Refrigerant recovery device

A single pass refrigerant recovery device recovers refrigerant from a refrigeration system. The device includes at least one hose for withdrawing refrigerant from the refrigeration system and a first oil separator disposed downstream of the refrigerant hose. A filter is disposed downstream from the oil separator and a compressor is disposed downstream from the filter. A second oil separator is disposed downstream from the compressor, and the condensor is disposed downstream from the second oil separator. A moisture indicator is disposed downstream from the condensor, and a storage tank is disposed downstream from the moisture indicator. The refrigerant recovery device also contains an inventive oil separator/filter device that includes a canister having a first chamber portion for separating oil from the refrigerant and a second chamber portion for filtering refrigerant. An inlet is provided through which refrigerant can be introduced into the first chamber portion, and an oil outlet is provided for conducting oil from the first chamber portion. A filter cartridge is placeable in the second chamber portion. A refrigerant outlet is provided through which refrigerant can be withdrawn from the second chamber portion.

FIELD OF THE INVENTION 
The present invention relates to a device for use in connection with a 
mechanical refrigeration system, and more particularly to a device for 
recovering refrigerant from a mechanical refrigeration system, processing 
the refrigerant so recovered to remove contaminants therefrom, and storing 
the processed refrigerant. 
BACKGROUND OF THE INVENTION 
A wide variety of mechanical refrigeration systems are currently in use in 
a wide variety of applications. Those familiar with mechanical 
refrigeration systems recognize that such systems require servicing 
periodically. This servicing often takes the form of the addition of 
refrigerant into the system to replace refrigerant which has escaped from 
the system. Before adding refrigerant, it is often necessary to evacuate 
the refrigerant remaining in the system. Typically, this remaining 
refrigerant is removed by bleeding the refrigerant off to the atmosphere. 
In recent years, much concern has arisen about this practice of releasing 
fluorocarbon based refrigerants into the atmosphere. It is believed that 
the release of such fluorocarbons depletes the concentration of ozone in 
the atmosphere. This depletion of the ozone layer is believed to adversely 
impact the environment and human health. 
To avoid releasing fluorocarbons into the atmosphere, devices have been 
constructed that are designed to recover the refrigerant from the 
refrigeration system. These refrigerant recovery devices often include 
means for processing the refrigerant so recovered so that the refrigerant 
can be reused. 
Currently, several companies are involved in the manufacture and 
development of refrigerant recovery devices. These companies include 
K-Whit Tools, Inc., the assignee of the instant application, the ROBINAIR 
Manufacturing Corporation (later known as Kent-Moore Corporation), The 
Draf Tool Co., Inc., and the Murray Corporation. 
Examples of products developed by K-Whit Tools, Inc., include the devices 
disclosed in U.S. Pat. No. 4,942,741 and U.S. patent application Ser. No. 
07/579,779, both of which were invented by the inventors of the instant 
application, John P. Hancock and Ralph A. McClelland. 
Examples of devices originating from ROBINAIR include those shown in Cain 
U.S. Pat. No. 4,261,178; Cain U.S. Pat. No. 4,363,222; Lower, et al. U.S. 
Pat. No. 4,441,330; Manz, et al. U.S. Pat. Nos. 4,768,347; 4,805,416; 
4,809,520; and 4,938,031; and Punches et al U.S. Pat. No. 4,878,356. 
An example of a device developed by Draf Tools Co., is shown in Koser U.S. 
Pat. No. 4,285,206. Koser discloses a device which both reclaims 
refrigerant, and is capable of providing fresh refrigerant for recharging 
the refrigeration system once evacuated. An example of a device developed 
by the Murray Corporation is shown in Proctor, et al. U.S. Pat. No. 
4,909,042. 
In addition to those devices developed by the organizations discussed 
above, several others have developed refrigerant recovery devices. 
Examples of these other devices are shown in Sparano U.S. Pat. No. 
3,232,070; Massengale U.S. Pat. No. 3,357,197; Owen U.S. Pat. No. 
4,110,998; Goddard U.S. Pat. No. 4,476,688: Margulefsky et al. U.S. Pat. 
Nos. 4,480,446 and 4,554,792; Staggs et al. U.S. Pat. No. 4,539,817; 
Taylor U.S. Pat. No. 4,646,527; and Lounis U.S. Pat. No. 4,862,699. 
