USRE20921E - Absorption refrigerating apparatus - Google Patents
Absorption refrigerating apparatus Download PDFInfo
- Publication number
- USRE20921E USRE20921E US20921DE USRE20921E US RE20921 E USRE20921 E US RE20921E US 20921D E US20921D E US 20921DE US RE20921 E USRE20921 E US RE20921E
- Authority
- US
- United States
- Prior art keywords
- gas
- conduit
- nozzle
- absorber
- evaporator
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- 238000010521 absorption reaction Methods 0.000 title description 39
- 239000007789 gas Substances 0.000 description 99
- 239000011261 inert gas Substances 0.000 description 51
- 239000006096 absorbing agent Substances 0.000 description 50
- 239000012530 fluid Substances 0.000 description 43
- 239000003795 chemical substances by application Substances 0.000 description 33
- 239000000203 mixture Substances 0.000 description 16
- 239000003507 refrigerant Substances 0.000 description 10
- 239000007788 liquid Substances 0.000 description 7
- 230000003534 oscillatory Effects 0.000 description 7
- 238000005057 refrigeration Methods 0.000 description 4
- 238000000926 separation method Methods 0.000 description 4
- 238000010276 construction Methods 0.000 description 2
- IJGRMHOSHXDMSA-UHFFFAOYSA-N nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 description 2
- 241000405147 Hermes Species 0.000 description 1
- KWGRBVOPPLSCSI-WCBMZHEXSA-N Pseudoephedrine Chemical compound CN[C@@H](C)[C@@H](O)C1=CC=CC=C1 KWGRBVOPPLSCSI-WCBMZHEXSA-N 0.000 description 1
- 239000003570 air Substances 0.000 description 1
- QGZKDVFQNNGYKY-UHFFFAOYSA-N ammonia Chemical compound N QGZKDVFQNNGYKY-UHFFFAOYSA-N 0.000 description 1
- 230000015572 biosynthetic process Effects 0.000 description 1
- 238000001816 cooling Methods 0.000 description 1
- 239000000498 cooling water Substances 0.000 description 1
- 230000000875 corresponding Effects 0.000 description 1
- 238000007599 discharging Methods 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000001704 evaporation Methods 0.000 description 1
- 238000005755 formation reaction Methods 0.000 description 1
- 239000001257 hydrogen Substances 0.000 description 1
- 229910052739 hydrogen Inorganic materials 0.000 description 1
- 125000004435 hydrogen atoms Chemical class [H]* 0.000 description 1
- 238000005461 lubrication Methods 0.000 description 1
- 229910052757 nitrogen Inorganic materials 0.000 description 1
- 239000002245 particle Substances 0.000 description 1
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 1
Images
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B15/00—Sorption machines, plants or systems, operating continuously, e.g. absorption type
- F25B15/10—Sorption machines, plants or systems, operating continuously, e.g. absorption type with inert gas
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A30/00—Adapting or protecting infrastructure or their operation
- Y02A30/27—Relating to heating, ventilation or air conditioning [HVAC] technologies
-
- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B30/00—Energy efficient heating, ventilation or air conditioning [HVAC]
- Y02B30/62—Absorption based systems
Definitions
- This invention relates to continuous absorption refrigerating apparatus of the type in which an inert gas is used as a pressure equalizing medium and more particularly to the use of means for circulating inert gas or other fluid within such a system or apparatus.
- the gas circulating means of the' type shown in the Geppert patent requires a seal or stufflng box where the shaft used to drive thefan enters 26 some of the refrigerant within the boiler is wasted, in so'i'ar as cooling effect is concerned, in order that it may be employed for circulating the inert gas.
- FIG. 1 is a diagrammatic illustration of a continuous absorption refrigerating system in which inert gas is circulated between the evaporator and the absorber by means of a gas circulating device constructed in accordance with the present invention
- FIG. 2 is an enlarged fragmentary view of a portion of the conduit forming part of the inert gas circuit of the arrangement of Figure 1, the conduit being partly cut away to show how the gas circulating means is associated therewith, 1
- Figure 3 is a vertical cross sectional view of a modified form'of gas circulator which maybe used in place of the gas circulator of Figure 1, the figure showing a fragment of an inert gas conduit associated therewith, and
- Figure 4 is a vertical cross sectional view of still another embodiment of gas circulating means which may be used in place of the arrangement of Figure 1, the view showing gas conduits connected thereto.
- a continuous absorption refrigerating system has been illustrated as consisting of a generator or boiler i having a gas lift pump 2 associated therewith for conveying refrigerant gas and absorption liquid to the gas separation chamber I.
- the gas separation chamber 3 is connected to the top of the absorber 5 by a liquid conduit I.
