US1826253A - Liquid cooling apparatus - Google Patents

Liquid cooling apparatus Download PDF

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US1826253A
US1826253A US463677A US46367730A US1826253A US 1826253 A US1826253 A US 1826253A US 463677 A US463677 A US 463677A US 46367730 A US46367730 A US 46367730A US 1826253 A US1826253 A US 1826253A
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liquid
tube
tubes
chambers
cooler
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US463677A
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Henry H Marshall
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BRUNSWICKKROESCHELL Co
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BRUNSWICKKROESCHELL Co
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D31/00Other cooling or freezing apparatus
    • F25D31/002Liquid coolers, e.g. beverage cooler
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28DHEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
    • F28D7/00Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall
    • F28D7/10Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall the conduits being arranged one within the other, e.g. concentrically
    • F28D7/106Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall the conduits being arranged one within the other, e.g. concentrically consisting of two coaxial conduits or modules of two coaxial conduits
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F9/00Casings; Header boxes; Auxiliary supports for elements; Auxiliary members within casings
    • F28F9/26Arrangements for connecting different sections of heat-exchange elements, e.g. of radiators

Definitions

  • This invention relates to improvements in liquid cooling systems, and more particularly to a safety device for liquid coolers whereb damage to said coolers by freezing is avoide
  • a safety device for liquid coolers whereb damage to said coolers by freezing is avoide
  • the refrigerating industry 5 it has been a practice to cool the brine, water and other liquids in coolers, such, for example, as double pipe coolers or shell and tube coolers.
  • the refrigerants used in such coolers are usually at tem ratures below that at which water or we brine will freeze.
  • the main object of the present invention is toprovide improved coolers which will not be destroyed even if the liquid therein is frozen solid. Another object is to provide coolers of this kind such that their normal 30 operation cannot easily be affected by tamermg.
  • Fig. 1 is a fragmentary view, partly broken away, of a cooler of the double tube type embodying one form of the invention
  • Fig. 2 is a section of a shell and tube cooler embodying another form of the present invention.
  • Fig. 1 of the drawin 10 designatesv a double pipe cooler, inclu g a set of inner pipes or tubes 11.having connections at their ends so that the liquid to be' cooled will pass through .all of said inner tubes 11 in succession, and outer tubes 12 surrounding said inner tubes so as to provide therebetween space for the circulation of suitable refrigerant and also connected so'that an inlet pipe 16 and a tubular member 16a.
  • each return bend 14 of the inner tube connections is connected by a small pipe 19 to a liquid relief valve 20.
  • each of the inlet and outlet pipes 13 and 15 is similarly connected with a ipe 19.
  • a suitable check valve 21 is plac in each connection with the pipes 19 so that the liquid maypass through the check valves 21 into the lpes 19, but maynot pass in the opposite irection.
  • Each relief valve 20 is so adjusted as to open at a pressure slightly in excess of the maximum operating pressure imposed on the li uid being cooled.
  • the passages through the heads 14 are made of sufficient depth or volume to provide for such expansion so that when the ice finally fills all of the space, it will do so without having created at any time a bursting pressure at any point.
  • the chambers in the connections 13a and 15a serve a similar purpose. It will be seen that the entire arrangement operates in such a way as to make the equipment operative in an ordinary manner as soon as thawing has progressed sufficiently to allow circulation of liquid through all of the tubes.
  • a cooler 10a of the shell and tube type which includes a central section having tubular portions 11a to accommodate the passage of the liquid to be cooled and which are surrounded by refrigerant in the shell 12a.
  • the refrigerant is admitted through an inlet 16 at the bottom of the shell and discharged from the top thereof through an outlet 18.
  • heads 25 and 26 At opposite ends of the central section are heads 25 and 26.
  • the head 25 is provided with a chamber 27 communicating with the upper tubular portion 11a and also with an inlet pipe 28 to supply liquid to be cooled.
