Patent Application
20130261812
The present invention relates to apparatus and methods for monitoring a hot water tank of a hot water heating system, particularly with a view to minimising the energy consumed in supplying sufficient hot water.
A conventional hot water heating system typically uses a tank thermostat and a programme-based timer to control boiler firing in order to maintain the water in the tank at the desired temperature. The user of the system is provided with a means of specifying the desired temperature and a simple timer to set when the water should be kept at the specified temperature. The thermostat senses the temperature of the water inside the cylinder. It switches on the water heating when the temperature falls below the set temperature, and switches off once the settings have been reached.
Such conventional systems continuously regenerate hot water or heat the water during a repeating user-defined schedule, and expend more heat energy than is necessary, regardless of the actual demand for hot water.
The present invention provides apparatus for monitoring a hot water tank of a hot water heating system, comprising:
In a preferred embodiment, the processing arrangement is configured to calculate the volume of hot water usage in a predetermined period during a repeating usage cycle, and determine when the water in the tank should be heated such that said volume of hot water is provided during the predetermined period.
For example, the repeating usage cycle may equate to a day, a week or a month. Once the volume of hot water used in a predetermined period within the cycle is known, the hot water heating system may be controlled to heat the water in the hot water tank appropriately to ensure that sufficient hot water is available during the next occurrence of that period (that is, during the next repetition of the usage cycle). This is may involve heating the water prior to the predetermined period, and may also involve heating the water during the period as well.
In a further embodiment, the processing arrangement may be configured to determine when the water in the tank should be heated, such that said volume of hot water is provided during the predetermined period plus an additional volume of hot water as a contingency measure. The size of this additional volume of hot water may be adjusted over time by the processing arrangement having regard to the tank sensor signals during a subsequent occurrence (or occurrences) of the predetermined period. For example, it may be reduced (or increased) if the hot water consumption within the predetermined period is less than (or greater than) the volume provided when the contingency amount is included. These adjustments may be made incrementally over time as the number of occurrences of the predetermined period on which the calculations are based increases, if a substantially consistent pattern of usage emerges.
The processing arrangement may be configured to determine when the predicted volume of hot water required during the remainder of the current period of hot water usage is approaching or substantially equal to the hot water capacity of the tank, and generate an output signal in response thereto. As discussed further below, it may be advantageous in terms of energy efficiency to initiate heating the tank at this stage until the full tank volume is heated to at least the desired hot water temperature. Accordingly, the processing arrangement may be configured to generate an output signal to trigger heating of the hot water at this stage.
Preferably, the hot water tank monitoring apparatus includes at least three tank temperature sensors for sensing the temperature at at least three different tank heights and generating respective sensor signals in response to the monitored temperatures for receipt by the processing arrangement.
The hot water level parameter calculated by the processing arrangement with reference to the tank sensor signals may be substantially proportional to the proportion of the tank volume which is above a predetermined temperature threshold.
In embodiments, the processing arrangement may be configured to calculate a completion time parameter value having regard to the tank sensor signals, wherein the completion time parameter is related to the time it will take to heat the water in the tank until substantially all the water in the tank is above a predetermined temperature threshold.
The processing arrangement may be configured to calculate a heating rate parameter value for the hot tank having regard to the tank sensor signals, wherein the heating rate parameter is related to the rate at which the volume of water in the tank that is above a predetermined temperature threshold increases during heating of the water. Preferably, the heating rate parameter value is adjusted over time having regard to the tank sensor signals, to give a more accurate value by reference to signals received over a longer period of time. In some embodiments, the completion time parameter value may be calculated with reference to the heating rate parameter value.
Apparatus embodying the invention may include a user interface for communicating to a user at least one of: the hot water level parameter value, the completion time parameter value, and the heating rate parameter value.
Preferably the tank sensors are arranged over the height dimension of the tank so as to substantially minimise the vertical distance between any part of the tank and the nearest sensor. More particularly, the tank sensors may be arranged so as to substantially minimise the vertical distance between any part of the effective height of the tank and the nearest sensor.
The processing arrangement may be arranged to calculate the volume of hot water usage against time with reference to the tank sensor signals. More particularly, the processing arrangement may be configured to calculate the volume of hot water usage against time with reference to the hot water level parameter.
The processing arrangement may be configured to calculate the volume of hot water usage against time whilst taking account of the rate of heat loss from the tank to its surroundings.
The apparatus may include an outflow pipe temperature sensor for generating an output signal responsive to the temperature of or in an outflow pipe of a hot water tank, wherein the outflow pipe temperature sensor is used to detect when water is being drawn from the tank. The processing arrangement may be configured to calculate the rate of heat loss having regard to the output signal from the outflow pipe temperature sensor, as this is may be monitored to detect when water is being drawn from the tank. When water is being drawn, a reduction in the hot water level in the tank may therefore be largely attributable to the withdrawal of hot water rather than heat losses by other means.
