USRE20672E

USRE20672E - Refrigerating system

Info

Publication number: USRE20672E
Authority: US
Publication date: 1938-03-15

Description

March 15, 1938. F, KOPSA I Re. 20,672

REFR IGERAT ING SYSTEM Original Filed Sept. 22, 1952 Reiaued Mar. 1938 UNITED STATES PATENT OFFICE 2Ci672 V REFRIGERATING SYSTEM Julius F. Kopsa, Chicago, lll., assignor to Kopolator Corporation, Chicago, Ill., acorporation of Illinois 10 Claims.

The present invention relates generally to refrigerating systems. More particularly, the invention relates to mechanical refrigerating systems of the type wherein a refrigerant, such as ammonia or like gas, is delivered in a compressed state from a motor-driven compressor to a condenser and from the condenser to an expansion valve, and after passing through the valve flows through an evaporating coil and thence back to the compressor.

In refrigerating systems of this type, it has been found that during operation, the oil which is used to lubricate the crank shaft and other operating parts of the compressor, gradually works its way into the compressor cylinder and is carried by therefrigerant through the expansion valve and into the evaporating coil where it congeals and, due to its gumminess, impairs the operation and reduces the eiliciency of the system. In some instances, it has been found that so much of the oil works its way into the compressor cylinder that the oil remaining in the crank case of the compressor is not sufficient properly to lubricate the crank shaft and other operating parts, with the result that damage or faulty operation occurs.

One object of the invention is to provide a mechanical refrigerating system of the type under consideration which is an improvement upon, and more emcient in operation than, previously designed systems, in that it includes a centrifugal separator between the compressor and the condenser whereby any oil from the compressor is removed or disunited from the refrigerant prior to passage of the refrigerant to the evaporating coil in order to insure proper and efficient operation of the system and prevent dilution of the refrigerant and clogging of the expansion valve and the evaporating coil.

Another object of the invention is to provide a refrigerating system of the last mentioned character which contemplates simple means whereby the oil which is. removed from the refrigerant by the centrifugal separator is automatically drained back into the crank case of the compressor so that proper lubrication of the crank shaft and operating parts of the compressor is at all times assured.

A further object of the invention is to provide a mechanical refrigerating system of the character last specified in which the means for automatically returning the separated oil from the centrifugal separator to the crank case of the compressor comprises a tank which receives the separated oil directly from the separator is connected to the separator so that it is subjected to the pressure of the refrigerant andembodies a float-controlled valve which is adapted to open when the oil in the tank reaches a predetermined level and permits the oil under the pressure of the refrigerant to drain back to the crank case of the compressor.

Other objects of the invention will be apparent from a consideration of the following detailed description.

'The invention consists in the several novel features which are hereinafter set forth and are more particularly defined by claims at the conclusion hereof.

In the drawing which accompanies and forms a part of this specification or disclosure and in which like numerals of reference denote corresponding parts throughout the several views:

Figure 1 is a more or less diagrammatic view of a refrigerating system embodying the invention;

Figure 2 is a vertical section of the improved centrifugal separator for removing or disuniting oil from the refrigerant of the system and returning it to the crank case of the compressor;

Figure 3 is an enlarged vertical section of the separator illustrating in detail the construction and arrangement of the various operating parts; and

Figure 4 is a horizontal section on the line 44 of Figure 3.

The invention is exemplified in a mechanical refrigerating system which embodies a compressor 5. The latter serves to compress the refrigerant for the system and comprises a vertically extending cylinder 6 and a piston I. The piston is slidably mounted in the cylinder and operates upon its down stroke to draw the refrigerant from the low side of the system through a pipe 8 into the cylinder, and upon the up stroke thereof to compress the refrigerant in the cylinder and force it to a condenser 9 through the medium of a pipe III. From the condenser, the refrigerant passes through an expansion valve. ll into an evaporating coil l2 and thence back to the compressor via. the pipe 8 in a manner well understood in the art. Back flow of the refrigerant through the pipes 8 and II is prevented by suitable check valves (not shown). The piston is reciprocated in the cylinder 8 for refrigerant compressing purposes, by means of a pitman H which is connected pivotally to, and extends between, the piston and a crank ll on a crank shaft IS. The crank shaft I5 is provided at one end thereof with a pulley Ii whereby it is adapt- 'ity, and is journalled in a crank case I1 which is positioned beneath and is in the nature of a sage to the expansion valve ll.

continuation of the cylinder 6. The crank. case I1 is adapted to retain oil so as to lubricate the crank shaft, the pivotal connections between the pitman and the piston and the crank shaft and the inner periphery of the cylinder.

