US1967770A - Method of manufacturing refrigerating apparatus - Google Patents
Method of manufacturing refrigerating apparatus Download PDFInfo
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- US1967770A US1967770A US668441A US66844133A US1967770A US 1967770 A US1967770 A US 1967770A US 668441 A US668441 A US 668441A US 66844133 A US66844133 A US 66844133A US 1967770 A US1967770 A US 1967770A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B31/00—Compressor arrangements
- F25B31/02—Compressor arrangements of motor-compressor units
- F25B31/023—Compressor arrangements of motor-compressor units with compressor of reciprocating-piston type
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/46—Burning in, wearing in, or oil burnishing
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/4935—Heat exchanger or boiler making
- Y10T29/49359—Cooling apparatus making, e.g., air conditioner, refrigerator
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/4981—Utilizing transitory attached element or associated separate material
- Y10T29/49812—Temporary protective coating, impregnation, or cast layer
Definitions
- My invention relates to a method of manufacturing refrigerating apparatus and particularly to refrigeration apparatus of the hermetically sealed compression type, and is a continuation in part of application Serial No. 564,455, filed by me September 22, 1931 for Drying process and apparatus therefor.
- any lubricant is present in the apparatus when it is dried by an oxygen containing gas, breakdown of the lubricant usually occurs, and moisture is continuously formed in the apparatus until the breakdown ceases due to exhaustion of certain materials from the lubricant which combine with the oxygen. The exhaustion of these materials from the lubricant is very slow and the time for drying a. lubricant impregnated a cheap method of obtaining moisture free hermetically sealed refrigerating apparatus.
- Fig. l is a view, partly in section, of the working parts of a compression refrigerator showing a test stator attached to a supporting frame;
- Fig. 2 is a view, partly in section, of a sealed motor compressor refrigerating unit manufactured in accordance with a preferred embodiment of my invention
- Fig. 3' is a view, partly in section, of a complete refrigerating apparatus of the hermeticaliy sealed compression type with proper connections for drying and charging the same, and,
- Fig. 4 is a schematic view of a drying system for refrigerating apparatus.
- My invention generally comprises placing a test stator in operable relation with the rotor of a refrigerating apparatus to run in the bearing surfaces of the apparatus and to perform certain tests thereon. After these steps are performed, the test stator is removed, all traces of lubricant are washed from the remainder of the apparatus and a permanent stator which is free of lubricant is disposed in operable relation with the rotor. The remaining steps in the manufacture of the apparatus are then completed.
- a refrigerating apparatus is shown in Figs. 1, 2 and .3 similar to that disclosed in a co-pending application Serial No. 841,284,.flled November 4, 1932 for Refrigeration apparatus by M. C. Terry et a1, and assigned to the assignee of the present application.
- the apparatus generally comprises 5. a sealed motor-compressor unit 1, a condenser 2,
- a conduit connects the motor-compressor unit 1 with the condenser 2 and a conduit 2a connects the condenser 2 with the float valve 3.
- a con-- duit 6 connects the float valve 3 with the evaporator 4i and a suction line '7-connects the evaporator with the motor compressor unit 1.
- the motor-compressor unit 1 further comprises a cup-shaped casing 8 having a sealing cap 9 welded at the open end thereof. Restricted openings l0, l1 and 12 are provided in the cas- 2 ing.
- the suction conduit '7 is inserted in the opening 10 and soldered therein, while the discharge conduit 5 is inserted in the opening 11 and soldered therein.
- the opening 12 is provided for the insertion of a coriduit 13 for a purpose hereinafter described.
- the motor-compressor unit 1 further comprises a motor, generally designated, at 14, which includes a stator 15 and rotor 16 both supported by a frame 17.
- the frame also supports a com- 39 .pressor 18, a drive shaft 19 between the motor and compressor, and rnufiiers 20, as fully explained in the aforesaid application of Terry et al.
