CA2383489A1 - Heat temperature raising system - Google Patents

Heat temperature raising system Download PDF

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Publication number
CA2383489A1
CA2383489A1 CA002383489A CA2383489A CA2383489A1 CA 2383489 A1 CA2383489 A1 CA 2383489A1 CA 002383489 A CA002383489 A CA 002383489A CA 2383489 A CA2383489 A CA 2383489A CA 2383489 A1 CA2383489 A1 CA 2383489A1
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heat
temperature
medium
carrying medium
vapor
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French (fr)
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Hsiang-Jen Cheng
Sing-Wang Cheng
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F1/00Tubular elements; Assemblies of tubular elements
    • F28F1/10Tubular elements and assemblies thereof with means for increasing heat-transfer area, e.g. with fins, with projections, with recesses
    • CCHEMISTRY; METALLURGY
    • C09DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
    • C09KMATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
    • C09K5/00Heat-transfer, heat-exchange or heat-storage materials, e.g. refrigerants; Materials for the production of heat or cold by chemical reactions other than by combustion
    • C09K5/02Materials undergoing a change of physical state when used
    • C09K5/06Materials undergoing a change of physical state when used the change of state being from liquid to solid or vice versa
    • C09K5/063Materials absorbing or liberating heat during crystallisation; Heat storage materials
    • 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
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B25/00Machines, plants or systems, using a combination of modes of operation covered by two or more of the groups F25B1/00 - F25B23/00

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Chemical & Material Sciences (AREA)
  • Thermal Sciences (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Combustion & Propulsion (AREA)
  • Organic Chemistry (AREA)
  • Materials Engineering (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Geometry (AREA)
  • Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)
  • Physical Water Treatments (AREA)
  • Vaporization, Distillation, Condensation, Sublimation, And Cold Traps (AREA)
  • Physical Or Chemical Processes And Apparatus (AREA)
  • Sorption Type Refrigeration Machines (AREA)

Abstract

Disclosed is a process and apparatus for transferring heat from a heat sourc e at a first temperature (16) to a heat sink at a second higher temperature (1 7) in a phase change of a heat transfer fluid. The heat transfer fluid is subjected to a pressure variation which changes the temperature at which pha se change takes place.

Description

HEAT TEMPERATURE RAISING SYSTEM
Technical Field This invention relates to a process and apparatus for raising heat temperature, i.e., transferring heat from a low temperature heat source to a higher temperature heat sink.
More specifically, in one embodiment, the invention relates to a process and apparatus for transforming a heat carrying substance under a first pressure Pi and producing a vapor of a second heat carrying substance at a second pressure P2.
Background of the Invention The process of the invention is based on the principle that the melting point of a substance changes as the applied pressure changes. A set of multiple heat conductive and pressure rated (i.e. pressurizable) conduits is connected with pressurizing equipment.
Inside these conduits is a mass of Heat Temperature Raising Medium (HTR
medium) which is capable of undergoing a phase change upon the application of pressure. When the HTR medium is subjected to a pressure variation, it allows the said medium to absorb and store heat at low temperature. After the HTR medium has absorbed and stored the heat at low temperature, a high pressure is applied to the HTR medium. This increase in pressure on the HTR medium causes the melting point of the medium to increase and allows the medium to release the heat it has stored to the higher surrounding temperature.
Thus, the HTR medium can successfully elevate the temperature from a low temperature to a higher temperature. Another medium, Heat Carrying Medium (HCM medium), is used in the present invention to assist and complete the cycle of raising heat temperature from low temperature heat source to a higher temperature heat sink.
The use of a melting point inversion for water purification of saline water is disclosed in U.S. Patent number 3,354,083. This process requires a large sum of saline water and mediums to be exposed to high pressure and low pressure. Due to the difficulty of such operation, this process was unsuccessful. Hence there remains a need in the art for a process and apparatus which can make use of the latent heat of fusion and/or latent heat of evaporation of heat transfer materials to transfer heat without subjecting large quantities of process fluids to high pressure.
SUBSTITUTE SHEET (RULE 26) Disclosure of the Invention It is accordingly an aspect of the invention to provide a process and apparatus for transferring heat from a heat source at one temperature to a heat sink at a higher temperature.
It is another aspect of the invention to provide a process and apparatus, as above, which accomplishes the heat transfer by effecting a phase change of a heat transfer medium using variable pressure to alter the temperature at which the phase change occurs.
It is another aspect of the invention to provide a process and apparatus, as above, which minimizes the amount of fluid subjected to the variable pressure.
Unlike the above prior process, the present invention maintains the Heat Temperature Raising Medium (HTR medium) inside conduits. By subjecting the HTR
medium to a pressure fluctuation between low pressure and high pressure, the invention allows the HTR medium to absorb heat at low temperature and release heat at a higher temperature. Thus, the HTR medium can successfully elevate the heat temperature, i.e., transfer heat from a first temperature to a second, higher temperature without the need of exposing large quantities of materials to low pressure and high-pressure operation.
In the present invention, the high-pressure zone is preferably stationary and is secured inside a Heat Temperature Raiser (HTR unit), while the transportation of the heat between the low temperature source and high temperature sink is accomplished by the Heat Carrying Medium (HCM medium) operating at low pressure. Therefore, large quantities of material moving between low pressure and high-pressure operation are not required.
The present invention provides for a Heat Temperature Raising System, referred to as a HTR system, for taking in heat from a low temperature (TL) heat source and supplying heat to a high temperature (TH) heat sink. A HTR system comprises a heat temperature raising unit, referred as a HTR unit, a mass of heat temperature raising medium, referred to as HTR medium, and a mass of a first heat carrying medium, referred to as HCM-medium, and a mass of second heat carrying medium, referred to as HCM-2 medium. The system is divided into three compartments: a central compartment referred to as a HTR
compartment, containing the HTR units, a heat source compartment and a heat sink compartment. There is a first valuing means separating the heat source compartment and SUBSTITUTE SHEET (RULE 26) the HTR compartment and a second valuing means separating the heat sink compartment and the HTR compartment.
The HTR unit is preferably a stationary unit, i.e., the HTR medium is not itself conveyed between the heat source and the heat sink. The HTR unit comprises a set of heat conductive and pressure sustaining conduits, a mass of HTR medium contained in the HTR
unit and a pressurizer for pressurizing and depressurizing the HTR medium contained in the HTR unit.
The pressurizer can be, for example, a mechanical compressor such as a plunger mechanism, a steam source, or other compressive fluid source, or any other device which can apply substantially hydrostatic pressure to the HTR medium. The HTR medium is subjected to a series of cyclic operations that comprise melting under a first pressure and a first temperature, respectively referred to as a first HTR pressure and a first HTR
temperature and solidifying under a second pressure and a second temperature, respectively referred to as a second HTR pressure and a second HTR temperature. A mass of first heat carrying medium HCM-1 is vaporized by receiving heat from the heat source to form a HCM-1 vapor and the vapor passes through the first valuing means to come in contact with the HTR unit and melt the HTR medium. The HCM-1 vapor is thereby condensed to form a mass of HCM-1 condensate. Then, a mass of the second heat carrying medium HCM-2 is brought in contact with the HTR medium to thereby solidify the HTR medium under the second HTR pressure and temperature and thereby form a vapor stream of the second heat carrying medium, referred to as HCM-2 vapor. The HCM-2 vapor passes through the second valuing means and releases heat to the heat sink and thereby condenses to form a condensate of HCM-2 medium. The condensate is recycled to the vaporization operation described. It is noted that since the HTR medium is preferably contained within a stationary HTR unit, it takes the first and second HCM medium to exchange heat with the heat source and the heat sink.
It is also within the scope of the invention to use the same medium for both and HCM-2. 1n this alternative, the HCM-1 condensate formed in the low temperature condensation operation may be used in the high temperature evaporation operation, and the HCM-2 condensate formed in the high temperature condensation operation may be used in the low temperature vaporization operation.
SUBSTITUTE SHEET (RULE 26) A HTR system can be used in providing chill water and air conditioning and used in vacuum freezing processes, in ice production processes, ice storage processes, distillative freezing processes and mufti-effect evaporation processes.
Brief Description of the Drawing For a full understanding of the invention, the following detailed description should be read in conjunction with the drawings, wherein:
Fig. 1 is a schematic illustration of one embodiment of an HTR system of the invention;
Fig. 2 illustrates one embodiment of an HTR unit of the invention;
Fig. 2A illustrates another embodiment of an HTR unit of the invention;
Fig 2B illustrates the structure of one embodiment of a longitudinal fin unit of the invention;
Fig. 2C is a partial cutaway view of an HTR unit containing the fin unit of Fig.
2B;
Fig. 3A is a cross-sectional view of one embodiment of a multiple connected conduit unit of the invention;
Fig. 3B is a cross-sectional view of the multiple conduit unit of Fig. 3A with longitudinal fin units installed;
Fig. 4A is a cross-sectional view of another embodiment of a multiple conduit unit of the invention;
Fig. 4B is a cross-sectional view of the conduit unit of Fig. 4A with longitudinal fin units installed;
Fig. 5A is a cross-sectional view of one embodiment of mufti-void metal block unit of the invention;
Fig. 5B is a cross-sectional view of the mufti-void metal block unit of Fig.