- the absorber 5 consists of a cylindrical vessel, the lower portion of which may act as a reservoir as indicated in Figure 1, while the other portion is provided with baffle plates and a jacket through which cooling water may be passed to take heat away from the fluids therein.
- the condenser 8 may be a coil of pipe or a bank of reversely bent pipes, as illustrated, and functions to cause the refrigerant vapor to liquefy.
- the bottom of the condenser is connected to the evaporator IIlby means of a conduit 9.
- the evaporator may consist of a vertically disposed cylindrical vessel provided with baflie plates therein. It is connected to the absorber by means of two inert gas conduits II and I2.
- the conduit II is adapted to convey gas from the top of the absorber 5 to the bottom of the evaporator III, while the conduit I2 is adapted to convey gas from the top of the evaporator into the lower or intermediate portions of the absorber vessel 5 beneath the bafileplates in that vessel.
- Suitable power driven means may be associated with either of the conduits I I or I2 or with the evaporator or the absorber which go to make up the inert gas circuit.
- the arrangement of Figures 1 and 2 shows the gas circulator associated with the conduit I2. The arrangement is such that the inert gas or other gases are caused to circulate from left to right in this conduit as viewed in Figures 1 and 2.
- the gas circulator includes a nozzle l3 located within the pipe I 2 and means for applying gas to this nozzle at a slightly higher pressure than that existing in the conduit I2 so that as gas emerges from the nozzle, directional movement-is imparted to gases in the conduit I2.
- the driving gas is supplied tothe nozzle I3 by means of a conduit Il connected to the conduit I2 slightly in advance of the nozzle I3, the conduit I4 having a small gas.
- compressor I5 connected therein.
- the compressor I5 may be driven 'by a small motor IE or by other motivating means exterior of the conduits II. It would, of course, be within the purview of the invention to mount the motor or other actuating means for the compressor I5 within a hermetically sealed chamber if desired.
- a small annular disk I1 may be located just in front of the nozzle l3 within the pipe I2, the opening in the disk corresponding in area to the cross section of the gas jet emanating from the nozzle in order to aid in the circulation of gases through the pipe I2.
- the refrigerantgas (such as ammonia), generated in the boiler system, flows through the conduit T, thence in the condenser 8, where it is liquefied, and flows into the evaporator.
- the inert gas such as hydrogen, nitrogen, air, or the like,
- the mixture of refrigerant gas and inert gas enters the absorber, and flows upwardly therethrough, coming into contact with the absorption liquid (such as water) as it does so.
- Refrigerant is absorbed out of the inert gas by the absorption liquid and passes back to the boiler system through the conduit 6.
- absorption liquid is circulated through the boiler system and absorber, the absorption liquid flowing from the boiler through the conduit 2, to the gas separation chamber and then through the conduit 4 into the absorber and back to the boiler through the conduit 6.
- Figure 1 illustrates only a conventional absorption refrigerator inert gas circuit, but it is obvious that the present invention may be employed to drive inert gas or other fluids in other hermetically sealed systems, for example, refrigerating systems in which two inert gas circuits are employed as disclosed in U. S. patent to Altenkirch, No. 2,000,005, granted May 7, 1935.
- the nozzle outlet I3 is connected to a casing or chamber member 20 by means of a conduit I9.
- is disposed within the casing 20 in such a manner that it may oscillate upon being energized by alternating current electromagnets 22, which project through and are hermetically sealed to the wall of the casing 20.
- within the casing 20 will change the volume of the space between that diaphragm and the lower part of the casing 20 and this will cause air tobe sucked into and expelled from the nozzle I3.
- the air flow into and out of the nozzle is peculiar in that the air which flows into the nozzle enters from points around the rim, as indicated by the arrows in Figure 3, whereas that which is expelled passes in parallel with the axis of the nozzle mouth.
- may be such that practically a continuous stream or jet of expelled gas is produced and the operation of the nozzle and the disk I! in front of it becomes practically the same as though a continuous stream of air were provided as in the arrangement of Figure 1.
- FIG. 4 A modified arrangement similar to that of Figure 3' is shown in the arrangement of Figure 4, in which a casing or chamber member is so connected to the conduit I2 that the entire pump assembly, that is, the nozzle, diaphragm, and electromagnet are mounted therein.
- the discharge portion of the conduit I2 extends upwardly through the bottom of the nozzle so that its upper end acts in a way similar to that of the perforated disk I! in the arrangement of Figures 2 and 3.
- , mounted in the upper part of the chamber, is oscillated by the electro-magnet 22 just the same as in the arrangement of Figure 3, and a pulsating jet is thus delivered from the nozzle due to the changes in volume of the gas space 24 between the diaphragm and the nozzle.
- the direction of movement of gas is indicated by the arrows.