During operation of the compressor, the oil in the crank case l1 vaporize's to a small..ex-. tent and continually works its way into the cylinder 6 where it'unites with the refrigerant.. In, order to separate or disunite the oil from the refrigerant and thus prevent it from passing through the expansion valve into the evaporating coil where it is likely to congealj and i'm pair the efllciency and operation of the system, a centrifugal separator I8 is provided. This separator is located between the compressor and the condenser and comprises a vertically extendjing, cylindrical casing l9 'and a vertical series of rotatable deflectors 28. The casing l9 surrounds the series'of rotatable deflectors 28 and consists of a cylindrical side wall 2|, a circular bottom head 22 and a circular top head 23.. The.

bottom head 22 serves as a closure for the bottom part of the casing and is secured to an inwardly extending flange 24 in the lower end of the side wall 2| by screws 25. The top head 23 'rests on a ring 26 on an inwardly extending flange 21 at the upper end of the side wall 2| of the casing, -and is secured in place by means of screws 28 which extend through the ring and into the aforementioned flange. erant in a compressed state is delivered into the casing of the separator by way of an inlet nipple 29. This nipple extends through a hole 38 in the central part of-the bottom head 22 and embodies at the central portion thereof an integral, radially extending flange 3| which fits against the portion of the bottom head around the hole 38. A nut 32 is connected by a screw thread 33to the lower end of the inlet nipple and serves to clamp the flange 3| against the'bottom head so as to secure the inlet nipple in fixed relation'with respect to the casing. The inlet nipple is connected to the pipe J8 bya union 34 and operates to direct the compressed refrigerant upwardly through the casing It]. The central portion of the top head 23 is shaped to form an upwardly extending outlet nipple 35. This nipple is connected to a pipe 31 which delivers the refrigerant to the condenser for pas The outlet nipple 35 is preferably of the same diameter as the inlet nipple 23 and is coaxial with the latter.

- The deflectors 28 are formed of disks of sheet metal and are slit radially and bent so that they embody radially-extending blades 38. They embody, in addition to the blades 38, hubs 38 and are mounted for horizontal rotation on a vertically extending shaft 40. The latter is longitudirefrigerant passing to the condenser-by way of are preferably four in number.

The refrigbelow each deflector.

The com- This rotation of the deflectors ed to be driven by a belt or like instrumentalthe pipe 31 and from the condenser and expansion valve to the vaporating c'oil} is 'free' from oil. In order to increase the efficiency of the deflectors, the central portions of the blades 38 are deflected to form radially extending ribs 43; The

latter operate in a measure as baiiies and guide the oil outwardly in the casing. The deflectors the bottom deflector and the one third from the bottoin are twisted {so' that thesetwo deflectors rotate in one direction. The blades ofthe deflector second from the bottom and the one at the top are oppositely twisted so that these two defiectors rotate in opposite directions. As a result of this construction, the refrigerant is subjected to' the action of rotating deflectors, some of which rotate in one direction and others of which rotate in the opposite direction, with the result that'any' and all oil accompanying the refrigerant is effectively separated or disunited from the refrigerant priorto passage of the latter The blades of i intotheoutlet nipple 35; A tubular sheet metal 1 shell 44 surrounds the deflectors. This shell is spaced from the'side wall 2| of the separator casing and extends between thetop head 23 and a radially extending flange z45 at' the upper end of the inlet'nipple 29. An annular series of slots 4li'is formed'in 'the shell 44' adjacent each deflector 28. These slots allow the oil which has separated from therefrigerant to'flow through theshell and to drop onto the bottom head '22 of the separator'casin'g. The slots of each series are preferably staggered with respect to the slots of the-adjacent series; as shown in Figure 2. In order to guide or direct the oil to the slots 48, a ring 41 is located above, and a ring 48 is located The rings 4'! extend upwardly and outwardly and overlie the upper side edges of the blades 38. The rings 48 extend downwardly" and outwardly and underlie the bottom side edges of the deflector blades and direct the oil in thedirection of the slots 48. The rings 41 and 48 are supported at the outer edges thereof by spacers 49 which are positioned one on top of a pair of pipe sections 53' and 54. The tank 52 is positioned directly beneath the separator casing 19 andcomprises a cylindrical 'side wall 55,

a circular top 56 and a circular bottom 51. The pipe section 53 extends through a hole 22 in the bottom head 22 and is connected to a pipe section 54 by a union 58. extends through the top of the tank 52 and in conjunction with the pipe section 53, forms a conduit through which'the oil in the casing I 9 flows into the tank- 52. A pair of

pipe sections

59 and 68 extend between'the bottomu'iead 22 of theseparator casing and the top 58' of the tank and serve as a vent. These pipe sections are connected together by a union GI and are located diagrammatically opposite the

pipe sections

53 and 54. A tube 62 is secured in the vent oil from clogging the sections 59 and 88. Due to the fact that the refrigerant passing The pipe section 54.