with longitudinal fin units installed;
Fig. 6A illustrates one embodiment of an HTR system of the invention with heat transfer from a first Heat Carrying Medium;
Fig. 6B illustrates the HTR system of Fig. 6A with heat transfer to a second Heat Carrying Medium;
SUBSTITUTE SHEET (RULE 26) Fig. 7A illustrates another embodiment of an HTR system of the invention with heat transfer from a first Heat Carrying Medium;
Fig. 7B illustrates the HTR system of Fig. 7A with heat transfer to a second Heat Carrying Medium;
5 Fig. 8A illustrates an embodiment of an HTR system of the invention which is useful in vacuum freezing with heat transfer from a first Heat Carrying Medium;
Fig. 8B illustrates the HTR system of Fig. 8A with heat transfer to a second Heat Carrying Medium;
Fig. 9A illustrates another embodiment of an HTR system of the invention useful in vacuum freezing with heat transfer from a first Heat Carrying Medium;
Fig. 9B illustrates the HTR system of Fig. 9B with heat transfer to a second Heat Carrying Medium;
Fig. l0A illustrates another embodiment of the HTR system of the invention useful in vacuum crystallization of an aqueous solution and non-aqueous mixtures with heat transfer from a first Heat Carrying Medium;
Fig. lOB illustrates the HTR system of Fig. l0A with heat transfer to a second Heat Carrying Medium;
Fig. 11A illustrates one embodiment of a multiple effect evaporating system incorporating HTR units of the invention and operated in a first cycle;
Fig. 11B illustrates the mufti-effect evaporating system of Fig. 11A operated a second cycle;
Fig. 12A illustrates a multiple effect evaporator system similar to that of Fig. 1 lA
and employing corrugated metal walls to form falling film evaporators and operated in a first cycle;
Fig. 12B illustrates the multiple effect evaporator of Fig. 12A operated in a second cycle;
Fig. 13 illustrates an automatic valuing system of the invention; and3 Fig. 13A illustrates a single valve of the invention.
Detailed Description of the Preferred Embodiments A heat temperature raising system (HTR system) of the present invention utilizes a heat temperature raising medium (HTR medium) that undergoes cyclic solidification and SUBSTITUTE SHEET (RULE 26) melting operations and one or more heat carrying mediums (HCM mediums) that undergo vaporization and condensation operations. An HTR system is used to take in heat at a low temperature heat source and discharge heat to a higher temperature heat sink.
Figure 1 illustrates the processing steps of an HTR system. In this and other figures, like numerals denote the same structure. In the system, a mass of HTR medium contained within a multitude of heat conductive and pressure sustaining conduits is subjected to a cyclic operations undergoing: (a) a first step of melting most of the HTR
medium under pressure PHTRI ~d temperature T~1, [state 1 - state2]; (b) a second step of varying the medium pressure from PH-,-R, to PHT~ [state 2 - state 3]; (c) a third step of solidifying most of the HTR medium under pressure PHT~ and temperature THT~ [state 3 - state 4]; and (d) a fourth step of varying the medium pressure from PHA to PHTRi [state 4 -state 1].
A first heat carrying medium [HCM-1 medium] receives heat from a low temperature heat source and thereby generates a first HCM medium vapor, HCM-1 medium vapor, which is condensed by releasing heat Q~ to the HTR medium in step 1. A
second heat carrying medium [HCM-2 medium] receives heat from the HTR medium in step 3 to form a HCM-2 medium vapor, which is condensed by rejecting heat QH to the heat sink at an elevated temperature.
Figure 2 illustrates the construction of a Heat Temperature Raising unit (HTR
unit). It comprises a multitude of heat conductive and pressure sustaining conduits 2, a mass of heat temperature raising medium (HTR medium) 3, a header 4, and a cylinder and piston 5 for pressurizing and depressurizing the HTR medium. The use of a cylinder and piston is of course merely one example of a method for pressurizing the HTR
medium. Other well-known methods will readily occur to those skilled in the art.
Figure 2A illustrates another heat temperature raising unit similar to that of Figure 2, except that there is a fin unit 6 installed in each conduit to enhance heat transfer. Figure 2B illustrates the structure of a longitudinal fin unit 6 and Figure 2C
illustrates a cutaway view of a conduit 2 containing a fin unit 6.
Figure 3A illustrates a cross section of a unit of multiple connected conduits 7 unit formed by bonding two sheets 8 of corrugated material. The neighboring conduits are connected by wings 9. Figure 3B illustrated a cross section of a multiple conduit 7 unit similar to that of Figure 3A with a fin unit 10 installed in each conduit 7 to enhance heat transfer.
SUBSTITUTE SHEET (RULE 26) Figure 4A illustrates a cross section of a multiple conduit unit or a multiple tube assembly in which each conduit 7 is isolated from neighboring conduit. Figure illustrates cross-sections of a multiple conduit unit similar to that of Figure 4A with a fin unit 10 installed in each conduit to enhance heat transfer.
Figure SA illustrates a cross-section of multivoid metal blocks that has multiple conduits 12. Figure 5B illustrates a cross section of a unit similar to that of Figure SA with a fin unit 13 in each of the conduits.
It is noted that the mass of the wall (MW) of a HTR unit, e.g., walls of the conduits and header (see Figure 2) and block (see Figures SA, SB) is a major factor that affects the efficiency of the HTR operation. It is important to keep the ratio of the mass of the wall of the HTR unit (MW) to the mass of HTR medium to a low value. Referring again to Figure l, as the HTR unit is heated in step 2, the wall (not shown) is heated from T~
to TZ and thereby absorbs sensible heat. Therefore a part of the HTR medium is solidified to meet the energy balance relation. Thus, the amount of the remaining HTR medium to be solidified becomes less and the heat released in step 3 becomes less. Again in Figure 1, as the HTR
unit is cooled in step 4, the wall is cooled from TZ to T~ and thereby releases sensible heat.
Thus, a part of the HTR medium is melted to meet the energy balance relation.
Therefore, the amount of the remaining HTR medium to be melted becomes less and the heat absorbed in step 1 becomes less. The problem described is referred to as "Thermal Inertia Problem".
It is important to note that the higher the ratio of the mass of the wall of a HTR unit to the mass of the HTR medium, the more serious the "Thermal Inertia Problem" becomes and the lower the productivity of the HTR unit becomes and the lower the efficiency of the HTR
unit becomes.
Suitable materials of construction of the HTR unit include aluminum, steel, copper, brass, and other metal and non-metal materials having sufficient heat transfer characteristics to permit acceptable heat transfer from the first Heat Carrying Medium and from the HTR
unit to the second Heat Carrying Medium including heat transfer through the walls.
The mass ratio of the wall to the HTR medium is the lowest for a HTR unit with multiple tube assembly illustrated by Figures 4A and 4B. The mass ratio of the wall to the HTR medium is higher in a HTR unit with connected walls illustrated by Figures 3A and 3B. The mass ratio of the wall to HTR medium is the highest in a HTR unit made of a multivoid block illustrated by Figures SA and SB.
SUBSTITUTE SHEET (RULE 26) Thus, the use of a multivoid block is generally less preferred, because the mass ratio of wall to HTR medium is so high that the efficiency of HTR operation is low, its efficiency becomes so low that it is not very usefizl when the TZ - Tl, referred to as temperature lift, is high.
Figures 6A and 6B show a HTR system that comprises a Heat Temperature Raising Zone 15, HTR Zone (Zone - 1), a flash cooling Zone 16 (Zone - 2), and a direct contact condensation Zone 17 (Zone - 3). Figure 6A shows that a feed liquid 21 is flash vaporized to be cooled and generate a heat carrying medium vapor V1 (HCM-1 vapor). The medium vapor is then passed through an automatic valve 18 (made of, for example, a grating and flaps made of thin film), and it is brought in contact with the outer surface 22 of the HTR conduits for exchanging heat with the HTR medium in the HTR unit to thereby melt the HTR medium at T~RI and P,-i~~. Figure 6B shows that a mass of heat carrying medium is brought in contact with the HTR unit under pressure PHA and at temperature THE to thereby generate a heat carrying medium vapor VZ (HCM-2 vapor) and solidify the HTR medium. The HCM-2 medium vapor is then passed through an automatic valve 19, (made of, again for example, a grating and flaps made of thin film), and is brought in direct contact with a fluid 24 introduced in Zone-3 to contact the HCM-2 vapor and heat the said fluid. This system is useful in producing chilled water for air conditioning and also for other industrial cooling operations.
Figure 7A and 7B illustrate another HTR system that comprises a HTR Zone 15 (Zone 1), HCM-1 vapor generation Zone 16 (Zone-2A) and heat source Zone 26 (Zone 2B), a HCM-2 vapor condensation Zone 17 (Zone-3A) and a heat sink Zone 17 (Zone-3B).
Figure 7A illustrates that a HCM medium is brought in heat exchange relation with a heat source in Zone-2B to generate HCM-1 vapor V1 in Zone 2A. The HCM-1 vapor is condensed and the HTR medium is melted at T~1 and PHI in Zone 1. Figure 7B
shows that a mass of HCM-2 is applied on the outer surface 23 of the conduit of the HTR unit and is vaporized to form HCM-2 vapor VZ and solidify the HTR medium at THE and P
Hue.
The HCM-2 vapor is then pass through a second valve 19 and condensed in Zone-3A by releasing heat to a heat sink 27 in Zone-3B.
Figures 8A and 8B illustrate a HTR system used in a vacuum freezing operation.
This system is useful in seawater desalination, industrial solution concentration, waste water concentration and crystallization of aqueous solution and non-aqueous mixtures. The SUBSTITUTE SHEET (RULE 26) system comprises a HTR Zone 29 (Zone-1), a vacuum-freezing Zone 30 (Zone-2), a crystal melting Zone 34 (Zone-3) and a crystal washing Zone 23 (Zone-4).
The processing steps conducted in the system are explained by referring to sea water desalination as an example. Referring to Fig 8A, a sea water feed is subjected to a deaeration and a heat exchange operation and is flash vaporized in Zone-2 to form a first low pressure water vapor that is designated as HCM-1 vapor V~ and a mass of ice crystals 35. The pressures of the HCM-1 vapor is around 3.5 torr, which is lower than the triple point pressure of water (4.58 torr). The mass of ice crystals and the concentrated mother liquid form a slurry stream that is subjected to a crystal washing Zone 23 (Zone 4) and the purified ice is introduced to Zone-3. The low-pressure water vapor V~ (HCM-1 vapor) is brought in contact with the HTR unit that is at pressure PHTRi and temperature T ,-,~1. The water vapor is desublimed to form a mass of desublimate (ice) 36 on the outer surfaces of the HTR unit and the HTR medium is melted. Referring to Figure 8B, the HTR
