The different types of solar thermal panel collectors

 

What are the different types of solar thermal hot water technologies?

Evacuated tube solar thermal systems

Evacuated Tube Solar Thermal Collector

The evacuated tube solar thermal system is one of the most popular solar thermal systems in operation. An evacuated solar system is the most efficient and a common means of solar thermal energy generation with a rate of efficiency of 70 per cent. As an example, if the collector generates 3000 kilowatt hours of energy in a year then 2100 kilowatt hours would be utilised in the system for heating water. The rate of efficiency is achieved because of the way in which the evacuated tube systems are constructed, meaning they have excellent insulation and are virtually unaffected by air temperatures. The collector itself is made up of rows of insulated glass tubes that contain copper pipes at their core. Water is heated in the collector and is then sent through the pipes to the water tank. This type of collector is the most efficient, but also the most expensive.

There are two main types of tubes that are used inside the collector which are glass-glass and glass-metal. The glass-glass version uses two layers of glass fused together at both ends. The double glass tubes have a very reliable vacuum but reduce the amount of light that reaches the absorber inside. The double glass system may also experience more absorber corrosion due to moisture or condensation forming in the non-evacuated area of the tube. The second kind of tube is a glass-metal combination. The glass-metal combination allows more light to reach the absorber and reduces the chances of moisture corroding the absorber.

The cylindrical shape of evacuated tubes means that they are able to collect sunlight throughout the day and at all times in the year. Evacuated tube collectors are also easier to install as they are light, compact and can be carried onto the roof individually. What’s more, the tubes can be replaced individually if one becomes faulty, avoiding the need to replace the whole collector. The system is an efficient and durable system with the vacuum inside the collector tubes having been proven to last for over twenty years. The reflective coating on the inside of the tube will also not degrade unless the vacuum is lost.

Flat plate solar thermal systems

Flat Plate Solar Thermal Collector

are another common type of solar collector which have been in use since the 1950s. The main components of a flat plate panel are a dark coloured flat plate absorber with an insulated cover, a heat transferring liquid containing antifreeze to transfer heat from the absorber to the water tank, and an insulated backing. The flat plate feature of the solar panel increases the surface area for heat absorption. The heat transfer liquid is circulated through copper or silicon tubes contained within the flat surface plate.

Some panels are manufactured with a flooded absorber that involves having two sheets of metal and allowing the liquid to flow between them. Using a flooded absorber increases surface area and gives a marginal boost in efficiency. The absorber plates themselves are usually made from copper or aluminium and are painted with a selective heat coating which is much better at absorbing and retaining heat than ordinary paints.

In an area that produces an average level of solar energy, the amount of energy a flat plate solar collector generates equates to around one square foot panel generating one gallon of one day's hot water.

The flat plate panel design utilises many different absorber configurations with the main design being the harp configuration. The harp design is usually used in low pressure thermosyphon systems or pumped systems. Other configurations include the serpentine which uses a continuous S shaped absorber and is used in compact hot water only systems which do not utilise space heating. There are also the flooded absorber systems and boundary absorbers which use multiple layers of absorber sheet where the heat is then collected in the boundary layer of the sheets.

Polymer flat plate collectors are an alternative to metal plate collectors. Metal plates are more prone to freezing whereas the polymer plates themselves are freeze tolerant so can dispense with antifreeze and simply use water as a heat transferring liquid. Any antifreeze that is added to the heat transfer liquid will reduce its heat carrying capacity at a marginal rate. A benefit of polymer plates is that they can be plumbed straight into an existing water tank removing the need for a heat exchanger which increases efficiency. Some polymer panels are painted with matte black paint rather than a selective heat coating. This is done to prevent overheating although high temperature silicone is now normally used to prevent overheating.

This design of solar panel is, overall, slightly less compact and less efficient when compared with an evacuated tube system, however this is reflected in a cheaper price. This design of solar can work well in all climates and can have a life expectancy of over 25 years.


Thermodynamic panels

Thermodynamic Panel

Thermodynamic solar panels are a new development in solar thermal technology. They are closely related to air source heat pumps in their design but are deployed on the roof or walls like regular solar thermal panels and do not have to be south facing. The concept behind thermodynamic solar technology is that it acts like a reverse freezer and they differ from conventional solar thermal in that they do not use solar radiation to heat up heat transferring liquids.

The panels have a refrigerant passing through them which will absorb heat. The heat that passes through the panel will then in turn become a gas. The gas is then compressed which raises its temperature and it will then be passed on to a heat exchanging coil that is located within a hot water cylinder. The heated water in the cylinder is heated to 55 degrees and can then be used around the property. The system has a built in immersion which occasionally raises the temperature to 60 degrees to eliminate the risk of legionella.

A thermodynamic system can produce up to 100% of domestic heating needs. A system that uses thermodynamic panels will in theory be able to generate energy all year round due to it not being reliant on having optimal climate conditions to reach its maximum output potential. A thermodynamic panel can work in temperatures as low as -5 degrees Celsius although there are not as yet any official performance figures for systems operating in the UK. The main manufactures of thermodynamic systems are in Spain and Portugal and these systems were not designed for the UK initially. More companies are now developing more UK specific models and bringing them to market. As an example of performance, a four person family would need to utilise one panel and a 250 litre cylinder.