- an absorption refrigerating apparatus of the continuous type comprising agenerator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigera ing agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit for emitting a gas jet to direct said gaseous agents in a predetermined direction of circulation, and an electrically operated mechanical means connected with said nozzle for forcing a portion of said gas travelling in said conduit through said nozzle to produce said jet.
- an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a second conduit branching off said first-named conduit and terminating'in a nozzle in said first-named conduit to direct the gas mixture in said conduit in a predetermined direction of circulation, and an electrically operated mechanical means connected with said branch conduit for producing the gas pressure required for forcing a portion of said conduit gas through said nozzle.
- an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an, auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid-conduit connecting said evaporator. and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, an enclosed gas chamber connected with said nozzle and electrically operated mechanical means for varying periodically the volume of said gas chamber for drawing conduit gas through said nozzle into said space and for forcing it out through said nozzle back into said conduit in the desired circulating direction.
- condenser an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting-said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, and an electrically operated mechanical means for producing the gas pressure required for forcing a portion of said gas through said nozzle, comprising a closed gas chamber connected with said nozzle and having a diaphragm for closing said chamben to the diaphragm to periodically vary the volume of said gas chamber, for drawing conduit gas through said nozzle into said chamber and forcing it out through "said nozzle back into said conduit in the desired circulating direction.
- an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzlein said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, and an electrically operated mechanical means for producing the gas pressure required for forcing a portion of said gas through said nozzle, comprising a closed gas chamber connected with said nozzle and having a diaphragm for closing said chamber to the outside, and electrical means for oscillating said diaphragm to periodically vary the volume of said gas chamber, for drawing conduit gas rhrough said nozzle into said chamber and for forcing it out through said nozzle back into said conduit in the desired circulating direction, said circulation conduit being enlarged-into a chamber-like space at
- an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent, and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connectingsaid evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, and means for producing the gas pressure required for forcing a portion of said conduit gas through said nozzle, comprising a closed gas chamber connected with said nozzle, an oscillatably disposed disk for closing said gas chamber to the exterior, and an electrically energized magnet outside of said space for oscillating said disc continuously to periodically vary the volume of said chamber, said circulation conduit beingenlarged at the portion surrounding said nozzle into a chamberlike space located in the path of said gas at a point where the flow of gas changes direction.
- an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator, and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to-direct said gaseous agents in a predetermined direction of circulation, and means for producing the gas pressure required for forcing a portion of said gas through said nozzle, comprising a closed gas chamber, connected with said. nozzle and electricallyoperated mechanical means outside, and electrical means for oscillating said 1y perforated disk disposed in said conduit in front of the outlet of said nozzle.
- an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas between said vessels, and an electrically operated diaphragm gas pump hermetically connected with said conduit for drawing in conduit gas and for forcing it back into said conduit in the direction of the other vessel to produce a gas circulation in said direction in the cir culating system.
- an absorption refrigerating apparatus of the continuous type having a gas mixture circuit including an absorber, an evaporator and tubular connections between said vessels, an electromagnetically operated oscillatory diaphragm exposed to the gas mixture in one of said tubular connections and hermetically sealed against the outside for impelling thegas contacting with the diaphragm in the direction of one of said vessels to maintain gas circulation between said vessels.
- an absorption refrigerating apparatus of the continuous type having a gas mixture circuit including an absorber an evaporator and tubular connections between said vessels, an electromagnetically operated diaphragm gas pump connected with one of said tubular connections and communicating with the gas mixture therein, for impelling the mixture by the diaphragm oscillations, and means disposed in said connection opposite to said diaphragm for guiding the im elled gas in a desired direction.
- an absorption refrigerating apparatus of the continuous type having a gas circuit containing a gas, and including an absorber, an evaporator and tubular connections between said vessels, a gas conveyor hermetically sealed to said gas circuit and comprising an electromagnet cally operated oscillatory diaphragm ex- 1 posed to the gas in one of said tubular connections, for impelling the gas contacting with the diaphragm in the direction of one of said vessels to produce movement of the gas from. one vessel to the other.
- conduits providing a circuit ,for the inert gas and means for driving the inert gas over its circuit, said means including an electro-magnetically operated vibratoryelement mounted in one of said conduits and positioned to cause directional movement to be imparted to a body of the inert gas adjacent thereto.
- conduits providing a circuit for the inert gas and means for driving the inert gas over its circuit
- said means including a flexible vibratory element mounted in one of said conduits and positioned to cause directional movement to be imparted to a body of the inert gas adjacent thereto and an arrangement for transmitting power to the element to operate the same from the exterior of of the conduit in which'said element is located.
- conduits providing, a circuit for the inert gas and means for driving the inert gas over its circuit, said means including a flexible vibratory element mounted in one of said conduits and positioned to cause directional movement to be imparted to a body of the inert gas adjacent thereto and an arrangement for causing said element to oscillate.