unit is then subjected to pressure PHA and temperature T HT~ to generated a second water vapor VZ
(HCM-2 vapor) at a pressure around 5 ton, which is higher than the triple point pressure of water. The second water vapor Vz is brought in contact with the ice in Zone 3 to thereby simultaneously melt the ice and condense the second water vapor VZ as output stream 39.
Both the condensate of the second vapor VZ and the melt 39 of the ice become purified product water.
The system illustrated in Figures 9A and 9B is similar to that of Figures 8A
and 8B
and operations conducted in this system are also similar. In this system the HCM-2 vapor is brought into an indirect contact heat exchange with the purified crystals in Zone 3. Melt liquid exits in stream 47.
The system illustrated by Figures 10A and lOB is usefizl in vacuum crystallization of aqueous solution and non-aqueous mixtures. In this system the HCM-2 vapor formed is condensed by a cooling medium in Zone-3, and the crystal formed is not melted by the HCM-2 vapor. This system is particularly usefixl in ice block making whereby the small ice made in Zone 2 can be compressed to form ice block. This system is also very useful in conducting a distillative freezing process as described in U.S. Patent Nos.:
4218893, 4433558, 4451273 and 4578093, which are hereby incorporated by reference in their entirety.
SUBSTITUTE SHEET (RULE 26) Figures 11A and 11B illustrates a mufti-effect evaporating system that comprises a first multiple effect evaporator, Z-lA, a second multiple effect evaporator, Z-1B, in the major processing Zone Z-1, a first HTR unit 61 in Z-2A and a second HTR unit 62 in Z-2B
at the first end of the system, a third HTR unit 63 in Z-3A and a fourth HTR
unit 64 in Z-3B
S at the second end of the system. The HTR units are operated cyclically and the mufti-effect evaporators are operated nearly continuously.
The first multiple effect evaporator Z-lA comprises, as an example, nine evaporators 69-77 (ZE-1 through ZE-9) connected in series, with operating pressures decreasing successively in the direction from the left end ZE-1 toward the right end ZE-9.
10 The second multiple effect evaporator Z-1B, comprises nine evaporators 78-86 (ZE'-1 through ZE'-9) connected in series, with operating pressures decreasing successively in the direction from the right end ZE'-1 toward the left end ZE'-9. It is readily understood that more or less than 9 effects may be used, the actual number being selected based on perameters such as operating conditions and economics.
1 S Each of the four HTR units is operated cyclically and alternately serves as an evaporator and as a condenser. The four HTR units are operated in a coordinated manner.
While one of the two HTR units at each end serves as an evaporator, the other unit serves as a condenser. As illustrated in Figure 11A, the HTR units in Z-2A and Z-3B
serves as two vapor generators and the HTR units in Z-2B and Z-3A serve as two condensers.
The vapor streams generated are used as steam supplies to the two ZE-1 Zones and ZE'-1 Zones and thereby initiate the multiple effect evaporator operations.
The vapor steams leaving the last effect ZE-9 and ZE'-9 are condensed in the two HTR-units serving as condensers. Figure 11B illustrates the same system in the other half of the cycle, in which the HTR units in Z-2B and Z-3A become the vapor generators and the HTR
units in Z-2A and Z-3B become the condensers.
Figures 12A and 12B illustrate a multiple effect evaporator system similar to those illustrated by Figures 11A and 11B. In this system, corrugated metal walls 96, 97 are used to form falling film evaporators 89-95 and 98-104.
Figure 13 illustrates an Automatic valuing system that provides vapor passages from one chamber to another without any mechanical actuating device or any electrical switch.
The automatic valuing system is made of a mesh 105 for structural support as well as a grating 107 for the two chambers with flaps 106 (made of thin filin) attached on to the SUBSTITUTE SHEET (RULE 26) grating 107. The gratings with attached thin films fiznction as dividers between two chambers. The thin film flaps 106 are pressure sensitive where when one chamber's pressure is higher than the other, the flap will automatically opens allowing the vapor to flow from the first chamber with higher pressure to the second chamber with the low S pressure. It automatically closes when the pressure of the second chamber becomes higher than that in the first chamber.
Figure 13A illustrates a single valve made of thin film flap attached onto a holder on the top of flap.
In nature, heat flows from a high temperature heat source to a low temperature heat sink. The present invention discloses a process and apparatus with proper input of energy to accomplish just the opposite of what nature does. Theoretically the work input (applied pressure times the volume change of the HTR medium) to the HTR for a given amount of heat raised (the latent heat of HTR medium) per unit temperature rise is inversely proportional to the absolute temperature. This relationship may be derived from the Clausius-Clapeyron equation (Journal of Chemical Physics, Volume 25, No. 3), and can take the form: f POV/~T}=1/T, representing the law of heat temperature raiser.
This invention is based on the principle that as the applied pressure changes the melting point changes.
There are generally two types of compounds suitable for an HTR medium: a Type A substance is the most common, for which, as the pressure applied on the medium increases, its melting point increases. Thus, the said medium will absorb heat at low temperature and low pressure; and as the applied pressure increases, the melting point of the medium increases, allowing it to release heat and solidify at a higher temperature. For a Type B substance, such as water, as the applied pressure increases, the melting temperature decreases. As the pressure applied upon ice increases, the melting point decreases whereby allowing ice to absorb heat at temperature below 0°C to melt and again solidify at 0°C as the pressure is released. Nonetheless, both types of substances can be used to absorb heat at a lower temperature and to release heat at a higher temperature by subjecting the medium to a pressure variation. Therefore, any medium with proper variation in melting point can be used as a Heat Temperature Raising Medium. Suitable Heat Temperature Raising Medium include compounds having melting points ranging from between -30°C and 100°C as described, for example, in the Handbook of Chemistry and Physics, which is incorporated SUBSTITUTE SHEET (RULE 26) herein by reference. Any resulting mixture should have a eutectic point range of between -30°C and 100°C. A mixture can also be used as a HTR medium. The figures will now again be discussed in fiuther detail.
In the system of Figure l, a mass of HTR medium contained within a multitude of heat conductive and pressure sustaining conduits is subjected to a cyclic operations undergoing: (a) a first step of melting most of the HTR medium under pressure PHTRI ~d temperature THAI, [state 1 - state2]. (b) a second step of varying the medium pressure from PHTRI to PH~z [state 2 - state 3]. (c) a third step of solidifying most of the HTR medium under pressure PHT~ and temperature TE,T~ [state 3 - state 4], and (d) a fourth step of varying the medium pressure from PHA to P,~RI [state 4 - state 1]. A first heat carrying medium [HCM-1 medium] receives heat from a low temperature heat source and thereby generate a first HCM medium vapor, HCM-1 medium vapor, which is condensed by releasing heat QL to the HTR medium in step 1. A second heat carrying medium [HCM-2 medium] receives heat from the HTR medium in step 3 to form a HCM-2 medium vapor, which is condensed by rejecting heat QH to the heat sink at an elevated temperature.
Still referring to Figure 1, the masses of HTR medium in the solid and liquid states in state 1 are respectively represented by (ms)~~,1 and (mL)~,1; the masses of HTR
medium in the solid and liquid states in state 2 are respectively represented by (ms)~-,T~ and (m~)HT~; the mass of HTR medium in the solid and liquid states in state 3 are respectively represented by (ms)~,3 and (m~)~,3; the mass of HTR medium in the solid and liquid states in state 4 are represented by (ms),-ITRa and (mL),-,~,a. Then, the heat taken in at the low temperature heat source QL is given by: QL={(mL)HTR,z - (mL)HT~,1 } x ~.m where 7,,", is the latent heat of melting of the HTR medium. It also shows that the heat given to the high temperature heat sink minus QH is given by: - QH ={(ms)HTa,a - (ms)H~ra,3} x ~,,~". As the HTR unit changes its temperatures from TH~,4 to THTa,I, the HTR unit releases sensible heat. Therefore, a portion of the HTR medium melts to satisfy the energy balance relation.
Therefore, (mL)HTR,i is greater than (m~)~~4. This makes the heat removable from the low temperature heat source smaller. Similarly, as the HTR unit changes its temperature from T~ to THE the HTR unit absorbs sensible heat. Therefore, a portion of the HTR
medium solidifies to satisfy the energy balance relation. Therefore, (ms)H~,3 is greater than (ms)HTR,2. This makes the heat available to the high temperature heat sink smaller. The loss in the amount of heat transferable is referred to as "Thermal Inertia Problem." It can be SUBSTITUTE SHEET (RULE 26) shown that as the mass of the HTR conduits increases, the more serious the Thermal Inertia Problem becomes, and the greater the temperature lift, {TH~,Z - THra,i } is the more serious the Thermal Inertial Problem becomes.
The figure also shows that one may use the same substance for both HCM-l and HCM-2 mediums. In this case, one may use as the HCM-1 a condensate obtained in the low temperature condensation operation as the HCM-2 medium and subject it to a high temperature vaporization operation and one may also used the HCM-2 condensate formed in the high temperature condensation operation as the HCM-1 medium and subject it to a low temperature vaporization operation.
Figure 2 illustrates the construction of a heat temperature raising unit (HTR
unit) 1.
It comprises a multitude of heat conductive and pressure sustaining tubes 2, a mass of heat temperature raising medium 3, a header 4, and a cylinder and a piston 5 for pressurizing and depressurizing the HTR medium. This pressure device can be just a piston or any other type of pressurizing device.