- the assembly of the apparatus is accomg -plished in the following manner: Referring first to Figs. 1 and 2, the rotor 16 is assembled on the shaft 19, and the shaft is disposed in the frame 17. The compressor is is then fastened to the frame 17, and the shaft 19 is operatively con- 44 nected to the compressor in a manner well lrnown in the art. A test stator 15a is then disposed within the frame 17 and it is fastened securely therein by any suitable means, for example, by 'a set screw 21 fitting a tapped hole 22 in the frame 17. The assembly, as shown in Fig. i, is
- test stator 15a is energized by connecting the plug 23 to a suitable source or electrical energy, and the Working parts the 59 ,unit are run in. It is obvious that the cloth or paper insulation of the test stator 15a becomes soaked with lubricant at this time, and it is, of course, used over again in this state. Varnish or gum impregnated test stators are preferably used vto prolong their life. After run in, the emciency of the compressor is tested. If the unit shown in Fig. I successfully passes test and inspection, the test stator 15a is removed from the frame 17 and the rest of the unit, being entirely metallic,
- the unit After the xylol bath, the unit is dried with compressed air, or by other suitable means, and a a" new, lubricant free stator is disposed in the then soldered to the openings 11 and 10, respectively, after the condenser 2, float valve 3 and evaporator Ahave been operatively connected together and to said suction and discharge conduits.
- the float valve assembly 3 is provided with a removable plug 30, which. is left open at this time for a purpose hereinafter described, as
- the apparatus is now in condition for gas drying. Before drying, however, a valved conduit 24 is connected by a union joint 25 to the conduit 13 for a purpose hereinafter described.
- a form of drying apparatus is shown in Fig. 4, and is more fully described in my co-pending application Serial No. 564,455, filed. September The drying apparatus forms no part of this invention and a detailed description of it is, therefore, deemed'unnecessary.
- the apparatus generally comprises apump 31 which preferably draws air from the atmosphere and forces it to a dehydrator 32 where the air is dried. The air then passes through a heater 33 to a plurality of refrigerating units in an oven 34.
- the warm dry air enters each unit at a valve 35, isforoed through conduits 24 and 13 and into the motor-compressor unit 1, where it branches, part of the air flowing through dis charge conduit 5, condenser 2 and out of the open float valve 3.
- the float valves of a plurality of the units in the oven are connected in parallel in the oven 3%, and the air leaving the float valves is conveyed by a conduit 36 to the atmosphere.
- the air also branches from the motor-compressor unit 1, through suction conduit 7, through the evaporator 4 and out of thefloat valve 3 to the conduit 36. The air may escape therefrom because the apparatus shown in Fig. 3 is placed in the oven 34 upside down so that the float valve is held open.
- the air is forced through the unit at a pre determined rate and at a predetermined tem perature, in order to obtain the most economical but efiective drying, taking the time of drying into account as afactor in the economy thereof.
- the most economical temperatures for the gas are above 90 C.
- a valve 3'? in the air conduit 36 is closed, a valve 38 is opened which connects the conduit 36 to vacuum pump 39.
- a valve All at the entrance of the air line to the oven 34 is also closed. units are then evacuated, the valve s closed, and the float valve 3 is closed by the screw plug 3@.
- the apparatus is charged with refrigerant and lubricant through the valve 35 and conduit 13.
- the conduit 13 is then pinched shut above the joint 25 and may be soldered, as shown in Fig. 2, so that the unit is completely sealed.
- a method of manufacturing a hermetically sealed refrigerating unit including a motor comprising a permanent stator and a rotor, a compressor, and a scalable casing for the motor and compressor, which includes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide an operative motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, disposing the permanent stator in operable relation with the rotor, and hermetically sealing the casing with the motor and compressor therein.
- a method of manufacturing a hermetically sealed refrigerating unit including a motor com- 1 prising a permanent stator and a rotor, a comvide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, disposing the permanent stator in operable relation with the rotor, hermetically sealing the casing with the motor and compressor therein, and drying the unit by means of air flow therethrough.
- a method of manufacturing a hermetically sealed refrigerating unit including a motor comprising a permanent stator and a rotor, a compressor, and a scalable casing for the motor and compressor, which includes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, dis-' posing the permanent stator in operable relation with the rotor, hermetically sealing the casing with the motor and compressor therein, and drying the unit by means of forcing a dry gas therethrough.
- a method of manufacturing a hermetically sealed refrigerating unit which utilizes a refrigerant chemically active with respect to water and which includes a motor comprising a permanent stator and a rotor, a compressor, and a scalable casing for the motor and compressor, which ineludes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator and disposing the permanent stator in operable relation with the rotor, hermetically sealing the casing With'the motor and compressor therein, and drying the unit by means of gas iiow therethrough.
