US3074646A - Air separator fitting for hydronic system - Google Patents

Air separator fitting for hydronic system Download PDF

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US3074646A
US3074646A US70722A US7072260A US3074646A US 3074646 A US3074646 A US 3074646A US 70722 A US70722 A US 70722A US 7072260 A US7072260 A US 7072260A US 3074646 A US3074646 A US 3074646A
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air
tank
liquid
chamber
outlet
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US70722A
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Edwin B Tidd
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ITT Bell and Gossett Inc
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Bell and Gossett Co
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24DDOMESTIC- OR SPACE-HEATING SYSTEMS, e.g. CENTRAL HEATING SYSTEMS; DOMESTIC HOT-WATER SUPPLY SYSTEMS; ELEMENTS OR COMPONENTS THEREFOR
    • F24D19/00Details
    • F24D19/08Arrangements for drainage, venting or aerating
    • F24D19/082Arrangements for drainage, venting or aerating for water heating systems
    • F24D19/083Venting arrangements
    • YGENERAL 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
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T137/00Fluid handling
    • Y10T137/5109Convertible
    • Y10T137/5283Units interchangeable between alternate locations

Definitions

  • This invention relates to a novel tank type fitting for use in separating entrained air from a fluid flowing in a hydronic heating or cooling system and more particularly it is concerned with a tank type fitting for universal installation in all types of heat exchangers and boilers. For this purpose it has inlet and outlet openings arranged to accommodate connection to either side outlet or top outlet arrangements.
  • Another object of the invention is the provision of a fitting of the above type that may also be connected for either upfeed or downfeed radiation circuits'or both in the case of multiple zone system-s.
  • FIG. 1 is a vertical sectional view through the novel fitting'of this invention
  • FIG. 2 is a top plan view of the fitting with parts broken away and sectioned to facilitate disclosure
  • FIG. 3 is a fragmentary diagrammatic illustration of a hot water heating system having a side outlet type boiler that is shown equipped with the air separator fitting of this invention
  • FIG. 4 is a fragmentary diagrammatic illustration of a hot water heating system having a top outlet type boiler that is shown equipped with the identical air separator fitting;
  • FIG. 5 is a diagrammatic side elevational view illustrating the application of the fitting with a packaged type boiler installation.
  • FIGS. 1 and '2 a preferred form of air separator fitting as is illustrated in FIGS. 1 and '2, for purposes of disclosure, comprises a vertically elongated hollow tank 10 having generally elliptically shaped surrounding side wall structures 10S and correspondingly shaped top and bottom walls 10T and 10B, respectively, enclosing and defining an air separation chamber 11 of substantially greater flow capacity than the piping of the liquid flow circuit in which it is used.
  • a water outlet or port opening 12 and an air outlet opening 13 are provided in the top wall adjacent its opposite extremities with a dip tube 14 being fitted permanently within the liquid outlet and projecting to a point adjacent the bottom wall of the fitting.
  • the dip tube thus provides a separate chamber located within the confines of the main separator chamber 11, and the lower end of the dip tube is open and is cut on a bias to more efficiently receive the air free liquid pooling in the bottom of the chamber for discharge through the top outlet.
  • An opening or port 15 is provided adjacent the top and approximately centrally of one of the major side wall sections to provide an inlet port for convenient connection to a side outlet type boiler arrangement.
  • As fluid enters the port 15 from a side inlet pipe connection it jets across the separation chamber at high velocity to strike the opposite major side wall section and deflect for directing the fluid stream toward the bottom of the tank. at. a greatly reduced velocity.
  • This reduction in velocity of the entering liquid permits the entrained air to separate from the moving stream, whereupon the air rises to the top of the tank for delivery through the air outlet port 13.