By changing the pressure applied to the Heat Temperature Raiser unit, the Heat Temperature Raising Medium (HTR medium) 3 absorbs heat at a low temperature and releases heat at a higher temperature. The present invention will be illustrated by use of a type A substance as a Heat Temperature Raising Medium. The HTR at a low pressure melts and store the heat in the form of latent heat of the HTR medium. As the applied pressure is increased, the melting point of the HTR medium increases. Under the higher pressure, the latent heat of the medium HTR medium will be released at a higher temperature, and the HTR medium will solidify again. Therefore by changing the applied pressure, HTR will allow the HTR medium to perform a batch processing of the elevating heat temperature from a lower temperature to a higher temperature. The faster the rate of the heat transfer through the conduits of the Heat Temperature Raiser, the faster the HTR
medium can absorb and release its latent heat. Therefore, the pressure changes have to take place faster. Therefore the amount of the heat temperature raising per unit length of the conduits of the HTR per unit time will be greater. A set of fins can be installed inside of the conduits to increase the rate of the heat transfer within the HTR medium.
Figure 2A shows a HTR unit similar to that of Figure 2, except that there are a set of longitudinal fins 6 installed in the conduits. Figure 2B shows the construction of a longitudinal fin. Figure 2C
shows a partial cut away view of a conduit with a longitudinal fin installed therein.
SUBSTITUTE SHEET (RULE 26) The conduit of the Heat Temperature Raiser is made of a heat conductive and pressure sustaining material. There are different ways of constructing conduits used in constructing a HTR unit:
Figure 3A illustrates a set of conduits 7 formed by bonding together corrugated plates 8. The neighboring conduits are connected by wings 9. Figure 3B
illustrates a set of conduits with connecting wings similar to that shown in Figure 3A, except that longitudinal fins are installed within the conduits.
Figure 4A illustrates a set of conduits 7 that have substantially uniform wall thickness 8 and that the conduits are individually separated without having any connecting walls between two neighboring conduits. Figure 4B shows a similar unit with fins 10 in the conduits.
Figure SA illustrates a multivoid metal block having conduits that do not have substantial uniform thicknesses. Figure SB illustrates a similar structure with fins in the conduits.
During the high-pressure operation of the HTR, the melting point of HTR medium will increase as the pressure is increased, thereby allowing the HTR medium to release heat at the higher temperature. At the same time, the outer wall of the conduits of the HTR will also increase its temperature by absorbing heat released by HTR medium. After pressure is released from HTR, the pressure of HTR will decrease and the melting point of the HTR
medium will decrease which will allow the HTR medium to absorb heat at the lower temperature while the outer walls of the conduit of the HTR will reduce the temperature by releasing heat. The effectiveness of HTR in upgrading heat temperature of the HCM
medium from a low temperature heat source to a higher temperature heat sink is dependent on the amount of latent heat of HTR medium elevated by the batch process of HTR minus the amount of sensible heat used by the outer walls of the conduits.
Therefore, the less sensible heat used by the outer wall of the conduits, the more effective the HTR in upgrading heat temperature will be. Thus, materials with less sensible heat retention used in constructing the HTR, the less sensible heat will be lost, and the effectiveness of the HTR
will increase.
Therefore, in the above mentioned types of conduits, a set of conduits with relatively uniform wall thickness is preferred over the multivoid block conduits for constructing HTR because a set of conduits with relatively uniform wall thickness will SUBSTITUTE SHEET (RULE 26) minimize the loss of sensible heat per unit volume of conduit. The amount of the material used by the multivoid block conduits is too large causing too much sensible heat loss per unit volume of conduit; thus it is not preferred and may be suitable for use in the HTR to elevate heat temperature in the HTR. On the other hand, a set of the conduits with 5 relatively uniform wall thickness has a relatively small mass of material used in the walls of the conduits which can reduce the loss in effectiveness due to the sensible heat per unit volume of the conduit.
By alternating between high-pressure and low-pressure in the HTR, the temperature of HCM medium vapor will increase; whereby HCM medium vapor will condense onto the 10 HTR allowing its latent heat to transfer through the walls of the conduits into the HTR
medium and allow the latent heat to liquefy the HTR medium. As the pressure of HTR is increased, the melting point of the HTR medium will increase and the HTR
medium will transfer its latent heat at a higher temperature out of the HTR and back to the HCM
medium. The capacity of the heat elevation of the HTR depends on the speed of the HTR
1 S pressure alternation between high-pressure and low-pressure. The alternation between high-pressure and low-pressure of HTR is dependent on the rate of the heat of HCM
medium transferring into HTR medium or the rate of heat of HTR medium transferring back out to HCM medium.
The heat transfer resistance in condensing HCM-1 vapor is low and the heat transfer resistance through the conduit wall is low. The major heat transfer resistance is in the heat transfer through the HTR medium itself.
The condensing rate of HCM medium vapor is very fast, and the heat transfer rate through the wall of the conduits is very fast, but the heat transfer rate of the HTR medium inside the metallic tube is very slow. Therefore, the rate of the alternation of HTR between high-pressure and low-pressure depends on the heat transfer rate of the medium inside the HTR. Hence, in order to increase the rate of the heat transfer resistance of the HTR
medium in the conduits, it is necessary to install a set of fins inside the conduits of the HTR.
There are many types of fins such as longitudinal radial fins and longitudinal radial fins with holes on the fins. There are many methods and materials can be used to form these heat conductive fins. For example, a piece of thin metal may be folded in a zigzag shape and then formed into a circular shape as shown in figure 2B to become a longitudinal radial fin. One skilled in the art can readily select a fin design from many well-known designs.
SUBSTITUTE SHEET (RULE 26) The fins will greatly increase the heat transfer rate of the medium inside the HTR because the radial fms transfer heat in the radial direction of the tube. The installation of the fms will greatly reduced the heat transfer resistance of the HTR and allow increase in the speed of the pressure alternation of the HTR, and thereby increase the heat raising capacity of the HTR.
The Heat Temperature Raiser (HTR) is preferably a stationary device only acting as an elevator to elevate the temperature of the latent heat of the HTR medium.
It does not by itself have the ability to transfer heat from the low temperature heat source to the higher temperature heat sink. Therefore, one or two Heat Carrying Mediums (HCM
mediums) are needed to assist in transferring heat from low temperature heat source to a higher temperature heat sink. Any compound that has proper vapor pressure at the desired operating temperature can be used as the Heat Carrying Medium.
HCM-1 medium in the Zone with heat source either enters in direct contact or through a heat exchanger absorbs heat from the heat source and vaporizes itself to become HCM-1 vapor. The HCM-1 medium vapor flows to the Zone where HTR is located and condenses onto the surface of the HTR. As HCM-1 medium vapor condenses on the surface of the HTR, HTR medium solid melts and the heat absorbed by the HTR
medium is stored as the latent heat of the HTR medium. After the HTR medium is melted, a high pressure is applied onto the HTR medium to elevate the melting point of the HTR medium to a high temperature. At the same time, the applied high pressure will cause the latent heat of melting to be elevated to a higher temperature as well. Then, the HTR
medium releases heat to the HCM-2 medium and the HCM-2 medium vaporizes at a higher temperature.
The HCM-2 medium vapor enters into the higher temperature heat sink Zone where HCM-2 vapor releases heat to the higher temperature heat sink through direct or indirect heat exchange. The whole process of this invention comprises subjecting the HTR
medium inside of the HTR unit to batch processing of elevating the heat temperature;
and subjecting the HCM mediums to vaporization, condensation, absorbing, and releasing of the heat. The HCM mediums perform the functions of transferring heat from a low temperature heat source to a high temperature heat sink. Therefore, a Heat Temperature Raising System comprises a Heat Temperature Raiser, a Heat Temperature Raising Medium, and one or two Heat Carrying Mediums.
SUBSTITUTE SHEET (RULE 26) Since the process for elevating heat temperature by the HTR is a batch process, the amount of latent heat of HTR medium elevated from each batch is limited. Thus, when the amount of the latent heat produced by one process is not enough to cover the sensible heat loss of the outer walls of the conduits, multiple sets of HTR systems can be used to elevate the process stepwise to the desired temperature.
Under different types of heat source, there are different operation methods.
The methods are as follows:
When the heat source and the HCM medium cannot be allowed to make direct contact, a heat exchanger can be used for the heat transfer. For example, in an air conditioning operation, water is used as HCM-1 and room air serves as the heat source and an indirect heat exchange takes place.
When the heat source and the HCM medium may make direct contact, HCM
medium absorbs heat directly from the low temperature heat source and HCM-2 medium condenses and releases the heat to the high temperature heat sink. For example, one may 1 S use a water insoluble substance as HCM medium to remove heat from an aqueous solution.
The material processed may provide a HCM medium and also serves as the heat source. For example, in flash vaporizing an aqueous solution, a part of the water becomes HCM-1 and the remaining part serves as heat source.
Exotherrnal chemical reaction produces heat for vaporizing Heat Carrying Medium to produce HCM medium vapor.