- a method of manufacturing compression refrigerating apparatus which includes the steps of running in the working parts of the apparatus in the presence of a lubricant, completely removing the lubricant from the apparatus, forcing dry gas through the apparatus to dry the same, charging the apparatus with refrigerant and lubricant and finally completely sealing the aping parts in the presence of a lubricant before.
- a hermetically sealed refrigerator unit including a motor comprising a rotor and. a permanent stator, a compressor, and a sealable casing for the motor and the compressor, which includes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, removing all lubricant from the'unit, disposing a permanent stator in operable relation with the rotor, hermetically sealing the casing with the assembled motor and compressor therein and drying the unit by means of forcing gas therethrough.
- the method of manufacturing a compression refrigerating apparatus which includes the steps of running in the working parts of the apparatus in the presence of a lubricant, completely removing the lubricant from the apparatus by applying a solvent thereto, forcing gas through the apparatus to dry the same and charging the apparatus with refrigerant and lubricant.
- the method of manufacturing a compression refrigerating apparatus which includes the steps of running in the working parts of the apparatus in the presence of a lubricant, completely removing the'lubricant from the apparatus by applying a solvent thereto, and forcing gas through theapparatus at a predetermined rate to dry the same.
Description
July 24, 1934.
J. G. FORD METHOD 0E MANUFACTURING REFRIGERATING APPARATUS 2 Sheets-Sheet l -giimmmmmma FIG. 1.
13 3g uj l6 l I I I ll l in Q 17 :Jl t
' 7 \IO WITNESSES a 2 INVENTOR James 6. FORD BY a). (is. M
ATTQRNEY J. 6. FORD 1,967,770
METHOD OF MANUFACTURING REFRIGERATING APPARATUS July 24, 1934.
Filed April 28. 1933 2 Sheets-Sheet 2 FIG. 4-.
INVENTOR James G. Fem:
WITNESSES:
BY 0V! I M ATTORNEY Patented July 24, 1934 TED STAT S METHOD OF MANUFACTURING REFRIGER- ATING APPARATUS James G. Ford, Forest Hills, Pa., assignor to Westinghouse Electric & Manufacturing florapany, East Pittsburgh, Pa., a corporation of Pennsylvania Application April 28, 1933, Serial No. scat n 11 Claims.
My invention relates to a method of manufacturing refrigerating apparatus and particularly to refrigeration apparatus of the hermetically sealed compression type, and is a continuation in part of application Serial No. 564,455, filed by me September 22, 1931 for Drying process and apparatus therefor.
In themanufacture of refrigeration apparatus of the hermetically sealed compression type, it is necessary in practice to run in the bearing surfaces of the apparatus and to test the compressor before the apparatus is charged with refrigerant and lubricant. The apparatus must also be freed of moisture by drying before it is charged. The running in and test of the apparatus and the subsequent drying thereof gives rise to several 7 .diiiiculties in the steps of the manufacture thereof.
One of the difficulties arises from the fact that the run in and test are preferably completed before the apparatus is assembled in a scalable casing, so that the parts of'the apparatus are accessible and so that inspection may be made as to clearances and wear on the motor and compressor bearing surfaces, without having to remove the apparatus from the casing and replacing it. Since the apparatus is, therefore, handled outside of the scalable casing during test and run in in actual practice, it is exposed to rough handling in the shop. The most vulnerable part of the apparatus is the cloth or paper insulated stator, and bumps or knocks are liable to break the insulation and cause a short circuit in the stator.
Another difiiculty arises from the fact that gas drying is used since it is advantageous and extremely effective in the manufacture of hermetically sealed refrigerators. Drying is used so that substantially all the moisture in the apparatus will be removed before it is charged with refrigerant and lubricant. It is necessary that the apparatus be substantially moisture free because of the fact that many refrigerants, for example SOB, react with water and form substances which attack and corrode various parts of the apparatus. In addition to this, it is necessary to obtain substantially moisture free apparatus be cause any moisture therein collects at the ex pansion or float valve and forms ice, since this point is one of the coldest in the system, and
thereby impairs the operation of the apparatus. However, if any lubricant is present in the apparatus when it is dried by an oxygen containing gas, breakdown of the lubricant usually occurs, and moisture is continuously formed in the apparatus until the breakdown ceases due to exhaustion of certain materials from the lubricant which combine with the oxygen. The exhaustion of these materials from the lubricant is very slow and the time for drying a. lubricant impregnated a cheap method of obtaining moisture free hermetically sealed refrigerating apparatus.