  • the air-free fluid collecting in the bottom of the tank is continuously drawn up the dip tube to exit through the liquid outlet port 12.
  • a side outlet type boiler 20 the fitting 10 of this invention mounted alongside the boiler and connected through a conduit, not shown, which leads into its side inlet port 15 to deliver a stream of water entrained with air bubbles
  • a booster pump 21 having its suction side connected to the top outlet port 12 by a conduit 22 and having its dis-I charge side connected through supply piping 23 leading to the radiation gear, with the piping 24 constituting a return line from the radiation gear and feeding into the bottom of the boiler.
  • a conventional compression tank 25 is connected through a line of piping 26 to the air outlet port 13 for receiving and storing the air that is sep-. arated out by the fitting 10.
  • a cold water supply line 27 is shown tapped into the piping 26 and includes a con trol valve 28 for initially filling the system.
  • An opening or port 16 is provided through the bottom wall 10B of the tank at-an extremity thereof adjacent to the end of the top wall at which the air outlet port 13 is located and this'port' is bidirectional in that in some applications of the fitting air-free liquidvemerges-from the tank through this port and in other applications liquid entrained with air enters the tank for separation of the air in the tank.
  • FIG. 3 When the fitting is used on a side outlet boiler arrangement such as is shown in FIG. 3, it may be required that the air-free liquid be withdrawn from the port 16 of the bottom wall rather than through the dip tube.
  • An ar rangement of this type is also shown in FIG. 3 wherein, for the moment, it may be assumed that the outlet port 12 of .the dip tube is plugged up.
  • a separate radiation system isshown having piping 29 connected to extend from the bottomport 16 of the fitting 10 to the suction side. 'of a booster pump 30, the discharge side of which 3 is connected to piping 31 that feeds radiation gear, not shown, with the return line 24 being assumed to be connected to the other side of this system.
  • FIG. 3 may also be viewed as an illustration of a multiple zone radiation system having one radiation circuit that includes the booster pump 21 being supplied with air free liquid from the dip tube 14 and outlet port 12 and having a separate radiation circuit that includes the booster pump 30 being supplied with air-free liquid through the bottom outlet port 16.
  • An added advantage of the fitting of this invention is that it is conveniently adaptable to the connection arrangements for such a multiple zone system and moreover it maintains its efliciency even in such a multiple zone system.
  • the air separating action in the tank is substantially identical, since in both instances the air-free liquid is drawn out from a point closely adjacent the bottom of the tank.
  • liquid may be drawn simultaneously through both the dip tube 14 and the bottom port 16.
  • the other function of the bottom port 16 of the fitting 10 relates to the use of the fitting with top outlet type boiler arrangements such, for example, as is shown in FIG; 4 in which case the port 15 of the side wall is plugged up.
  • the liquid entrain'ed with air issues from the boiler and enters through the bottom port 16 and air free liquid is drawn otf through the dip tube.
  • the air entrainedliquid enters atthe bottom of the fitting and flows into the enlarged air separation chamber 11
  • its velocity of flow is reduced sufliciently to permit air bubbles to separate out from the liquid, whereupon the air bubbles again rise to the top of the separation chamber for delivery to the compression tank 25.
  • This action is, in general, similar to that described previously, and a radiation system is shown in FIG.
  • fittinglfl is mounted directly above the boiler 20 that is illustrated as being of the' top outlet type, with piping 20F connecting the liquid being discharged from the boiler into the bottom port of the fitting.
  • Air-free liquid is drawn off through the piping 22 by a booster pump 21 which circulates the airf reeliquid throughout the system.
  • the compression tank 25 is connected through the piping 26 to the air outlet port 13 and a water supply line 27 having a valve 28 is again shown tapped into the piping 26.
