US2089626A

US2089626A - Refrigerating apparatus

Info

Publication number: US2089626A
Application number: US742273A
Authority: US
Inventors: Rolf M Smith
Original assignee: Motors Liquidation Co
Current assignee: Motors Liquidation Co
Priority date: 1934-08-31
Filing date: 1934-08-31
Publication date: 1937-08-10
Anticipated expiration: 1954-08-10

Description

Aug. 1937- R. M. SMITH 2,089,626

REFRIGERATING APPARA'] l -Filed Aug. 31, 1934 2 Sheets-Sheet 1 INVENTOR.

ATTORNEY.

Aug. '10, 1937.

R. M. SMITH 2,089,626

REFRIGERATING APPARATUS Filed Aug. 31, 1934 2 Sheets-Sheet 2 INVENTOR. WOLF /7. SM/ 7' fl wgm 752..

ATTORNEY.

Patented Aug. 10, 1937 PATENT OFFICE REFRIGERATING APPARATUS Rolf M. Smith, Dayton, Ohio, assignor to General Motors Corporation, Dayton, Ohio, a corporation of Delaware Application August 31, 1934, Serial No. 742,273

4 Claims.

This invention relates to refrigerating apparatus and more particularly to motor-compressor units for use with refrigerating apparatus.

Hitherto, in the design of motor-compressor units of the character described, particularly for such units which employ a rotary-compressor, it has been customary in order to reduce the vibration produced in operation to provide counter-balancing means for the unbalanced moving portion of the rotary compressor. Commonly, units of this type and especially those which are mounted within a hermetically sealed housing, are constructed with the rotor of the electric motor directly connected to the compressor by means of a shaft which mounts both the rotor and the moving portion of the compressor. Since the rotor is generally a symmetrical body, it is inherently self-balanced and in order to balance the moving portions of the compressor, counter-weights have been applied to the shaft in one position or another generally within the compressor itself or at a point closely adjacent thereto.

By the present invention, there is provided a motor-compressor unit in which the rotating system comprising the rotor, the shaft, and the moving portion of the compressor, are balanced both statically and dynamically by giving a predetermined unbalance to the rotor itself which is of such relation to the unbalance of the moving portion of the compressor, that the complete rotating system becomes fully balanced.

It is an object of the invention, therefore, to provide a statically and dynamically balanced motor-compressor unit wherein the rotor of the motor is given an unbalance which is so corre lated with the unbalance of the moving portion of the compressor as to completely counter-balance the same both statically and dynamically.

A. further object is to provide a rotor for use in a motor-compressor unit having a degree and character of unbalance such that when assembled with a compressor having a moving portion of predetermined unbalance, a completely balanced unit will result.

Another object is to provide a method of balancing a motor-compressor unit and particularly a method of assembling a rotor for use in such a .unit in a manner which provides both static and dynamic balance of the complete unit.

Further objects and advantages of the present invention will be apparent from the following description, reference being had to the accompanying drawings,'wherein a preferred form of the present invention is clearly shown.

In the drawings:

Fig. 1 is a cross section of a motor-compressor unit embodying the present invention and showing diagrammatically the refrigerating system in conjunction therewith;

Fig. 2 is a perspective view of the rotating system of the motor-compressor unit shown in Fig. 1;

Fig. 3 is a top View of a rotor illustrating a 'second embodiment of the present invention;

while Fig. i is a cross section on line t-t of Fig. 3.

Referring to Fig. i, there is shown a motorcompressor unit generally designated as if! having a refrigerant outlet l2 from which compressed gaseous refrigerant is delivered by means of a conduit it to a condenser 56 of suitable form, the drawings illustrating one of the flat hollow plate type. A conduit it delivers refrigerant liquefied in the condenser it to a heat interchanger 263 formed in a header of the evaporator 22. From the heat interchanger 2t, cooled liquid refrigerant is delivered to a refrigerant control restrictor 2t, whence it is permitted to expand into the evaporator 22 through the conduit 26. Evaporation of refrigerant in the evaporator 22 withdraws heat from a cabinet or other object to be cooled (not shown) and the evaporated refrig- Y erant is withdrawn from the evaporator and delivered to the inlet 28 of the compressor ill by means of a conduit 30. A suitable automatic switch (not shown) may be provided to maintain substantially constant temperatures at the evaporator 22. v

The motor-compressor unit preferably comprises a hermetically sealed casing 32 which is closed by a base plate 34 secured thereto as by crimping and welding at 36. 'Rigidly mounted between the end plate 34 and a recess 38 formed in the top of the housing 32 is a hollow stationary shaft 40. A hollow rotary shaft 42 is journaled on the shaft and carries at its upper end a rotor 44 and its lower end the moving portion d6 of a rotary-compressor 48. The compressor may be of any well known type in which the moving portion is not symmetrical with the axis of the shaft 42 and is, therefore, unbalanced. Merely by way of example, the compressor illustrated is of the type having a cylindrical impeller journaled on an eccentric on the drive shaft and which is given a revolving or gyrating movement within a cylindrical compression chamber con centric to the axis of the shaft 422, a vane or divider block being provided in the cylinder block to divide the cylinder chamber into a suction space and a compression space. Such compressors are well known in the art, and further description thereof is unnecessary.

