Abstract:
An improved continuous process and apparatus for treating an impure liquid to produce purified liquid, particularly, water, the process having an electrically activating a thermoelectric module to provide a first heated surface and a cooler surface; feeding the impure liquid to the first heated surface to produce vapour of the liquid; and transferring the vapour to the cooler surface to effect heat transfer to the cooler surface, the improvement being directing a minor portion of the vapour to the cooler surface to maintain the cooler surface at a temperature at or near the boiling point of the liquid; and transferring a major portion of the vapour to a condenser remote from the module to effect heat transfer and condensation of the vapour to produce the purified liquid and collecting the purified liquid from the condenser. The process is continuous in that it does not need to be intermittently stopped, or require auxiliary cooling of the module. Preferably, the heat from the condenser is transferred to pre-heat the impure liquid feed.

Description:
FIELD OF THE INVENTION 
     This invention relates to a process of purifying a liquid, particularly water, using a thermoelectric module; and apparatus of use in said process. 
     BACKGROUND TO THE INVENTION 
     Thermoelectric modules are small, solid state, heat pumps that cool, heat and generate power. In function, they are similar to conventional refrigerators in that they move heat from one area to another and, thus, create a temperature differential. 
     A thermoelectric module is comprised of an array of semiconductor couples (P and N pellets) connected electrically in series and thermally in parallel, sandwiched between metallized ceramic substrates. In essence, if a thermoelectric module is connected to a DC power source, heat is absorbed at one end of the device to cool that end, while heat is rejected at the other end, where the temperature rises. This is known as the Peltier Effect. By reversing the current flow, the direction of the heat flow is reversed. 
     It is known that a thermoelectric element (TEE) or module may function as a heat pump that performs the same cooling function as Freon-based vapor compression or absorption refrigerators. The main difference between a TEE device and the conventional vapor-cycle device is that thermoelectric elements are totally solid state, while vapor-cycle devices include moving mechanical parts and require a working fluid. Also, unlike conventional vapor compressor systems, thermoelectric modules are, most generally, miniature devices. A module typical measures 2.5 cm×2.5 cm×4 mm, while the smallest sub-miniature modules may measure 3 mm×3 mm×2 mm. These small units are capable of reducing the temperature to well-below water-freezing temperatures. 
     Thermoelectric devices are very effective when system design criteria requires specific factors, such as high reliability, small size or capacity, low cost, low weight, intrinsic safety for hazardous electrical environments, and precise temperature control. Further, these devices are capable of refrigerating a solid or fluid object. 
     A bismuth telluride thermoelectric element consists of a quaternary alloy of bismuth, tellurium, selenium and antimony—doped and processed to yield oriented polycrystalline semiconductors with anisotropic thermoelectric properties. The bismuth telluride is primarily used as a semiconductor material, heavily doped to create either an excess (n-type) or a deficiency (p-type) of electrons. A plurality of these couples are connected in series electrically and in parallel thermally, and integrated into modules. The modules are packaged between metallized ceramic plates to afford optimum electrical insulation and thermal conduction with high mechanical compression strength. Typical modules contain from 3 to 127 thermocouples. Modules can also be mounted in parallel to increase the heat transfer effect or stacked in multistage cascades to achieve high differential temperatures. 
     These TEE devices became of practical importance only recently with the new developments of semiconductor thermocouple materials. The practical application of such modules required the development of semiconductors that are good conductors of electricity, but poor conductors of heat to provide the perfect balance for TEE performance. During operation, when an applied DC current flows through the couple, this causes heat to be transferred from one side of the TEE to the other; and, thus, creating a cold heat sink side and hot heat source side. If the current is reversed, the heat is moved in the opposite direction. A single-stage TEE can achieve temperature differences of up to 70° C., or can transfer heat at a rate of 125 W. To achieve greater temperature differences, i.e up to 131° C., a multistage, cascaded TEE may be utilized. 
     A typical application exposes the cold side of the TEE to the object or substance to be cooled and the hot side to a heat sink, which dissipates the heat to the environment. A heat exchanger with forced air or liquid may be required. 
     Water in bulk may be purified by a number of commercial methods, for example by reverse osmosis and by distillation processes. 