The patents discussed above are of interest in that they disclose a wide 
variety of devices for removing refrigerant from a refrigeration system, 
and processing the refrigeration so recovered. Some of the devices, such 
as the device shown in Manz et al U.S. Pat. No. 4,805,416 include a 
recycling loop wherein refrigerant that is withdrawn from a refrigeration 
system can be recycled through the purification loop of the recovery 
device to further purify the refrigerant. Other devices such as that shown 
in Cain U.S. Pat. No. 4,261,178 are primarily "single pass" devices 
wherein whatever processing is done to the refrigerant is done in a single 
pass of the refrigerant from the refrigeration system, through the device, 
and into the storage or disposal tank. 
Although some, if not all of the devices discussed above are capable of 
removing and processing refrigerant, room for improvement exists. In 
particular, room for improvement exists in producing a more simple device 
which performs its intended function with less complexity than some prior 
known devices. Another area for improvement resides in providing a more 
simple oil separator and filter apparatus for use in a refrigerant 
recovery device. 
It is therefore one object of the present invention to provide a 
refrigerant recovery device that provides a relatively simple, yet 
effective means for recovering refrigerant from a refrigeration system, 
and processing the refrigerant so recovered. 
SUMMARY OF THE INVENTION 
In accordance with the present invention, a single pass refrigerant 
recovery device is provided for recovering refrigerant from a 
refrigeration system. The device comprises at least one refrigerant hose 
for withdrawing refrigerant from the refrigeration system, and a first oil 
separator means disposed downstream from the refrigerant hose. A filter 
means is disposed downstream from the oil separator means. A compressor 
means is disposed downstream from the filter means and a second oil 
separator means is disposed downstream from the compressor means. A 
condenser means is disposed downstream from the second oil means, and a 
moisture indicator means is disposed downstream from the condenser means. 
A storage tank means is disposed downstream from the moisture indicator. 
Also in accordance with the present invention, a combination oil separator 
and filter device is provided for a refrigerant recovery apparatus. The 
oil separator/filter device comprises a canister means having a first 
chamber portion for separating oil from the refrigerant and a second 
chamber portion for filtering the refrigerant. An inlet means is provided 
through which refrigerant can be introduced into the first chamber 
portion. An oil outlet means is provided for conducting oil from the first 
chamber portion. A filter cartridge is placeable in the second chamber 
portion and a refrigerant outlet means is provided through which 
refrigerant can be withdrawn from the second chamber portion. 
Preferably, the canister includes a screen disposed in the path of 
refrigerant flow between the first chamber portion and the second chamber 
portion. A refrigerant hose connector is also provided for connecting a 
downstream end of a low side refrigerant hose and a downstream end of a 
high side refrigerant hose to the inlet means. An extended capillary tube 
means is provided that extends between the downstream end of the high side 
refrigerant hose and the inlet means to promote evaporation of refrigerant 
in the oil separator means. 
One feature of the present invention is that the oil separator and filter 
are provided within a single canister structure having a first chamber 
portion for serving as an oil separator, and a second chamber portion for 
holding a filter cartridge. This feature has the advantage of providing a 
means for removing the predominant contaminants from the refrigerant that 
is efficient in operation, is elegant in design, is relatively inexpensive 
to manufacture, and is relatively compact when compared to some known 
devices. 
Another feature of the present invention is that an extended capillary tube 
extends between the high side refrigerant hose and the inlet of the oil 
separator. This feature has the advantage of providing a more fine stream 
of liquid refrigerant flowing toward the oil separator. The use of this 
relatively more fine stream facilitates evaporation of the liquid 
refrigerant within the oil separator, and thus reduces the likelihood that 
refrigerant will pass through the oil separator and filter in a liquid 
phase. 
Another feature of the present invention is that an oil return line is 
provided for returning oil from the second oil separator to the compressor 
wherein the flow of oil through the line is controlled by a solenoid valve 
and a timer arrangement. The solenoid valve is biased to be open when the 
device is in an off condition. This feature has advantages both when the 
device is operating and the device is shut off. 
