Geothermal Heat Pump

A geothermal heat pump system is a heating or air conditioning system that uses the earth's ability to store heat in the ground and water thermal masses. These systems operate based on the stability of underground temperatures: The ground a few feet below the surface has a very stable temperature throughout the year, depending upon the location's annual climate. A geothermal heat pump uses that available heat in the winter and puts heat back into the ground in the summer. A geothermal system differs from a conventional furnace or boiler in its ability to transfer heat (as opposed to the standard method of producing heat). As energy costs continue to rise and pollution concerns continue to be a hot topic, geothermal systems may hold a solution to both of these concerns.

Ground source heating and air conditioning

Geothermal heat pumps are also known as GeoExchange systems (a term created by an industry association) and ground-source heat pumps. The latter term is useful as it clearly distinguishes the technology from air-source heat pumps. Geothermal heat pumps, which can be used in almost any region, should also be distinguished from geothermal heating. Geothermal heating is used in areas where exceptionally high underground temperatures, such as those at hot springs and steam vents, are used to heat indoor spaces without the use of a heat pump.

This article focuses on geothermal heat pumps that use water to exchange heat with the ground, often referred to as water-source geothermal heat pumps or water loop geothermal heat pumps. Another technology, the direct exchange geothermal heat pump, is also available and is briefly discussed.

1 Introduction
2 Components
3 Common Systems
4 Standing Column Well
5 Common Heat Pumps
6 Direct Exchange (not recommended)
7 Benefits of Geothermal Heat Pumps
8 Costs and Savings
9 External Links

Introduction

A geothermal heat pump is a heat pump that uses the earth as either a heat source, when operating in heating mode, or a heat sink, when operating in cooling mode.

Geothermal heat pumps can be characterized as having one or two loops. The heat pump itself consists of a loop containing refrigerant. The refrigerant is pumped through a vapor-compression refrigeration cycle that moves heat from a cooler area to a warmer one.

In a single loop system, the copper tubing refrigerant loop actually leaves the heat pump appliance cabinet and goes out of the house and under the ground and directly exchanges heat with the ground before returning to the appliance. Hence the name direct exchange (or DX). In a double loop system, the refrigerant loop exchanges heat with a secondary loop made of plastic pipe containing water and antifreeze (propylene glycol, denatured alcohol, or methanol). After leaving the heat exchanger, the plastic pipe then leaves the appliance cabinet, and goes out of the house and under the ground before returning, so the water is exchanging heat with the ground. This is known as a water-source system. Secondary loops are popular for ground use because they are not pressurized, so cheap plastic tubing can be used, and because they reduce the amount of expensive refrigerant required. Copper loop DX systems are gaining acceptance due to their increased efficiency and lower installation costs.

Components

Geothermal systems require three primary components: a length of buried tubing on the property, a liquid pump pack, and a water-source heat pump. The tubing can be installed horizontally as a loop field or vertically as a series of long U-shapes. The purpose of the tubing is to transfer heat to and from the ground. The size of the loop field depends on the size of the building being conditioned. Typically, one loop (400 to 600 ft) has the capacity of one ton or 12,000 British thermal units per hour (BTU/h) or 3.5 kilowatts (kW). An average house will range from 3 to 5 tons (10 to 18 kW) of capacity. The second component is a liquid pump pack, which sends the water through the tubing and the water-source heat pump. Lastly, the water-source heat pump is the unit that replaces the existing furnace or boiler. This is where the heat from the tubing is transferred for heating the structure. Heat pumps have the ability to capture heat at one temperature reservoir and transfer it to another temperature reservoir. Another example of a heat pump is a refrigerator—heat is removed from the refrigerator's compartments and transferred to the outside.

