UA103904U - Thermoelectric freshwater maker based on solar lake - Google Patents

Abstract

Thermoelectrical testing of salt water to clean the piping system, loading and cooling colliery, controlling the water supply of the clarified water, a system for visualizing the salt surplus and the control unit. Dodatkovo introduced viparovuvach of brackish water, roastings in the bottom convective zone of the “sleep rate”, a thermoelectric condenser of water bet, to take revenge on the Pelt block of cooling modules; thermoelectric generators, hot spas of thermo-batteries, which, through heat conduits, may have a thermal contact from the external part of the viparovuvach casing; a water heat exchanger, with a heat switch for hot Pelti modules at a condenser, water vapor and cold spas, thermo-generators, an electric heating system, a circulation pump and a Pelti cooling system.

Description

The useful model belongs to devices for desalination of highly mineralized natural and sea water and can be used in agriculture, chemical and food industry, etc.

In our time, the problem of obtaining water suitable for drinking is becoming global for humanity.

For example, a number of regions of Ukraine have huge underground water reserves with a total mineralization of 1-35 g/l. Such water can become suitable for consumption if it is desalinated.

Many water desalination devices are known that work using chemical precipitation, electrodialysis, direct or reverse osmosis, freezing, evaporation, and many others (1). One of the most accessible, simple and relatively cheap water desalination devices are those that use the principle of distillation. However, even for such devices, the cost of thermal energy is about 40 95 of the cost of the received water. Therefore, active research is being conducted to create more efficient, low-cost devices for water desalination.

A known device for desalination of water that works using solar energy (21. It consists of: a container with salt water, which is covered by a flat fence with a coating that absorbs solar radiation; a condensate collector, made in the form of a tube, passing through the zone of condensation of water vapor The disadvantage of such a desalination device is significant heat loss from the flat surface to the surrounding space, the impossibility of functioning in the absence of lighting of sufficient intensity, low productivity, a long time for the desalination process, and others.

Based on a set of common features, the closest analogue to the proposed useful model is the well-known water desalination device described in IZ). The water desalination device contains a housing with a hole for draining water, a thermoelectric module for freezing and thawing seawater, a device for draining and receiving fresh water; pipelines for supplying salt water; control unit; heating and cooling units; salt residue removal system. Despite the originality of such a device, it has a number of disadvantages, the main of which is the long (up to 480 minutes) duration of obtaining fresh water; inefficient use of thermoelectric Peltier modules as a device for cooling and crystallization of water with subsequent heating of ice. Thermoelectric modules have different optimization modes for operation as a cooler and as a heater, therefore, despite such a small

The efficiency of the modules, the use of the same modules for cooling and heating is suboptimal |4| and only increases energy costs for water desalination. The degree of water purification from salts is difficult to predict. In addition, water desalination using freezing does not guarantee disinfection of the resulting melt water. First of all, heavy water containing an isotope of hydrogen, which is considered radioactive, freezes. To avoid radioactive contamination, it is necessary to remove the first layer of frozen water, which further complicates the already complicated method of obtaining fresh water when using such an apparatus.

Therefore, the task of the proposed useful model is to create a thermoelectric system for desalination of salt water, devoid of the above-mentioned disadvantages, which would be characterized by energy saving, availability and ease of use.

The task is solved by the fact that the thermoelectric salt water desalinator of salt water, which contains a system of pipelines through which salt water is pumped by a circulation pump, heating and cooling units, a means of controlling the discharge of desalinated water, a system for removing salt residue and a control unit, according to a useful model, the desalination unit consists of: a salt water evaporator located in the bottom convective zone of the "solar pond", and the outer part of the evaporator body has thermal contact with the hot water of the bottom convective zone of the "solar pond" due to which the salt water is heated and evaporated; water vapor thermoelectric condenser containing a block of Peltier cooling modules; thermoelectric generators, the hot junctions of thermobatteries of which have thermal contact with the outer part of the evaporator case through heat pipes; a water heat exchanger, with which the hot junctions of the Peltier modules in the water vapor condenser and the cold junctions of the thermal batteries of thermogenerators have thermal contact, and water circulation in which is carried out through the fresh zone of the "solar pond" with the help of a circulation pump; electric power supply systems for circulation pumps and Peltier cooling modules, both from thermoelectric generators that use the thermal energy of the "solar pond" for operation, and from traditional sources of power supply; system of maintaining the given salinity gradient of the "solar pond" due to the salt released in the process of desalination of salt water.

A useful model offers a fundamentally new solution for the design of a device used for desalination of salt water. The design of the thermoelectric desalinator for salt water is based on the use of thermal energy from the "solar pond". Most of the energy costs for water desalination are carried out at the expense of a renewable source of thermal energy, which is a "solar pond". It is a shallow (2-3 meters deep) natural or artificial water body in which there is a salinity gradient according to the water profile. The water in the bottom convective zone of the "solar pond" is heated by solar radiation to 100 "C and more. The "solar pond" is also a powerful thermal energy accumulator.

The originality and effectiveness of the proposed useful model lies in the fact that seawater is evaporated by an evaporator that takes heat from the "solar pond". At the same time, the heat of the evaporator ensures the operation of thermoelectric generators, which, if necessary, in addition to traditional power sources, feed circulation pumps and Peltier modules in the thermoelectric condenser of water vapor. Cooling of cold junctions of thermogenerators and hot junctions of Peltier modules is provided by a water heat exchanger, which circulates water through the fresh zone of the "solar pond". In addition, the design of the desalinator provides for the presence of a system for maintaining the given salinity gradient of the "solar pond" due to the salt released in the process of desalination of salt water.