It is another object of my invention to provide hermetically sealed refrigerating apparatus with a perfect motor stator after test and run in, without any substantial additional expense.
It is another object of my invention to provide a completely lubricant free refrigerating apparatus so that gas drying may be used without in any way retarding the time necessary to obtain substantially moisture free apparatus.
It is still another object of my invention to provide refrigerating apparatus completely lubricant free so that it may be dried by air or other gas which breaks down lubricants, so that moisture is not formed before charging with refrigerant and lubricant.
These and other objects are effected by my invention, as will be apparent from the following description and claims taken in connection with the accompanying drawings, forming a part of this application, in which:
Fig. l is a view, partly in section, of the working parts of a compression refrigerator showing a test stator attached to a supporting frame;
Fig. 2 is a view, partly in section, of a sealed motor compressor refrigerating unit manufactured in accordance with a preferred embodiment of my invention;
Fig. 3' is a view, partly in section, of a complete refrigerating apparatus of the hermeticaliy sealed compression type with proper connections for drying and charging the same, and,
Fig. 4 is a schematic view of a drying system for refrigerating apparatus.
My invention generally comprises placing a test stator in operable relation with the rotor of a refrigerating apparatus to run in the bearing surfaces of the apparatus and to perform certain tests thereon. After these steps are performed, the test stator is removed, all traces of lubricant are washed from the remainder of the apparatus and a permanent stator which is free of lubricant is disposed in operable relation with the rotor. The remaining steps in the manufacture of the apparatus are then completed.
Referring more particularly to the drawings, a refrigerating apparatus is shown in Figs. 1, 2 and .3 similar to that disclosed in a co-pending application Serial No. 841,284,.flled November 4, 1932 for Refrigeration apparatus by M. C. Terry et a1, and assigned to the assignee of the present application. The apparatus generally comprises 5. a sealed motor-compressor unit 1, a condenser 2,
a float valve 3, and an evaporator a. A conduit connects the motor-compressor unit 1 with the condenser 2 and a conduit 2a connects the condenser 2 with the float valve 3. A con-- duit 6 connects the float valve 3 with the evaporator 4i and a suction line '7-connects the evaporator with the motor compressor unit 1. The operation of the refrigerating apparatus need not be described since it is well known in the art and forms no part of the present invention.
The motor-compressor unit 1 further comprises a cup-shaped casing 8 having a sealing cap 9 welded at the open end thereof. Restricted openings l0, l1 and 12 are provided in the cas- 2 ing. The suction conduit '7 is inserted in the opening 10 and soldered therein, while the discharge conduit 5 is inserted in the opening 11 and soldered therein. The opening 12 is provided for the insertion of a coriduit 13 for a purpose hereinafter described.
.The motor-compressor unit 1 further comprises a motor, generally designated, at 14, which includes a stator 15 and rotor 16 both supported by a frame 17. The frame also supports a com- 39 .pressor 18, a drive shaft 19 between the motor and compressor, and rnufiiers 20, as fully explained in the aforesaid application of Terry et al.
The assembly of the apparatus, more. particularly the motor-compressor unit 1, is accomg -plished in the following manner: Referring first to Figs. 1 and 2, the rotor 16 is assembled on the shaft 19, and the shaft is disposed in the frame 17. The compressor is is then fastened to the frame 17, and the shaft 19 is operatively con- 44 nected to the compressor in a manner well lrnown in the art. A test stator 15a is then disposed within the frame 17 and it is fastened securely therein by any suitable means, for example, by 'a set screw 21 fitting a tapped hole 22 in the frame 17. The assembly, as shown in Fig. i, is
then partially immersed in a lubricant containing trough (not shown), the stator is energized by connecting the plug 23 to a suitable source or electrical energy, and the Working parts the 59 ,unit are run in. It is obvious that the cloth or paper insulation of the test stator 15a becomes soaked with lubricant at this time, and it is, of course, used over again in this state. Varnish or gum impregnated test stators are preferably used vto prolong their life. After run in, the emciency of the compressor is tested. If the unit shown in Fig. I successfully passes test and inspection, the test stator 15a is removed from the frame 17 and the rest of the unit, being entirely metallic,
so .may be easily washed thoroughly with an oil solvent, such as xylol to remove substantially all of the lubricant.