Common Systems

Closed Loop Fields

A closed loop system, the most common, circulates the fluid through the loop fields' pipes and does not pull in water from a water source. In a closed loop system there is no direct interaction between the fluid and the earth, only heat transfer across the pipe. The length of vertical or horizontal loop required is a function of the ground formation thermal conductivity, ground temperature, and heating and cooling power needed, and also depends on the balance between the amount of heat rejected to and absorbed from the ground during the course of the year. A rough approximation of the soil temperature is the average daily temperature for the region. Although copper and other metals can be used, polyethylene seems to be the most common tubing material used currently by installers. A common size for the tubing would be 3/4 inch (19mm) inside diameter.

There are four common types of closed loop systems: vertical, horizontal, slinky, and pond (slinky and pond loops depicted below).

Vertical closed loop field: A vertical closed loop field is composed of pipes that run vertically in the ground. A hole is bored in the ground, typically 150 to 250 ft deep (45–75 m). Pipe pairs in the hole are joined with a U-shaped cross connector at the bottom of the hole. The borehole is commonly filled with a bentonite grout surrounding the pipe to provide a good thermal connection to the surrounding soil or rock to maximize the heat transfer. Vertical loop fields are typically used when there is a limited square footage of land available. Boreholes are spaced 5–6 m apart and are generally 50 ft (15 m) deep per kW of cooling. During the cooling season, the local temperature rise in the bore field is influenced most by the moisture travel in the soil. Reliable heat transfer models have been developed through sample boreholes as well as other tests.

Horizontal closed loop field: A horizontal closed loop field is composed of pipes that run horizontally in the ground. A long horizontal trench, deeper than the frost line, is dug and U-shaped coils are placed horizontally inside the same trench. A trench for a horizontal loop field will be similar to one seen under the slinky loop field; however, the width strictly depends on how many loops are installed. Horizontal loop fields are very common and economical if there is adequate land available.

Slinky closed loop field: A slinky closed loop field is also installed in the horizontal orientation; however, the pipes overlay each other. The easiest way of picturing a slinky field is to imagine holding a slinky on the top and bottom with your hands and then move your hands in opposite directions. A slinky loop field is used if there is not adequate room for a true horizontal system, but it still allows for an easy installation. The image above shows a 3-ton slinky loop prior to being covered with soil. In the picture you can see the three slinky loops running out horizontally and three straight lines returning the end of the slinky coil to the heat pump. The pump is used to heat the house.

Closed pond loop: A closed pond loop is not as common, but is becoming increasingly popular. A pond loop is achieved by placing coils of pipe at the bottom of an appropriately sized pond or water source. This system has been promoted by the DNR (Department of Natural Resources), which supports geothermal systems and the use of ponds for geothermal systems. The bottom two images above show a pond loop close up and the pond loop as it is about to be sunk to the bottom of a pond. This loop field is for a 12-ton system, which is unusually large for most residential applications. As you can tell by the pictures, a pond loop is similar to a slinky loop, but it is attached to a frame and located in a body of water rather than in soil.

Open Loop Systems

In contrast to the closed loop systems, an open loop system pulls water directly from a well, lake, or pond. Water is pumped from one of these sources into the heat pump, where heat is either extracted or added. The water is then pumped back into a second well or source body of water. There are three general types of systems: First water can be pumped from a vertical water well and returned to a nearby pond. Second, water can be pumped from a body of water and returned to the same body of water. Third, water can be pumped from a vertical well and then returned to the same well. While thermal contamination (where the ground temperature is affected by the operation of the system) is possible with any geothermal system, with proper design, planning, and installation any loop configuration can work very well for a very long time. Deep lake water cooling uses a similar process with an open loop for air conditioning and cooling. Open loop systems using ground water are usually much more efficient than closed systems because they will be heat exchanging with water always at ground temperature. Closed loop systems, in comparison, have to make do with the inefficient heat transfer between the water flowing through the tubing and the ground temperature.

One of the benefits of an open loop system is that for most configurations (depending on the local environment) you are dealing with ground water at a constant temperature of about 50°F/10°C. In closed loop systems the temperature of the water coming in from the loop is often within 10°F/6°C of the temperature of the water entering the loop showing how little heat was exchanged. The constant ground water temperatures significantly improve heat pump efficiency.