Industrial use of the proposed device does not require special technologies and materials. Its implementation is possible at existing enterprises of the construction, food, chemical, and instrument-making industries.

The proposed device functions as follows.

The salt water supplied to the evaporator is heated to the evaporation temperature due to the thermal energy of the "solar pond" in the bottom - the most heated zone in which the evaporator is located. First, light fractions of water evaporate, which in the form of steam go into a thermoelectric condenser, where they cool down and turn into fresh water. Residues of salts in the form of pus are removed from the evaporator by the salt removal system, and fresh water from the condenser is removed from it by the fresh water drain control. Powering the pumps and Peltier modules in the water vapor condenser is provided by a unit of thermoelectric generators, which operates due to the heat of the "solar pond". To increase the performance of the thermoelectric desalination system, the water heating system in the evaporator, as well as the Peltier cooling modules in the water vapor condenser, can be additionally supplied by traditional sources

From electricity supply. Cooling of the cold junctions of thermogenerators and Peltier modules is provided by water heat exchangers, the circulation of water through which is carried out through the fresh water zone of the "solar pond". At the same time, the heat is transferred to the water of the "solar pond". In addition, to maintain the given salinity gradient of the "solar pond", the salt released in the process of desalination of salt water can be used. In this way, autonomous, maximally energy-saving operation of the thermoelectric salt water desalination unit is ensured.

Confirmation of the industrial suitability of the proposed utility model is the following assessment.

In work I5)| information is provided on the implementation of a number of projects using "solar ponds" to obtain electricity in various ways. According to data (5), the specific power of steam turbine plants using the thermal energy of the "solar pond" is about 20 W/m" of the surface of the reservoir. The coefficient of useful performance (efficiency) of steam turbine plants using low-potential thermal energy is the lowest among the known technologies of electricity generation It is about 795. At the same time, for the "solar pond" temperature regime, the efficiency of the thermoelectric generator will be close to 1-1.5 95. Therefore, by the thermoelectric method of converting the thermal energy of the "solar pond" it is possible to obtain about 2.5-2.8 W/m. Accordingly, 1-1.1 kW of electricity can be obtained from a 20x20 (m) solar pond.

The circulation pump for supplying cold water to the cooling zone of hot junctions of thermal batteries in the condenser consumes no more than 0.1-0.15 kW. Water, heated by the heat that passed through the thermal battery, will flow into the "solar pond" zone with fresh water on its own, without the need for electricity.

Salt water can also enter the evaporator by gravity, without the need for electricity.

Therefore, about 1 kW of electricity can be used to power the water vapor condensation system.

To condense water vapor, it is enough to cool it by several degrees. Calculations show that when it is cooled by 50 "C, with the consumption of 1 kW of electricity, it is possible to obtain Z kW of cooling capacity, which allows you to obtain - 4.8 l/h of condensed water, that is, about 115 l/day. Further increase in the productivity of salt water desalination with the proposed method can be achieved both by increasing the energy efficiency of the "solar pond" and 60 by additional use of energy resources of traditional power sources.

Due to its simplicity, energy efficiency and affordability, such a device can be used anywhere, even in salt water spaces, on ships, offshore platforms, etc.

Sources of information: 1. Slesarenko V.N. Modern methods of desalination of sea and salt water. - M., 1973. 2. AS USSR Mo 1483199 A1. Solar desalination plant. Karnaukhov N.S., submitted 07/10/87, publ. 30.05.89, Bull. Mo 20.

Z. pbr/KoiopKa-avziga.gy/odiiadi/yetanu/1414-ietapomki-orgizpepp|a-togvKoii-modi-spavi-1.piti. 4. Anatchuk L.M. Thermocouples and thermoelectric devices. Directory. - K.:

Scientific thought. 1979. - 768 p. 5. Lobunets Yu.M. Solar pond with thermoelectric energy converter / Lobunets

Yu.M. // Thermoelectrics. - 2013. - Volume 2. - P. 91-94.

Claims (1)

UTILITY MODEL FORMULA A thermoelectric salt water desalinator comprising a piping system through which salt water is pumped by a circulation pump, heating and cooling units, desalinated water discharge control means, a salt removal system, and a control unit that is distinguished by the fact that it consists of a salt water evaporator , located in the bottom convective zone of the "solar pond", and the outer part of the evaporator body has thermal contact with the hot water of the bottom convective zone of the "solar pond", due to which the salt water is heated and evaporated; water vapor thermoelectric condenser containing a block of Peltier cooling modules; thermoelectric generators, the hot junctions of thermobatteries of which have thermal contact with the outer part of the evaporator case through heat pipes; a water heat exchanger, with which the hot junctions of the Peltier modules in the water vapor condenser and the cold junctions of the thermal batteries of thermogenerators have thermal contact, and water circulation in which is carried out through the fresh zone of the "solar pond" with the help of a circulation pump; electric power supply systems for circulation pumps and Peltier cooling modules, both from thermoelectric generators that use the thermal energy of the "solar pond" for operation, and from traditional sources of power supply; system of maintaining the given salinity gradient of the "solar pond" due to the salt released in the process of desalination of salt water.