- a main conduit forming part of means providing a circuit for the flow of the inert gas
- a branch conduit branching oif from the main conduit electrically operated means for raising the gas pressure in'said branch conduit and means for discharging gas from the branch conduit back into said main conduit to impart directional movement to the gas in said main conduit and thereby cause the gas to travel over its circuit.
- a main conduit forming part of means providing a circuit for the flow of the inert gas a branch conduit having a portion located within said main conduit, electrically operated oscillatory means for raising the gas pressure within said main conduit forming part of means providing a circuit for the flow of the inert gas, a branch conduit having a portion located within said main conduit, electrically operated oscillatory means for raising the gas pressure within said branch conduit and for causing the gas to be discharged from said branch conduit back into said main conduit to impart directional movement to the gas in said main conduit and thereby cause the gas to travel over its circuit, said electrically operated oscillatory means being herme ally sealed to the apparatus.
- absorption refrigerating apparatus of the type using a pressure equalizing medium
- the combination of an evaporator and an absorber means interconnecting the absorber and evaporator in circuit to form a passage for the equalizing medium, and means for circulating said medium including electro-magnetically operated means for altering the movement of portions of the medium. and then suddenly imparting pulsating movement thereto in a direction to cause movement of the main body of the medium in a direction parallel to the axis thereof.
- a refrigerating apparatus means for providing a, circulating system for the flow of fluid therein in a circuit between the evaporator and absorber, and vibratable means in said sys- H tern operable to remove portions of said fluid from the main body of fluid in said system and to expel said portions of fluid in a different direction into said main body of fluid to move the main body of fluid in said different direction.
- means for providing a circulating system for the flowof fluid therein in a circuit between the evaporator and absorber, and directional fluid impelling means comprising conduit means arranged in said circulating system and having a discharge opening arranged in the direction desired to impel the main body of fluid in the circulating system, and means for causing portions of the fluid in said system to travel inwardly of said conduit means and for pulsatingly expelling said portions of fluid through said discharge opening into contact with the main body of fluid in said circulating system to cause the fluid to travel in said desired direction.
- a method of circulating arfluid in a fluid circuit between the evaporator and absorber of a refrigerating system comprising causing portions of the fluid to be removed from the main body of fluid and then pulsatingly impelling said removed portions of fluid into said main body of fluid to urge the main body of fluid to travel in the same direction as the direction of said impelled portions of fluid when brought into contac with said main body of fluid.
- an absorption refrigerating apparatus comprising a generator, acondenser," an evaporator and an absorber and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, means including the evaporator and absorber providinga circuit for the agent and the auxiliary gas, a nozzle in the circuit for said nozzle for forcing a portion of said gas travelling in said conduit through said nozzle to produce said jet.
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- General Engineering & Computer Science (AREA)
- Sorption Type Refrigeration Machines (AREA)
Description
Nov. 15, 1938. p SCHOLL ET AL Re. 20,921
ABSORPTION REFRIGERATING APPARATUS Original Filed F eb. 27, 1932 l/ :I l
Ream! Na. 15, 1938 UNITED STATES PATENT OFFICE 20,921 ABSORPTION REFBIGERATING APPARATUS Original No. 1,956,402, dated April 24, 1934, Serial No. 595,486, February 27, 1932. Application for reissue April 2, 1936, Serial No. 72,334.
Germany March 4, 1931 28 Claims.
This invention relates to continuous absorption refrigerating apparatus of the type in which an inert gas is used as a pressure equalizing medium and more particularly to the use of means for circulating inert gas or other fluid within such a system or apparatus.
It is well known in the art of continuous absorption refrigeration to employ an inert gas as an auxiliary pressure equalizing medium and it is also well known to circulate this gas by means of a fan or the like. Such an arrangement is disclosed in the 'U. S. patent to Geppert, No. 662,690.
It is also old to provide a nozzle or jet for circulating the inert gas in a system of the-type described,'gas being supplied to the jet or nozzle by means of a boiler or the like. Such an arrangement is disclosed in the U. S. patent to Altenkirch, No. 1,615,353, which was reissued as Reissue No.
The gas circulating means of the' type shown in the Geppert patent requires a seal or stufflng box where the shaft used to drive thefan enters 26 some of the refrigerant within the boiler is wasted, in so'i'ar as cooling effect is concerned, in order that it may be employed for circulating the inert gas.
It is an object of the present invention to over- 30 come both of the disadvantages mentioned above by providing electro-magnetic gas circulating devices for circulating fluids in absorption refrigerating systems or the like. which devices may or :may not" be hermetically sealed within the 36 system, as desired.