When the device is operating, the solenoid valve is normally closed. The 
valve is actuated to open in response to a timed cycle controlled by the 
timer. This controlled cycle provides a means for properly, controllably 
replenishing the supply of oil within the compressor. 
When the device is not operating, the return tube allows refrigerant to 
flow to the upstream side of the compressor from the downstream side of 
the compressor. This flow of refrigerant to the upstream side of the 
compressor helps to balance the pressure on the upstream side of the 
compressor with the pressure on the downstream side of the compressor. The 
placement of the compressor in this balanced condition improves the start 
up characteristics of the compressor in succeeding operating cycles. 
Additional features and advantages of the present invention will become 
apparent to those skilled in the art upon consideration of the following 
detailed description of a preferred embodiment exemplifying the best mode 
of carrying out the invention as perceived presently.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
A refrigerant recovery device 10 is shown in FIG. 1 as having a generally 
upright metal frame 12 supported on the ground by a pair of wheels 14. A 
handle 16 is coupled to the frame 12 to permit the device 10 to be wheeled 
into position for servicing a refrigeration system. 
The device 10 includes a storage tank 20 which is generally similar in 
size, shape and construction to propane tanks used in connection with 
outdoor barbecue grills. The storage tank 20 is held within the lower 
portion of the device 10 and is intended for holding recovered 
refrigerant. 
The operating components of the device are housed in the upper portion 24 
of the device 10. A control panel 26 is disposed on the front surface of 
the upper portion 24. The control panel 26 includes a rocker type on/off 
switch 28 for energizing and de-energizing the control circuitry and 
components of the device 10. A system operating light 30 is also contained 
on the control panel 26. System operating light 30 is designed to be 
lighted when the on/off switch 28 is in its on position and the system is 
operating. 
A tank full light 32 is provided for being lighted when the storage tank 20 
is full, and a high pressure light 34 is provided for being lighted when 
an over-pressure condition exists within the device 10. As will be 
explained in more detail below, the lighting of the tank full light 32 and 
high pressure light 34 are usually accompanied by a cessation of operation 
of the compressor of the device 10. 
A sight glass type moisture indicator 36 is also disposed on the control 
panel 26. A pressure gauge 38 is provided to enable the user to determine 
the pressure within the refrigeration system to be evacuated. 
Three push button type controls are also disposed on the control panel 26. 
These push button controls include a momentary start button 42, a pressure 
test button 44, and an air purge valve button 45. 
The momentary start button 42 is a depressible button that starts the 
operation of the components of the device 10 to begin its refrigerant 
recovery cycle. Momentary start button 42 is designed to be actuated and 
start the cycle of the device 10, only after the on/off switch 28 is 
placed in its on position. 
The pressure test button 44 is directly coupled to, and actuates the 
opening of a valve to begin a pressure test function of the device 10. As 
will be explained in more detail below, the pressure test function permits 
some refrigerant contained within the device 10 to be directed back into 
the refrigeration system to be tested. Once the refrigerant enters into 
the refrigeration system to be tested, a refrigerant "sniffer" can be used 
to detect leaks within the refrigeration system. 
The air purge valve button 45 is also directly coupled to a valve 98 that 
is normally closed. Depression of the air purge valve button 45 opens the 
valve 98 to allow collected air and separated oil to be purged from the 
device 10. 
The lid 48 of the filter/oil separator 90 is disposed on the top surface of 
the refrigerant recovery device 10. The lid 48 is disposed externally of 
the device 10 to facilitate its removal during the replacement of a filter 
cartridge 104 within the filter/oil separator 90. 
The device 10 also includes a plurality of hoses. The hoses enable the 
device 10 to be coupled in fluid communication to the refrigeration system 
to be serviced, and the storage tank 20. The hoses include a low side 
refrigerant hose 52 having a blocking valve connector member 53 disposed 
at its distal end. Blocking valve connector member 53 couples hose 52 to 
the low side refrigerant port of the refrigeration system to be serviced. 
A high side refrigerant hose 54 also includes a blocking valve connector 
member 55 at its end, which permits the high side refrigerant hose 54 to 
be coupled to the high pressure port of the refrigerant system to be 
serviced. 
Blocking valve connector members 53, 55 are designed so that the flow of 
gas and liquid through the connecting members 53, 55 is normally blocked. 
