REFRIGERANT RECOVERY SYSTEM
BACKGROUND OF THE INVENTION
In recent years a considerable concern regarding the status of the ozone layer, which surrounds the earth at an altitude in the range of six to thirty miles, has developed. More particularly, scientists have estimated that as much as seven percent of the so-called ozone belt has already been destroyed. Moreover, researchers have found evidence of
"holes" in the ozone layer, including one over the Antarctica having an area of more than a million square miles.
The consequences of this deterioration of the world's ozone layer can, it is believed, lead to a dramatic increase in skin cancer and cataracts, this including a lowered resistance of all organisms on the planet to infection. From this impact upon plant-life, which is believed to be probable, damage to the food chain would also occur. In addition, it is believed that with further thinning of the ozone layer, a general warming trend of the earth will occur, this leading to a possibly disastrous rise in sea-levels.
As a result of a near universal recognition of the above threat to human and other life, at a United Nations conference, twenty-four countries have signed an agreement requiring that the production of ozone-destroying chemicals be reduced at least in half by the year 1999. These ozone destroying chemicals are, particularly, man-made compounds known as chloroflurocarbons (CFG's).
In simple terms, the protection of the ozone layer against further deterioration is basically a two-fold matter, namely, that of the reduction of production of CFC's, and, secondly, the control of the release of CFG's into the atmosphere.
At present, it is believed that most CFC's are released into the atmosphere as a result of carelessness when such items as refrigerators and air conditioning systems are permitted to release their CFC's (many of which are sold under the brand name FREON). Accordingly, an important aspect of the protection of the ozone layer from further decay is a matter of training mechanics and technicians working in the
refrigeration and air conditioning field regarding how to prevent the escape of FREON and related materials from the equipment with which they work. Further, it is necessary to provide such mechanics and technicians with equipment particularly adapted to capture, in a simple and economic fashion, FREON and other CFC's which would otherwise be likely to escape in the course of repair or replacement of refrigeration and air conditioning equipment.
The present invention addresses the above problem of CFC/Freon recovery from air conditioning and refrigeration system in the course of repair or replacement of such systems.
Relevant prior art known to the inventor comprises U.S. Patent NO. 4,285,206 (1981) to Koser; No. 4,476,688 (1984) to Goddard; No. 4,539,817 (1985) to Staggs; and U.S.P.N. 4,646,527 to Taylor (1987). This art, suffers from shortcomings of efficiency, economy and convenience of use, all of which difficulties are solved by the instant invention.
SUMMARY OF THE INVENTION
The invention is a system for refrigerant recovery and purification. It includes a hollow fluid -tight pressure vessel having fluid input means; and a hollow, annular jacket having its exterior inner surface in thermal communication with said pressure vessel, said jacket having a polar axis in substantial alignment with the gravity vector, said jacket having liquid accumulation means at the bottom thereof, said jacket further having fluid output means. Also provided is fluid communication means for defining a fluid path, external of said vessel, between said vessel and an input to said jacket, said fluid communication means further comprising expansion valve means for selectively increasing the volume of fluid flowing from said vessel prior to its entry into said jacket. Condensing means are in fluid communication with said output means, said condensing means having an output in fluid communication with said input means of said pressure vessel,
whereby the temperature of said vessel will be lowered by virtue of its thermal communication with said jacket, thereby enhancing the efficiency of said condensing means and, consequently, of the entire system.
It is an object of the present invention to provide a method and means for the recovery of refrigerants from a refrigeration system when that refrigeration system is being repaired or replaced.
It is another object to provide a method which will prevent escape of harmful CFC's into the atmosphere while effecting an economic benefit.
The above and yet other objects and advantages of the present invention will become apparent from the hereinafter set forth
Detailed Description of the Invention, the Drawings, and the Claims appended herewith.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is a schematic view of the present inventive refrigerant recovery system.
Fig. 2 is an enlarged area of the view of Fig. 1 with specific reference to the condensing means and heating means.
Fig. 3 is a schematic view of an alternate embodiment of the pressure vessel and jacket means.
DETAILED DESCRIPTION OF THE INVENTION
With reference to Fig. 1, there is shown, to the left of the figure, the system 8 to be evacuated. This system includes a compressor 10, a condenser 12, an evaporator 14, a liquid line service valve 16 and a liquid receiver 17.
The interface or tap between the present inventive refrigerant recovery device and the system 8 uses manifold gauges 7. he center hose is attached at connection 18.
The low pressure hose of manifold gauges 7 connects to a suction service valve 11. A high pressure hose of manifold gauges 7 connects to said liquid service valve 16.
This method of connection is useful when large amounts of liquid refrigerant are present within the system being evacuated.
An alternate method of connection places the low pressure hose of manifold gauges 7 at suction service valve 11 while the high pressure hose of gauges 7 connects to service valve 16 and the center hose connects to valve 65. This method is useful in the automotive area where only vapor is generally available for recovery.
Following the first method of connection described above, a high pressure liquid refrigerant line 18 carries liquid refrigerant from the evacuated system 8 to a metering device 24. The function of the metering device is to controllably permit an expansion of the refrigerant liquid thereby creating a pressure differential between the high pressure liquid refrigerant line 18 and the inside of annular jacket 26 at a substantially lower pressure. For example, the pressure within high pressure liquid refrigerant line 18 will, at conditions of 90 degrees Fahrenheit and R12 refrigerant, be 90 psi while the conditions within annular jacket 26 will be about 20 pounds per square inch.
Annular jacket 26 surrounds special purpose storage bottle 28 which is provided with a valve-operated drain 31.