  • the head 25 is also provided with a chamber 29 to connect the second and third tubular portions 11a, and with a chamber 30 communicating with the lowest tubular portion 11a and with an outlet 31.
  • the head 26 is provided with a chamber 32 connecting the right hand ends of the first and second tubular sections 11a and with a chamber 33 connecting the corresponding ends of the third and fourth tubular sections 11a.
  • the check valves 21a-could be connected with pipes provided with relief valves, as shown in connection with the double tube cooler of Fig. 1, but, as here shown, the check valves 21a discharge into chambers in false heads 34 and 35, each of which is provided at the bottom thereof with an outlet tube 36 controlled by an automatic relief valve 37.
  • the action will be similar to that described in connection with the double tube cooler in that ice will form inthe tubular sections 11a and shove the water out into the chambers in the heads 25 and 26.
  • the check valves 21a When the pressure in the chambers in the heads reaches a certain predetermined degree, the check valves 21a will permit the water to be discharged therethrough into the chambers in the heads 34 and 35, and when the pressure in said false heads 34: and 35 becomes sufliciently great, the liquid discharged into the same will be. forced out through the relief valves 37. After such freezing, the apparatus will again be in condition for use as soon as the ice therein melts.
  • the relief valves 37 may be replaced by suitable rupture diaphragms.
  • liquid cooling apparatus including a tube to conduct the liquid to be cooled through a refrigerant container, the combination of said tube and means for preventing damage to the apparatus by the freezing of the liquid in the tube, including chambers at the inlet and outlet ends of the tube and outside of the refrigerant container to accommodate the liquid forced out of the ends of said tube.
  • liquid coolin apparatus including a tube to conduct the liquid to be cooled through a refrigerant container, the combination of said tube and means for preventing damage to the apparatus by the freezing of the liquid in the tube, including chambers at the inlet and outlet ends of the tube and outside of the refrigerant container to accommodate the liquid forced out of the ends of the tube and means including outwardly opening relief valves to discharge liquid from said chambers when the pressure eX- ceeds a predetermined degree.
  • liquid cooling apparatus including a tube to conduct the liquid to be cooled through a refrigerant container, the combination of said tube and means for preventing damage to the apparatus by the freezing of the liquid in the tube, including chambers at the inlet and outlet ends of the tube and outside of the refrigerant container to ac commodate the liquid forced out of the ends of the tube, outwardly opening check valves to discharge liquid from said chambers when the pressure exceeds a predetermined degree, means for receiving liquid from said check valves and relief means to discharge liquid from the receiving means at a pressure slightly in excess of the maximum pressure for normal operation.
  • liquid cooling apparatus including i a plurality of parallel tubes to conduct the liquid to be cooled through refrigerant containing means, the combination of said tubes and means for preventing damage to the apparatus by the freezing of the liquid in said 'tubes including chambers in return bends connecting successive tubes and outside of the refrigerant containing'means to accommodate the liquid forced out of the corresponding ends of the tubes, outwardly opening check valves individual to said chambers, a container at each end of the apparatus to receive the liquid from the check valves, and a relief device for each of said containers to discharge the liquid therefrom at a pressure slightly in excess of the maximum pressure for normal operation.
  • liquid cooling apparatus including a plurality of parallel tubes to conduct the liquid to be cooled through refrigerant containing means
  • the combination of said tubes and means for preventing damage to the apparatus by the freezing of the liquid in said tubes including chambers in return bends connecting successive tubes and outside of the refrigerant containing means to accommodate the liquid forced out of the corresponding ends of said tubes, chambers at the inlet end of the first tube and the outlet end ofthe last tube respectively, outwardly opening check valves individual to said chambers, a container at each end of the apparatus to receive liquid from the check valves at such ends, and a relief device for each of said containers to discharge the liquid therefrom at a pressure slightly in excess of the maximum pressure for normal HENRY H. MARSHALL.