After the xylol bath, the unit is dried with compressed air, or by other suitable means, and a a" new, lubricant free stator is disposed in the then soldered to the openings 11 and 10, respectively, after the condenser 2, float valve 3 and evaporator Ahave been operatively connected together and to said suction and discharge conduits. "The float valve assembly 3 is provided with a removable plug 30, which. is left open at this time for a purpose hereinafter described, as
is the conduit 13.
The apparatus is now in condition for gas drying. Before drying, however, a valved conduit 24 is connected by a union joint 25 to the conduit 13 for a purpose hereinafter described. A form of drying apparatus is shown in Fig. 4, and is more fully described in my co-pending application Serial No. 564,455, filed. September The drying apparatus forms no part of this invention and a detailed description of it is, therefore, deemed'unnecessary. The apparatus generally comprises apump 31 which preferably draws air from the atmosphere and forces it to a dehydrator 32 where the air is dried. The air then passes through a heater 33 to a plurality of refrigerating units in an oven 34. The warm dry air enters each unit at a valve 35, isforoed through conduits 24 and 13 and into the motor-compressor unit 1, where it branches, part of the air flowing through dis charge conduit 5, condenser 2 and out of the open float valve 3. The float valves of a plurality of the units in the oven are connected in parallel in the oven 3%, and the air leaving the float valves is conveyed by a conduit 36 to the atmosphere. The air also branches from the motor-compressor unit 1, through suction conduit 7, through the evaporator 4 and out of thefloat valve 3 to the conduit 36. The air may escape therefrom because the apparatus shown in Fig. 3 is placed in the oven 34 upside down so that the float valve is held open.
The air is forced through the unit at a pre determined rate and at a predetermined tem perature, in order to obtain the most economical but efiective drying, taking the time of drying into account as afactor in the economy thereof. As set forth in my co-pending application above referred to, the most economical temperatures for the gas are above 90 C. The most econcrni-= rates of flow for a complete unit of substaniy 5 liters volume lie between .5 cubic feet 32 hour and 1 cubic foot per hour.
riihen the apparatus is completely dry, a valve 3'? in the air conduit 36 is closed, a valve 38 is opened which connects the conduit 36 to vacuum pump 39. A valve All at the entrance of the air line to the oven 34 is also closed. units are then evacuated, the valve s closed, and the float valve 3 is closed by the screw plug 3@. The apparatus is charged with refrigerant and lubricant through the valve 35 and conduit 13. The conduit 13 is then pinched shut above the joint 25 and may be soldered, as shown in Fig. 2, so that the unit is completely sealed. The
apparatus is then ready for operation when lubricant-free apparatus so that gas drying, such as air, may be used to effectively remove all mois ture. As hereinbefore pointed out, air drying has been found to be very economical and effective, but it is essential that lubricant be entirely removed from the apparatus.
While I have shown my invention in but one form, it will be obvious to those skilled in the art that it is not so limited, but is susceptible of various changes and modifications without departing from the spirit thereof,.and I desire, therefore, that only such limitations shall be placed thereupon as are imposed by the prior art or as are specifically set forth in the appended claims.
What I claim is:---
1. A method of manufacturing a hermetically sealed refrigerating unit, including a motor comprising a permanent stator and a rotor, a compressor, and a scalable casing for the motor and compressor, which includes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide an operative motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, disposing the permanent stator in operable relation with the rotor, and hermetically sealing the casing with the motor and compressor therein.
2. A method of manufacturing a hermetically sealed refrigerating unit, including a motor com- 1 prising a permanent stator and a rotor, a comvide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, disposing the permanent stator in operable relation with the rotor, hermetically sealing the casing with the motor and compressor therein, and drying the unit by means of air flow therethrough.
3. A method of manufacturing a hermetically sealed refrigerating unit, including a motor comprising a permanent stator and a rotor, a compressor, and a scalable casing for the motor and compressor, which includes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, dis-' posing the permanent stator in operable relation with the rotor, hermetically sealing the casing with the motor and compressor therein, and drying the unit by means of forcing a dry gas therethrough.
4. A method of manufacturing a hermetically sealed refrigerating unit which utilizes a refrigerant chemically active with respect to water and which includes a motor comprising a permanent stator and a rotor, a compressor, and a scalable casing for the motor and compressor, which ineludes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator and disposing the permanent stator in operable relation with the rotor, hermetically sealing the casing With'the motor and compressor therein, and drying the unit by means of gas iiow therethrough.