     Reverse osmosis (R.O.) technology relies on a membrane filtration system that is operated under high pressure. While this technology is one of the two leading technologies of water purification, it suffers from the following main disadvantages: 
     (a) the infrastructure of the system is complex because of the operating pressure, typically 8 atmospheres, required to cause the reverse osmosis process in the membrane; 
     (b) the membrane is an expensive component that needs to be replaced, frequently, depending on the salinity and the purity of the source water, generally, every 4 to 6 months. Also, there is a problem of membrane fouling, if the quality of the source water is not within certain bounds. The restriction on the water quality that is inputted into the system precludes many sources of water or would necessitate the utilization of pretreatment systems; 
     (c) the amount of purified water is very low when compared to the amount of water that has to be pumped into the system. Therefore, the cost of pumping and discharging the rejected water (capital cost to install the required facility and the energy cost to operate and maintain it) makes this system very costly; 
     (d) the quality of purified water obtained by the reverse osmosis process is inferior to that of distilled water, in the sense that it leaves small microorganisms and any impurities that are small enough to go through the membrane. Also, as the membrane ages, the water quality does not remain consistent; 
     (e) the system is feasible from a physical and economical point of view, for only large commercial installations. The system is not amenable for use in household units or even in small commercial units; and 
     (f) energy, operating and maintenance costs are high for the R.O. system. 
     The main disadvantages of distillation technologies, such as the multistage flashback evaporation systems, are: 
     (i) relatively large capital cost needed to assemble and install the system; 
     (ii) high energy costs to perform the evaporation, provide energy and equipment for the vacuum system and the condensation in, literally, three independent subsystems; 
     (iii) significant corrosion problems that necessitate significant pretreatment of input water and complete replacement of plant equipment as frequently as every three to four years; 
     (iv) the system, generally, needs to be installed only near large power plants and large bodies of water; and 
     (v) the disadvantages listed in item (e) and (f) hereinabove. 
     There is, therefore, a need to provide a means for producing a purified liquid, particularly water, in a safe, reliable, convenient, relatively cheap manner, having low energy requirements, and which either eliminates or reduces the aforesaid disadvantages. 
     Offenlegungsschrift DE 35 39 08 6A (Wagner Finish Tech Center GmbH) published May 7, 1987, describes apparatus for the purification of organic solvents containing paint or varnish by evaporation and condensation by use of a Peltier element which functions as both a heating and cooling element during the evaporation and condensation stages. An essential feature is the condensation of the solvent vapor solely on the cooling element. 
     It is known that in addition to the production of a temperature differential across the module between the ‘hot’ and ‘cold’ surfaces that heat may be beneficially “pumped” from the cold surface to the hot surface through the module. For example, latent heat of condensation of a vapor on the cold surface may be captured by the cooler element and pumped to the hot side. It is also known that the heat pumped by the cold side varies linearly with the cold side temperature. 
     However, in the apparatus and process described in OLS DE3539086A a balanced continuous evaporation and condensation equilibrium cannot be established by reason that the cold side of the module absorbs the latent heat which is then pumped to the hot element and, thus, very significant amounts of latent heat of the steam generated upon condensation must be removed from the vessel or the process ‘shut down’, intermittently, for periods of time to prevent the hot element overheating. This is an unsatisfactory situation when continuous process conditions are desired. 
     Japanese Kokai JP 07 209841, published Aug. 11, 1995 to Koicki Hayashi describes a small, low-cost and high-efficiency developer waste solution concentrator for use in small-scale retail stores. The concentrator is provided with a concentrating tank divided into an evaporation tank and a condensation tank, the upper parts of these tanks being in communication with-each other; a heat-generating/heat-absorbing section which is made up of Peltier element parts wherein a heat-generating side is in contact with the evaporation tank and a heat-absorbing side with the condensation tank; a replenishing pump to control the volume of waste solution in the evaporation tank to a liquid volume within the certain constant range; and a cooling section to control the temperature of the heat-generating element side to a value within a certain constant range. The embodiments described therein effect condensation on the cooler element side of the module surface to provide purified liquid. To maintain the hot surface of the element at the desired temperature, a cooling fan means in conjunction with heat release fins are provided. However, such heat control means results in the need for additional physical items and reduced electrical and thermal energy efficiency. 