A unit of HTR is shown in Figure 2, whereby the Heat Temperature Raising Unit has the multitude of heat conductive pressure sustaining conduit 2, and a heat temperature raising medium 3 filled inside of the conduit 2 and a header 4 and a pressurizing device 5.
In order to increase heat transfer rate one may install a longitudinal radial fin 6 inside of each of the heat conductive pressure sustain conduits 2 as shown in Figure 2A.
The system illustrated by Figures 3A, 4A, and SA illustrates the cross section taken at section AA of Figure 2 and Figures 3B, 4B, and SB illustrates the cross section taken at section AA of Figure 2A.
Figure 3A illustrates a cross section view of a multiple connected conduits containing HTR medium 7 and heat conductive conduit with pressure sustaining wall 8 and connecting walls between neighboring conduits 9. Figure 3B illustrates a cross section view of a multiple connected conduits containing HTR medium 7 and heat conductive SUBSTITUTE SHEET (RULE 26) conduit with pressure sustaining wall 8 and connecting walls between neighboring conduits 9 and a heat conductive fin 10 installed inside of the conduit. Figure 4A
illustrates a cross section view of a multiple tube assembly containing HTR medium 7 and heat conductive and pressure sustaining wall 8 enclosing each conduit. It shows that there are no connecting walls between two neighboring conduits. Figure 4B illustrates a cross section view of a multiple tube assembly containing HTR medium 7 and heat conductive and pressure sustaining wall 8 enclosing each tube and it shows there are no connecting wall between two neighboring tube and a heat conductive fin 10 installed inside of the tube. Figure SA
illustrates a cross section view of multivoid heat conductive block containing multitude of conduits 11 which containing HTR medium 12. Figure SB illustrates a cross section view of mufti void heat conductive block containing multitude of conduits 11 which containing HTR medium 12 and a heat conductive fin 13 installed inside of the conduit.
The system illustrated by Figures 6A and 6B is a vapor pressure raising system. It comprises a vapor pressure raising Zone Z-1 15, a low pressure first vapor generation Zone, 1 S Z-2 16, and high pressure vapor condensing Zone Z-3 17, and a valve 18 connecting from Zone Z-2 to Zone Z-1 and a valve 19 connecting from Zone Z-1 to Zone Z-3.
Figure 6A
illustrates that the first step of generating first vapor, HCM-1 vapor, in Zone 2. Adjusting the pressure of the HTR medium at the first pressure, where the melting temperature of the HTR medium is lower than the condensing temperature of the first vapor, HCM-1 vapor, thereby condensing the first vapor, HCM-1 vapor, and melting the HTR medium inside of the HTR conduits. Upon actuating a pressure variation device, one can control the transformation temperature such that the first vapor, HCM vapor, generating in Zone 2 enters through a self actuating valve (made of a grating and flaps made of thin films attached on to the grating) 18 transfers heat from the first vapor, HCM vapor, to HTR
medium thereby condenses the HCM-1 vapor into the solid or liquid form and melts the HTR medium.
Figure 6B illustrates that upon applying the pressure to the medium by actuating the HTR pressurizing device, and applying a HCM-2 liquid outside of the HTR
conduits, heat transfers from the HTR medium to the HCM-2 liquid thereby solidifies the HTR
medium and vaporizes the HCM-2 liquid thereby forming a high pressure vapor, HCM-2 vapor.
The HCM-2 vapor flows from Zone 1 to Zone 3 through another self actuating valve 19 to thereby condense inside of Zone 3.
SUBSTITUTE SHEET (RULE 26) The system illustrated by Figures 7A and 7B are similar of those of Figures 6A
and 6B with two added Zones; a low temperature heat source Zone and a high temperature heat sink Zone. Figure 7A and 7B illustrate a system for providing air conditioning or producing chill water. It comprises vapor pressure raising Zone Z-l and first vapor generating Zone Z-2A and second vapor condensing Zone Z-3A and low temperature heat source Zone Z-2B
containing low temperature heat exchanger coil 26 and high temperature heat sink Zone Z-3B containing high temperature heat exchanger coil 27. Air or water is introduced into Zone Z-2B to exchange heat with the process liquid HCM medium thereby forming a first HCM1 vapor. The first HCM1 vapor enters into Zone Z-1 heat exchange with HTR
medium condenses therein and melts the HTR medium. Referring to Figure 7B the pressure is adjusted to raise the solidification temperature of HTR medium and applying process liquid on the outside of the heat transfer conduits. Thereby, heat is transferred from the HTR medium to the process liquid and solidifying the HTR medium and generating a second HCM-2 vapor. Second HCM-2 vapor enters into Zone Z-3A and the air is circulated in Zone Z-3B. The second HCM-2 vapor is heat exchanged with air or water in Zone Z-3B to thereby condenses and heat is removed by the outside air or cool water.
The system illustrated by Figures 8A and 8B are similar to that of Figures 6A
and 6B. In this system, simultaneous vaporization and freezing operations take place to produce HCM-1 vapor and a mass of solid of the process substance. Figures 8A and 8B
illustrate a system for providing pure water. It comprises vapor pressure raising Zone Z-1 and first vapor generating Zone Z-2 and second vapor condensing Zone Z-3 and a crystal washing Zone Z-4. The process substance 32 is feed into the Zone Z-2 to generate first HCM1 vapor and solid simultaneously. The solid generated in Zone Z-2 along with mother liquid is sent to the Zone Z-4 for crystal washing. The first HCM 1 vapor generated in Zone Z-2 enters into Zone Z-1 heat exchange with HTR medium condensed therein and melts the HTR
medium. Figure 8B illustrates the pressure is adjusted to raise the solidification temperature of HTR medium and applying process liquid on the outside of the heat transfer conduits.
Thereby, heat is transferred from the HTR medium to the process liquid and solidifies the HTR medium, generating second HCM-2 vapor. The washed crystals 33 from Zone Z-4 are then sent to Zone Z-3 to allow the second HCM-2 vapor to condense and thereby melt and generate pure water 39.
SUBSTITUTE SHEET (RULE 26) The system illustrated in Figures 9A and 9B is similar to that of Figures 8A
and 8B
and operations conducted in this system are also similar. In this system the HCM-2 vapor is brought into an indirect contact heat exchange with the purified crystals in Zone 3.
The system illustrated by Figures 10A and lOB is useful in vacuum crystallization 5 of aqueous solution and non-aqueous mixtures. In this system the HCM-2 vapor formed is condensed by a cooling medium in Zone 3, and the crystal formed is not melted by the HCM-2 vapor. This system is particularly usefizl in making ice blocks whereby the small pieces of ice made in Zone 2 can be compressed to form an ice block. This system is also very useful in conducting the distillative freezing process invented by Chen-Yen Cheng and 10 Sing-Wang Cheng and described in U.S. Patent Nos.: 4218893, 4433558, 4451273 and 4578093.
Figures 11A and 11B illustrate a multi-effect evaporating system that comprises a first multiple effect evaporator, Z-lA, a second multiple effect evaporator, Z-1B, in the major processing Zone Z-1, a first HTR unit 61 in Z-2A and a second HTR unit 62 in Z-2B
15 at the first end of the system, a third HTR unit 63 in Z-3A and a fourth HTR unit 64 in Z-3B
at the second end of the system. The HTR units are operated cyclically and the mufti-effect evaporators are operated nearly continuously.
The first multiple effect evaporator Z-lA comprises, as an example, nine evaporators ZE-1 through ZE-9, 69 through 77 connected in series, with operating pressures 20 decreasing successively in the direction from the left end ZE-1 toward the right end ZE-9.
The second multiple effect evaporator Z-1B, comprises nine evaporators ZE'-1 through ZE'-9, 78 through 86 connected in series, with operating pressures decreasing successively in the direction from the right end ZE'-1 toward the left end ZE'-9.
Each of the four HTR units is operated cyclically and alternately serves as an evaporator and as a condenser. The four HTR units are operated in a coordinated manner.
While one of the two HTR units at each end serves as an evaporator, the other unit serves as a condenser. As illustrated in Figure 11A, the HTR units 61 in Z-2A and Z-3B
64 serves as two vapor generators and the HTR units in Z-2B 62 and Z-3A 63 serve as two condensers.
The vapor streams generated are used as steam supplies to the two ZE-1 Zones and ZE'-1 Zones and thereby initiates the multiple effect evaporator operations.
The vapors leaving the last effect ZE-9 and ZE'-9 are condensed in the two HTR-units serving as condensers. Figure 11B illustrates the same system in the other half of the cycle, in which SUBSTITUTE SHEET (RULE 26) the HTR units in Z-2B and Z-3A become the vapor generators and the HTR units in Z-2A
and Z-3B become the condensers.
Figures 12A and 12B illustrate a multiple effect evaporator system similar to those illustrated by Figures 11A and 11B. In this system, corrugated metal walls are used to form falling film evaporators. The operations of this system are similar to those described in connection with figures 11A and 11B.
Figure 13 illustrates a self actuating valuing system that provides vapor passages from one chamber to another without any mechanical device or any electrical switch. The valuing system is made of a mesh 105 for structural support as well as a divider for the two chambers with flaps 106 (made of thin film) attached onto the divider. These dividers with attached thin films 106 will be the dividers between two chambers. The thin film flaps 106 are pressure sensitive wherein when one chamber's pressure is higher than the other, the flap will automatically opens allowing the vapor to flow from the first chamber with higher pressure to the second chamber with low pressure. It automatically closes when the 1 S pressure of the second chamber becomes higher than the pressure in the first chamber.
Figure 13A illustrates a single vent made of thin film 106 attached onto a holder 107 on the top of the vent.
The concept of the present invention has a wide range of usage, such as air condition, water purification, distillative freezing, ice making, waste water treatment, desalinization, distillation operation under ambient temperature or high temperature, or organic chemical purification and separation, and other areas which may require the use of raising heat temperature from low temperature heat source to a high temperature heat sink.
SUBSTITUTE SHEET (RULE 26)