However, the blocking valve connector members 53, 55 open to allow the 
passage of refrigerant therethrough when attached to the respective ports 
of the refrigeration system. 
The third hose contained on the device 10 comprises a refrigerant delivery 
hose 58 which includes a blocking valve connector member 59 at its distal 
end. Blocking valve connector member 59 is coupled to a refrigerant inlet 
port 64 of the storage tank 20. The fourth hose of the device comprises an 
air purge hose 60 having a blocking valve connector member 62 at its 
distal end for connecting the air purge hose 60 to an air purge port 66 of 
the storage tank 20. 
The operating components and refrigerant flow path are best shown in FIG. 
2. 
The device 10 is shown in FIG. 2 as being coupled to a refrigeration system 
72 to be serviced. Refrigeration system 72 can take the form of a 
refrigerator, air conditioner, heat pump, or other mechanical 
refrigeration system. Refrigeration system 72 includes a compressor 74, a 
high pressure port H disposed downstream from the compressor, and a low 
pressure port L disposed upstream the compressor. The high and low 
pressure ports H, L provide ports through which refrigerant can be added 
or removed from the refrigeration system 72. 
The blocking valve connector member 55 of the high side refrigerant hose 54 
is connected in fluid communication with the high pressure port H of the 
refrigeration system 72. The low side refrigerant hose 52 of the device 10 
is coupled through blocking valve connector member 53 to the low pressure 
port L of the refrigeration system 72. 
The high side refrigerant hose 54 is coupled at its proximal end to a first 
fitting member 78. The low side refrigerant hose 52 extends between the 
blocking valve connector member 53 at the distal end of the low side 
refrigerant hose 52, and a second fitting member 80. Second fitting member 
80 is disposed adjacent to the proximal end of the low side refrigerant 
hose 52. A capillary tube means 82 extends between the first fitting 78 
and second fitting 80. Capillary tube means 82 transfers refrigerant 
removed from the high pressure side H of the refrigeration system 72 to 
the second fitting 80, to cause the refrigerant recovered from the high 
pressure side H of the refrigeration system 72 to intermingle and mix with 
the refrigerant recovered from the low pressure side of the refrigeration 
system 72. 
The capillary tube means 82 preferably comprises a long, reduced diameter 
tube preferrably between about 5 feet and 7 feet (1.52 m and 2.13 m) in 
length. For example, in one preferred embodiment, the capillary tube 82 
comprises a six foot (1.83 m) coil of 0.020 inch (0.51 mm) (inner 
diameter) copper tubing. The purpose of the capillary tube means 82 is to 
channel the refrigerant drawn from the high pressure side of the 
refrigeration system 72 into a fine stream within the capillary tube means 
82 to better facilitate the evaporation of the stream of refrigerant once 
it enters the oil separator. 
The device 10 also includes a pressure gauge a 38 and a vacuum switch 84 
which are disposed upstream from the filter-dryer/oil separator 90. The 
vacuum switch 84 and the pressure gauge 38 are configured to be responsive 
to the pressure of the refrigeration system 72 to be serviced. The vacuum 
pressure switch 84 will cause the device 10 to cease operation upon 
sensing a vacuum in the refrigeration system 72. The sensing of such a 
vacuum indicates that all refrigerant has been recovered from the 
refrigeration system 72. An example of a commercially available pressure 
gauge is a gauge manufactured by AMETEK. Preferrably vacuum pressure 
switch 84 is a 20PS034ECV04CV10C model vacuum switch manufactured by TEXAS 
INSTRUMENTS of Dallas, Tex., and is designed to be actuated to open at 
pressures less than 5 mm Hg. 
Turning now to FIGS. 2, 3, and 4, the canister 90 for containing the 
combination filter-dryer/oil separator is shown in more detail. 
The canister 90 includes an inlet 86 disposed downstream of both the high 
side refrigerant hose 54 and the low side refrigerant hose 52. The inlet 
86 opens into a first, or lower chamber portion 92 of the canister 90. The 
lower chamber portion 92 comprises the oil separator portion of the 
canister 90. Lower portion 92 has generally cylindrical sidewalls, and a 
hemispherical bottom portion 109. A purge port 96 is disposed at the 
bottom of the lower chamber 92, through which separated oil O and 
separated air can be removed. Purge port 96 terminates at its distal end 
in a purge valve 98. Purge valve 98 is operatively coupled to purge valve 
button 45 (FIG. 1). The purge valve 98 controls the flow of air and oil 
through the purge port 96. Purged oil which flows through purge valve 98 
is emptied into a receptacle 100 for storage and later disposal. 
