with the conduit. Detailed Description of the Invention Although the present invention will be primarily described for the capture of gaseous refrigerants, particularly polarized gases, and especially ammonia, from refrigeration systems, it is to be understood that it may be useful in broader applications, as will be explained hereinafter. Referring to Figure 1, there is shown a schematic illustration of the components and features of an apparatus of the invention. The vessel 10 defines an interior chamber 11 capable of maintaining a pressurized gas. Within the interior chamber are a plurality of conduits or pipes 24 which extend exteriorly of the vessel to be connected to a source of heat exchange fluid, typically water. Any number of interior pipes may be used, depending on the size of the vessel, with the latter being of a number and size depending on the amount of refrigerant gas which is to be received and adsorbed when the system is used. The plurality of heat exchange pipes 24 are secured to a common inlet header or manifold 25 which may be interior or exterior to the vessel wall 10. Secured to header 25 is an inlet pipe 20 and valve 22 for being attached to a source of heat exchange fluid. The inclusion of valve 22 on the inlet line is optional, and instead, a coupling or connection means for simply securing the inlet pipe to a source of hot or cold water, which source
is usually valved, is also suitable. Each of the heat exchange pipes is also connected to an outlet header or manifold 35 interiorly or outside of the vessel walls. The manifold is connected to an exterior pipe or outlet line 30, which also may be provided with a valve 32.
A refrigerant gas inlet pipe 12, which also may have a valve 14 and/or coupling means for securing the inlet pipe to a refrigeration system line or conduit, extends exteriorly of the vessel 10 and provides the passageway for introducing and discharging a gaseous refrigerant to and from the apparatus.
The refrigerant gas inlet pipe 12 communicates with the interior chamber 11 of the vessel 10 so that the refrigerant gas may be directly introduced into the vessel when the valve or connection means is tapped into a gas line of a refrigeration system. Also shown extending from inlet pipe 12 is an accessory conduit or nipple 15, which may be provided with a valve or other shut-off means, for securing a pressure line from a pump or compressor. Although an accessory compressor or pump or other source of pressurizing the vessel may be installed as component of the apparatus, it is an optional feature since it may not be necessary to utilize pressure or suction assist where the refrigeration system to which the apparatus is connected has sufficient compressor capacity or where sufficiently high temperature heat can be supplied to the vessel to raise the temperature.
Secured in heat exchange communication with each of the pipes 24 is solid adsorbent 18 capable of alternately adsorbing and desorbing gaseous refrigerant. The solid adsorbent is preferably fixed or positioned around and in contact with the heat exchange pipes as disclosed in co- pending application Serial No. 07/320,652 filed March 8, 1989, the description of which is incorporated herein by reference. Preferably, the pipes include heat transfer projections in the form of plates, fins, trays, or the like extending from and preferably attached along the length of each of the heat exchange pipes for improving heat exchange between the heat exchange fluid passing through the pipes and the adsorbent
material. Extending around the exterior of the solid adsorbent is a barrier 16 for retaining the solid adsorbent particles or mass in place around the pipes and in contact with the heat exchange plates or surfaces. It is important that this barrier material be porous to allow the passage of the gaseous refrigerant to and from the adsorbent. For this purpose, the barrier material may be wire mesh, porous foam or refractory material, inert fabric, and the like. An example of the heat exchange pipes on the interior of the apparatus is illustrated in Figure 2, showing a heat exchange pipe having a plurality of fins 26 extending there- around, with solid adsorbent 18 located between the fins and further surrounded by a mesh or gaseous permeable fabric 16. The embodiment shown is only one example of such a construction, and other ways and means for designing the shape of the heat exchange pipes within the interior of the apparatus and for positioning the solid adsorbent and heat exchange communication with the pipes in such a manner that the gaseous refrigerant introduced into the vessel is readily exposed to the adsorbent may be used within the purview of the invention for achieving the desired purpose and results.
The specific solid adsorbent or adsorbents used within the apparatus will depend on the nature of the gas to be received and adsorbed. Where polar gases such as ammonia, water, sulfur dioxide, lower alkanols, alkylamines, polyamines or phosphine are to be received, preferred solid adsorbents include metal oxides, halides, carbonates, nitrates, nitrites, sulfates, oxalates, or sulfides capable of forming coordinative bonds with the refrigerant. Particularly suitable for such solid adsorbents are those in which the metal of the salt is selected from the group consisting of alkali or alkaline earth metals, transition metals, aluminum, zinc, cadmium or tin. Preferred adsorbents are capable of adsorbing gaseous refrigerant at between about -30°C and about 60 β C, and can adsorb an amount of refrigerant corresponding to at least about 25% of the weight of the compound.
Of particular interest are the solid adsorbents for creating complex compounds for use with ammonia refrigeration systems. For that purpose, the solid adsorbent salts and complex compounds disclosed in U.S. Patent No. 4,848,944, the description of which is incorporated herein by reference, are particularly desirable. Within those groups, the preferred complex compounds comprise chlorides, bromides, sulfates and chlorates of metals selected from the group consisting of alkali and alkaline earth metals, chromium, manganese, iron, cobalt, nickel, cadmium, tantalum, and rhenium or double metal chloride salts. The preferred ammonia/salt complex compounds are those having an equilibrium temperature at 1 bar pressure at least 20 β C higher than the ammonia equilibrium temperature, and _>t greater than about 160 β C. Most preferred ammoniated complex compounds used in the apparatus of the invention are those selected from the group consisting of CaCl 2 -4-8 (NH 3 ) , SrCl 2 -l-8 (NH 3 ) , CaBr 2 -2-6 (NH 3 ) , SrBr 2 -0-8 (NH 3 ) , and LiCl■0-3 (NH 3 ) . Mixtures of these compounds may also be used. The solid adsorbent composition may also comprise a mixture of the complex compound and a solid inert material such as pumice, alumina silica, porous metal granulates, etc., especially porous and highly thermally conductive materials.