  • FIG. 5 a side outlet type boiler 20 is shown connected to the fitting 10 and a metal jacket 32 encases these parts as well as a number of related components. Since the fitting is elliptical it may be mounted alongside the boiler with a minimum of lateral projection and therefore the enclosing jacket may be of correspondingly smaller size,
  • a multiple purpose air separator for direct interposition in a forced circulation hydronic system of the type including a boiler of either the side outlet or top outlet type and also including a booster pump and piping connecting the boiler, the separator and the booster pump in series, and a compression tank connected for trapping air separated from liquid in said system, said separator comprising a tank.
  • said tank having openings therein providing a vertically elongated chamber of substantially greater flow capacity than said openings in said tank, said tank having surrounding side wall structure provided with an inlet opening horizontally therethrough for supplying liquid entrained with air horizontally into said chamber to impinge upon an opposing portion of said side wall structure and effect a velocity reduction of said liquid as it enters said tank to allow for separation of entrained air and a pooling of air free liquid within the lower end of said chamber, said tank having a top wall having a liquid outlet opening and an air outlet opening at opposite extremities thereof and having a dip tube in said liquid outlet opening and projecting to adjacent the lower end of said chamber for drawing air free liquid pooling within the lower end of said chamber, and said tank having a bottom wall having an opening to said chamber and optionally connectable either as a liquid outlet that communicates only with air free liquid pooling within the lower end of said chamber or as a liquid inlet opening into said chamber for supplying liquid entrained with air therein to effect a velocity reduction of said liquid as it enters said
  • a multiple purpose air separator for direct interposition in a forced circulation hydronic system of the type including a boiler of either the side outlet or top outlet type and also including a booster pump and piping connecting the boiler, the separator and the booster pump in series, and a compression tank connected for trapping air separated from liquid in said system, said separator comprising a tank having openings therein providing a vertically elongated chamber of substantially greater flow capacity than said openings in said tank, said chamber having a generally elliptical horizontal cross-sectional configuration, said tank having surrounding side wall structure provided centrally within one major wall section thereof with an inlet opening horizontally therethrough for supplying liquid entrained with air horizontally into said chamber to impinge upon an opposing major wall section of said side wall structure and effect a velocity reduction of said liquid as it enters said tank to allow for separation of entrained air and a pooling of air free liquid withinthe lower end of said chamber, said tank having a top wall having a liquid outlet opening and an air outlet opening at opposite extremities thereof and having a dip tube
  • a forced circulation hydronic system including a boiler of either of the side outlet or top outlet type, a multiple purpose air separator, a booster pump, piping connecting the boiler, the separator and the booster pump in series, and a compression tank con nected for trapping air separated from liquid in said system
  • said separator comprising a tank having openings therein providing a vertically elongated chamber of substantially greater flow capacity than said openings in said tank, said tank having surrounding side wall structure provided with an inlet opening horizontally therethrough for supplying liquid entrained with air horizontally into said chamber to impinge upon an opposing portion of said side wall structure and efiect a velocity reduction of said liquid as it enters said tank to allow for separation of entrained air and a pooling of air free liquid within the lower end of said chamber, said tank havng atop wall having a liquid outlet opening and an air outlet opening at oppositeextremities thereof and having a dip tube in said liquid outlet opening and projecting to adjacent the lower end of said chamber for drawing air free liquid pool