The canister also includes a second, or upper chamber portion 102. Second 
chamber portion 102 is provided for containing a filter element 104, and 
comprises the filter-dryer portion of the canister 90. A screen 105 is 
disposed between the first chamber portion 92 and the second chamber 
portion 102 so that all refrigerant passing from the first portion 92 into 
the second portion 102 must pass through the screen 105. Preferably, 
screen 105 is a 100 mesh screen that is designed to help trap particulate 
matter. Additionally, screen 105 provides a surface which fosters the 
condensation of oil droplets in the refrigerant passing therethrough. 
Refrigerant flowing into the lower chamber 92 will tend to evaporate into 
its vaporous form. Additionally, oil contaminants contained within the 
refrigerant will tend to precipitate out of the refrigerant, coalesce into 
droplets, and fall into the bottom of lower chamber 92 adjacent to purge 
port 96. 
As best shown in FIG. 3, the canister 90 comprises a shell 107 having a 
generally cylindrical sidewall 108 and a generally hemispherical bottom 
109. The canister 107 also includes a refrigerant outlet 126 through which 
filtered refrigerant can flow out of second chamber 102. 
A connector 110 is removably coupled to the inlet 86 of the canister 92. 
The connector 110 contains four fittings, including a first fitting 78, a 
second fitting 80, a third fitting 114 and a fourth fitting 116. Each of 
the four fittings 78, 80, 114, 116 includes a T-shaped passageway to 
permit the flow of fluid therethrough. A first coupler 118 attaches the 
first fitting 78 to the fourth fitting 116. First coupler 118 includes a 
blocked passageway, to prevent the flow of fluid between first fitting 78 
and fourth fitting 116. This blockage forces refrigerant flowing through 
fitting 78 to pass through the capillary tube 82 and into second fitting 
80. The blockage in connector 118 prevents the refrigerant from bypassing 
the capillary tube 82. 
The second coupler 120 extends between the second fitting 80 and the third 
fitting 114, to permit fluid to flow therebetween. The second coupler 120 
includes an interior passageway, which permits the flow of fluid therein. 
The third coupler 122 includes a hollow passageway to permit the flow of 
fluid between third fitting 114 and fourth fitting 116. 
Third fitting 114 is coupled to the distal end 60 of the air purge hose 60. 
Air purge hose 60 extends between the third fitting 114 and the storage 
tank 20 to permit purged air to be removed from the storage tank 20. 
Fourth fitting 116 is coupled to inlet 86 of the canister 90, and includes 
a passageway to permit fluid flowing through fourth fitting 116 to flow 
into the inlet 86. 
As best shown in FIG. 4, the canister 107 includes a generally circular, 
radially inwardly extending interior flange 132 upon which the filter 
cartridge 104 rests. A circular flat gasket 136 is placed between the 
flange 132 and the filter cartridge 104 to sealingly engage the filter 104 
to the flange 132. This sealing engagement between the filter 104 and the 
flange 132 forces refrigerant to flow through the filter 104, and prevents 
flow around the filter cartridge 104. 
Alternately, flat gasket 136 can be formed as a part of the filter 
cartridge 104 or permanently affixed to the lower end of the filter 
cartridge 104. 
The filter cartridge 104 has the shape of an inverted cup. The purpose of 
the filter cartridge 104 is to filter out both particulate matter and 
water from the refrigerant passing therethrough. An example of a filter 
cartridge 104 which will function in connection with the present invention 
is the RC 4267 model filter cartridge manufactured by SPORLAN VALVE CO. 
An expansion spring 138 is disposed between the cap 48 and the filter 
cartridge 104 to press downwardly on the filter cartridge 104 to maintain 
the sealing engagement between the filter cartridge 104, gasket 136 and 
flange 132. An example of a cap 48 and spring 138 which will function in 
connection with the present invention is one manufactured by the SPORLAN 
VALVE COMPANY. 