Description

. H. H. MARSHALL LIQUID COOLING APPARATUS 2 Sheets-Sheet 1 Filed June 25, 1950 rRA E H. H. MARSHALL LIQUID COOLI NG APPARATUS Filed June 25, 1930 2 SheetsSheet' 2 Patented Oct. 6, 1931 UNITED STATES PATENT OFFICE HENRY H. MARSHALL, O! HIGHLAND PARK, NEW JERSEY, ASSIGNOB '10 BRUNSWICK- KBOESOHELL COMPANY, 0 F NEW BRUNSWICK, NEW JERSEY, A CORPORATION 01 LIQUID coonrue arremrus Application fled June 25, 1930. Serial no. man.
This invention relates to improvements in liquid cooling systems, and more particularly to a safety device for liquid coolers whereb damage to said coolers by freezing is avoide Heretofore, in the refrigerating industry 5 it has been a practice to cool the brine, water and other liquids in coolers, such, for example, as double pipe coolers or shell and tube coolers. The refrigerants used in such coolers are usually at tem ratures below that at which water or we brine will freeze.
Consequently it has been necessary to exercise not however been satisfactory, due to various conditions, such, for example, as failure to operate properly due to tampering therewith or change of adjustments thereof. i
The main object of the present invention is toprovide improved coolers which will not be destroyed even if the liquid therein is frozen solid. Another object is to provide coolers of this kind such that their normal 30 operation cannot easily be affected by tamermg.
The above and other objects are accomplished by apparatus of which two embodiments are illustrated in the accompanying drawings, in which: Fig. 1 is a fragmentary view, partly broken away, of a cooler of the double tube type embodying one form of the invention; and Fig. 2 is a section of a shell and tube cooler embodying another form of the present invention.
Referring to Fig. 1 of the drawin 10 designatesv a double pipe cooler, inclu g a set of inner pipes or tubes 11.having connections at their ends so that the liquid to be' cooled will pass through .all of said inner tubes 11 in succession, and outer tubes 12 surrounding said inner tubes so as to provide therebetween space for the circulation of suitable refrigerant and also connected so'that an inlet pipe 16 and a tubular member 16a.
surrounding the discharge end of the lowest inner tube 11 into the space between the same and the corresponding outer tube 12 and after passing through outer tubes 12 and return bends 1?, connecting the same, is finally discharged from the last outer tube 12 throu h a discharge pipe 18 connected with this'tu 12 by a tubular member 180 surrounding the discharge end thereof.
At each end of the double pipe cooler 10,
each return bend 14 of the inner tube connections is connected by a small pipe 19 to a liquid relief valve 20. Also each of the inlet and outlet pipes 13 and 15 is similarly connected with a ipe 19. A suitable check valve 21 is plac in each connection with the pipes 19 so that the liquid maypass through the check valves 21 into the lpes 19, but maynot pass in the opposite irection. Each relief valve 20 is so adjusted as to open at a pressure slightly in excess of the maximum operating pressure imposed on the li uid being cooled.
In t e event that the temperature of the cooled liquid is lowered sufiiciently to cause freezing, ice accumulates at the 1nner surfaces of the tubes 11 and, inasmuch as the change from liquid to ice is accompanied byan increase in volume, the pressure on the remaining water is increased and, as the tubes close-at their middle points, the water is pushed to the dead ends of the tubes. The check valves 21 are then forced open and as the pressure reaches the predetermined point, the water is forced out through the valves 20. This action continues spasmodicallv as 50 refrigerant circulated therethrough will pass the ice continues to form and any confined water is pressed out of its confinement through the ice crystals to the point where it may be relieved by a valve 20.
The passages through the heads 14 are made of sufficient depth or volume to provide for such expansion so that when the ice finally fills all of the space, it will do so without having created at any time a bursting pressure at any point. The chambers in the connections 13a and 15a serve a similar purpose. It will be seen that the entire arrangement operates in such a way as to make the equipment operative in an ordinary manner as soon as thawing has progressed sufficiently to allow circulation of liquid through all of the tubes.
In some cases it may be desirable to install in place of the relief valves 20 rupture diaphragms or elements designed to break under a suitable pressure to give corresponding protection. It would, of course, be necessary to install new rupture elements before placing the cooler in service again.
It should be understood that the parts of the double tube cooler may be fastened together in any suitable manner.
In Fig. 2, the invention is illustrated as applied to a cooler 10a of the shell and tube type, which includes a central section having tubular portions 11a to accommodate the passage of the liquid to be cooled and which are surrounded by refrigerant in the shell 12a. The refrigerant is admitted through an inlet 16 at the bottom of the shell and discharged from the top thereof through an outlet 18. At opposite ends of the central section are heads 25 and 26. As here shown the head 25 is provided with a chamber 27 communicating with the upper tubular portion 11a and also with an inlet pipe 28 to supply liquid to be cooled. The head 25 is also provided with a chamber 29 to connect the second and third tubular portions 11a, and with a chamber 30 communicating with the lowest tubular portion 11a and with an outlet 31. The head 26 is provided with a chamber 32 connecting the right hand ends of the first and second tubular sections 11a and with a chamber 33 connecting the corresponding ends of the third and fourth tubular sections 11a.
