This document discusses solar ponds, which are large bodies of saltwater that can store solar energy as heat. It describes the principle behind solar ponds, which uses salinity gradients to trap heat at the bottom of the pond. The document outlines the different types of solar ponds and discusses their components and functioning in detail. It covers the design, construction, operation, and maintenance of salinity gradient solar ponds, which have three distinct temperature zones. Methods for establishing salinity gradients and extracting the stored heat are also summarized. Advantages of solar ponds include being environmentally friendly and providing reliable energy, while disadvantages are the need for space, salts, and water along with heat losses.
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Solar Ponds.pptx
1. ENERGY STRATEGY AND
ENERGY ECONOMICS
Solar Ponds
School of Energy and Power Engineering
XI’AN JIAOTONG UNIVERSITY
2. Contents
Introduction
Principle of Solar Ponds
Types of Solar Ponds
Salinity Gradient Solar Pond
Design and Construction
Settling the salinity Gradient
Control and Maintenance
Heat Extraction
Saturated Solar Ponds
Solar Gel and Membrane Ponds
Shallow Solar Pond
3. Introduction
Solar energy is regarded as one of the most promising substitutes for traditional
energy resources.
Its intermittent and unstable nature is a major drawback, which leads to a disparity
between supply and demand.
Thermal energy storage systems utilize either thermochemical reactions or the
sensible or latent heat capacity of materials to provide a heating or cooling resource.
In sensible thermal storage, energy is stored by changing the temperature of the
storage material.
Water is one of the best storage liquids for low-temperature heat storage
One way to trap solar energy is through the use of solar ponds. Solar ponds are large
scale energy collectors with integral heat storage for supplying thermal energy.
4. Principle of Solar Ponds
A solar pond is a three-dimensional, open-air pit,
filled with water endowed with special
properties.
Divided into three zones
In a pond, the creation of a salinity gradient
results in a higher salt concentration and
density at the bottom, and the heat absorbed
remains trapped there because the salinity
gradient inhibits natural convection and the
cooler water at the surface acts as an
insulator as it does not mix with the saline
water.
5. Types of Solar Ponds
Solar ponds can be classified according to four basic factors
1. Convecting or nonconvecting
2. Partitioned (multi-layered) or non-partitioned
3. Gelled or nongelled
4. Separate collector and storage or in-pond storage
6. Salinity Gradient Solar Pond
It consist of three distinct zones
1. Upper convective zone (UCZ)
2. Non-convective zone (NCZ)
3. Lower convective zone (LCZ)
7. Design and Construction
The availability of a salt source (salt or brine), freshwater, and enough land area
Depth = 3 m
Thickness = 1 m
Radiation received = 20-25 %
After heat losses = 15-20 %
Rise of Temperature = 40-45 °C.
8. Design and Construction
For example,
The annual solar energy incident 7 GJ 𝑚−2
𝑎−1
Annual load = 2800 GJ , Area = 400 𝑚2
Multiply surface area by a factor of 5-10 to estimate surface area of solar pond
The required solar pond area should be between 2000-4000 𝑚2
9. Design and Construction
Several strategic considerations for construction
Location of pond
Earth excavation
Lining
Insulation
Pond shape
Local geology
10. Settling the Salinity Gradient
Three methods for the establishment of the initial salt density gradient
1. Natural diffusion
2. Stacking
3. Redistribution
11. Settling the Salinity Gradient | Redistribution
Scheme of the redistribution method and the density profile obtained during salinity gradient settling in
the 500 𝑚2
Escuzar Solar Pond.
12. Control and Maintenance
Addition of saturated salt solution at the bottom
Washing the surface with freshwater
Monitoring and controlling disturbances such as algae blooms
Maintaining high transparency
Acidification
Maintaining the pH in the salt gradient zone
Using windbreaker to avoid surface turbulence
13. Heat Extraction
There are three methods for extraction of heat
1. External heat exchanger
2. Internal heat exchangers
3. Internal heat exchanger at the gradient zone
14. Heat Extraction
External heat exchanger
An external heat exchanger is used to extract heat
from brine and the cooled brine is returned to the
bottom of the pond
It includes the pumping hot brine from the LCZ
through a diffuser to prevent excessive velocity and
motion within the pond and thereby minimize erosion
of the gradient zone.
15. Heat Extraction
Internal heat exchanger
It involves a heat exchanger that is placed in the lower
convective zone of the pond.
Its most appropriate position is just below the gradient
zone, so that the heat removal can stimulate
convection throughout the lower convective zone and
remove heat from its entire volume
The low thermal conductivity of the plastic pipes is
compensated by increasing the heat transfer area on
the in-pond pipes; that is, by installing more pipes
and/or increasing the diameter of the pipes.
16. Heat Extraction
Internal heat exchanger at the gradient zone
In this method, heat is extracted from the NCZ as well as, or
instead of, the LCZ
Theoretical and experimental investigation showed that heat
extraction from the NCZ increases overall thermal efficiency
by up to 55% compared with the conventional method of
heat extraction solely from the LCZ
17. Saturated Solar Ponds
Saturated solar pond is designed to improve or reduce the level of maintenance of the salinity
gradient by making the pond saturated at all levels
A number of salts besides 𝐾𝑁𝑂3 have been used and are found to be appropriate, these include
𝑁𝑎2𝐵4𝑂7 (borax), KAl(𝑆𝑂4) 2 , 𝐶𝑎𝐶𝑙2, 𝑀𝑔𝐶𝑙2, and 𝑁𝐻4𝑁𝑂3
This gives these ponds the advantage of inherent stability
Zero salt flux throughout the pond eliminates the need for addition of salt
due to the high concentration in the bottom region a higher bottom temperature can be achieved
before the onset of boiling of the salt solution, thus increasing the thermal efficiency of the pond
18. Solar Gel and Membrane Ponds
A solar gel or viscosity-stabilized pond is a nonconvective and nonsalt solar pond and was
proposed to minimize or eliminate evaporation losses from the surface by reduction of heat
losses.
These ponds use a transparent polymer gel as a nonconvecting layer. The polymer gel has low
thermal conductivity.
Materials suitable for viscosity-stabilized solar ponds should have high transmittance for solar
radiation, high efficiency of the chosen thickness, and should be capable of performing at
temperatures up to 60 °C. Polymers such as gum arabic, locust bean gum, starch, and gelatin
are all potentially useful materials for this configuration
The disadvantage is the reduction of total transmission of sunlight to the bottom of the pond
Three types of membranes are suggested for the membrane-stratified solar pond, which are
horizontal sheets, vertical tubes, and vertical sheets.
19. Shallow Ponds
the depth of water in the SSP is relatively small, typically (4–15) cm
An SSP is essentially a large water bag or pillow placed within an enclosure with a clear upper
glazing.
Water is placed within the bag, which is generally constructed from clear upper plastic film and a
black lower plastic film, in such a way that the film is in contact with the top surface of the water,
and thus prevents the cooling effect due to evaporation.
The black bottom of the pond absorbs solar radiation, as a result, the water gets heated.
Solar energy collection efficiency is directly proportional to water depth, whereas water
temperature is inversely proportional to water depth.
This type of pond is suitable for supplying warm water for household use and other low-
temperature applications, for example, laundries, textile factories, canned food factories,
greenhouses.
20. Advantages
Environment friendly energy i.e. no pollution
Reliable energy source
Can be constructed according to the requirement
No need of a separate collector from this thermal storage system
Low maintenance cost
21. Disadvantages
Space availability
Salt and water supply needed
Low efficiency due to:
Heat losses
Bottom losses
Top losses
Radiation losses