It is. another object to provide an oscillatory element rather than a rotary one, for actuating the fluid, so that no moving parts such as shafts, or rotary fans are necessary and no lubrication l is required.
It is another object of the invention to provide an improved electro-magnetically operated oscillatory element in combination with a nozzle of a particular construction, the arrangement being ,Ji such that inert gas may be circulated in a system of the type mentioned.
It is still another object to provide a nozzle for circulating a fluid in a refrigerating system with power driven means for supplying gas to the 60 nozzle, the power driven means being adapted to be sealed within the system, if desired.
It is still a fm'ther object of the invention to mount a diaphrgm in a hermetically sealed chamber connected to a refrigerating system or the like, and to provide means for transmitting power through the wall of the chamber to cause the diaphragm to oscillate and thus in turn cause movement of fluids within the refrigerating system.
Other objects and advantages reside in certain novel features of the arrangement and construction as will be apparent from the following description taken in connection with the accompanying drawing, in which- Figure 1 is a diagrammatic illustration of a continuous absorption refrigerating system in which inert gas is circulated between the evaporator and the absorber by means of a gas circulating device constructed in accordance with the present invention,
- Figure 2 is an enlarged fragmentary view of a portion of the conduit forming part of the inert gas circuit of the arrangement of Figure 1, the conduit being partly cut away to show how the gas circulating means is associated therewith, 1
Figure 3 is a vertical cross sectional view of a modified form'of gas circulator which maybe used in place of the gas circulator of Figure 1, the figure showing a fragment of an inert gas conduit associated therewith, and
Figure 4 is a vertical cross sectional view of still another embodiment of gas circulating means which may be used in place of the arrangement of Figure 1, the view showing gas conduits connected thereto.
Referring to the drawing in detail, and first to the arrangement of Figure 1,- it will be seen that a continuous absorption refrigerating system has been illustrated as consisting of a generator or boiler i having a gas lift pump 2 associated therewith for conveying refrigerant gas and absorption liquid to the gas separation chamber I. The gas separation chamber 3 is connected to the top of the absorber 5 by a liquid conduit I. The absorber 5 consists of a cylindrical vessel, the lower portion of which may act as a reservoir as indicated in Figure 1, while the other portion is provided with baffle plates and a jacket through which cooling water may be passed to take heat away from the fluids therein. The
bottom of the absorber vesseli is connected to the top of the gas separation chamber to the condenser 8. The condenser 8 may be a coil of pipe or a bank of reversely bent pipes, as illustrated, and functions to cause the refrigerant vapor to liquefy.
The bottom of the condenser is connected to the evaporator IIlby means of a conduit 9. The evaporator may consist of a vertically disposed cylindrical vessel provided with baflie plates therein. It is connected to the absorber by means of two inert gas conduits II and I2. The conduit II is adapted to convey gas from the top of the absorber 5 to the bottom of the evaporator III, while the conduit I2 is adapted to convey gas from the top of the evaporator into the lower or intermediate portions of the absorber vessel 5 beneath the bafileplates in that vessel.
The important features of the present invention reside in the means for causing the inert gas to circulate over the path just described. Suitable power driven means may be associated with either of the conduits I I or I2 or with the evaporator or the absorber which go to make up the inert gas circuit. For purposes of illustration the arrangement of Figures 1 and 2 shows the gas circulator associated with the conduit I2. The arrangement is such that the inert gas or other gases are caused to circulate from left to right in this conduit as viewed in Figures 1 and 2.
Broadly speaking, the gas circulator includes a nozzle l3 located within the pipe I 2 and means for applying gas to this nozzle at a slightly higher pressure than that existing in the conduit I2 so that as gas emerges from the nozzle, directional movement-is imparted to gases in the conduit I2.
In the arrangement of Figures 1 and 2, the driving gas is supplied tothe nozzle I3 by means of a conduit Il connected to the conduit I2 slightly in advance of the nozzle I3, the conduit I4 having a small gas. compressor I5 connected therein. The compressor I5 may be driven 'by a small motor IE or by other motivating means exterior of the conduits II. It would, of course, be within the purview of the invention to mount the motor or other actuating means for the compressor I5 within a hermetically sealed chamber if desired.
A small annular disk I1 may be located just in front of the nozzle l3 within the pipe I2, the opening in the disk corresponding in area to the cross section of the gas jet emanating from the nozzle in order to aid in the circulation of gases through the pipe I2. With such an arrangement the kinetic energy of the gas particles flowing through the disk is more readily transferred to the gas mixture within the conduit t2, and since the gas jet completely fills the opening in disk I I there is but little tendency for the formation of eddy currents in the conduit I2.