Within said jacket 26 there is formed a so called puddle 27 of refrigerant. This puddle will form within jacket 26 when a sufficient volume of low pressure gas accumulates therewithin. From puddle 27, which is technically known as a flooding evaporator, refrigerant will be drawn through a perforated suction tube 29.- Liquid refrigerant, from the end of said tube 29, will be drawn from puddle 27 while the perforations therewithin will draw gas from the portion of said jacket above said puddle 27. Accordingly, a combination of both liquid and vapor refrigerant will enter a low pressure suction line 30. This combination of fluid may be considered a boiling liquid, and its condition as between a liquid or vapor will be determined by various system variables.
From low pressure suction line 30, the boiling liquid refrigerant travels to the right, passing a low pressure gauge 47. Therefrom (see Fig. 2 for enlarged view) refrigerant enters suction dryer means 36. Suction dryer means 36 performs the functions of filtering and drying.
As may be noted in Fig. 2, low pressure suction line 30 is in fluid communication with suction dryer means 36 and refrigerant exits at connection line 68. Below connection line 68 is shown an oil trap 33, the function of which is to remove oil from the boiling liquid refrigerant. This oil trap exists for the purpose of protecting the compressor 40 from the introduction of oils, moisture, or any other contaminants, from the system being evacuated.
It should be appreciated that the combination of jacket means 26, the suction line 30 and said dryer means 36, constitutes a segmented evaporator in which the superheat therein is controlled by either (1) an automatic expansion valve responding to compressor capacity, (2) a thermostatic expansion valve responding to a bulb positioned at point 67, or (3) any other known metering device.
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From connection line 68, the refrigerant enters suction dryer 66, having a heat strip 65, which performs the function of a second dryer, and further protects compressor 40 from liquid refrigerant entering thereto. Said heat strip 65 is controlled by a temperature sensor on line 32. Accordingly, the refrigerant, upon exiting from 66 is assured to be in the vapor state. Therefrom, gaseous refrigerant travels through low pressure vapor suction line 32 and passes point 38 which is the connecting point for a low pressure control switch, i the function of which is to turn off the entire system, including compressor 40, in the event of zero pressure..
At compressor 40 the low pressure vapor refrigerant is compressed in order to create a high pressure gaseous refrigerant output which passes through high pressure hot vapor line 48. This line then travels to oil separator 44, the function of which is to assure that compressor 40 is at all times supplied with oil. This is effected through oil return line 46 which connects oil separator 44 to low pressure suction line 32.
From oil separator 44, the high pressure gaseous refrigerant passes through high pressure hot vapor extension line 49 into air cooled condenser 52 which functions to reduce the temperature of the refrigerant passing by high pressure gauge 54. The refrigerant then passes from air cooled condenser 52 to a reduced temperature high pressure line 57.
From line 57, condensed refrigerant enters high pressure water cooled refrigerant line 55, where further cooling is achieved by water cooled condenser 53 bringing the refrigerant into a liquid state. In operating water cooled condenser 53, tap water is used which in certain areas of the country may be as warm as 70 degrees. In other areas it may be about 60 degrees.
Upon exiting the water cooled condenser 53, the liquified refrigerant passes through high pressure liquid line 62 into one way valve 56. The one way valve prevents refrigerant from flowing back from the special bottle 28 into the system when bottle pressure is higher than the system pressure. Further, it allows the refrigerant to flow into the bottle when the system pressure is higher than the bottle pressure.
From one way valve 56 the liquid refrigerant flows through high pressure liquid line 62 and into bottle access valve 64 where storage of the recycled, recovered refrigerant is effected.
It is to be appreciated that one of the functions of jacket 26 is to maintain bottle 28 at a low temperature to thereby enhance the overall efficiency of the system.
It is to be appreciated that in this system, three separate condensing mediums, namely, gas, air and water are used. This is especially important in adapting the system to use in the automotive industry where mainly gas vapor is being removed rather than liquid refrigerant. It has been found when removing refrigerant in vapor form freeze-ups may occur. By lowering the pressures in the evacuated system refrigerant tends to liquify and an ice bank will occur. To combat this occurrence, auxiliary heating pad 15 is wrapped around the suction accumulator 17 or any other available iced-up area.
Recovered refrigerant must strictly comply with the standards of the Society of Automotive Engineers, and other industrial bodies, before being reintroduced into systems under warranty by the industry. It is therefor another function of this device to recycle recovered refrigerant in a constant refrigeration circuit, passing the recovered refrigerant many times through the distilling, filtering and drying means of the circuit.
The above can be accomplished, independent of any recovery, 5 by including liquid line 19, filter 20 and solenoid valve 51 into the circuit. Also provided is refrigerant hand valve 21.
When solenoid valve 51 is energized and hand valve 21 is opened, a complete refrigerant circuit exists, drawing liquid refrigerant out of the storage bottle 28, through liquid line 19 containing filter 20, to connection point 18, through
metering device 24, into jacket 26, and continuing on through the system as many times as is desired to achieve a desired degree of purity of the refrigerant, this continuing on, through the cycle, as long as solenoid valve 51 is energized. When valve 51 is de-energized the system pumps down and shuts off automatically, returning the refrigerant to the storage bottle.
Shown in Fig. 3 is an alternate embodiment of the invention in which jacket 26 is replaced by separate regions 126 which function in the manner of said jacket 26.
While there has been herein shown and described the preferred embodiments of the instant invention, it is to be understood that said invention may be embodied, otherwise than is herein illustrated and described and that within said embodiment, certain changes in the details of construction, and in the form and arrangement of the parts, may be made without departing from underlying idea or principles of this invention within the scope of the appended claims.