     There is, therefore, a need for a simple, safe, convenient and reliable process operable under continuous conditions of purifying a liquid, particularly water. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to provide a method and apparatus for producing a purified liquid, particularly water under continuous conditions in a safe, convenient, reliable and relatively cheap manner by means of thermoelectric modules to generate hot and cold elements. 
     Accordingly, in one aspect the invention provides an improved, continuous process for treating an impure liquid to produce purified liquid, said process comprising electrically activating a thermoelectric module to provide a first heated surface and a cooler surface; feeding said impure liquid to said first heated surface to produce vapor of said liquid; and transferring said vapor to said cooler surface to effect heat transfer to said cooler surface, the improvement comprising (a) directing a minor portion of said vapor adjacent to or onto said cooler surface to maintain said cooler surface at a temperature at or near to the boiling point of said liquid; (b) directing a major portion of said vapor to condensation means comprising a second cooler surface to effect heat transfer to said second cooler surface and condensation of said vapor to produce said purified liquid and collecting said purified liquid. 
     In this specification and claims the term “heatable or heated surface” means a surface of said thermoelectric module which is heated when said module receives an electric current or a surface in thermal communication with said module as to be heated thereby. The term “coolable or cooled surface” means a surface of said module which is cooled when said module receives an electric current or a surface in thermal communication with said module as to be cooled thereby. 
     By the term “continuous process” in this specification is meant a process as defined that does not need, of necessity, to be intermittently stopped or slowed, or requiring auxiliary cooling of the thermoelectric module in order to prevent overheating of the module. 
     The term “minor portion” means less than half of the vapour or steam generated by the hot element of the module, and which is a function of the design of the apparatus and operating conditions as to prevent overheating of the module by excessive heat transfer to the cooler element. 
     Generally less than about 40% of the steam is directed to the cooler element. 
     In a particularly valuable aspect, the liquid is water, and by the term “impure water” is herein meant water containing impurities such as, for example, dissolved salts and other matter, and/or suspended particulate matter which impure water may be evaporated and concentrated without unwanted carry-over of such impurities. 
     The term “vapor” includes “steam”. 
     Preferably, the invention provides process for treating an impure liquid to produce purified liquid, said process comprising 
     (i) electrically activating a thermoelectric module to provide a heated surface in a first chamber and a cooler surface in a second chamber; 
     (ii) feeding said impure liquid to said heated surface to produce liquid vapour; 
     (iii) directing said liquid vapor from said first chamber to said second chamber; 
     (iv) contacting a minor portion of said liquid vapor with said cooler surface to effect heat transfer to said cooler surface; 
     (v) cooling a major portion of said vapor in said second chamber with condensation means comprising a second cooler surface to effect heat transfer from said vapor to said second cooler surface and condensation of said vapor to provide said purified liquid; and 
     (vi) collecting said purified liquid. 
     In a further aspect, the invention provides an improved liquid purifier for purifying a liquid under continuous operating conditions comprising thermoelectric module means having a first heatable surface and a coolable surface; means for contacting said impure liquid with said heatable surface to produce vapor of said liquid; means for transferring said vapor to effect heat transfer to said coolable surface; means for condensing said vapor to said purified liquid; and means for collecting said purified liquid; the improvement comprising (a) means for directing a minor portion of said vapor to said coolable surface to maintain said cooler surface at a temperature near or at the boiling point of said liquid; (b) condenser means comprising a second coolable surface means to effect heat transfer to said second coolable surface and, consequently, condensation of a major portion of said vapor to produce said purified liquid; (c) means for directing said major portion of said vapor to said condenser means; and (d) means for collecting said purified liquid from said condenser means, wherein said thermoelectric module is adapted to receive an electric current to activate said module to heat said heatable surface and cool said coolable surface. 
     In prior art apparatus, the coolable surface constitutes the means for condensing the vapor to purified liquid. 
     The means for directing vapor to the coolable surface may, include, for example, merely, conduit, passage, guide or the like which allows a portion minor of the vapor to pass to the cold sink. 