Assuming that the electric motor I6 of the arrangement shown in Figure 1 just described is energized and that heat is applied to the boiler I, the refrigerating system operates as follows:
The refrigerantgas (such as ammonia), generated in the boiler system, flows through the conduit T, thence in the condenser 8, where it is liquefied, and flows into the evaporator. In the evaporator it evaporates into the inert gas, (such as hydrogen, nitrogen, air, or the like,) and flows with the inert gas through the conduit I2 under the influence of the compressor I5 and nozzle I3. The mixture of refrigerant gas and inert gas enters the absorber, and flows upwardly therethrough, coming into contact with the absorption liquid (such as water) as it does so. Refrigerant is absorbed out of the inert gas by the absorption liquid and passes back to the boiler system through the conduit 6.
At the same time, absorption liquid is circulated through the boiler system and absorber, the absorption liquid flowing from the boiler through the conduit 2, to the gas separation chamber and then through the conduit 4 into the absorber and back to the boiler through the conduit 6.
At the same time the inert gas is circulated from the evaporator III through the conduit I2 under the influence of the nozzle I3, the upper portion of the absorber vessel 5, and back to. the evaporatorthrough the conduit I I.
Any liquid collecting in the evaporator which had not evaporated may flow into the absorber through the U-pipe I8.
The arrangement of Figure 1 illustrates only a conventional absorption refrigerator inert gas circuit, but it is obvious that the present invention may be employed to drive inert gas or other fluids in other hermetically sealed systems, for example, refrigerating systems in which two inert gas circuits are employed as disclosed in U. S. patent to Altenkirch, No. 2,000,005, granted May 7, 1935.
In the arrangement of Figures 1 and 2 the motor which is used to drive the compressor I5 is shown as not hermetically sealed within the refrigerating system. An arrangement which is, or
may be hermetically sealed within a refrigerating system, and which has additional advantages over that shown in the arrangement of Figures 1 and 2, is shown in Figure 3.
In Figure 3, the nozzle outlet I3 is connected to a casing or chamber member 20 by means of a conduit I9. A flexible diaphragm 2| is disposed within the casing 20 in such a manner that it may oscillate upon being energized by alternating current electromagnets 22, which project through and are hermetically sealed to the wall of the casing 20. In accordance with known principles, vibration of the diaphragm 2| within the casing 20 will change the volume of the space between that diaphragm and the lower part of the casing 20 and this will cause air tobe sucked into and expelled from the nozzle I3. The air flow into and out of the nozzle, however, is peculiar in that the air which flows into the nozzle enters from points around the rim, as indicated by the arrows in Figure 3, whereas that which is expelled passes in parallel with the axis of the nozzle mouth. The frequency of vibration of the diaphragm 2| may be such that practically a continuous stream or jet of expelled gas is produced and the operation of the nozzle and the disk I! in front of it becomes practically the same as though a continuous stream of air were provided as in the arrangement of Figure 1. I
A modified arrangement similar to that of Figure 3' is shown in the arrangement of Figure 4, in which a casing or chamber member is so connected to the conduit I2 that the entire pump assembly, that is, the nozzle, diaphragm, and electromagnet are mounted therein. The discharge portion of the conduit I2 extends upwardly through the bottom of the nozzle so that its upper end acts in a way similar to that of the perforated disk I! in the arrangement of Figures 2 and 3. The diaphragm 2|, mounted in the upper part of the chamber, is oscillated by the electro-magnet 22 just the same as in the arrangement of Figure 3, and a pulsating jet is thus delivered from the nozzle due to the changes in volume of the gas space 24 between the diaphragm and the nozzle. As in Figure 3 the direction of movement of gas is indicated by the arrows.
In the arrangements described above, only a few of the embodiments of the present invention have been disclosed, but it is obvious that various changes may be made without departing from the spirit of the invention or the scope of the annexed claims. v I
We claim:
1. In an absorption refrigerating apparatus of the continuous type comprising agenerator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigera ing agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit for emitting a gas jet to direct said gaseous agents in a predetermined direction of circulation, and an electrically operated mechanical means connected with said nozzle for forcing a portion of said gas travelling in said conduit through said nozzle to produce said jet.
2. In an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a second conduit branching off said first-named conduit and terminating'in a nozzle in said first-named conduit to direct the gas mixture in said conduit in a predetermined direction of circulation, and an electrically operated mechanical means connected with said branch conduit for producing the gas pressure required for forcing a portion of said conduit gas through said nozzle.
3. In an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an, auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid-conduit connecting said evaporator. and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, an enclosed gas chamber connected with said nozzle and electrically operated mechanical means for varying periodically the volume of said gas chamber for drawing conduit gas through said nozzle into said space and for forcing it out through said nozzle back into said conduit in the desired circulating direction.