In order to put the rotating system which com-' 6 prises the rotor 48, the shaft 42 and the moving portion 48 into both static and dynamic balance, the rotor 84 is provided with means forming two counter-weights, one at either end of the rotor. In the form of the invention illustrated in Fig. 1, these may comprise an upper counter-weight 58 situated on the same side of the shaft as the center of gravity of the moving portion 48 and a lower balance weight 52 situated diametrically opposite to the weight 50 and the center of gravity of the moving portion 48. The weight and the position of the counter-balances 50 and" are determined in accordance with the unbalance of the moving portion 85 in the following manner. Referring to Fig. 2, if the point Wo be considered the theoretical center of inertia which is located at a distance Xn from the shaft axis AA equal of the radius of gyration of the moving portion 48 with reference to the axis AA; Wi the center of inertia of the counter-weight 52 located at the distance X1 from the axis A--A equal to the radius of gyration of the counter-weight 52; and W: the center of inertia of the counter-weight 58 which is located at a distance X: from the axis A -A equal to the radius of gyration of the counter-weight 58, and if the vertical distance between the points We and W1 be taken as Y1 and the vertical distance between the points Wu and W: be taken as Y2, the requirements for static balance are:

This means that the sum of the moments of inertia of the three unbalanced portions of the rotating system with respect to the axis A-A must be equal to giving proper regard to the. sign of each.

In order to put the system in dynamic balance as well, it is necessary that the sum of the products of inertia of the three unbalanced portions of the system taken about a point on the axis A--A be equal to 0. For convenience, 8. reference point may be taken as the center of gyration of the mass W0. Then Conveniently, the distance X1 may be made equal to the distance X: and may be assigned any arbitrary value less than the radius of the rotor 88.

With the value of the quantities W0, X0, Y1, and 55 Y: together with the value for x1 and X: thus known they may be substituted in the above formulas to determine the quantities W1 and W2. From these values suitable counter-weights may be designed and attached to the rotor 44 in the manner illustrated.

Referring now to Figs. 3 and 4, there is illustrated a modification of the present invention wherein the necessary unbalance of the rotor is provided by lightening holes formed in the rotor opposite to the points where additional weight is necessary for counter-balancing. This rotor 54 may conveniently comprise a plurality of laminations 58 of sheet metal. At one side of the rotor and in the top section thereof, there is formed one or more lightening holes 58, while at the opposite'side near the bottom, there is formed a similar number of corresponding lightening holes 88. Conveniently in order to provide a passage for gaseous refrigerant through the rotor, smaller holes 82 are formed therein communicating with the lightening holes 58 and 88, although it will be understood that this feature is not essential to the present invention. It will be noted that the holes 58 are of lesser depth than the holes 68, and that there is thus provided a preponderance of weight at the top of the rotor opposite the holes 58 and a preponderance of weight at the bottom of the rotor opposite the holes 68, and that the preponderance at the bottom is greater than the preponderance at the top corresponding to the greater weight of the counter-balance 52 relative to the counter balance 58. The holes 58 and 88 may be formed by drilling the rotor after it is assembled. It is preferred, however, to form the rotor of laminations with holes punched therein to correspond to the holes 58 and the holes 68. It will be noted that each of the laminations may be formed from the same die and that the proper unbalance can be provided by assembling the laminations in such a manner that the upper portion of the rotor has the large holes 58 located at one side of the axis while the lower portion has the large holes 88 located at the opposite side of the axis. It will be understood that while the rotor illustrated is formed of laminations, all of which are identical, it is possible to form a rotor from a stack of more than one kind of laminations and that the depth of the hole 58 plus the depth of the hole 88 need not be equal to the thickness of the rotor as is illustrated in Fig. 4.

By this construction, there is provided a rotor which when assembled with a shaft and the moving portion of a compressor having a predetermined degree of unbalance, provides a rotating.

system which is completely balanced both statically and dynamically without additional counterweights.

While the form of embodiment of the invention as herein disclosed, constitutes a preferred form, it is to be understood that other forms might be adopted, all coming within the scope of the claims which follow.

What is claimed is as follows:

1. In a motor-compressor unit, the combination of a sealed casing, a drive shaft within said casing, a dynamically unbalanced compressor rotor on the lower portion of said shaft, a compressor stator cooperating with said rotor, a motor stator in the upper portion of said casing, a motor rotor on the drive shaft, the compressor discharging compressed fluid into the interior of said casing below said rotor, said motor rotor having openings therethrough which dynamically unbalance said motor rotor with respect to itself but dynamically balance said motor rotor and said compressor rotor as a unit, means for conveying gas to said compressor and means for withdrawing compressed gas from the space above said motor rotor whereby said openings serve as gas passageways.

2. In a motor-compressor unit, the combination of a sealed casing, a motor stator in said casing, a compressor stator in said casing, bearing means in said casing, a drive shaft on said bearing means, a motor rotor on said shaft, a dynamically unbalanced compressor rotor on said shaft, said motor rotor being located above said compressor rotor and having'openings placed and proportioned for dynamically unbalancing said motor rotor but dynamically balancing said motor rotor and compressor rotor as a unit, means for ingress and egress of gas to and from said compressor so constructed and arranged that at least a portion of the c pressed gas passes through said motor rotor ope through said motor rotor openings.

4. In a motor-compressor unit, the combina-p tion oi! a sealed casing, a motor stator in said casing, a compressor stator in said casing below said motor stator, bearing means ,in said casing, a drive shaft on said bearing means, a motor rotor on said shaft; a dynamically unbalanced compressor rotor on said shaft, said motor rotor having openings therethrough which dynamically unbalance said motor rotor with respect to itself but dynamically balance said motor rotor and said compressor rotor as a unit, means for conveying gas to said compressor and means for withdrawing compressed gas from within the sealed casing, said last named means comprising,

an outlet located above said motor rotor whereby at least a portion oi! the compressed gas passes through said motor rotor openings.

ROLF M. SMITH.