What’s more, thermodynamic panels are also not currently approved by the Micro generation Certification Scheme, which means that they are not eligible for government green heat payments such as the Renewable Heat Incentive (RHI). This is sure to change however, and it is probable that thermodynamic panels will be eligible for the RHI in the future. The government says that it is currently gathering information on standards and performance.

Solar thermal air collectors

Solar-Air-Heater

Solar air heaters are mostly used for space heating and can be both glazed and unglazed. They are among the most efficient and economical solar thermal technologies available and are mostly used in the commercial sector. The top sheet of a glazed system has a transparent top layer and an insulated surrounding frame and back panel to prevent heat loss to the surrounding air. An unglazed system uses an absorber plate which air passes over while heat is taken from the absorber.

Solar thermal bowl collectors

Bowl-Solar-Thermal-Collector

A solar thermal bowl is similar in fashion to a parabolic dish but has a fixed mirror instead of a tracking mirror which a parabolic dish would use. A tracking mirror is designed to track the sun’s movement which is very costly on a large scale. A spherical or bowl mirror gets around the problem of tracking the sun in order to focus the light in one spot. A fixed mirror is at a disadvantage with regard to energy output as it cannot track the sun in order to focus the sunlight, however a fixed bowl will save the energy output that is associated with having to move a giant mirror to track the sun.

 

Domestic Solar Hot Water Systems

 

Low temperature solar thermal technologies, especially those that do not generate electricity, rely on the scientific principles behind the Greenhouse Effect to generate heat. Electromagnetic radiation from the sun, including visible and infrared wavelengths, penetrates into the collector that is absorbed by the surfaces inside the collector. Once the radiation is absorbed by the surfaces within the collector, the temperature rises. This increase in temperature can be used to heat water.

Domestic Solar Water Heating Systems

Solar Water Heating (SWH) is an effective method of utilising available energy sources to perform useful work. The energy from the sun can provide hot water for many domestic and industrial applications, displacing the need to burn fossil fuels. In Australia, around 25% of domestic energy consumption is devoted to the heating of water to low temperatures, of less than 100oC.
Two main components of SWH systems are collectors and storage tanks. There are many different types of configurations and collectors. The most commonly used type of collector is the flat plate.

Flat Plate Collectors

These collectors consist of airtight boxes with a glass, or other transparent materia,l cover. There are several designs on the arrangement of the internal tubing of flat plate collectors as shown in Figure 1.

fig1

Traditional collectors, like the Serpatine and Parallel tube examples above, consist of a number of copper tubes, known as risers that are orientated vertically with respect to the collector and placed in thermal contact with a black coloured, metal absorbing plate. The use of selective surfaces on absorbers improves the efficiency of solar water heaters significantly due to a very high absorbance (percentage of incoming energy that a material can absorb) and low emittance (percentage of energy that a material radiates away) of electromagnetic radiation. At the top and bottom of the metal absorbing plate, thicker copper pipes, known as headers, assist in the removal of heated water and the arrival of colder water to be heated. Insulation is placed between the absorbing plate and the external wall to prevent heat losses.

Whilst the principles of operation for flat plate collectors are fairly consistent, significant improvements in the design of systems, particularly absorber plates have occurred. Flooded plate collectors are similar to their tubed cousins, except that two metal absorbing plates are sandwiched together, allowing the water to flow through the whole plate. The increased thermal contact results in significant improvements in the efficiency of the system. In recent years, much research has been conducted on selective surfaces, which has seen significant improvements in the efficiency of solar water heaters. Today, a majority of absorber plates are composed of solar selective surfaces, made of materials that strongly absorb electromagnetic radiation (i.e. sunlight) but only weakly emit.

Batch Water Heaters

Batch water heaters, also known as ‘breadboxes’ are very simple passive systems for heating water using solar energy and have been used since the early 1900s. Batch systems consist of black storage tanks contained within an insulated box that has a transparent cover. Cold water is added to the hot water stored in the tanks whenever hot water is removed. Modern batch systems are used as preheating systems, where the water is then heated further by conventional gas, electric or wood systems. To retain the heat within the water, the system requires insulated covering to be placed over the glazing at night to prevent the heat being lost to the environment. Figure 2 shows a typical Breadbox water heater.

fig2

Selective Surfaces

According to Planck’s Law, the wavelength of radiation emitted from a surface is proportional to the temperature of the surface. Therefore, an ideal selective surface (the dark coloured material that lines the inside of the collector) for solar collectors should strongly absorb electromagnetic radiation (light) in the visible range and only weakly emit radiation back in the infrared range of the spectrum, so that the maximum amount of energy from the incoming sunlight is used to heat water.
Several coating methods for selective surfaces are used in the manufacture of solar collector absorber plates:

  • Chemical
  • Electroplated
  • Vapour deposited
  • Oxide

Chemical coatings are usually sprayed onto the absorber plate metal, with or without the use of electricity. These coatings do not alter the re-radiative properties of the plate metal, only enhance the absorption of the solar radiation. The thickness of the chemical coating is proportional to the selectivity of the surface. That is, the coating thickness influences not only the absorptivity of the surface, but also the emissivity (how easily the surface emits the longer wavelength IR radiation). Despite the low relative cost and ease of application, chemical coatings are often undesirable because of the temperatures reached inside collectors, which can cause a degradation in the chemical coatings. For example, black paint applied to the plate is considered to be a chemical coating. At high temperatures, the paint is likely to melt or burn off the surface, releasing volatile organic compounds into the environment.