4. In an absorption refrigerating apparatus of the continuous type comprising a generator, a
condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting-said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, and an electrically operated mechanical means for producing the gas pressure required for forcing a portion of said gas through said nozzle, comprising a closed gas chamber connected with said nozzle and having a diaphragm for closing said chamben to the diaphragm to periodically vary the volume of said gas chamber, for drawing conduit gas through said nozzle into said chamber and forcing it out through "said nozzle back into said conduit in the desired circulating direction.
5. In an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzlein said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, and an electrically operated mechanical means for producing the gas pressure required for forcing a portion of said gas through said nozzle, comprising a closed gas chamber connected with said nozzle and having a diaphragm for closing said chamber to the outside, and electrical means for oscillating said diaphragm to periodically vary the volume of said gas chamber, for drawing conduit gas rhrough said nozzle into said chamber and for forcing it out through said nozzle back into said conduit in the desired circulating direction, said circulation conduit being enlarged-into a chamber-like space at the portion surrounding said nozzle. Y,
6. In an absorption refrigerating apparatus of the continuous type comprisinga generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent, and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connectingsaid evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to direct said gaseous agents in a predetermined direction of circulation, and means for producing the gas pressure required for forcing a portion of said conduit gas through said nozzle, comprising a closed gas chamber connected with said nozzle, an oscillatably disposed disk for closing said gas chamber to the exterior, and an electrically energized magnet outside of said space for oscillating said disc continuously to periodically vary the volume of said chamber, said circulation conduit beingenlarged at the portion surrounding said nozzle into a chamberlike space located in the path of said gas at a point where the flow of gas changes direction.
7. In an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator, and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas, a nozzle in said fluid conduit to-direct said gaseous agents in a predetermined direction of circulation, and means for producing the gas pressure required for forcing a portion of said gas through said nozzle, comprising a closed gas chamber, connected with said. nozzle and electricallyoperated mechanical means outside, and electrical means for oscillating said 1y perforated disk disposed in said conduit in front of the outlet of said nozzle.
8. In an absorption refrigerating apparatus of the continuous type comprising a generator, a condenser, an evaporator and an absorber, and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, a fluid conduit connecting said evaporator and said absorber to form a circulating system for said agent and said auxiliary gas between said vessels, and an electrically operated diaphragm gas pump hermetically connected with said conduit for drawing in conduit gas and for forcing it back into said conduit in the direction of the other vessel to produce a gas circulation in said direction in the cir culating system.
9. In an absorption refrigerating apparatus of the continuous type having a gas mixture circuit including an absorber, an evaporator and tubular connections between said vessels, an electromagnetically operated oscillatory diaphragm exposed to the gas mixture in one of said tubular connections and hermetically sealed against the outside for impelling thegas contacting with the diaphragm in the direction of one of said vessels to maintain gas circulation between said vessels.
10. In an absorption refrigerating apparatus of the continuous type having a gas mixture circuit including an absorber an evaporator and tubular connections between said vessels, an electromagnetically operated diaphragm gas pump connected with one of said tubular connections and communicating with the gas mixture therein, for impelling the mixture by the diaphragm oscillations, and means disposed in said connection opposite to said diaphragm for guiding the im elled gas in a desired direction.
11. In an. absorption refrigerating apparatus of the continuous type having a gas circuit containing a gas, and including an absorber, an evaporator and tubular connections between said vessels, a gas conveyor hermetically sealed to said gas circuit and comprising an electromagnet cally operated oscillatory diaphragm ex- 1 posed to the gas in one of said tubular connections, for impelling the gas contacting with the diaphragm in the direction of one of said vessels to produce movement of the gas from. one vessel to the other.
12. In absorption refrigerating apparatus of the type using an inert gas, the combination of conduits providing a circuit ,for the inert gas and means for driving the inert gas over its circuit, said means including an electro-magnetically operated vibratoryelement mounted in one of said conduits and positioned to cause directional movement to be imparted to a body of the inert gas adjacent thereto.
13. In absorption refrigerating apparatus 0 the type using an inert gas, the combination of conduits providing a circuit for the inert gas and means for driving the inert gas over its circuit, said means including a flexible vibratory element mounted in one of said conduits and positioned to cause directional movement to be imparted to a body of the inert gas adjacent thereto and an arrangement for transmitting power to the element to operate the same from the exterior of of the conduit in which'said element is located.
14. In absorption refrigerating apparatus of the type using an inert gas, the combination of conduits providing, a circuit for the inert gas and means for driving the inert gas over its circuit, said means including a flexible vibratory element mounted in one of said conduits and positioned to cause directional movement to be imparted to a body of the inert gas adjacent thereto and an arrangement for causing said element to oscillate.