     In one embodiment, the invention provides a liquid purifier comprising a housing having a first chamber and a second chamber; divider means separating said first and second chamber one from the other; said divider means comprising a thermoelectric module having a heatable surface received within the first chamber and a coolable surface within the second chamber; means for contacting impure liquid with said heatable surface within said first chamber to produce vapor; first transfer means for directing a minor said portion of vapor to said coolable surface to effect heat transfer to said coolable surface to maintain the temperature of said coolable surface at or near the boiling point of said liquid; condenser means having a second coolable surface for condensing a major portion of said vapor within said second chamber by heat transfer to produce said purifier liquid; second transfer means for directing said major portion of said vapor by means to said condenser means; and means for pre-heating said impure liquid feed by said heat transfer with said condenser means; and wherein said thermoelectric module is adapted to receive an electric current to activate said module to heat said heatable surface and cool said coolable surface. 
     Most preferably, the apparatus has a plurality of the thermoelectric modules aligned coplanar within a divider between the chambers and/or within one or more walls of the chamber. 
     Thus, preferably, a plurality of modules are arrayed in coplanar fashion in a planar member to provide, for example, a plurality of heatable surfaces at one, i.e. top face of the module and a plurality of coolable surfaces on its bottom face. The aforesaid top face may constitute an inner face of an evaporation chamber and the aforesaid bottom face constitute the corresponding outer face of the evaporation chamber. 
     Thus, the essence of the present invention is to achieve a continuous evaporation and condensation equilibrium within the apparatus by removing the majority of the thermal (latent) energy of the vapor remote from the coolable surface of the module. The presence of this remote secondary condenser surface which, preferably, effects heat transfer of at least about 60% from the steam enables satisfactory continuous removal of excess heating power from the module. In one embodiment, a 100% conversion from vapor to liquid within the same chamber containing the module cold side can be achieved. 
     Maximum efficiency of the heat pump can be achieved by maintaining the temperature of the module coolable surface essentially at the boiling point of the liquid, i.e. 97°-100° C. for water by means of a suitable minor portion acting on the coolable surface to effect suitable, but not excessive heat transfer. 
     In a most preferred aspect, the heat transferred from the major portion of condensed vapor with the condenser is used to pre-heat the impure liquid feed, preferably from ambient temperature to a temperature of at least 90° C. in the case of water. This preheating of the feed water increases the electrical utilization efficiency to over 167% and provide significant power savings when compared to, say, 95% power utilization efficiencies achieved with prior art conventional water purifiers, hereinbefore described. 
     Thus, the present invention provides in one aspect a water purification system which provides the advantages of: 
     (a) providing both water evaporation and cooling within the same unit; 
     (b) being significantly energy efficient by the use amount of electrical energy and heat transfer to perform evaporation and condensation; which energy utilization does not exist in any of the water purification technologies known at this time; 
     (c) recovering all of the water inputted into the system as pure water, without having to discharge water with high concentrations of impurities and salt as is the case in reverse osmosis technology; 
     (d) portability of the system and its ability to be scaled up over a very wide range of dimensions and capacities; and wherein the capacity of the system can be increased in a modular fashion; 
     (e) having the ability to energize the system from a very wide variety of power sources, such as, for example, operable throughout in the world, including remote areas that are not even connected to an energy generation grid; and 
     (f) having the ability of the system to handle any type of water regardless of its salinity and impurities, while still producing pure water that has the same quality as distilled water, which is free from all organic, non-organic and microbial elements. 
     I have found that non-insulated surfaces of vapor-receiving chambers, conduits and the like enhance condensation of the vapor to reduce the load on the module colder surface. This advantageous arrangement can be enhanced by passing the feed liquid through or around the “cold” chamber to enhance condensation external of the module cooler surface and also pre-heat the feed water. 
     It is a further aspect of the present invention to provide a plurality of multimodule units in the form of an assembly, which may be so designed to be of modular construction as to be built-up to any desired operating size. 