upper end of the pipe section 59 and projects upwardly into the separator casing so as to prethrough the separator casing is under pressure, the oil on the bottom head 22 of .the casing is forced into the tank via the

pipe sections

53 and 54. The tank is connected by a pipe 68 to return the oil to the crank case H of the compressor 5. This pipe is connected by a union 64 to an outlet nipple 65 which extends through the central portion of the bottom of the tank. Return of the oil to the crank case is controlled by means of a valve 66. This valve is vertically slidable in the upper end of the nipple'GS and is adapted when shifted upwardly to .allow the oil to return to the crank case through the pipe 63, and when shifted downwardly, to close the nipple. The upper end of the valve is extended so as to form a stem 61. This stem is guided in a bracket 68 in the upper end of the tank and embodies a transversely extending pin 69 at its upper end.

Opening and closing of the valveis accomplished by means of a float 10 which is slidably mounted on the stem 69. As the oil flows into the tank from the separator casing, the float I0 rises.

When the float strikes the pin 69 at the upper end of the stem, the valve 66 is lifted into its open position and the oil in the tank is permitted to flow into the crank case I]. As the oil drains from the tank to the crank case, the float Ill moves downwardly on the stem 61 until it is arrested by an abutment II on the lower end of the stem. When the float engages the abutment, the weight of the float is applied to the-valve with the result that the valve is shifted into its closed position. The abutment II is preferably located so that the valve BI is closed by the float before all of the oil in the tank drains into the crank case, in order that the refrigerant is not allowed to escape into the crank case. In order to insure a proper opening and closing of the valve.

mounted in a vertical bracket 16 on the tank I bottom 51 and is connected pivotally to the portion of the plate 12 which is disposed between the abutment and the shoulder. A spring I1 is applied to the stem and operates through the medium of the links 12 to snap the 'valve into and out of its closed position. When the link I2 is raised in response to upward-shift of the stem 53 and opening of the valve 66', the spring" operates to snap the link upwardly as soon as it passes a truly horizontal position, with the result that the valve is quickly shifted into its open position and held in such position by spring pressure. When the link 12 is swung downwardly in response to downward movement of the stem 86 by the float, the spring 11 snaps. the link downwardly as soon as it passes a dead center or truly horizontal position, and eflccts a quick closing of the valve. The float I0 exemplifies simple means for openingthe valve 66 when the oil in the tank reachesv a predetermined level.

The operation of the system is as follows:

When the compressor is operated by the application of power to the pulley Hi, the piston l" operates to draw the refrigerant in the system from the low side and to compress it in the cylinder 5. From the cylinder 6, the refrigerant in a compressed state and together with any oil that works its way into the cylinder from the compressor crank case l1, flows to the inlet nipple 29 of the centrifugal separator by way of the pipe "I.

From the inlet nipple 29, the refrigerant flows upwardly through the shell 24 to the outlet nipple 23 from whence it flows or passes to the condenser via the pipe 31. As the refrigerant flows through the-shell 38, the rotatable deflectors 20 are caused Y to rotate and operate by the centrifugal action of the blades 38 to disunite and throw outwardly the oil from the refrigerant. The oil so disunited from the refrigerant is'directed to the slots 48 by the guide rings 48 and drops to the bottom head 22 of the separator casing from whence it drains into the tank 52 by way of the pipe sections 5; and. The refrigerant passing upwardly into the outlet nipple 35 is free from oil which, if allowed to pass or flow to the evaporating coil l2, would congeal and clog or impair the operation of the system. When the oil which is disunited from the refrigerant and drains into the tank 52 is sufllcient in amount to raise the float III to a point at which it strikes against the pin 69 and raises the stem 67, the valve 66 is opened and allows the oil in the tank to drain back into the crank case of the compressor through the pipe 63. Passage or return of the oil to the crank case is facilitated by virtue of case. As previously pointed out, closing of the valve is preferably effected when a small quantity of oil still remains in the tank so that the refrigerant is not permitted to flow into the crank case and there cause injury to the operating parts of thecompressor. The separator and the mechanism within the tank 55 are entirely automatic in their operation and need no lubrication because of the fact that they come in contact with the oil which-is removed from the refrigerant.

The refrigerating system which is disclosed herein is exceedingly eflicient in operation in view of the fact that it comprehends the complete and efficient removal of oil from the refrigerant prior to passage of the refrigerant to the condenser. The centrifugal separator whichis used to effect removal of the oil from the refrigerant consists of but a small number of parts and may be produced at a comparatively low cost.