Standing Column Well

A standing column well system is less expensive and more efficient than a comparably sized closed loop system. Water is drawn from the bottom of a deep rock well, passed through a heat pump, and returned to the top of the well, where traveling downward it exchanges heat with the surrounding bedrock. The choice of a standing column well system is often dictated where there is near-surface bedrock and limited surface area is available. A standing column is typically not suitable in locations where the geology is comprised of mostly clay, silt, or sand. If bedrock is deeper than 200 ft from the surface, the cost of casing to seal off the overburden may become prohibitive.

A multiple standing column well system can support a large structure in an urban or rural application. The standing column well method is also popular in residential and small commercial applications. There are many successful applications of varying sizes and well quantities in the many boroughs of New York City, and is also the most common application in the New England states. This type of earth-coupling system has some heat storage benefits, where heat is rejected from the buillding and the temperature of the well is raised, within reason, during the summer cooling months. The heat can then be harvested in the winter months, thereby increasing the efficiency of the heat pump system. As with closed loop systems, sizing of the standing column system is critical in reference to the heat loss and gain of the existing building. As the heat exchange is actually with the bedrock, using water as the transfer medium, a large amount of production capacity (water flow from the well) is not required for a standing column system to work. However, if there is adequate water production, then the thermal capacity of the well system can be enhanced by periodic discharge during the peak summer and winter months.

Since this is essentially a water pumping system, standing column well design requires critical considerations to obtain peak operating efficiency. Should a standing column well design be misapplied—leaving out critical shut-off valves, for example—the result could be an extreme loss in efficiency and higher operational costs than anticipated. The development and promotion of standing column well technology is generally credited to Carl Orio CGD from Atkinson, New Hampshire.

Common Heat Pumps

A heat pump in combination with heat and cold storage

There are also different types of water-source heat pumps. A variety of products are available, for both residential and commercial applications: There are water-to-air heat pumps, water-to-water heat pumps, and hybrids of the two. Some manufacturers are now producing a reversible heat pump for chillers also.

Water-to-air: The water-to-air heat pumps are designed to replace a forced-air furnace and possibly the central air conditioning system. The term water-to-air signifies that the heat pump is designed for forced-air applications and indicates that water is the source of heat. The water-to-air system is a single central unit that is capable of producing heat during the winter and air conditioning during the summer months. There are variations of the water-to-air heat pumps that allow for split systems, high-velocity systems, and ductless systems.

Water-to-water: A water-to-water heat pump is designed for a heating system that utilizes hot water for heating the building. Systems such as radiant underfloor heating, baseboard radiators, and conventional cast iron radiators would use a water-to-water heat pump. The water-to-water heat pump uses the warm water from the loop field to heat the water that is used for conditioning the structure. Just like a boiler, this heat pump is unable to provide air conditioning during the summer months.

Hybrid: A hybrid heat pump is capable of producing forced-air heat and hot water simultaneously and individually. These systems are largely being used for houses that have a combination of under floor and forced-air heating. Both the water-to-water and hybrid heat pumps are capable of heating domestic water also. Almost all types of heat pumps are produced commercially and residentially for indoor and outdoor applications.

Direct Exchange (not recommended)

While this article focuses on water-source systems in which the refrigerant exchanges its heat with a water loop that is placed in the ground, a direct exchange system (often known as DX) is one in which the refrigerant circulates through a copper pipe placed directly in the ground. This eliminates the need for a heat exchanger between the refrigerant loop and the water loop, as well as eliminating the water pump. These simpler systems are able to reach higher efficiencies while also requiring a shorter and smaller pipe to be placed in the ground, and are thus less expensive to install. Compared to water-source systems, DX systems are a relatively new technology. DX systems, like water-source systems, can also be used to heat water in the house for use in radiant heating applications and for domestic hot water, as well as for cooling applications.

However, this application is less environmentally sound than any of the other earth-coupling methods. The burial of copper pipes, which would likely corrode in a few years, filled with copious amounts of expensive refrigerant, just does not make good environmental sense. The copper pipes are grouted into bore holes and cannot be serviced or easily removed. Once the copper pipes fail, they will spill the refrigerant into the surrounding earth.