     The apparatus according to the invention may be operated over significant periods of time although there may be a build-up of impurities in the evaporation tray of the hot side surface of the module which may require down-time cleaning. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     In order that the invention may be better understood, preferred embodiments will now be described by way of example only, with reference to the accompanying drawings wherein 
     FIG. 1 is a diagrammatic vertical sectional view of a water purifier according to the invention having evaporation and condensing chambers with natural convection water pre-heating, and showing, in part, an enlarged thermoelectric module as an insert; 
     FIG. 2 is a diagrammatic vertical sectional view of a water purifier according to the invention having evaporation and condensing chambers with natural and forced air convection water pre-heating; 
     FIG. 3 is a diagrammatic vertical sectional view of a water purifier according to the invention having evaporation and condensing chambers with natural convection water pre-heating and condensing surface heat transfer boost via thermoelectric elements; 
     FIG. 4 is a diagrammatic vertical sectional view of a water purifier according to the invention having evaporation and condensing chambers with convention and forced air convection water pre-heating and condensing surface heat transfer boost via thermoelectric elements; 
     FIG. 5 is a diagrammatic vertical sectional view of a water purifier according to the invention having evaporation and condensing chambers with heat exchanger coil water pre-heating; wherein the arrows indicate steam current flows or where indicated air flows; and the same numerals denote like parts. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Generally, a water holding compartment is used to hold water to be purified and located on top of the heat extraction chamber so that some of an heat extracted from the condensing process is used to pre-heat the water to be purified. This may also release some of the volatile organic compounds present in the water. The pre-heating process reduces the amount of additional heat energy required to make the water boil in the evaporation tray. 
     In preferred embodiments, heat exchanger means is used to cool the top of a condensing chamber, whereby the rate of heat extraction from the top of the condensing chamber determines the rate of condensing of the steam produced inside the condensing chamber. Cooling is performed, for example, by using natural convection, forced air convection with fans blowing ambient temperature air through the fins, or liquid cooling by feeding impure feed fluid circulated through a remote secondary heat exchanger. 
     With reference to FIG. 1, this shows generally as  10 , a closed cylindrical tank  12 , formed of a plastics material and having a purified water outlet  14  at tank bottom  16  and a thin thermally conductive stainless top  18 . Centrally suspended by means not shown within tank  12  is a cylindrical open-topped metal tank  20 . The base  22  of tank  20  is constituted by a plurality of thermoelectric modules  24  (Polar TEC™ model HT4-12-30-Melcor Corporation, Trenton, N.J., U.S.A.) in coplanar array one adjacent another (twelve modules in the embodiment shown) having ceramic upper and lower surfaces  26  and  28 , respectively. Upper surface  26  constitutes the hot or heatable surface, while the lower surface  28  constitutes, the cooler or coolable surface. The lower wall portion  30  of a hood  31  and upper surface  26  form a water evaporation tray  32 . Hood  31  is suspended by attachment to an impure feed water pipe  34  which passes through tank top  18  into a feed water holding tank  36 , which holds water to a level  38  to the top of pipe  34 . Water is fed to tank  36  on demand from conduit  40  to preheat the impure liquid feed, preferably from ambient temperature to a temperature of at least 90° C. in the case of water. 
     Hood  31  surrounds tank  20  at a distance to define a cylindrical cavity or steam guide  42  and terminates at its lower end as an inwardly directed lip  44  or cusp adjacent base  14 . Lip  44  is so shaped as to direct a minor portion of generated steam out of guide  42  adjacent or onto module coolable surface  28 . 
     In operation, feed water from tank  36  drops down pipe  34  in controllable fashion into tray  32  onto surface  26  whereby it is converted into steam, which rises and passes through guide  42 . A portion of the steam is directed onto surface  28  to effect heat transfer and provide the additional heat to be pumped to hot surface  26 , at a rate to maintain the cooler surface between 97° and 100° C. The remaining major portion of the steam rises to condense on the inner surface  46  of top  18  whereby the latent heat of condensation is transferred through top  18  to pre-heat the water in tank  36 , to, preferably, a temperature of at least 90° C. Water produced at surface  46  runs down the side of tank  12  and is drawn out of pipe  14 . 
     This preheating of the feed water can increase the electrical utilization efficiency to over 167% to provide significant power savings when compared to, say, 95% power utilization efficiencies achieved with prior art conventional water purifiers hereinbefore described. 
