Tankless water heating

Tankless water heatersalso called instantaneous, continuous flow, inline, flash, on-demand, or instant-on water heatersare water heaters that instantly heat water as it flows through the device, and do not retain any water internally except for what is in the heat exchanger coil unless the unit is equipped with an internal buffer tank. Copper heat exchangers are preferred in these units because of their high thermal conductivity and ease of fabrication. However, copper heat exchangers are more susceptible to scale buildup than stainless steel heat exchangers.
Tankless heaters may be installed throughout a household at more than one point-of-use, far from or without a central water heater, or larger centralized whole house models may still be used to provide all the hot water requirements for an entire house. The main advantages of tankless water heaters are a plentiful, practically limitless continuous flow of hot water, and potential energy savings under some conditions due to the use of energy only when in use, and the elimination of standby energy losses since there is no hot water tank.
The main disadvantage of these systems other than their high initial costs is the required yearly maintenance.
In order to provide on-demand, continuous hot water, tankless units use heat exchangers with many small passageways consisting of parallel plates or tubes. This increased number of passageways and small internal size create a large surface area for fast heat transfer. Unfortunately, this design can result in scale build up that can block the small channels of the heat exchanger reducing efficiency and eventually cause the unit to shutdown from over heating. For this reason most manufacturers require accurate water testing and installation of a water treatment system before installing the unit and yearly descaling using permanently installed service valves. Due to the high efficiency ratings of tankless water heaters, these costs are usually offset by the energy savings and rebates from utility, state, and federal programs for installing energy efficient equipment.

Operation

The heater is normally turned off, but is equipped with flow sensors which activate it when water travels through them. A negative feedback loop is used to bring water to the target temperature. The water circulates through a copper heat exchanger and is warmed by gas or electrical heating. Since there is no finite tank of hot water that can be depleted, the heater provides a continuous supply. To protect the units in acidic environments, durable coatings or other surface treatments are available. Acid-resistant coatings are capable of withstanding temperatures of 1000 °C.

Combination boilers

Combination or combi boilers combine the central heating with domestic hot water in one device. When DHW is used, a combination boiler stops pumping water to the heating circuit and diverts all the boiler's power to heating DHW. Some combis have small internal water storage vessels combining the energy of the stored water and the gas or oil burner to give faster DHW at the taps or to increase the DHW flow rate.
Combination boilers are rated by the DHW flow rate. The kW ratings for domestic units are typically 24 kW to 54 kW, giving approximate flow rates of per minute. Larger units are used in commercial and institutional applications, or for multiple-unit dwellings. High flow-rate models can simultaneously supply two showers.
Combination boilers require less space than conventional tanked systems, and are significantly cheaper to install, since water tanks and associated pipes and controls are not required. Another advantage is that more than one unit may be used to supply separate heating zones or multiple bathrooms, giving greater time and temperature control. For example, one 'combi' might supply the downstairs heating system and another the upstairs, duplication guarding against complete loss of heating and DHW in the event that one unit fails, provided that the two systems are interconnected with valves.
Combination boilers are popular in Europe where market share in some countries is in excess of 70%, with a projected rise in the United Kingdom to 78% by 2020. This trend is attributed in part by a social trend towards more numerous but smaller households and an ever-increasing trend towards physically smaller and often high density housing.
Disadvantages of combination systems include water flow rates inferior to a storage cylinder particularly in winter, and a requirement that overall power ratings must match peak heating requirements. The heating and DHW demands usually differ, and since installers will select a boiler to meet the larger demand, it will be oversized for the smaller demand; an oversized boiler will operate less efficiently due to problems such as short cycling and having increased return water temperatures that reduce efficiency. While ‘on demand’ water heating improves energy efficiency, the volume of water available at any given moment is limited, and the design of a 'combi' must be matched to the water supply pressure.
Some designs dating from before the 21st century, notably the Ideal Sprint, included as standard a flow regulator that permitted the same model to function efficiently in both high and low pressure mains water supply areas, thus accommodating wide supply pressure variations often encountered in otherwise similar urban settings such as Greater London.
While combination boilers have more moving parts and are thus widely held to be less reliable than tank systems, the twin trends towards replacement of parts based on a pre-set design life and replaceable digital controls for 'traditional' systems has largely eroded this distinction.