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Steam Or Hot-Water Central Heating Systems (AREA)

Description

Jan. 22, 1963 E. B. TIDD AIR SEPARATOR FITTING FOR HYDRONIC SYSTEM Filed Nov. 21, 1960 $1 n M MB mmm Z d E United States PatentOfiflce Bflldfidfi Patented Jan. 22, 1963 3,074,646 AIR SEPARATQR FlTTiNG FOR HYDRONHC SYEsTEM Edwin B. Tidd, Park Ridge, 111., assignor to Bell & Gossett Company, a corporation of Illinois Filed Nov. 21, 1960, Ser. No. 70,722 3 Claims. (Cl. 237-63) This invention relates to a novel tank type fitting for use in separating entrained air from a fluid flowing in a hydronic heating or cooling system and more particularly it is concerned with a tank type fitting for universal installation in all types of heat exchangers and boilers. For this purpose it has inlet and outlet openings arranged to accommodate connection to either side outlet or top outlet arrangements.
It is well known that as a flowing stream of water is heated air bubbles-become entrained in the stream and are carried with it through the piping and radiation gear of a hydronic system. These entrained air bubbles cause gurgling noises throughout the system and in many instances become lodged in part of the radiation gear so as to interfere with or actually prevent the desired 'circulation through the system. Various facilities are known for separating these entrained air bubbles from the main stream of the fluid circuit and collecting and depositing the air bubbles in a compression tank that is Provided for the system. Prior to the present invention the fa cilities for side outlet and top outlet boiler arrangements have been distinctively diflerent due to the varying fluid connection and air separation problems that are involved. Moreover, the present day facilities have been unduly expensive in many instances and have required special piping and other auxiliary fittings to facilitate their incorporation into a system and in other instances have been diflicult to locate.
The provision of a tank type air separator fitting of compact low-cost construction and of substantially universal application to both side outlet and top outlet types of boilers is the principal object of this invention.
Another object of the invention is the provision of a fitting of the above type that may also be connected for either upfeed or downfeed radiation circuits'or both in the case of multiple zone system-s.
Other objects and advantages of this invention will be apparent during the course of the following description.
In the accompanying drawings forming a part of this specification, and in which like numerals are employed to designate like parts throughout the same:
FIG. 1 is a vertical sectional view through the novel fitting'of this invention;
FIG. 2 is a top plan view of the fitting with parts broken away and sectioned to facilitate disclosure;
FIG. 3 is a fragmentary diagrammatic illustration of a hot water heating system having a side outlet type boiler that is shown equipped with the air separator fitting of this invention;
FIG. 4 is a fragmentary diagrammatic illustration of a hot water heating system having a top outlet type boiler that is shown equipped with the identical air separator fitting; and
FIG. 5 is a diagrammatic side elevational view illustrating the application of the fitting with a packaged type boiler installation.
Referring now to the drawings, a preferred form of air separator fitting as is illustrated in FIGS. 1 and '2, for purposes of disclosure, comprises a vertically elongated hollow tank 10 having generally elliptically shaped surrounding side wall structures 10S and correspondingly shaped top and bottom walls 10T and 10B, respectively, enclosing and defining an air separation chamber 11 of substantially greater flow capacity than the piping of the liquid flow circuit in which it is used.
A water outlet or port opening 12 and an air outlet opening 13 are provided in the top wall adjacent its opposite extremities with a dip tube 14 being fitted permanently within the liquid outlet and projecting to a point adjacent the bottom wall of the fitting. The dip tube thus provides a separate chamber located within the confines of the main separator chamber 11, and the lower end of the dip tube is open and is cut on a bias to more efficiently receive the air free liquid pooling in the bottom of the chamber for discharge through the top outlet.
An opening or port 15 is provided adjacent the top and approximately centrally of one of the major side wall sections to provide an inlet port for convenient connection to a side outlet type boiler arrangement. As fluid enters the port 15 from a side inlet pipe connection, it jets across the separation chamber at high velocity to strike the opposite major side wall section and deflect for directing the fluid stream toward the bottom of the tank. at. a greatly reduced velocity. This reduction in velocity of the entering liquid permits the entrained air to separate from the moving stream, whereupon the air rises to the top of the tank for delivery through the air outlet port 13. The air-free fluid collecting in the bottom of the tank is continuously drawn up the dip tube to exit through the liquid outlet port 12. The pertinent elements of a forced hot water heating system,'as shown in FIG. 3, include a side outlet type boiler 20, the fitting 10 of this invention mounted alongside the boiler and connected through a conduit, not shown, which leads into its side inlet port 15 to deliver a stream of water entrained with air bubbles, and a booster pump 21 having its suction side connected to the top outlet port 12 by a conduit 22 and having its dis-I charge side connected through supply piping 23 leading to the radiation gear, with the piping 24 constituting a return line from the radiation gear and feeding into the bottom of the boiler. A conventional compression tank 25 is connected through a line of piping 26 to the air outlet port 13 for receiving and storing the air that is sep-. arated out by the fitting 10. A cold water supply line 27 is shown tapped into the piping 26 and includes a con trol valve 28 for initially filling the system.
