US2581466A

US2581466A - Means for maintaining liquid level in heat-exchange apparatus

Info

Publication number: US2581466A
Application number: US6083A
Authority: US
Inventors: Carlyle M Ashley
Original assignee: Carrier Corp
Current assignee: Carrier Corp
Priority date: 1948-02-03
Filing date: 1948-02-03
Publication date: 1952-01-08
Anticipated expiration: 1969-01-08

Description

Jan. 8, 1952 c. M. ASHLEY 2,581,466

MEANS FOR MAINTAINING LIQUID LEVEL IN HEAT-EXCHANGE APPARATUS Filed Feb. 5, 1948 OOOOOOOOOOOO a O O Patented Jan. 8, 1952 MEANS FOR MAINTAINING LIQUID LEVEL IN HEAT-EXCHANGE APPARATUS Carlyle M. Ashley, Syracuse, N. Y., assignor to Carrier Corporation, Syracuse, N. Y., a corporation of Delaware Application February 3, 1948, Serial No. 6,083

1 Claim. 1

This invention relates to heat exchange. apparatus and more particularly to automatic means for preventing the liquid level in the evaporator or cooler of, for example, a centrifugal refrigeration machine, from rising above a predetermined; point under overload conditions.

In centrifugal refrigeration systems, for example, a balanced charge of refrigerant is normally maintained in the evaporator. In use, however, as the load imposed upon the system increases, the amount of refrigerant gas trapped in the liquid in the evaporator increases. The increase in the amount of gaseous refrigerant present in the evaporator decreases the density of the liquid refrigerant. the liquid refrigerant results in a greater volume of refrigerant and an increase in foam in the space above the tubes. of the evaporator. Generally, eliminators are provided to break up the foam and to prevent liquid carry-over to the compressor. The use of eliminator-s increases the-cost of the system and in addition increases the amount or" space required. Without eliminators, however, the amount of space required, to perform the same function is so great as to be impracticable under normal conditions of use.

The chief object of the present invention is. to

provide heat exchange apparatus inwhich carryover at high loads is prevented andv increased, capacity is obtained at low loads.

An. object of the present invention is to provide a refrigeration system including means. for effectively preventing the liquid. level in the. cooler from. rising above a predetermined point. under overload conditions.

A further object of the invention, is to provide a. refrigerationsystem includingmeans for automatically regulating the liquid level maintained in, the evaporator under all conditions of use.

A; still further object is to provide a refrigeration system including a collecting chamber attached, to the evaporator of the system, the collecting chamber being effective for withdrawing a portion of the liquid refrigerant from the evaporator upon an increase in load to prevent a corresponding increase in the effective liquid level maintained in the evaporator, andmeansfor returning thewithdrawn refrigerant to the cooler when. such conditions have, ceased. Other objects of my invention will be readily perceived. from the following description.

This. invention relates to a refrigeration system including a compressor, a condenser, and an evaporator or cooler. As. is well known, an economizer may be providedto reduce the costof op- The decrease in density of eration of the system. Liquid refrigerant is collected in the evaporator and is placed in heat exchange relation with a medium to be cooled. Such medium passes through a coil disposed in the evaporator. The system is designed to operate upon a balanced refrigerant charge so that a predetermined quantity of liquid refrigerant is present in the evaporator under normal load con ditions. As load imposed upon the system increases, the density of the liquid decreases due to trapping of gaseous refrigerant in the form of bubbles. Trapping of gaseous refrigerant within the pool. of liquid refrigerant maintained in the evaporator causes an increase in the effective level of the liquid refrigerant; such increase or rise in effective level of the liquid refrigerant results in a considerable increase in the amount of foam present. above the tubes of the evaporator and permits carry-over to some extent of liquid refrigerant to the compressor. In order to stabilize the level of refrigerant within the evaporator at a maximum point under overload conditions, a collecting chamber is provided disposed with its opening slightly above the top level of the coil and with its bottom at approximately the shut-down level of the liquid. Such chamber may belocatedwithinor without the evaporator. As the load imposed upon the system; increases, the level of-foam within the evaporator increases until it is slightly above the openingleading to the collecting chamber. The foam then spills over intothe collecting chamber; the collecting chamber eventually fills with liquid, thereby removing a portion of the refrigerantchargefrom active circulation in the system and stabilizing the level-of refrigerant in the evaporator ata predetermined point. Preferably, means are provided to returna portion or all ofthe liquid collected in the collecting chamber to the evaporator when the load imposed upon the system decreases:

The-attached drawing illustrates a preferred embodiment of. myinvention, in i which Figure 1 is a diagrammatic viewof a centrifugal refrigeration system embodying the present-invention;

Figure 2 is a sectional View through the'evaporator of; the system shown in Figure 1 illustrat ing the collecting chamber;

Figured is aview in elevation of the evaporator of the system. shown in Figure 1;

Figure dis a sectional view of amodified form of evaporator illustrating the collectingchamber disposed within the evaporator; and

Figure-,5 is a: sectional view illustrating the cooler. into the suction of compressor 3; the suction gas to the condenser water.

-3 present invention embodied in an absorption refrigeration system.

Referring to the drawing, the present invention is illustrated embodied in a centrifugal refrigeration system of the type disclosed in Jones Patent No. 2,314,402, granted March 23, 1943. The system comprises an evaporator or cooler 2 connected to a centrifugal compressor 3 which in turn is connected to a condenser 4 by line 5. A plurality of tubes or coils 6 are disposed in condenser 4. Cooling water is passed through the tubes t in heat exchange relation with compressed gaseous refrigerant forwarded to condenser 4 by compressor 3 to liquefy the same. Liquid refrigerant from condenser 4 flows into an economizer l. Refrigerant from economizer '1 passes into cooler 2 and serves as make-up refrigerant for the refrigerant being evaporated therein. Tubes or coils 8 are disposed in cooler 2. A medium to be cooled is passed through the tubes 8 in heat exchange relation with refrigerant in cooler 2; gaseous refrigerant formed in cooler 2 passes to compressor 3, is compressed and again forwarded to condenser 4.

v To maintain a desired liquid level in cooler 2 even under conditions of overload of the system, a collecting chamber 9 is provided extending longitudinally of cooler 2. Preferably, chamber 9 is disposed without the shell of cooler 2. Suitable trough-like members I connected to chamber 9 extend above tubes 8 to permit foam within cooler '2 to spill therein and to flow into collecting chamber 9. I The member H! are disposed in such position within the cooler 2 as to maintain a maximum liquid level within the cooler under overload conditions. A line H connects chamber 9 with the bottom of cooler 2 to permit refrigerant condensed therein to be returned to the evaporator or cooler 2 as hereinafter described. A restriction I2 is disposed in line l2 in order to regulate the quantity of refrigerant returning to the cooler. Preferably, restriction I2 is so designed as to limit returned refrigerant to such quantity as to balance the rate of collection, i. e., permitting an equivalent amount of liquid refrigerant to return to the cooler to balance the amount of foam which spills over into, the collecting chamber.

In operation, conditioning medium flowing through the tubes 6 of cooler 2 is warmer than the liquid refrigerant in the cooler. Consequently, heat is transferred from the conditioning medium to the liquid refrigerant. This heat evaporates or boils off the refrigerant at a temperature corresponding to the pressure in the The refrigerant evaporated is drawn '(gaseous refrigerant) is partially compressed by the first stage impeller of compressor 3 and then enters the second stage impeller of the compressor. Compression of the gaseous refrigerant is completed by the following compressor stages and the compressed gas is discharged into condenser 4. Refrigerant discharged by compressor 3 into condenser 4 condenses on the exterior of the condenser tubes 6 at a temperature corresponding to condenser pressure. This temperature is higher than that of the water in tubes 6 so that the heat of condensation is transferred Liquefied refrigerant drains from condenser 4 into economizer I and is supplied from economizer 1 to cooler 2 as previously described.