Refrigerant flowing out of the canister 90 flows into the primary flow path 
144 of the device 10. A check valve 146 is disposed downstream from the 
canister 90 outlet 126. The check valve 146 is biased to allow refrigerant 
to move in the direction indicated by the arrows from the canister 90 
toward the compressor 158, but to prevent refrigerant flow in an opposite 
direction through the primary flow path 144. 
A pressure test loop 148 has a first or upstream end 150 disposed 
downstream from check valve 146, and a second or downstream end 152 
disposed upstream from check valve 146. Test loop 148 also includes a 
normally closed, user operable manual valve 44, and a check valve 154 to 
permit the flow of fluid in the test loop 148 in only one direction, from 
first, (upstream) end 150 toward second, (downstream) end 152. 
The test loop 148 is used to enable a technician-user to pressurize the 
refrigeration system to be serviced to test for leaks in the refrigeration 
system. 
When servicing a refrigeration system, it is not unusual that the 
technician will determine that no refrigerant exists any longer within the 
refrigeration system 72. Rather, this refrigerant has "leaked out" of the 
refrigeration system 72. In such case, it is also incumbent upon the 
technician to determine the source of the leak. 
To determine the source of the leak, the technician allows the device 10 to 
remain in its "system off" condition, and depresses valve 44 to permit 
refrigerant to flow from the device 10 back into the refrigeration system 
72. Typically, the technician will open the valve 44 for only a short 
period of time to allow only a small amount of refrigerant to flow back 
into the refrigeration system 72. The technician will then use a "sniffer" 
such as the K-Whit Tools, Inc. model 03000 sniffer to determine the point 
in the refrigeration system 72 wherein the leak occurs. 
A compressor 158 is disposed downstream of the test loop 148. Examples of 
compressors that function with the instant invention are the 1/4 and 1/3 
horsepower compressors manufactured by a variety of compressor 
manufacturers. 
A high pressure sensor and switch arrangement 202 are disposed downstream 
of the compressor, and upstream of the second oil separator 162. The high 
pressure sensor senses the pressure downstream from the compressor. If the 
pressure sensed by high pressure sensor 34 is too high, the high pressure 
switch 202 will stop operation of the compressor 158 to allow the pressure 
within the device 10 to become reduced to a lower, and hence safer level. 
Preferably, the high pressure sensor and switch 202 are set to deactuate 
the compressor 158 if the high pressure sensor senses a pressure in excess 
of 435 PSIG. Commercially available high pressure cut-off switches of the 
type described are available from TEXAS INSTRUMENTS CORPORATION of Dallas, 
Tex. 
A second oil separator 162 is disposed downstream from the compressor 158. 
An oil return loop 164 has its first, or upstream end 166 disposed at the 
downstream side of the oil separator 162. The second of downstream end 168 
of the oil return loop 164 is disposed upstream from the compressor 158. A 
solenoid valve 172 which is actuated by a timer 174 is also contained 
within the oil return loop 164. 
As will be appreciated, the operation of the compressor 158 causes oil to 
be depleted from the compressor 158, and to be added to the refrigerant 
exiting from the compressor 158. The second oil separator 162, removes 
this added oil, and returns it via the oil return line 164 to the 
compressor 158 to replenish the oil lost from the compressor 158. An 
example of a commercial available "second" oil separator is the Model 304 
Oil Separator manufactured by Temprite Co. Inc. 
The solenoid valve 172 controls the flow of oil back to the compressor. The 
opening and closing of the solenoid 172 is controlled largely by timer 
174. 
When the device 10 is not in operation, or the recovery system within the 
device 10 is not operating, the solenoid valve 172 is biased to be 
normally open. By being normally open, oil and refrigerant can flow within 
the oil return loop 164. By permitting this flow of fluid, the pressure on 
the upstream side of the compressor 158 becomes balanced with the pressure 
on the downstream side of the compressor 158 when the system 10 is not 
operating. This balanced pressure condition on both the upstream and 
downstream side of the compressor 158 facilitates the start up of the 
compressor 158 when a new refrigerant recovery cycle commences. 