An opening or port 16 is provided through the bottom wall 10B of the tank at-an extremity thereof adjacent to the end of the top wall at which the air outlet port 13 is located and this'port' is bidirectional in that in some applications of the fitting air-free liquidvemerges-from the tank through this port and in other applications liquid entrained with air enters the tank for separation of the air in the tank. vj
When the fitting is used on a side outlet boiler arrangement such as is shown in FIG. 3, it may be required that the air-free liquid be withdrawn from the port 16 of the bottom wall rather than through the dip tube. An ar rangement of this type is also shown in FIG. 3 wherein, for the moment, it may be assumed that the outlet port 12 of .the dip tube is plugged up. A separate radiation system isshown having piping 29 connected to extend from the bottomport 16 of the fitting 10 to the suction side. 'of a booster pump 30, the discharge side of which 3 is connected to piping 31 that feeds radiation gear, not shown, with the return line 24 being assumed to be connected to the other side of this system.
FIG. 3 may also be viewed as an illustration of a multiple zone radiation system having one radiation circuit that includes the booster pump 21 being supplied with air free liquid from the dip tube 14 and outlet port 12 and having a separate radiation circuit that includes the booster pump 30 being supplied with air-free liquid through the bottom outlet port 16. An added advantage of the fitting of this invention is that it is conveniently adaptable to the connection arrangements for such a multiple zone system and moreover it maintains its efliciency even in such a multiple zone system. For such an application the air separating action in the tank is substantially identical, since in both instances the air-free liquid is drawn out from a point closely adjacent the bottom of the tank. Alternatively, in a multiple zone radiation system liquid may be drawn simultaneously through both the dip tube 14 and the bottom port 16. I The other function of the bottom port 16 of the fitting 10 relates to the use of the fitting with top outlet type boiler arrangements such, for example, as is shown in FIG; 4 in which case the port 15 of the side wall is plugged up. The liquid entrain'ed with air issues from the boiler and enters through the bottom port 16 and air free liquid is drawn otf through the dip tube. As the air entrainedliquid enters atthe bottom of the fitting and flows into the enlarged air separation chamber 11, its velocity of flow is reduced sufliciently to permit air bubbles to separate out from the liquid, whereupon the air bubbles again rise to the top of the separation chamber for delivery to the compression tank 25. This action is, in general, similar to that described previously, and a radiation system is shown in FIG. whereinthe fittinglfl is mounted directly above the boiler 20 that is illustrated as being of the' top outlet type, with piping 20F connecting the liquid being discharged from the boiler into the bottom port of the fitting. Air-free liquid is drawn off through the piping 22 by a booster pump 21 which circulates the airf reeliquid throughout the system. The compression tank 25 is connected through the piping 26 to the air outlet port 13 and a water supply line 27 having a valve 28 is again shown tapped into the piping 26.
The elliptical shape of the fitting not only contributes to increased efficiency of air separation but it provides space saving features of particular importance in the packaged type boiler installations that are becoming so popular. In FIG. 5a side outlet type boiler 20 is shown connected to the fitting 10 and a metal jacket 32 encases these parts as well as a number of related components. Since the fitting is elliptical it may be mounted alongside the boiler with a minimum of lateral projection and therefore the enclosing jacket may be of correspondingly smaller size,
It should be understood that the description of the preferred form 0f;tl16 i11VeHll0t1 is for the purpose of complying withSection 112, Title 35 of the United States Code, and that the appended claims should be construed as broadly as the prior art will permit.
I claim:
1. A multiple purpose air separator for direct interposition .in a forced circulation hydronic system of the type including a boiler of either the side outlet or top outlet type and also including a booster pump and piping connecting the boiler, the separator and the booster pump in series, and a compression tank connected for trapping air separated from liquid in said system, said separator comprising a tank. having openings therein providing a vertically elongated chamber of substantially greater flow capacity than said openings in said tank, said tank having surrounding side wall structure provided with an inlet opening horizontally therethrough for supplying liquid entrained with air horizontally into said chamber to impinge upon an opposing portion of said side wall structure and effect a velocity reduction of said liquid as it enters said tank to allow for separation of entrained air and a pooling of air free liquid within the lower end of said chamber, said tank having a top wall having a liquid outlet opening and an air outlet opening at opposite extremities thereof and having a dip tube in said liquid outlet opening and projecting to adjacent the lower end of said chamber for drawing air free liquid pooling within the lower end of said chamber, and said tank having a bottom wall having an opening to said chamber and optionally connectable either as a liquid outlet that communicates only with air free liquid pooling within the lower end of said chamber or as a liquid inlet opening into said chamber for supplying liquid entrained with air therein to effect a velocity reduction of said liquid as it enters said tank and thereby allow for separation of entrained air and a pooling of air free liquid within the lower end of said chamber for exit through said clip tube.
2. A multiple purpose air separator for direct interposition in a forced circulation hydronic system of the type including a boiler of either the side outlet or top outlet type and also including a booster pump and piping connecting the boiler, the separator and the booster pump in series, and a compression tank connected for trapping air separated from liquid in said system, said separator comprising a tank having openings therein providing a vertically elongated chamber of substantially greater flow capacity than said openings in said tank, said chamber having a generally elliptical horizontal cross-sectional configuration, said tank having surrounding side wall structure provided centrally within one major wall section thereof with an inlet opening horizontally therethrough for supplying liquid entrained with air horizontally into said chamber to impinge upon an opposing major wall section of said side wall structure and effect a velocity reduction of said liquid as it enters said tank to allow for separation of entrained air and a pooling of air free liquid withinthe lower end of said chamber, said tank having a top wall having a liquid outlet opening and an air outlet opening at opposite extremities thereof and having a dip tube in said liquid outlet opening and projecting to adjacent the lower end of said chamber for drawing air free liquid pooling within the lower end of said chamber, and said tank having a bottom wall having an opening to said chamber at the extremity thereof that underlies said air outlet opening and optionally connectable either as aliquid outletthat communicates only with air free liquid pooling within the lower end of said chamber or as a liquid inlet opening into said chamber for supplying liquid entrained with air thereinto to efiect a velocity reduction of said liquid as it enters said tank and thereby allow for separation of entrained air and a pooling of'air free liquid within the lower end of said chamber for exit through said dip tube.
3. In a forced circulation hydronic system, the combination including a boiler of either of the side outlet or top outlet type, a multiple purpose air separator, a booster pump, piping connecting the boiler, the separator and the booster pump in series, and a compression tank con nected for trapping air separated from liquid in said system, said separator comprising a tank having openings therein providing a vertically elongated chamber of substantially greater flow capacity than said openings in said tank, said tank having surrounding side wall structure provided with an inlet opening horizontally therethrough for supplying liquid entrained with air horizontally into said chamber to impinge upon an opposing portion of said side wall structure and efiect a velocity reduction of said liquid as it enters said tank to allow for separation of entrained air and a pooling of air free liquid within the lower end of said chamber, said tank havng atop wall having a liquid outlet opening and an air outlet opening at oppositeextremities thereof and having a dip tube in said liquid outlet opening and projecting to adjacent the lower end of said chamber for drawing air free liquid pooling within the lower end of said chamber, and said tank having a bottom wall having an opening to said chamber and optionally connectable either as a liquid outlet that communicates only with air free liquid pooling within the lower end of said chamber or as a liquid inlet opening into said chamber for supplying liquid entrained with air thereinto to effect a velocity reduction of said liquid as it enters said tank and thereby allow for separation of entrained air and a pooling of air free liquid References Cited in the file of this patent within the lower end of said chamber for exit through 10 2,341,337
said dip tube.
UNITED STATES PATENTS Reilly Apr. 26, 1892 Yoder Nov. 24, 1936 Goerg May 30, 1939 Jepertinger Feb. 11, 1941 Goheen Sept. 15, 1953 Henken et a1 July 26, 1955 Haugen July 1, 1958