Benefits of Geothermal Heat Pumps

Geothermal systems are able to transfer heat to and from the ground with minimal use of electricity. Using a geothermal system, a homeowner can save anywhere from 30% to 70% annually on utilities compared with an ordinary system. Even with the high initial costs of purchasing a geothermal system, the payback period is relatively short, typically between three and five years. Geothermal systems are environmentally friendly; they are a renewable energy source, are non-polluting, and are recognized as one of the most efficient heating and cooling systems on the market.

The US Environmental Protection Agency (EPA) has called geothermal the most energy efficient, environmentally clean, and cost effective type of space conditioning system available. The life span of the system is longer than conventional heating and cooling systems. Most loop fields are warranted for 25 to 50 years and are expected to last at least 50 to 200 years. Geothermal systems do not use fossil fuels for heating the house and eliminate threats caused by combustion, like carbon monoxide poisoning. The fluids used in loop fields are designed to be biodegradable, nontoxic, and noncorrosive, and they also have properties that will minimize the pumping power needed.

Some electric companies will offer special rates to customers who install geothermal systems for heating and cooling their building. Electrical plants have the largest loads during summer months, and much of their capacity sits idle during winter months. When customers have geothermal systems, the electric company can use more of its facility during the winter months and sell more electricity. They can also reduce peak usage during the summer (due to the increased efficiency of heat pumps), thereby avoiding costly construction of new power plants. For the same reasons, other utility companies have started to pay for the installation of geothermal heat pumps at customer residences. They lease the systems to their customers for a monthly fee, at a net overall savings to the customer.

Geothermal heat pumps are especially well matched to underfloor heating systems, which do not require extremely high temperatures (as compared with wall-mounted radiators). Thus they are ideal for open plan offices. Using large surfaces such as floors, as opposed to radiators, distributes the heat more uniformly and allows for a lower temperature heat transfer fluid.

The earth below the frost line remains at a relatively constant temperature year-round. This temperature equates roughly to the average annual air temperature of the chosen location, so it is usually 7–21 °C (45–70 °F) depending on location. Because this temperature remains constant, geothermal heat pumps perform with far greater efficiency and in a far larger range of extreme temperatures than conventional air conditioners and furnaces, and even air-source heat pumps.

A particular advantage is that they can use electricity to heat spaces and water much more efficiently than an electric heater. Therefore, buildings can be heated with renewable energy without transporting and burning biomass on site, producing biogas for use in gas furnaces, or relying solely upon solar heating.

Geothermal heat pump technology is a natural building technique. It is also a practical heating and cooling solution that can pay for itself within a few years of installation.

Today there are more than 1,000,000 geothermal heat pump installations in the US.

The current use of geothermal heat pump technology has resulted in the following emissions reductions:

elimination of more than 5.8 million metric tons of CO₂ annually
elimination of more than 1.6 million metric tons of carbon equivalent annually

These 1,000,000 installations have also resulted in the following energy consumption reductions:

annual savings of nearly 8,000 GWh
annual savings of nearly 40 trillion BTUs of fossil fuels
reduced electricity demand by more than 2.6 GW

The impact of the current use of geothermal heat pumps is equivalent to

taking close to 1,295,000 cars off the road
planting more than 385 million trees
reducing US reliance on imported fuels by 21.5 million barrels (3,420,000 m³) of crude oil per year

Costs and Savings

The initial cost of installing a geothermal heat pump system can be two to three times that of a conventional heating system in most residential applications, new construction or existing. In retrofits, the cost of installation is affected by the size of living area, the home's age, insulation characteristics, the geology of the area, and location of the home or other property. For new construction, proper duct system design and mechanical air exchange should be considered in initial system cost. These systems can save the average family from $400 to $1400 per year, reducing the average heating and cooling costs by 35–70% per household.

External Links

This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Geothermal heat pump."