During operation of the system, the timer circuit 174 actuates the solenoid 
value 172 to close. The closed solenoid does not permit oil to flow from 
the second oil separator 162 back through to the compressor 158. The timer 
circuit 174 causes the solenoid valve 172 to open at timed intervals to 
permit the flow of oil in the return line 164 to replenish the oil lost 
from compressor 158. 
A condenser 178 is disposed downstream of the second oil separator 162. 
Condenser 178 can be a six foot coiled restrictor tube having a 0.083 inch 
inner diameter. A fan 180 is disposed adjacent to the condenser 178 to 
help remove heat from the condenser 178. 
The moisture indicator 36 is disposed downstream from the condenser 178. 
The refrigerant delivery hose 58 is disposed downstream from the moisture 
indicator 36. Refrigerant delivery hose 58 terminates at its distal end in 
the blocking valve connector member 59, which is coupled to a valved 
refrigerant inlet port 64 of the storage tank 20. The refrigerant inlet 
port has its opening at lower terminus 184. Terminus 184 is disposed 
adjacent to the bottom of the storage tank 20. 
The air purge hose 60 is coupled by a blocking valve connector member 62 to 
the air purge port 66 of the tank 20. The air purge port 66 is also 
controlled by a valve. The opening (terminus) 186 of the air purge port 66 
is disposed adjacent to the top of the storage tank 20. The terminus 186 
disposed adjacent to the top of the interior of tank 20 because air which 
becomes trapped within the storage tank 20 tends to collect adjacent to 
the top of the tank. The valve in refrigerant purge port 66 is normally 
closed. The storage tank 20 also includes a level sensor 190. The level 
sensor 190 is provided for sensing the level of refrigerant R within the 
interior of the storage tank 20. The sensor 190 includes a connector 192 
for connecting the sensor 190 to a communications port (not shown), which 
couples the sensor 190 to the device 10. The level sensor 190 also 
includes a probe 194 which extends into the interior of the storage tank 
20. Examples of liquid level sensors which will perform with the device of 
the present invention are shown in White and Hancock U.S. patent 
application Ser. No. 07-725834, entitled Liquid Level Sensor for 
Refrigerant Servicing Device, which is being filed contemporaneously with 
the instant application. 
The control circuitry 200 for the present invention is best shown in FIG. 
5. Circuit 200 includes a power supply 201 which is coupled to a 
two-position high pressure switch 202. When the pressure measured by the 
high pressure sensor (not shown) associated with switch 202 is less than 
the predetermined pressure, the high pressure switch 202 is placed in its 
position shown in FIG. 1. However, when the pressure at the high pressure 
sensor (not shown) is greater than the predetermined pressure, the two 
position high pressure switch 202 moves into its second position to form a 
connection with high pressure light 34. Main on/off switch 204 is also 
sequentially coupled to fan 180, so that engagement of the on/off switch 
204 will generally start the fan 180. 
The main power switch 204 is also connected to a tank full switch 206. Tank 
full switch 206 is coupled to the tank level sensor 190 (FIG. 2). When the 
tank level sensor 190 senses that the tank 20 is not full, the coil 212 of 
relay 210 engages contact between the common terminal 213 and the normally 
closed terminal 216. However, when the tank sensor 190 indicates that the 
storage tank 20 is full, the coil 212 of relay 210 moves the contact 
between the common terminal 213 and the normally open terminal 214. When 
so positioned, tank full light 232 will be caused to become lighted, and 
compressor 158 will be deactuated. 
Momentary start switch 220 is coupled to relay 224. Relay 224 includes a 
coil 226, a common terminal 226, a normally opened terminal 230, and a 
normally closed terminal 232. In relay 224, normally closed contact 232 is 
coupled to nothing. Normally open contact 230 is coupled to vacuum switch 
84. 
The momentary start switch 220 works in conjunction with main power on/off 
switch 204. When main on/off switch 204 is turned to the on position, the 
compressor 158 will not start operation. The operation of the compressor 
158 is started by tripping the momentary start switch 220. The momentary 
start switch 220 will remain engaged, to provide power to the compressor 
158 so long as vacuum switch 84 is closed. Vacuum switch 84 opens when the 
pressure measured by vacuum switch 84 (FIG. 2) drops below a predetermined 
rate. Thus, if one tries to use the momentary start switch 220 to actuate 
the compressor 158, the compressor 158 will be deactuated upon release of 
the spring loaded momentary start switch 220 if the vacuum switch 84 is in 
its open position. 