The invention is not to be understood as restricted to the details set forth, since these may be modified within the scope of the appended claims, without departing from the spirit and scope of the invention.

Having thus described the invention, what I claim as new and desire to secure by Letters Patent, is:

1. In a refrigerating system, the combination with a motor-operated compressor for compressing the refrigerant for the system and an evaporating coil connected by a pipe line to receivecompressed refrigerant from the compressor, of I a separator device adapted to remove foreign liquid from the refrigerant prior to passage of the refrigerant to the coil and comprising a cylindrical shell provided with side openings and ar-' ranged'with respect to the pipe line so that the refrigerant passes longitudinally therethrough, a deflector mounted in the shell for rotation transversely'thereof and having radially extending, angularly disposed blades whereby it is caused to rotate in response to passage of the refrigerant'throughthe shell and all foreign liquid in suspension in the' refrigerant is caused by centrifugalforce to be'thrown outwardly through the "side openings in the shell; and a casingv around the shell forcatching' the liquid that is flung or thrown outwardlythrough the side openings in the shell by the'deflector.

3. Ina' refrigerating system, 'a circulating system'including a condenser, an evaporator, an oil lubricated compressor for transferring refrigerantin gaseous'form from said evaporator to said condenser, a device included in the circulating system' between the compressor and con- I denser and a rotating element included in said device- 'for intercepting oil passed into the circulating system by the compressor and for removing-it from the gas stream by centrifugal force.

4. In'a refrigerating system, a circulating system including a condenser, an evaporator, an oil lubricated compressor for transferring refrigerant in gaseous form from said evaporator to said condenser, a separator included in the circulating system between the compressor and condenser, 'a rotating'element in said separator having blades against whichth'e gas impinges as it passes from the compressor and on which oil escaping from'the compressor accumulates, said blades being operative to impart a rotary motionto the'ac'cumulated oil and cause it to flow outwardly by centrifugal force, and 2. Compartment in the'separator for receiving the oil from said rotating elementr I 5.'In a refrigerating system,-a condenser, an evaporator, a compressor for transferring gaseous refrigerant from the evaporator to thelcondens'er, and means in the path of the flowing gas for precipitating and removing foreign liquid suspended therein, said means including arotating element on which the foreign liquid accumulates and over which it flows out of the gas stream by centrifugal force.

, 6. In a refrigerating system, a compressor, a closed circulating system through which ;said compressor forces refrigerant, the same being in the form of a" gas in certain parts of the system and in liquid form in another part, a rotating element included in the-system at a point where the-refrigerant is a gas for accumulating foreign liquid suspended in the gas and for impartinga rotary movement to such liquid which removes it from the gas stream by centrifugalforce'and" a receptacle in which the liquid is received from said rotating element.

\ 7. In a refrigerator, a circulating system in-' cluding refrigerating elements and a refrigerant which atone stage of the refrigerating cycle is a 1 gas, means for propelling the gaseous refrigerant and rotated by impinging of the gas stream thereon, said element operative during rotation to in-' tercept impurities present in the gas and impart to such impurities a rotary motion which moves them out of thegas stream by centrifugal force,

and means for collecting such impurities and for preventing them from being again the refrigerant.

8. In a refrigerator, apparatus for liquefying mixed with and purifying a gaseous refrigerating substance; said apparatus comprising a condenser, a rotatable element operable by gas flow, a compressor adapted to force said gaseous substance past said element to said condenser at suflicient velocity to the gas stream by centrifugal force, and means their return to the gas stream. 1

9. In a refrigerator, a circulating system including refrigerating elements and a refrigerantwhich in a portion of the system is in gaseous form, means for causing circulation of the refrigerant in said system, and a rotatable element included in said system at a point where'the refrigerant is a gas and is circulating at high velocity, said element being operated responsive to ,flow of the refrigerant and being effective to intercept impurities from the refrigerant and accelerate such impurities in a direction which tends to remove them from the circulating refrigerant. 10. In a. refrigerator, a circulating system for collecting said impurities and for preventing containing a refrigerant which in one part of the system is a gas, there being a variable'quantity of a foreign substance mixed with said-refrigerant and held in suspension therein, rotatable elements included in the system at a point where the said refrigerant is a gas, means for propelling the gaseous refrigerant past said point at a sufficient velocity to operate said elements, the same allowing the gas to pass substantially unimpeded but operating to collect said foreign substance and impart a whirling motion thereto,

whereby it is removed from the gas by centrifugal force.

JULIUS F. KOPSA.-