Claims (25)

1. ~A method for transferring heat from a heat source to a heat sink where the temperature of the heat sink is higher than the temperature of the heat source, comprising the steps of:
(a) formation of heat carrying medium vapor by direct or indirect contact method between the heat carrying medium and the heat source;
(b) transferring the heat from the heat carrying medium vapor to the heat temperature raising medium contained within the conduit; whereby the conduit is made from one of the following type of assembly: (1) a tube,(2) a multiple tube assembly, or (3) a multiple connected conduits; or conduits with heat conductive fins positioned within one of the following type of assembly: (1) a tube, (2) a multiple tube assembly, (3) a multiple connected conduits, or (4) a multi-void block;
(c) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;
(d) transferring heat via the latent heat of fusion from said heat temperature raising medium to the second heat carrying medium to form second heat carrying medium vapor; whereby the temperature of the second heat carrying medium is higher than the temperature of the first heat carrying medium;
(e) transferring the latent heat of the vapor of the second heat carrying medium to the a heat sink whereby the temperature of the heat sink is higher than temperature in said heat source.
2. ~A method for transferring heat from a heat source to a heat sink where the temperature of the heat sink is higher than the temperature of the heat source, comprising the steps of:

(a) formation of heat carrying medium vapor by direct or indirect contact method between the heat carrying medium and the heat source, whereby the temperature of the heat exchange is above the melting point of the material of heat source;
(b) transferring the heat from the heat carrying medium vapor to the heat temperature raising medium contained within conduit assembly, whereby the conduit is made from one of the following type of assembly: (1) a tube,(2) a multiple tube assembly, (3) a multiple connected conduits or (4) a multi-void block; or conduits with heat conductive fins positioned within one of the following type of assembly:
(1) a tube, (2) a multiple tube assembly, (3) a multiple connected conduits, or (4) a multi-void block;
(c) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;
(d) transferring heat via the latent heat of fusion from said heat temperature raising medium to the second heat carrying medium to form second heat carrying medium vapor; whereby the temperature of the second heat carrying medium is higher than the temperature of the first heat carrying medium;
(e) transferring the latent heat of the vapor of the second heat carrying medium to the a heat sink whereby the temperature of the heat sink is higher than temperature in said heat source.
3. A method for transferring heat from a heat source to a heat sink where the temperature of the heat sink is higher than the temperature of the heat source, comprising the steps of:

28~

(a) formation of heat carrying medium vapor by direct or indirect contact method between the heat carrying medium and the heat source;

(b) transferring the heat from the heat carrying medium vapor to the heat temperature raising medium contained within conduit assembly, whereby the conduit is made from one of the following type of assembly: (1) a tube,(2) a multiple tube assembly, (3) a multiple connected conduits or (4) a multi-void block; or conduits with heat conductive fins positioned within one of the following type of assembly:
(1) a tube, (2) a multiple tube assembly, (3) a multiple connected conduits, or (4) a multi-void block;

(c) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;

(d) transferring heat via the latent heat of fusion from said heat temperature raising medium to the second heat carrying medium to form second heat carrying medium vapor; whereby the temperature of the second heat carrying medium is higher than the temperature of the first heat carrying medium;

(e) transferring the latent heat of vapor of the second heat carrying medium to the a heat sink where the temperature of the heat sink is higher than temperature in said heat source; whereby the temperature of the heat sink is above the melting point of the material of the heat sink.
4. A process for purification of process substance, comprising the steps of:

(a) formation of heat carrying medium vapor and solid substance of the process feed by direct or indirect contact method between the heat carrying medium and the heat source;

(b) the partially solid process substance from the solidification of the water or the chemical feeds is sent to the washing or separation process for separating the mother liquid and the solid substance; whereby the said process is either by washing or draining method;
(c) transferring the heat from a heat source via a vapor of the first heat carrying medium passing through a valve mean to the conduit, whereby the conduit is one of the following type of assembly; (1) tube, (2) a multiple tube assembly, (3) multiple connected conduit assembly, or (4)multi-void block or conduits with heat conductive fins positioned within one of the following type of assembly: (1) tube, (2) a multiple tube assembly, (3) multiple connected conduit assembly, or (4)multi-void block;
(d) the heat is further transferred into the heat temperature raising medium inside of the conduit, whereby the heat temperature raising medium to undergoing a phase change from solid to liquid;
(e) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;
(f) transferring heat via a latent heat of fusion from said heat temperature raising medium out of the conduit to the second heat carrying medium whereby the second heat carrying medium will at least partially vaporize while the heat temperature raising medium will at least partial solidify;
(g) the second heat carrying medium vapor will pass through another valve mean to transfer the latent heat of the vapor of the second heat carrying medium to the heat sink whereby the temperature of the heat sink is higher than temperature in said heat source;

(h) the washed solid from the washing zone is brought into direct or indirect contact with the second heat carrying medium, thereby simultaneously condensing the second heat carrying medium and melting the solid process substance.
5. A method as claimed in Claim 1, 2, 3, or 4 wherein the step of transferring heat from a heat source via a first heat carrying medium to the heat temperature raising medium contained within an assembly, which comprises the first heat carrying medium to the heat temperature raising medium to undergoes a partial or complete phase change from vapor to liquid or solid, and said heat temperature raising medium undergoes a partial or complete phase change from solid to liquid; and wherein said step of transferring heat via a latent heat of fusion from said heat temperature raising medium to a heat sink comprises transferring sufficient heat from said heat temperature raising medium to said second heat carrying medium, such that said second heat carrying medium is at least partially vaporized and said heat temperature raising medium is at least partially solidified.
6. A method as claimed in Claim 5, wherein at least partially vaporizing the first heat carrying medium by one of the following method (a) an indirect contact heat exchange between the heat carrying medium and a heat source, (b) a flash vaporization of the heat carrying medium thereby producing a chilled liquid of the heat carrying medium, or (c) by using a vapor from a last effect of a multi-effect evaporator as the first heat carrying medium vapor.
7. A method as claimed in Claim 4, wherein at least partially vaporizing the first heat carrying medium by one of the following method (a) an indirect contact heat exchange between the heat carrying medium and a heat source, (b) a flash vaporization of the heat carrying medium thereby producing a chilled liquid of the heat carrying medium, (c) a simultaneous vaporization and freezing operation thereby producing a mass of solid process substance from the chemical feeds or (d) by using a vapor from a last effect of a multi-effect evaporator as the first heat carrying medium vapor.
8. A method as claimed in Claim 7, wherein a partially solid process substance from the solidification of the water or the chemical feeds is sent to wash and brought into a heat exchange relation with the second heat carrying medium, thereby simultaneously melting the solid process substance and condensing the second heat carrying medium.
9. A method as claimed in Claim 1, 2, 3, or 4 wherein the heat temperature raising medium is selected from the group consisting of an organic or inorganic chemical, and mixtures thereof, either in a pure form or in a compound with a melting point range between -30°C and 100°C, with the proviso that when the heat temperature raising medium is selected from a mixture of compounds, the mixture has a eutectic point range between -30°C and 100°C.
10. A method as claimed in Claim 1, 2, 3, or 4 wherein the step of transferring heat from a heat source via a first heat carrying medium to a heat sink comprises a multiple units of heat temperature raisers to elevate temperature of the heat carrying medium by multiple steps.
11. A method as claimed in Claim 1, 2, or 3, wherein said process is used in air-conditioning distillative freezing, ice making, cable water purification, waste water treatment, desalination, distillation operation under ambient temperature or high temperature, organic chemical purification and separation, or in any other process requiring the use of raising the temperature from a lower temperature heat source to a high temperature heat sink.
12. A method as claimed in Claim 2, wherein said process is used in air-conditioning, cable water purification, waste water treatment, desalination, distillation operation under ambient temperature or high temperature, organic chemical purification and separation, or in any other process requiring the use of raising the temperature from a lower temperature heat source to a high temperature heat sink where the temperature of the heat source is above the melting point of the material of the heat source.
13. A method as claimed in Claim 2, or 3, wherein for transferring heat from a heat source to a heat sink where the temperature of the heat sink is higher than the temperature of the heat source, comprising the steps of:
(a) formation of heat carrying medium vapor by direct or indirect contact method between the heat carrying medium and the heat source;
(b) transferring the heat from a heat source via a vapor of the first heat carrying medium passing through a valve mean to the conduit, whereby the conduit is one of the following type of assembly; (1) tube, (2) a multiple tube assembly, (3) multiple connected conduit assembly, or (4)multi-void block or conduits with heat conductive fins positioned within one of the following type of assembly: (1) tube, (2) a multiple tube assembly, (3) multiple connected conduit assembly, or (4) multi-void block;
(c) the heat is further transferred into the heat temperature raising medium inside of the conduit, whereby the heat temperature raising medium to undergoing a phase change from solid to liquid;