Where non-polar gases are to be adsorbed, zeolites or activated carbon may be used. Metal hydrides are useful for the adsorption of hydrogen used in certain refrigeration and chemical systems known in the art.
In operating a method utilizing the apparatus of the invention for receiving a gaseous refrigerant from a refrigeration system in which the refrigerant is to be withdrawn, for example, when necessary for repairs to the refrigeration system or its equipment, compressors, pumps, lines, and the like, the inlet pipe 12 and connector means 14 is connected to the refrigerant loop system at any suitable point, the heat exchange fluid inlet pipe 20 connected to a source of cooling heat exchange fluid, for example, water, and the outlet pipe 30 connected to a heat exchange fluid
discharge receiving means or drain. After the cooling heat exchange fluid has been passed through the heat exchange pipes for a time sufficient to cool the solid adsorbent to the desired temperature, valve 14 or other means for communicating the refrigeration system line to the gas inlet line 12 is opened. Because the adsorption reaction of the gaseous refrigerant with the solid adsorbent is exothermic, it is necessary or preferred to maintain an approximately constant temperature of the solid adsorbent during the time that the gaseous reactant is being introduced and adsorbed. By way of example, where ammonia is to be adsorbed on a solid adsorbent, for example, SrCl 2 , cooling fluid temperature ranges of between about 0 β C and about 25 β C at atmospheric pressure are used. The pressure within the adsorbent vessel may be adjusted as desired using the compressor of the refrigerant system being evacuated, or using an accessory compressor as previously described, or both. It will be understood that during adsorption, higher pressures will decrease the time requirements needed for adsorbing the gaseous refrigerant. The pressure of refrigerant systems encountered are typically between about 0.2 and about 20 bars, and often around 3 bars. During the adsorption, the pressure of the refrigerant in the system is reduced as adsorption occurs.
After the refrigerant has been effectively evacuated, the valve means between the.refrigeration system and the apparatus of the invention is closed, flow of heat exchange fluid into the apparatus terminated, and if desired, the apparatus may be disconnected. Thereafter, the apparatus may be stored with the refrigerant gas adsorbed on the solid adsorbent until it is desired to be recharged into the system from which it was removed or charged into another system.
When recharging of a refrigerant system is desired, the gas refrigerant inlet line 12 of the apparatus is secured into the refrigerant system line where desired, while heat exchange fluid is introduced into the heat exchange pipes of the apparatus. During this phase of using the apparatus, the
adsorbed refrigerant, is desorbed from the solid adsorbent by heating the solid adsorbent, thereby increasing the vapor pressure of the adsorbed gaseous refrigerant. If desired, the rate of the endothermic desorption reaction may be increased by reducing the pressure in the chamber of the vessel, for example, by pulling a suction on gas pipe 12 utilizing the vacuum side of an accessory compressor and/or the suction may be pulled from the compressor of the refrigeration system in which the gaseous refrigerant is being introduced. Again, constant temperatures of the heating fluid for desorbing the gaseous refrigerant is preferred. In an example using ammonia adsorbed on SrCl 2 , desorption temperatures of the heat exchange fluid and solid adsorbent between about 5°C and about 150 β C and preferably about 30 β C and about 125 β C are suitable. The use of a compressor for creating a suction in the line during the feedback of the gas into the refrigerant loop may not be required, although it should be understood that the lower the system pressure during desorption, the faster the rate of desorption. It has been found utilizing apparatus according to the invention for ammonia adsorption and desorption with SrCl 2 as the solid adsorbent, depending on pressure and temperature conditions, each adsorption and desorption phase can be completed in between about 15 minutes and about 2 hours. Again, lower coolingtemperatures during adsorption and higher heating temperatures during desorption accelerate the reaction to provide faster and more dramatic pull-down, or faster and higher pressure ammonia recycling, respectively. Of course, the heating and cooling of the solid adsorbent bed of the apparatus will depend on the temperature of the heat exchange fluid available at the site.
It is also within the purview of the invention that the apparatus be portable, where desired or otherwise convenient so that it may be moved to different refrigeration equipment or chemical sites for being connected to evacuate refrigeration or chemical loops as it is needed. For example,
portable systems incorporating reactors capable of adsorbing up to 1,000 lbs. of refrigerant may be especially useful. In other locations, especially where very large gas containing systems are installed, it may be preferred to permanently locate such an apparatus for evacuating and recharging (recycling) , whereby the apparatus of the invention need not be portable or moveable to any substantial extent. It may also be desirable to incorporate a gas detector with the system such that adsorption may be triggered by monitoring the atmosphere adjacent the refrigeration system for indicating a leak and by removal of gas where such a leak is detected. Such equipment may include valves automatically actuated in response to a detected gas leak for initiating a cool water supply into the heat exchange conduit of the apparatus and for opening the valve to begin withdrawing the gas, as previously described. Such equipment may be especially useful where injury to humans or expensive damage to products or materials could result in the event of significant exposure to leaking gases. These, as well as other modifications and advantages of the components of the invention and uses thereof, will be evident to those skilled in the art.