     The power supply (not shown) consists of a high voltage and a low voltage section. Input power is normally derived from a 120/230VAC input line. Alternative embodiments may use power supplied from natural energy sources, such as solar or wind power. The input power is converted by the power supply into a source of direct current at a high voltage average level of approximately 160V. This direct current is applied to the thermoelectric heat pumps in the evaporation tray, as well as any thermoelectric heat pumps, associated with the impure water feed as pre-heaters, heaters or chillers in the purified water storage compartment. 
     Input power is also converted by the power supply into a source of direct current as low voltage levels of approximately 12 and 5 volts. This low voltage power source may be used by any process supervisor unit, electronic flow control valves, feedback sensors for temperature, water level, and pressure, and by any user interface. 
     With reference to FIG. 2, this shows a modified version of the apparatus shown in FIG. 1 wherein top  18  is cooled by and, thus, preheats an air flow pulled into an air chamber  50  of an upper cylindrical tank  52  having lower intake and upper exhaust apertures  54 ,  56 , respectively. 
     Downpipe  34  communicates with water holding tank  36  and, within chamber  50 , a water pre-fill tray  58  via a three way valve  60 . Tray  58  has upper and lower water level detectors  62  and  64 , respectively, and is intermittently replenished from tank  36 . An air circulation fan  66  provides intake and exhaust air flow directions. Hot air generated by heat exchange surface  46  at top  18  pre-heats the water held in both tanks  58  and  36 . The remaining construction and process operation is as described for the apparatus of FIG.  1 . 
     FIG. 3 shows a modified version of FIG. 1, wherein top  18  has a plurality of thermoelectric modules  68  embedded therein or, optionally, adjacent thereto, with the coolable element  70  receiving the latent heat of condensation which is pumped to hot side  72  of modules  68 . Thus, this heat exchanger means provides pre-heating of feed impure water prior to transfer to tray  32  down pipe  34 . Electrical power supply leads to modules  68  are omitted for clarity. 
     FIG. 4 shows a modified version of the combined apparatus of FIGS. 2 and 3, wherein forced air is pre-heated by the hot sides  72  of modules  68 . 
     FIG. 5 shows a modified version of FIG. 1, wherein pipe  34  comprises a glass or steel heat exchanger coil  74  deposed within tank  12 , whereby impure water feed is pre-heated. 
     DC power is supplied to the thermoelectric module array in bottom  24  from, optionally, a solar panel  80  and/or 12 volt DC power supply  82  through microprocessor control module  84 . 
     COMPARATIVE TESTS 
     A high temperature, high throughput thermoelectric module (Part # HT4012-39) is commercially available from MELCOR THERMOELECTRICS. Operation of this particular module at 3.5 amperes and 15.71 volts, provides a hot side temperature of 103° C. The hot side temperature was chosen to be 103° C. in order to show the typical performance of this module when used to evaporate, at one atmosphere, a layer of water that is in contact with the hot side of the module. 
     It is known that the heat pumped by the module cold side varies linearly with the cold side temperature. For an electrical input of 55 W (15.71V, 3.5A), the module pumps 37 Watts at a “cold” plate temperature of 97° C., 29 Watts at a cold plate temperature of 80° C., and 10 Watts at a cold plate temperature of 34° C. Hence, for the same electrical input power, the heat pumping efficiency is 67% (37/55), 53%, and 18% when the cold side temperature is 97°, 80° and 34° C., respectively. This shows that to utilize the maximum heat pumping capability of such a module, the cold plate temperature must be elevated to be close to that of the hot plate temperature. For example, if a layer of water is in contact with the hot side of the module, and the cold side of the module is maintained at a temperature of 97° C., then a total heating power of 55 W electrical input plus 37 Watts of pumping equals 92 Watts is applied through the hot side of the module to the water. As the water boils, an equilibrium is established where the latent heat in the steam rising from the surface of the water equals the heat energy being applied through the hot side of the module to the water. The surface temperature of the water equals the temperature of the steam produced, which equals 100° C. for operation at a pressure of one atmosphere. Hence, 92 Watts applied to the water through the hot side of the module produces steam at 100° C. that has 92 Watts of latent heat. The surface temperature of the hot side of the module rises to higher than 100° C. since additional heat is required to overcome the pressure produced by the weight of the layer of water on the hot side of the module. Experiments conducted with these modules show that in practice, the hot side temperature rises 3° C. for every 1 cm of water thickness on the module hot side tray. 