15. In absorption refrigerating apparatus using inert gas, the combination of means providing a circuit for the inert gas, and forcirculating the inert gas therethrough, a vibratory element mounted in said means for driving the inert gas over its circuit and electrically actuated means for transmitting power from the exterior to the interior of said apparatus to cause oscillation of said element, said power transmitting means being hermetically sealed to the apparatus.
16. In continuous absorption refrigerating apparatus using inert gas, the combination of a main conduit forming part of means providing a circuit for the flow of the inert gas, a branch conduit branching oif from the main conduit, electrically operated means for raising the gas pressure in'said branch conduit and means for discharging gas from the branch conduit back into said main conduit to impart directional movement to the gas in said main conduit and thereby cause the gas to travel over its circuit.
17. In a continuous absorption refrigerating apparatus using inert gas, the combination of a main conduit forming part of means providing a circuit for the flow of the inert gas, a branch conduit having a portion located within said main conduit, electrically operated oscillatory means for raising the gas pressure within said main conduit forming part of means providing a circuit for the flow of the inert gas, a branch conduit having a portion located within said main conduit, electrically operated oscillatory means for raising the gas pressure within said branch conduit and for causing the gas to be discharged from said branch conduit back into said main conduit to impart directional movement to the gas in said main conduit and thereby cause the gas to travel over its circuit, said electrically operated oscillatory means being herme ally sealed to the apparatus.
19. In absorption refrigerating apparatus of the type using a pressure equalizing medium, the combination of an evaporator and an absorber, means interconnecting the absorber and evaporator in circuit to form a passage for the equalizing medium, and means for circulating said medium including electro-magnetically operated means for altering the movement of portions of the medium. and then suddenly imparting pulsating movement thereto in a direction to cause movement of the main body of the medium in a direction parallel to the axis thereof.
20. The method of circulating an inert medium in a fluid circuit between the evaporator absorber of an absorption refrigeration system.
comprising forming a stream, causing portions of the stream to move toward a focal point, and then suddenly imparting rapid movement to such portions in a direction parallel to the axis of the stream to thereby cause movement of the medium stream.
23. The method of circulating an inert medium in a fluid circuit between the evaporator and absorber of an absorption refrigeration system comprising forminga stream of the medium, momentarily altering the normalmovement of portions of the medium, and suddenly imparting pulsating movement to such portions in a direction to cause movement of the main portions of the stream in a direction parallel to the axis thereof.
24. The method of operating an absorption refrigeration system employing at least one refrigerant, an absorption medium therefor and a pressure equalizing medium, comprising separating the refrigerant from the absorption medium by the application of heat, condensing said refrigerant, allowing said refrigerant to evaporate into said pressure equalizing medium, passing said mediums last mentioned into intimate contact with the absorption medium and then returning the equalizing medium in a stream to the refrigerant evaporating zone bymomentarily withdrawing portions of the stream from its normal' path and suddenly returning such portions to the stream in pulsating jets in a direction parallel to the original axis of the stream to thereby cause forward movement of the main portions of the pressure equalizing medium.
25. In a refrigerating apparatus, means for providing a, circulating system for the flow of fluid therein in a circuit between the evaporator and absorber, and vibratable means in said sys- H tern operable to remove portions of said fluid from the main body of fluid in said system and to expel said portions of fluid in a different direction into said main body of fluid to move the main body of fluid in said different direction. I
26. In a refrigerating apparatus, means for providing a circulating system for the flowof fluid therein in a circuit between the evaporator and absorber, and directional fluid impelling means comprising conduit means arranged in said circulating system and having a discharge opening arranged in the direction desired to impel the main body of fluid in the circulating system, and means for causing portions of the fluid in said system to travel inwardly of said conduit means and for pulsatingly expelling said portions of fluid through said discharge opening into contact with the main body of fluid in said circulating system to cause the fluid to travel in said desired direction.
27. A method of circulating arfluid in a fluid circuit between the evaporator and absorber of a refrigerating system, comprising causing portions of the fluid to be removed from the main body of fluid and then pulsatingly impelling said removed portions of fluid into said main body of fluid to urge the main body of fluid to travel in the same direction as the direction of said impelled portions of fluid when brought into contac with said main body of fluid.
28. In an absorption refrigerating apparatus comprising a generator, acondenser," an evaporator and an absorber and containing a refrigerating agent and an auxiliary inert gas mixed with the refrigerating agent in the evaporator and absorber, means including the evaporator and absorber providinga circuit for the agent and the auxiliary gas, a nozzle in the circuit for said nozzle for forcing a portion of said gas travelling in said conduit through said nozzle to produce said jet.
.PAUL SCHOLL.
Publications (1)
Publication Number | Publication Date |
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USRE20921E true USRE20921E (en) | 1938-11-15 |
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ID=2086247
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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US20921D Expired USRE20921E (en) | Absorption refrigerating apparatus |
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