Assume an increase in load imposed upon the centrifugal system; such increase in load-reduces the density of the liquid refrigerant within cooler 2 since gaseous refrigerant is trapped in the liquid in the form of bubbles. Trapping of gaseous refrigerant increases the volume of refrigerant within cooler 2 which results in a considerable increase in the amount of foam present above tubes 8 of cooler 2. In order to prevent an increase in liquid refrigerant within cooler 2 beyond a desired point, collecting chamber 9 is provided. Under overload conditions, for example, the level of foam within cooler 2 increases until it is slightly above members I0 connected to the collecting chamber 9. The foam then spills over into members I0 and flows into the collecting chamber 9, thus maintaining a predetermined liquid level within cooler 2. The collecting chamber 9 eventually fills with liquid refrigerant thereby removing a portion of the refrigerant charge from active circulation in the system and stabilizing the level of the refrigerant in the evaporator at a predetermined point. As the load imposed upon the system decreases, liquid refrigerant in chamber 9 is returned to cooler 2 through line ll. Restriction I2 in line H serves to regulate the quantityof refrigerant returned to cooler 2.

In the system described above, collecting chamber 9 is disposed without the shell of cooler 2. In Figure 4, I have illustrated a modified form of my invention in which collecting chambers l3 are provided, such chambers 13 being disposed within the shell of cooler 2 between the bank. of coils 8 and the interior wall of the shell. Such chambers l3 serve the same function as chamber 9 in that upon an increase in load imposed upon the system with a resulting decrease in density of refrigerant within cooler 2, excess foam spills over into chambers 13 thus maintaining the liquid level within the cooler at a predetermined point. Such refrigerant may be returned to the cooler through restrictions I4 therein as the load imposed upon the system decreases.

Figure 5 illustrates the present invention applied to an absorption refrigeration system. An absorption refrigeration system may include a generator l5,condenser l6, absorber (not shown), and evaporator (not shown), connected by suitable lines permitting flow of strong and weak;

- therein is decreased and the level of solution in the generator rises, excess solution spilling over into the chamber 2!. Solution from chamber 20 is not returned directly to the generator but is forwarded to the strong solution line connecting the generator and the absorber for supply to the absorber of the system.

The present invention provides a simple and effective means for regulating the liquid level within the cooler, generator or evaporator of a refrigeration system under high and overload conditions. The invention may be applied to centrifugal, reciprocating and absorption refrigeration systems. The invention permits complete submergence at low load as well as preventing carry-over at high loads without substantial increase in the cost of the; system. The means longitudinally of the cooler and connected there to to receive excess refrigerant only when the so provided permits a reduction in the size of equipment required for'a specific load and reduces the initial cost oi the equipment by eliminating the various elements of the system heretofore required to prevent liquid carry-over from the cooler to the compressor.

While I have described .a preferred embodiment of the invention it will be understood the invention is not limitedthereto, since it may be otherwise embodied within the scope Of the following claim.

I claim: 1 I

In a centrifugal refrigeration system, the combination of a compressor, a condenser and a cooler connected in a closed circuit, a coil in the cooler through which a medium ,to be cooled passes, a pool of liquid refrigerant in the cooler surrounding at least a portion, ofthe coil, ebullition of the liquid occurring during operation of the system thereby increasing the liquid level in the cooler, a chamber without the cooler extending liquid level in the cooler reaches a predetermined maximum under overload conditions, a li'n'e connecting the chamber and the cooler to return refrigerant from the chamber to the cooler, and a valve in said line to regulate return of refrigerant from the chamber to the cooler.

CARLYLE M. ASHLEY.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,853,724 Davenport Apr. 12, 1932 2,010,547 Kenney et al. Aug. 6, 1935 2,032,286 Kitzmiller Feb. '25, 1936 2,247,107 Waterfill Jun 24, 1941 2,312,313 Beline May 2, 1943 2,384,413 Zwickl Sept. 4, 1945 2,408,480 Reid Oct. 1, 1946