     In conclusion, the net effect of the module, when used to heat water, is to produce an added heating power. Hence, for an electrical input of 55 Watts, a heating power of 92 Watts is produced if the cold side is at 97° C., 84 Watts if the cold side is at 80° C., and 65 Watts if the cold side is at 34° C. In this embodiment, the best utilization of the modules is when the cold side temperature is at 97° C. to effectively produce 1.67 Watts of water heating power for every 1 Watt of electrical input power applied. 
     Prior Art OLS DE3539086A1 uses the cold side of the modules to condense the evaporated steam that is produced by the heat transferred from the hot side of the modules into the liquid that is evaporated. If the aforesaid thermoelectric module (Part # HT4-12-30) is used in the apparatus and process described and illustrated in FIGS. 1,  2  and  3  of DE3539086A1, then it can be reasonably assumed for comparison purposes that the hot side temperature of the module will eventually reach 103° C., if (a) the solvent solution to be purified is water, (b) the pressure is one atmosphere, (c) the voltage applied to the module is 15.71V, (d) the current consumed by the module is 3.5 A, (e) the hot side of the module is in direct contact with the solution to be purified, and (f) the solution to be purified forms a 1 cm thick layer over the tope of the hot side of the module. As electricity is first applied to the module used in this embodiment, the temperatures of the hot side and cold side of the module are equal and assumed to be at ambient air temperature. The hot side receives 55 Watts of heating power, plus whatever heating power is pumped by the cold side to the hot side of the module. As there is no temperature difference between the hot and cold sides of the module during startup, the heating power pumped from the cold side to the hot side is at least 37 Watts. Hence, at least 92 Watts of heating power are initially applied by the hot side of the module to the water to be purified. The water temperature increases to 100° C. as the heating power transferred to the water from the hot side of the module increases the heat energy of the water. As the temperature of the water increases to 100° C., so does the temperature of the hot side of the module which is in direct thermal contact with the water. In order to maintain the maximum level of heat pumping at a zero temperature differential between the hot and cold sides of the module, the rise in the cold side temperature must directly match the rise in the hot side temperature of the module. As soon as the cold side temperature rises above ambient temperature, no heat pumping occurs as heat can not transfer naturally from the colder ambient air to the ‘cold’ plate. Instead, the cold side temperature will decrease below the ambient air temperature in order to maintain the Peltier heat pumping effect. Hence, the temperature differential between the hot and cold sides begins to increase, and at the same time the amount of heat pumping begins to decrease. This process continues until a large enough temperature differential between the hot and cold sides is produced so that the natural transfer of heat between the air at ambient temperature and the colder temperature colder side equals that rate of heat pumping from the cold side to the hot side of the module. 
     The temperature of the water to be purified and the hot side of the module will eventually reach 100° C. In fact, the hot side temperature will reach 103° C. The heating power applied by the hot side can no longer be absorbed by the water as liquid heat energy. The water begins to convert into steam at an equilibrium rate so that the latent heat in the steam rising from the surface of the water equals the heat energy being applied through the hot side of the module to the water. Thus, the latent heating power stored in the steam rising from the surface of the water is equal to 55 Watts, plus whatever heating power is being pumped by the Peltier effect from the cold side to the hot side of the module. This pumped heating power, as previously stated can vary from 10 Watts if the cold side temperature is at 34° C., to 37 Watts if the cold side temperature is at 97° C. At startup, the ambient air temperature inside the apparatus described in DE3539086A1 could reasonably be assumed to be 23° C. Hence, minimal added heat pumping occurs during the start of the evaporation of the water to be purified. As more steam is generated, the ambient air temperature increases, and the natural rate of heat transfer from the ambient air to the cold side of the module increases. The cold side warms up until the increased heat pumping produced by the decreased temperature differential between the hot and cold sides again matches the natural rate of heat transfer from the ambient air to the cold side. Hence, a higher heat rate and heat pumping efficiency is produced. Eventually, the temperature inside the vessel described in DE3539086A1 will rise towards the 100° C. temperature of the steam being produced. Steam coming in contact with the cold side releases its latent heat and condenses on the surface of the cold side. Equilibrium can only be established if the rate of condensation of the steam is equal to the rate of production of the steam. In order for all of the steam that is produced by the heating power transferred from the hot side to condense on the cold side, the cold side must absorb 55 W, plus whatever heat pumping occurs at the cold side. Since the cold side of the module can only absorb the heat that is pumped, 55 W of power that is stored in the latent heat of the steam must be removed from the vessel. Accordingly, a continuous evaporation and condensing equilibrium cannot be established with the apparatus and process described in DE3539086A1. 