(e) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;

(f) transferring heat via a latent heat of fusion from said heat temperature raising medium out of the conduit to the second heat carrying medium whereby the second heat carrying medium will at least partially vaporize while the heat temperature raising medium will at least partial solidify;

(g) the second heat carrying medium vapor will pass through another valve mean to transfer the latent heat of the vapor of the second heat carrying medium to the heat sink where the temperature of the heat sink is higher than the temperature of the heat source.
14. A method as claimed in Claim 4 or 13, wherein the valve means is the gate made of screen or mesh for structure support and thin film flaps for one way vapor passages.
15. A method as claimed in Claim 3, wherein the heat of the second vapor is at least partially released to the heat sink, whereby the material of the heat sink is one of the following: (a) air, (b) cool water, (c) salt water, (d) water evaporation.
16. A method of Claim 5, wherein the first heat carrying medium is selected from water, organic chemicals, or inorganic chemicals.
17. An apparatus of heat temperature raiser consists the following:

(a) heat temperature raising medium is contained within the conduit; whereby the conduit is made from one of the following type of assembly: (1) a tube,(2) a multiple tube assembly, or (3) a multiple connected conduits; or conduits with heat conductive fins positioned within one of the following type of assembly: (1) a tube, (2) a multiple tube assembly, (3) a multiple connected conduits, or (4) a multi-void block;
(b) a pressurizing device is connected on to the conduit to form the heat temperature raiser;
(c) the pressure inside of the heat temperature raiser fluctuates between low pressure and high pressure; and (d) the heat temperature raising medium absorbs heat at low temperature and release heat at high temperature.
18. An apparatus for transferring heat from a heat source to a heat sink where the temperature of the heat sink is higher than the temperature of the heat source, comprising the steps of:
(a) formation of heat carrying medium vapor by direct or indirect contact method between the heat carrying medium and the heat source, whereby the temperature of the heat exchange is above the melting point of the material of heat source;
(b) transferring the heat from the heat carrying medium vapor to the heat temperature raising medium contained within conduit assembly, whereby the conduit is made from one of the following type of assembly: (1) a tube,(2) a multiple tube assembly, (3) a multiple connected conduits or (4) a multi-void block; or conduits with heat conductive fins positioned within one of the following type of assembly: (1) a tube, (2) a multiple tube assembly, (3) a multiple connected conduits, or (4) a multi-void block;
(c) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;

(d) transferring heat via the latent heat of fusion from said heat temperature raising medium to the second heat carrying medium to form second heat carrying medium vapor; whereby the temperature of the second heat carrying medium is higher than the temperature of the first heat carrying medium;
(e) transferring the latent heat of vapor of the second heat carrying medium to the a heat sink where the temperature of the heat sink is higher than the temperature of the heat source.
19. An apparatus for transferring heat from a heat source to a heat sink where the temperature of the heat sink is higher than the temperature of the heat source, comprising the steps of (a) formation of heat carrying medium vapor by direct or indirect contact method between the heat carrying medium and the heat source;
(b) transferring the heat from the heat carrying medium vapor to the heat temperature raising medium contained within conduit assembly, whereby the conduit is made from one of the following type of assembly: (1) a tube,(2) a multiple tube assembly, (3) a multiple connected conduits or (4) a multi-void block; or conduits with heat conductive fins positioned within one of the following type of assembly: (1) a tube, (2) a multiple tube assembly, (3) a multiple connected conduits, or (4) a multi-void block;
(c) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;
(d) transferring heat via the latent heat of fusion from said heat temperature raising medium to the second heat carrying medium to form second heat carrying medium vapor; whereby the temperature of the second heat carrying medium is higher than the temperature of the first heat carrying medium;

(e) transferring the latent heat of vapor of the second heat carrying medium to the a heat sink where the temperature of the heat sink is higher than the temperature of the heat source; whereby the temperature of the heat sink is above the melting point of the material of the heat sink.
20. An apparatus for purification of process substance, comprising the steps of:
(a) formation of heat carrying medium vapor and solid substance of the process feed by direct or indirect contact method between the heat carrying medium and the heat source;

(b) the partially solid process substance from the solidification of the water or the chemical feeds is sent to the washing or separation process for separating the mother liquid and the solid substance; whereby the said process is either by washing or draining method;

(c) transferring the heat from a heat source via a vapor of the first heat carrying medium passing through a valve mean to the conduit, whereby the conduit is one of the following type of assembly; (1) tube, (2) a multiple tube assembly, (3) multiple connected conduit assembly, or (4)multi-void block or conduits with heat conductive fins positioned within one of the following type of assembly: (1) tube, (2) a multiple tube assembly, (3) multiple connected conduit assembly, or (4)multi-void block;

(d) the heat is further transferred into the heat temperature raising medium inside of the conduit, whereby the heat temperature raising medium to undergoing a phase change from solid to liquid;

(e) changing the pressure applied to said heat temperature raising medium from said first pressure to a second pressure;
(f) transferring heat via a latent heat of fusion from said heat temperature raising medium out of the conduit to the second heat carrying medium whereby the second heat carrying medium will at least partially vaporize while the heat temperature raising medium will at least partial solidify;
(g) the second heat carrying medium vapor will pass through another valve mean to transfer the latent heat of the vapor of the second heat carrying medium to the heat sink where the temperature of the heat sink is higher than the temperature of the heat source;
(h) the washed solid from the washing zone is brought into a direct or indirect contact with the second heat carrying medium, thereby simultaneously condensing the second heat carrying medium and melting the solid process substance.
21. Valve apparatus for the passage of vapor comprising a plurality of gates for one way passage of vapor, wherein the said gates further comprise at least one divider made of screen or mesh for structural support and vapor passages with thin film flaps secured to said divider.
22. An apparatus as claimed in Claim 17, 18, 19, or 20, wherein said apparatus includes valves for providing passages of the first heat carrying medium between the said heat source and said heat temperature raiser and passages for the second heat carrying medium between said heat temperature raiser and the said heat sink.
23. An apparatus as claimed in Claim 21, wherein said valves consist of plurality of gates comprises at least one divider made of screen or mesh for structural support and vapor passages with thin film flaps secured to said divider.
24. An apparatus as claimed in Claim 22, wherein said valves consist of plurality of gates comprises at least one divider made of screen or mesh for structural support and vapor passages with thin film flaps secured to said divider.
25. An apparatus as claimed in Claim 17, 18, 19, or 20, wherein said conduits are in fluid communication with a movable piston or other pressurizing device for varying the hydrostatic pressure on said heat temperature raising medium.
CA002383489A 1999-08-13 1999-08-13 Heat temperature raising system Abandoned CA2383489A1 (en)

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CN110898663B (en) * 2019-11-28 2024-03-22 国家电投集团远达环保工程有限公司重庆科技分公司 Flue gas temperature homogenizing device and method
CN113623927B (en) * 2020-05-09 2022-08-30 合肥华凌股份有限公司 Refrigeration equipment and control method thereof, refrigeration system and readable storage medium
CN113701420B (en) * 2020-05-21 2022-08-30 合肥华凌股份有限公司 Refrigeration equipment, control method, control device and computer readable storage medium
CN113720074B (en) * 2020-05-21 2022-09-09 合肥美的电冰箱有限公司 Refrigeration equipment, control method, control device and computer readable storage medium
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AU5558299A (en) 2001-03-13
WO2001013050A1 (en) 2001-02-22
EP1210555A1 (en) 2002-06-05
CN1406330A (en) 2003-03-26

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