Claims (1)

1. A MULTIPLE PURPOSE AIR SEPARATOR FOR DIRECT INTERPOSITION IN A FORCED CIRCULATION HYDRONIC SYSTEM OF THE TYPE INCLUDING A BOILER OF EITHER THE SIDE OUTLET OR TOP OUTLET TYPE AND ALSO INCLUDING A BOOSTER PUMP AND PIPING CONNECTING THE BOILER, THE SEPARATOR AND THE BOOSTER PUMP IN SERIES, AND A COMPRESSION TANK CONNECTED FOR TRAPPING AIR SEPARATED FROM LIQUID IN SAID SYSTEM, SAID SEPARATOR COMPRISING A TANK HAVING OPENINGS THEREIN PROVIDING A VERTICALLY ELONGATED CHAMBER OF SUBSTANTIALLY GREATER FLOW CAPACITY THAN SAID OPENINGS IN SAID TANK, SAID TANK HAVING SURROUNDING SIDE WALL STRUCTURE PROVIDED WITH AN INLET OPENING HORIZONTALLY THERETHROUGH FOR SUPPLYING LIQUID ENTRAINED WITH AIR HORIZONTALLY INTO SAID CHAMBER TO IMPINGE UPON AN OPPOSING PORTION OF SAID SIDE WALL STRUCTURE AND EFFECT A VELOCITY REDUCTION OF SAID LIQUID AS IT ENTERS SAID TANK TO ALLOW FOR SEPARATION OF ENTRAINED AIR AND A POOLING OF AIR FREE LIQUID WITHIN THE LOWER END OF SAID
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3486523A (en) * 1967-07-03 1969-12-30 Gen Electric Movable drain connection for humidifier sump

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US473591A (en) * 1892-04-26 Device for separating oil from feed-water
US2061605A (en) * 1934-10-01 1936-11-24 Penberthy Injector Co Heat control system
US2160801A (en) * 1937-11-30 1939-05-30 American Radiator & Standard Heating apparatus
US2231501A (en) * 1938-01-29 1941-02-11 Modine Mfg Co Air separator for fluid circulating systems
US2652069A (en) * 1947-05-26 1953-09-15 Herman M Goheen Distributing and venting header
US2713973A (en) * 1951-06-20 1955-07-26 Taco Heaters Inc Heating systems
US2841337A (en) * 1953-06-03 1958-07-01 Iron Fireman Mfg Co Hot water heating system

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US473591A (en) * 1892-04-26 Device for separating oil from feed-water
US2061605A (en) * 1934-10-01 1936-11-24 Penberthy Injector Co Heat control system
US2160801A (en) * 1937-11-30 1939-05-30 American Radiator & Standard Heating apparatus
US2231501A (en) * 1938-01-29 1941-02-11 Modine Mfg Co Air separator for fluid circulating systems
US2652069A (en) * 1947-05-26 1953-09-15 Herman M Goheen Distributing and venting header
US2713973A (en) * 1951-06-20 1955-07-26 Taco Heaters Inc Heating systems
US2841337A (en) * 1953-06-03 1958-07-01 Iron Fireman Mfg Co Hot water heating system

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3486523A (en) * 1967-07-03 1969-12-30 Gen Electric Movable drain connection for humidifier sump

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