Electroplated coatings are the most widely used coatings in the solar collector industry. These coatings are applied to the absorber plate metal using traditional electroplating technology. Prolonged exposure to elevated temperatures (around 200oC) and humidity can cause slow degradation in the selective coating as oxidation and crystal lattice reconstruction occurs. Black Chrome, a common electroplated coating used in the manufacture of solar collectors is relatively stable, particularly in humid, tropical conditions. Vapour deposited coatings are not traditionally used in flat plate collectors, as there are a number of significant engineering problems which are yet to be overcome. However, they are used extensively in evacuated collectors, which utilise a partial vacuum, such as the receivers in high temperature solar thermal systems.

Oxide coatings were the first type of coating used in solar collectors. Metals used in early solar collectors, such as copper and iron underwent natural oxidation, which have desirable absorptivity. However, as the oxidation processes occur naturally, they are difficult to control, which results in a change in the emissivity of the material and eventual degradation of the efficiency of the collector.

Evacuated tube solar thermal systems

The evacuated tube solar thermal system is one of the most popular solar thermal systems in operation. An evacuated solar system is the most efficient and a common means of solar thermal energy generation with a rate of efficiency of 70 per cent. As an example, if the collector generates 3000 kilowatt hours of energy in a year then 2100 kilowatt hours would be utilised in the system for heating water. The rate of efficiency is achieved because of the way in which the evacuated tube systems are constructed, meaning they have excellent insulation and are virtually unaffected by air temperatures. The collector itself is made up of rows of insulated glass tubes that contain copper pipes at their core. Water is heated in the collector and is then sent through the pipes to the water tank. This type of collector is the most efficient, but also the most expensive.

 

Storage Tanks

Depending on the water supply system, the system can be either a closed-coupled system or a gravity fed system. The most common tank in solar hot water systems is the close-coupled system, where the storage tanks are mounted with the collector on the roof. Tanks are located above the collectors to take advantage of thermosiphoning. Thermosiphoning utilises flat plate collectors to heat the water, which returns to the storage tank, located above the collector. Cold, denser water flows through the collector heating up and is then returned to the tank. As the heated water is less dense, it rises to the top of the tank. For thermosiphoning to be successful, it is essential that a constant rise in the pipe work is maintained and that the correct diameter pipes are used as risers and headers. In full sun a single pass through the collector can heat the water by as much as 20oC. Roof mounted flat plate collectors that utilise thermosiphoning are extremely popular in the Middle East, with 70% of the population using water heated by these systems. Figure 3 shows a typical thermosiphon water heater.

fig3

The density of water changes with respect to temperature. Generally, water is less dense at higher temperatures than at lower temperatures. Thermosiphoning uses this principle to circulate water through the collector, as cooler water from the mains will be drawn through the collector as the heated water is removed from the storage tanks. Two significant advantages exist with the close coupled system: this arrangement is the most cost effective system for installation and heated water is provided at mains pressure.

In gravity fed systems, the tank is installed in the roof cavity, with only the collector exposed to the sun. Positioning of the solar collectors must allow natural thermosiphoning to occur. Whilst these systems are usually the cheapest to purchase, household plumbing must be suitable for gravity feeding, i.e. larger pipes in the ceiling and down to the taps.

In forced circulation systems a mains pressure tank is located at ground level with the collector on the roof. In these systems, a pump is activated when the sun shines and cold water is pushed through the collector. Forced circulation systems are more expensive to purchase than either the close coupled or gravity feed systems, and electricity is required to provide power for the circulating pump.

 

Solar thermal heat storage

Water thermal Tank for Solar Thermal System

A thermal heat store will be necessary to retain the heat generated by a solar thermal installation unit until the heat is ready to be used. Thermal heat stores also work particularly well in conjunction with solar thermal panels. The main storage option in a domestic setting would be a large insulated cylinder that contains copper coils or plate heat exchangers. The system can also include a heating element like an immersion heater. A thermal storage unit can utilise a number of different and combined technologies for hot water generation and space heating. Thermal heat stores work at their best when managing input and output for a number of different systems and allowing flexibility in how you use both your solar thermal and current heating system together.

It may be necessary to also fit a new hot water tank as your existing tank may not be suitable, but this will vary depending on a number of factors such as what kind of solar thermal system you choose to install, your existing heating components and how many people the system will be designed to accommodate.

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