Hydronics
Hydronics is the use of liquid water or gaseous water or a water solution as heat-transfer medium in heating and cooling systems. The name differentiates such systems from oil and steam systems. Historically, in large-scale commercial buildings such as high-rise and campus facilities, a hydronic system may include both a chilled and a heated water loop, to provide for both heating and air conditioning. Chillers and cooling towers are used either separately or together as means to provide water cooling, while boilers heat water. A recent innovation is the chiller boiler system, which provides an efficient form of HVAC for homes and smaller commercial spaces.
District heating
Many larger cities have a district heating system that provides, through underground piping, publicly available high temperature hot water and chilled water. A building in the service district may be connected to these on payment of a service fee.Types of hydronic system
Basic types
Hydronic systems are of two basic types:- Hot water
- Chilled water
Classification
- Flow generation
- Temperature
- Pressurization
- Piping arrangement
- Pumping arrangement
Piping arrangements
Hydronic systems may be divided into several general piping arrangement categories:- Single or one-pipe
- Two pipe steam
- Three pipe
- Four pipe
- Series loop
Single-pipe steam
Despite its name, a radiator does not primarily heat a room by radiation. If positioned correctly a radiator will create an air convection current in the room, which will provide the main heat transfer mechanism. It is generally agreed that for the best results a steam radiator should be no more than one to two inches from a wall.
Single-pipe systems are limited in both their ability to deliver high volumes of steam and the ability to control the flow of steam to individual radiators. Because of these limitations, single-pipe systems are no longer preferred.
These systems depend on the proper operation of thermostatic air-venting valves located on radiators throughout the heated area. When the system is not in use, these valves are open to the atmosphere, and radiators and pipes contain air. When a heating cycle begins, the boiler produces steam, which expands and displaces the air in the system. The air exits the system through the air-venting valves on the radiators and on the steam pipes themselves. The thermostatic valves close when they become hot; in the most common kind, the vapor pressure of a small amount of alcohol in the valve exerts the force to actuate the valve and prevent steam from leaving the radiator. When the valve cools, air enters the system to replace the condensing steam.
Some more modern valves can be adjusted to allow for more rapid or slower venting. In general, valves nearest to the boiler should vent the slowest, and valves furthest from the boiler should vent the fastest. Ideally, steam should reach each valve and close each and every valve at the same time, so that the system can work at maximal efficiency; this condition is known as a "balanced" system.
Two-pipe steam systems
In two-pipe steam systems, there is a return path for the condensate and it may involve pumps as well as gravity-induced flow. The flow of steam to individual radiators can be modulated using manual or automatic valves.Two-pipe direct return system
The return piping, as the name suggests, takes the most direct path back to the boiler.Advantages
Low cost of return piping in most applications, and the supply and return piping are separated.Disadvantages
This system can be difficult to balance due to the supply line being a different length than the return; the further the heat transfer device is from the boiler, the more pronounced the pressure difference. Because of this, it is always recommended to: minimize the distribution piping pressure drops; use a pump with a, include balancing and flow-measuring devices at each terminal or branch circuit; and use control valves with a at the terminals.Two-pipe reverse return system
The two-pipe reverse return configuration which is sometimes called 'the three-pipe system' is different to the two-pipe system in the way that water returns to the boiler. In a two-pipe system, once the water has left the first radiator, it returns to the boiler to be reheated, and so with the second and third etc. With the two-pipe reverse return, the return pipe travels to the last radiator in the system before returning to the boiler to be reheated.Advantages
The advantage with the two-pipe reverse return system is that the pipe run to each radiator is about the same, this ensures that the frictional resistance to the flow of water in each radiator is the same. This allows easy balancing of the system.Disadvantages
The installer or repair person cannot trust that every system is self-balancing without properly testing it.Water loops
Modern systems almost always use heated water rather than steam. This opens the system to the possibility of also using chilled water to provide air conditioning.In homes, the water loop may be as simple as a single pipe that "loops" the flow through every radiator in a zone. In such a system, flow to the individual radiators cannot be modulated as all of the water is flowing through every radiator in the zone. Slightly more complicated systems use a "main" pipe that flows uninterrupted around the zone; the individual radiators tap off a small portion of the flow in the main pipe. In these systems, individual radiators can be modulated. Alternatively, a number of loops with several radiators can be installed, the flow in each loop or zone controlled by a zone valve connected to a thermostat.
In most water systems, the water is circulated by means of one or more circulator pumps. This is in marked contrast to steam systems where the inherent pressure of the steam is sufficient to distribute the steam to remote points in the system. A system may be broken up into individual heating zones using either multiple circulator pumps or a single pump and electrically operated zone valves.
Improved efficiency and operating costs
There have been considerable improvements in the efficiency and therefore the operating costs of a hydronic heating system with the introduction of insulating products.Radiator Panel system pipes are covered with a fire rated, flexible and lightweight elastomeric rubber material designed for thermal insulation. Slab Heating efficiency is improved with the installation of a thermal barrier made of foam. There are now many product offerings on the market with different energy ratings and installation methods.
Balancing
Most hydronic systems require balancing. This involves measuring and setting the flow to achieve an optimal distribution of energy in the system.In a balanced system every radiator gets just enough hot water to allow it to heat up fully.
Boiler water treatment
Residential systems may use ordinary tap water, but sophisticated commercial systems often add various chemicals to the system water. For example, these added chemicals may:- Inhibit corrosion
- Prevent freezing of the water in the system
- Increase the boiling point of the water in the system
- Inhibit the growth of mold and bacteria
- Allow improved leak detection
Air elimination
Air causes irritating system noises, as well as interrupting proper heat transfer to and from the circulating fluids. In addition, unless reduced below an acceptable level, the oxygen dissolved in water causes corrosion. This corrosion can cause rust and scale to build up on the piping. Over time these particles can become loose and travel around the pipes, reducing or even blocking the flow as well as damaging pump seals and other components.
Water-loop system
Water-loop systems can also experience air problems. Air found within hydronic water-loop systems may be classified into three forms:Free air
Various devices such as manual and automatic air vents are used to address free air which floats up to the high points throughout the system. Automatic air vents contain a valve that is operated by a float. When air is present, the float drops, allowing the valve to open and bleed air out. When water reaches the valve, the float lifts, blocking the water from escaping. Small versions of these valves in older systems are sometimes fitted with a Schrader-type air valve fitting, and any trapped, now-compressed air can be bled from the valve by manually depressing the valve stem until water rather than air begins to emerge.Entrained air
Entrained air is air bubbles that travel around in the piping at the same velocity as the water. Air "scoops" are one example of products which attempt to remove this type of air.Dissolved air
Dissolved air is also present in the system water and the amount is determined principally by the temperature and pressure of the incoming water. On average, tap water contains between 8-10% dissolved air by volume.Removal of dissolved, free and entrained air can only be achieved with a high-efficiency air elimination device that includes a coalescing medium that continually scrubs the air out of the system. Tangential or centrifugal style air separator devices are limited to removal of free and entrained air only.