     The only way to practically implement the process described in DE3539086A1 is to follow the teaching of the present invention and to add an external heat exchanger means to remove the excess 55 W of heating power stored as latent heat from the steam produced from the water to be purified. At a near optimal module cold side operating temperature of 97° C. and an ambient temperature of 23° C., the process described in DE3539086A1 could only condense 40% {37/(55+37)} of the steam it produces. As excess steam is produced, the pressure inside the vessel will increase until a pressure relief valve, if present, is activated. Excess steam will then be released into the environment at a rate that equals 1.5 times the rate that steam is being condensed. Hence, 60% of the purified water is lost to the environment as steam, which translates into 60% of the heating energy applied through the hot side of the module. Evaporation occurs readily as the water to be purified is quickly converted into steam. However, the low rate of condensing causes a rapid pressure buildup inside the evaporation chamber, which results in both excess pressure and steam release into the environment. Cascading of modules to increase the temperature differential between the hot and cold sides only decreases the heat pumping capability of the modules, and further reduce the condensing rate of the steam. 
     If the goal is to purify water using the embodiment described in DE3539086A1, then 55 W of applied electrical power yields only 37 W of energy transfer, for an electrical power utilization efficiency rate of 67%. The conventional purification of water using a heating element, such as that in a kettle, and a cooled condensing coil provides an electrical power utilization efficiency of over 95%. In fact, a similar analysis can be conducted to indicate that the embodiment described in DE3539086A1 is impractical for continuous use due to its inefficiency in any process that attempts to recover a liquid from a solvent solution by first evaporating the liquid and then condensing its vapour. If the goal is, however, to recover a higher boiling point liquid from a solvent solution by first evaporating all of the lower boiling point impurities, then the embodiment described in DE3539086A1 is practical, as it provides, at near optimal operation, a heating power capability of 92 W for an electrical input power of 55 W. Hence, an electrical power utilization efficiency of over 167% can be achieved. 
     In sharp contrast, the apparatus and process according to the present invention achieves a continuous evaporation and condensing equilibrium inside the vessel by removing the excess latent heat from the steam via “external” heat exchanger means remote from the module cooler surface. For the identical module described hereinbefore, and implemented with all of the previously made assumptions, an excess heating power of 55 W is removed from the vessel without the actual removal of steam. A secondary condensing surface remote from the module is utilized on which the remaining approximately at least 60% of the steam condenses and be collected with the no more than 40% of steam that condenses on the cold side of the module. A 100% conversion of steam to condensate can occur inside the vessel. An electrical power utilization efficiency of over 167% can be achieved as 55 W of electrical input power produces the heating effect of 92 W (55 W+37 W). The 55 W of heat removed from the secondary condensing surface is most preferably reapplied to the feed water entering the vessel. The practical utility of the present invention is that it can achieve full evaporation and condensation equilibrium in the vessel, and thereby increase the throughput of the embodiment described in DE3539086A1 by, say, 250%, (i.e. 100% condensate recovery vs. 40% condensate recovery). Pre-heating of the incoming water to be purified also increases electrical utilization efficiency to over 167% to provide significant power savings when compared with the 95% power utilization efficiency achieved with conventional water purifiers. 
     Although this disclosure has described and illustrated certain preferred embodiments of the invention, it is to be understood that the invention is not restricted to those particular embodiments. Rather, the invention includes all embodiments which are functional or mechanical equivalence of the specific embodiments and features that have been described and illustrated.