It will be apparent that liquid entering the cooler through the pipe 28 will be guided back and forth throughthe tubular sections 11a and finally discharged through the discharge or outlet pipe 31. In its passage through the cooler it will be acted upon by refrigerant in the various passages of the shell 12a and will be cooled as desired. The chambers in the heads 25 and 26 correspond with the return bends 14 and inlet and outlet chambers 13a and 18a of the shell and tube structure of Fig. 1, and are designed so as to act in connection with outwardly opening check" valves 21a; to accommodate the increase in volume of the contained liquid when it is frozen to form ice.
The check valves 21a-could be connected with pipes provided with relief valves, as shown in connection with the double tube cooler of Fig. 1, but, as here shown, the check valves 21a discharge into chambers in false heads 34 and 35, each of which is provided at the bottom thereof with an outlet tube 36 controlled by an automatic relief valve 37. In the event of freezing of the water in the cooler,'the action will be similar to that described in connection with the double tube cooler in that ice will form inthe tubular sections 11a and shove the water out into the chambers in the heads 25 and 26.
When the pressure in the chambers in the heads reaches a certain predetermined degree, the check valves 21a will permit the water to be discharged therethrough into the chambers in the heads 34 and 35, and when the pressure in said false heads 34: and 35 becomes sufliciently great, the liquid discharged into the same will be. forced out through the relief valves 37. After such freezing, the apparatus will again be in condition for use as soon as the ice therein melts. In this form, as in the double tube form, the relief valves 37 may be replaced by suitable rupture diaphragms.
I claim:
1. In liquid cooling apparatus including a tube to conduct the liquid to be cooled through a refrigerant container, the combination of said tube and means for preventing damage to the apparatus by the freezing of the liquid in the tube, including chambers at the inlet and outlet ends of the tube and outside of the refrigerant container to accommodate the liquid forced out of the ends of said tube.
2. In liquid coolin apparatus including a tube to conduct the liquid to be cooled through a refrigerant container, the combination of said tube and means for preventing damage to the apparatus by the freezing of the liquid in the tube, including chambers at the inlet and outlet ends of the tube and outside of the refrigerant container to accommodate the liquid forced out of the ends of the tube and means including outwardly opening relief valves to discharge liquid from said chambers when the pressure eX- ceeds a predetermined degree.
3. In liquid cooling apparatus including a tube to conduct the liquid to be cooled through a refrigerant container, the combination of said tube and means for preventing damage to the apparatus by the freezing of the liquid in the tube, including chambers at the inlet and outlet ends of the tube and outside of the refrigerant container to ac commodate the liquid forced out of the ends of the tube, outwardly opening check valves to discharge liquid from said chambers when the pressure exceeds a predetermined degree, means for receiving liquid from said check valves and relief means to discharge liquid from the receiving means at a pressure slightly in excess of the maximum pressure for normal operation.
4. In liquid cooling apparatus including i a plurality of parallel tubes to conduct the liquid to be cooled through refrigerant containing means, the combination of said tubes and means for preventing damage to the apparatus by the freezing of the liquid in said 'tubes including chambers in return bends connecting successive tubes and outside of the refrigerant containing'means to accommodate the liquid forced out of the corresponding ends of the tubes, outwardly opening check valves individual to said chambers, a container at each end of the apparatus to receive the liquid from the check valves, and a relief device for each of said containers to discharge the liquid therefrom at a pressure slightly in excess of the maximum pressure for normal operation.
5. In liquid cooling apparatus including a plurality of parallel tubes to conduct the liquid to be cooled through refrigerant containing means, the combination of said tubes and means for preventing damage to the apparatus by the freezing of the liquid in said tubes including chambers in return bends connecting successive tubes and outside of the refrigerant containing means to accommodate the liquid forced out of the corresponding ends of said tubes, chambers at the inlet end of the first tube and the outlet end ofthe last tube respectively, outwardly opening check valves individual to said chambers, a container at each end of the apparatus to receive liquid from the check valves at such ends, and a relief device for each of said containers to discharge the liquid therefrom at a pressure slightly in excess of the maximum pressure for normal HENRY H. MARSHALL.
. operation.
US463677A 1930-06-25 1930-06-25 Liquid cooling apparatus Expired - Lifetime US1826253A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2592216A (en) * 1947-01-02 1952-04-08 Watts Albert Edward Return fire tube boiler with indirectly heated domestic supply
US2713996A (en) * 1952-10-23 1955-07-26 Jr John E Pottharst Heat exchanger
EP0013700A1 (en) * 1979-01-22 1980-08-06 Piero Pasqualini Modules for heat exchanger or the like and heat exchanger thus obtained

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2592216A (en) * 1947-01-02 1952-04-08 Watts Albert Edward Return fire tube boiler with indirectly heated domestic supply
US2713996A (en) * 1952-10-23 1955-07-26 Jr John E Pottharst Heat exchanger
EP0013700A1 (en) * 1979-01-22 1980-08-06 Piero Pasqualini Modules for heat exchanger or the like and heat exchanger thus obtained

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