Point-of-use (POU) water heaters

Point-of-use tankless water heaters are located immediately where the water is being used, so the water is almost instantly hot, which reduces water wastage. POU tankless heaters also can save more energy than centrally installed tankless water heaters, because no hot water is left in lengthy supply pipes after the flow is shut off. However, POU tankless water heaters are often installed in combination with a central water heater, since the former type have usually been limited to under 6 litres/minute, which is sufficient for only light usage. In many situations, the initial expense of buying and installing a separate POU heater for every kitchen, laundry room, bathroom, and sink can outweigh the money saved in water and energy bills. In the US, POU water heaters until recently were almost always electrical, and electricity is often substantially more expensive than natural gas or propane. Regular maintenance, such as descaling, is essential for Point-of-use tankless water heaters to prevent mineral buildup, which can reduce efficiency and increase operating costs.
In recent years, higher-capacity tankless heaters have become more widely available, but their feasibility may still be limited by the infrastructure's ability to furnish energy fast enough to meet peak hot water demand. In the past, tank-type water heaters have been used to compensate for lower energy delivery capacities, and they are still useful when the energy infrastructure may have a limited capacity, often reflected in peak demand energy surcharges.
In theory, tankless heaters can always be somewhat more efficient than storage tank water heaters. In both kinds of installation, the absence of a tank saves energy compared to conventional tank-type water heaters, which have to reheat the water in the tank as it cools off while waiting for use. In some installations, the energy lost by a tanked heater located inside a building merely helps to heat the occupied space. This is true for an electric unit, but for a gas unit some of this lost energy leaves through the exhaust vent. However, if at any time the building must be cooled to maintain comfortable temperatures, the heat lost from a hot water tank located in the conditioned space must be removed by the air conditioning system, thus requiring larger cooling capacity and energy usage.
With a central water heater of any type, any cold water standing in the pipes between the heater and the point-of-use is dumped down the drain as hot water travels from the heater. This water wastage can be avoided if a recirculator pump is installed, but at the cost of the energy to run the pump, plus the energy to reheat the water recirculated through the pipes. Some recirculating systems reduce standby loss by operating only at select times—turning off late at night, for example. This saves energy at the expense of greater system complexity.

Hybrid water heaters

A hybrid water heater is a water heating system that integrates technology traits from both the tank-type water heaters and the tankless water heaters. It maintains water pressure and consistent supply of hot water across multiple hot water applications, and like its tankless cousins, it is efficient and can supply a continuous flow of hot water on demand.
The hybrid approach is designed to eliminate general shortcomings of other technologies. For example, hybrids are activated by either thermostat or flow.
Hybrids have small storage tanks that temper incoming cold water. Thus they only have to increase water temperature from warm to hot, unlike tankless which has to raise completely cold water to hot. The defining characteristics of a "hybrid water heater" are:

A combination of the water flow capacity of a tank, and efficiency of tankless
Built-in small storage water reservoir as part of heat exchanger
Dual activation: flow sensing and thermostat control

Hybrid water heaters can be gas-fired, or be electrically powered using a combination of heat pump and conventional electric heating element.

Operation

A gas hybrid water heater uses a modulating infrared burner that is triggered by water flow or thermostat. The multi-pass heat exchanger drives heat down then recycles it through baffled pipes for maximum efficiency. Water fills the reservoir from bottom up and spreads evenly around the heating pipes, producing continuous hot water with consistent pressure and temperature.
During low-flow situations, the hybrid behaves like a tank-type heater by having minimum fixed fuel usage and thermostat activation. Although equipped with some storage capacity, the small volume minimizes standby fuel usage. Hybrids also share additional traits with tank-type heaters like a floor-standing installation, standard PVC venting, draining pan, and they can be installed with a recirculation pump for even more water efficiency.
During high demand, high-flow situations, hybrid technology behaves more like a tankless heater, with high heating capacity and full modulation to supply a continuous stream of hot water across multiple applications. This produces fuel efficiencies similar to tankless heaters, but with higher flow capacity.