Circuit 200 is designed to permit compressor 158 to become engaged only if 
certain conditions are met. These conditions include the condition that 
the high pressure switch 202 be in its first position, that the main power 
switch 204 be turned on, that the momentary power switch 220 be depressed, 
that the tank full switch 206 not be indicating that the level of 
refrigerant R within the tank 220 is full, and that the vacuum switch 84 
is closed. 
The operation of the device 10 will now be described, and can be best 
understood with reference to FIG. 2. 
The device 10 is first properly coupled to the refrigeration system 72 to 
be serviced and to the storage tank 20. The rocker-type on-off switch 268 
is turned to its on position. The momentary start button 42 is then 
depressed to engage the compressor 158. Circuit 200 will cause compressor 
158 to become engaged if the conditions discussed above are met. 
Assuming that the required conditions are met, the compressor 158 will 
begin drawing refrigerant out of the refrigeration system 72. Refrigerant 
will be drawn both through the high side pressure hose 54 and the low side 
pressure hose 52. The capillary tube means 82 will conduct refrigerant 
between the first fitting 78 and the second fitting 80, to facilitate 
evaporation of the refrigerant being drawn from the high side H of the 
refrigeration system 72. The refrigerant will then be directed into the 
lower chamber 92 of the oil separator/filter canister 90. In the lower 
chamber 92, any liquid refrigerant will usually evaporate into a gaseous 
state. Oil and water within the refrigerant will tend to become separated 
from the refrigerant. Any oil drops which coalesce within the chamber 92 
interior, or upon screen 105, will generally drop and fall into the lower 
chamber portion 92. This separated oil can then be purged through the 
purge port 96, and purge valve 98, and stored ultimately in receptacle 
100. 
Evaporated refrigerant from which the oil has been separated then flows 
through screen 105 into the upper chamber 102 of the canister 90. 
Refrigerant then flows from the upstream surfaces of the filter cartridge 
104, through the filter, and then past the downstream surfaces of the 
cartridge 104, in the directions indicated generally by arrows F. During 
the passage of the refrigerant through the filter element 104, particulant 
matter and moisture is removed from the refrigerant. Thus, refrigerant 
emerging from the refrigerant outlet 126, and passing into the primary 
flow path 144 should be in a condition wherein it is substantially devoid 
of particulants and moisture. 
Refrigerant then flows through compressor 158, and through second oil 
separator 162. Oil separated in second oil separator 162 can be returned 
to compressor 158 by return line 164. Refrigerant passing through the 
second oil separator 166 then passes through a condenser 178, wherein the 
refrigerant begins to condense from its vaporous phase into liquid phase. 
Ultimately, the refrigerant emerging from condenser 178 passes through 
moisture indicator 36, and is delivered by refrigerant delivery hose 58 
into the interior of refrigerant storage tank 20. 
As will be appreciated, air often collects near the top spaces of the 
storage tank 20. To purge the air from the top of the storage tank 20, the 
air purge valve 45 on the control panel 26 of the device 10 is pressed. 
Pressing button 45 on the control panel 26 actuates valve 98, to cause 
waste oil and air within the lower chamber 92 of the canister 90 to be 
removed therefrom. Air purge line 60 is provided for transporting the air 
between the refrigerant storage tank 20 and the inlet 86 of the lower 
chamber 92 of the canister 90. 
When the compressor 158 is actuated so that it is operating, solenoid valve 
172 is closed. The solenoid valve 172 will open only in response to timer 
174. Timer 174 opens solenoid valve 172 on a timed basis. 
When the device 10 is turned off, the solenoid valve 172 is placed in its 
opened position to allow refrigerant to pass through the solenoid valve, 
thereby equalizing the pressure between the upstream and downstream sides 
of the compressor 158. Due to the presence of check valve 146 and normally 
closed pressure test valve 44, the opening of solenoid valve 172 will not 
permit any refrigerant to flow into the interior of canister 90. 
Having described the invention in detail, and by reference to the preferred 
embodiments thereof, it will be apparent that modifications and variations 
are possible without departing from the scope of the invention as defined 
in the appended claims.