5. A method of manufacturing compression refrigerating apparatus which includes the steps of running in the Working parts of the apparatus in the presence of a lubricant, completely removing the lubricant from the apparatus, forcing dry gas through the apparatus to dry the same and charging the apparatus with refrigerant and lubricant. r
6. A method of manufacturing compression refrigerating apparatus which includes the steps of running in the working parts of the apparatus in the presence of a lubricant, completely removing the lubricant from the apparatus, forcing dry gas through the apparatus to dry the same, charging the apparatus with refrigerant and lubricant and finally completely sealing the aping parts in the presence of a lubricant before.
disposition of said parts in the .casing,'completely removing the lubricant from the apparatus, disposing the working parts in the casing and sealing the ,same except for restricted openings therein, forcing dry gas through saidopenings to dry the apparatus, charging the apparatus with refrigerant and lubricant through one of the openings and completely sealing the casing from the atmosphere by closing said openings with respect to the atmosphere.
8. The method of manufacturing a hermetically sealed refrigerator unit, including a motor comprising a rotor and. a permanent stator, a compressor, and a sealable casing for the motor and the compressor, which includes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, removing all lubricant from the'unit, disposing a permanent stator in operable relation with the rotor, hermetically sealing the casing with the assembled motor and compressor therein and drying the unit by means of forcing gas therethrough.
9. 'I'he method of manufacturing a hermetically sealed refrigerator unit, including a motor comprising a rotor and a permanent stator, a compressor, and a scalable casing for the motor and the compressor, which includes the steps of assembling the compressor and rotor, disposing a test stator in operable relation with the rotor to provide a testing motor, energizing such motor to test the compressor and run in the bearing surfaces of the unit, removing the test stator, applying a solvent to remove all the lubricantfrom the units, disposing the permanent stator in operable relation with the rotor, hermetically sealing the casing with the assembled motor and compressor therein and drying the unit by means of forcing gas therethrough.
10. The method of manufacturing a compression refrigerating apparatus which includes the steps of running in the working parts of the apparatus in the presence of a lubricant, completely removing the lubricant from the apparatus by applying a solvent thereto, forcing gas through the apparatus to dry the same and charging the apparatus with refrigerant and lubricant.
11. The method of manufacturing a compression refrigerating apparatus which includes the steps of running in the working parts of the apparatus in the presence of a lubricant, completely removing the'lubricant from the apparatus by applying a solvent thereto, and forcing gas through theapparatus at a predetermined rate to dry the same. i
JAMES G. FORD.
DHSCLMMER h l,%7,770.-Jams 43?. Ford, Forest Hills, Pa, METHOD OF MANUFACTURING REFR-IG- ERATING APPARATUS, Patent datad July 24, 1934. Disclaimer filed'Fet rum'y 12, 1944, by the as'sigi lee Westinghouse Electric d2: Manufacturing Company. Hereby enfersthis disclaimer to clexims 1, 2, 3, and 4.
[Ofiicnii Gazette March 21, 1944}
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2551426A (en) * | 1948-05-11 | 1951-05-01 | Westinghouse Electric Corp | Method of dehydrating and assembling refrigeration apparatus |
US2557621A (en) * | 1945-09-21 | 1951-06-19 | Tecumseh Refrigeration Sales A | Method of dehydrating refrigeration units |
US2721029A (en) * | 1954-04-19 | 1955-10-18 | Gen Electric | Sound damping arrangement |
US3251117A (en) * | 1964-10-20 | 1966-05-17 | Massachusetts Inst Technology | Bearing pre-run process |
-
1933
- 1933-04-28 US US668441A patent/US1967770A/en not_active Expired - Lifetime
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2557621A (en) * | 1945-09-21 | 1951-06-19 | Tecumseh Refrigeration Sales A | Method of dehydrating refrigeration units |
US2551426A (en) * | 1948-05-11 | 1951-05-01 | Westinghouse Electric Corp | Method of dehydrating and assembling refrigeration apparatus |
US2721029A (en) * | 1954-04-19 | 1955-10-18 | Gen Electric | Sound damping arrangement |
US3251117A (en) * | 1964-10-20 | 1966-05-17 | Massachusetts Inst Technology | Bearing pre-run process |
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