The apparatus may be configured to distinguish between heat loss to its surroundings (“standing losses”) and hot water usage by monitoring the vertical temperature profile of the water in the tank. Standing losses will tend to lead to a generally uniform reduction in temperature (albeit with slightly greater losses from hotter regions of the tank), whereas hot water usage will lead to the temperature profile shifting up the tank as cold water is fed in at the bottom of the tank.
The invention further provides a hot water heating system including this apparatus.
Embodiments of the invention will now be described by way of example with reference to the accompanying schematic drawings, wherein:
In order to avoid wasting energy, a system is provided that heats water when there is an estimated or predicted demand for hot water and also provides feedback to the user.
Apparatus embodying the invention provides a hot water control system suitable for supplying domestic hot water on demand whilst conserving fuel. It also provides significant information which helps the user to make judgements about using energy.
The information that the system provides may include the amount of usable water in the tank (water which is above or equal to the user's desired temperature) and the estimated amount of time to arrival at a full hot water tank whilst heating.
A hot water cylinder contains water at different temperatures (layered). The hotter water will accumulate at the top with progressively cooler water further down. This is known as stratification. When water in the tank is heated, the cold water is heated evenly. If there is a warm band at the top of the tank, the cooler band below is initially heated until it reaches the same temperature, and then the whole tank continues to heat evenly. When heating is not in progress and water is drawn from the tank, the cold water is drawn in at the bottom of the tank, leaving the top section hot, with the bottom section cold (thus forming stratified regions in the tank). However the intersection between cold and hot “mixes” forming a mixed band separating the hot and cold regions. This mixed band, although referred to as a “de-stratified band”, does have its own temperature gradient ranging from hot at the top to cold at the bottom. The present system seeks to model this band to determine the level above which the water is at or above the desired temperature (“the tank level”) as discussed below. The term “de-stratified band” is used herein to refer to the mixed band separating the hot and cold water.
The “useful” or “effective” height (H) of the tank is defined as substantially equivalent to the height of the tank above the lowest heating point if it had the same volume and a constant horizontal cross-sectional area. In
In a preferred embodiment of the present invention, the apparatus performs tank level estimation by using three temperature sensors on the tank.
The three sensors are communicatively coupled to a control arrangement 20. This includes a processing arrangement 22, an electronic memory 24 and a user interface device 26. The control arrangement is in turn communicatively coupled via link 28 to a heat generation system (not shown) for heating the water. It will be appreciated that these components may be communicatively coupled via either wired or wireless links.
The system models the de-stratified band that exists in the tank between the hot and cold water, where hot water is water that is the same or above the desired temperature. The system uses interpolation and extrapolation to estimate the point at which the temperature within the tank is at the desired temperature, and thus determine the “level” of the tank. The system continuously monitors the level and keeps the user informed via the user-interface device 26. This may be provided on a dedicated display device or a user's general purpose electronic device, for example. An example of the type of image that may present this information is shown in
Preferably, an apparatus embodying the invention adaptively learns the pattern of usage of hot water for every day of week and aims to only heat water when required (hence saving the energy).
The system may be arranged to learn the hot water demand for periods which are marked with an occupancy of “in” in a schedule specified by the user.
Alternatively, every day of the week can be divided into regular intervals (for example 10 minute or 30 minute intervals) and the hot water consumption can be profiled during each interval. The hot water consumption is worked out using the tank level at start and end of the period minus the heat loss. The system may model the heat loss from the tank by using a fourth sensor 28 placed on the outlet pipe 1 of the hot water cylinder (using multiple sensors if the cylinder has multiple outlet pipes). When no major fluctuation is seen on the outflow pipe, it means that water is not being drawn and the change in the hot water level is due to heat loss.
In another implementation, heat loss is estimated by measuring the ambient temperature outside the hot tank, with the rate of heat loss being dependent on the temperature difference between the water in the tank and the surroundings of the tank.
Continuous periods with no hot water consumption are known as periods of inactivity. The system aim is preferably controlled so as to have a cold tank at the start of each significant inactive period in order to save energy.
It is preferable only to heat the tank during an active period when the current hot water level is insufficient to meet the estimated demand before the end of that period. More particularly, it may be advantageous to monitor the predicted hot water demand for the remainder of the current “active” period of hot water usage. When this amount approaches, or is substantially equal to, the hot water capacity of the tank, the processing arrangement of the apparatus may be arranged to trigger heating of the tank so as to provide a full tank of hot water at this stage to meet the demand. This is therefore expected to result in the tank being substantially exhausted of hot water at the end of the active period. It then lies cold during the subsequent inactive period, minimising energy wastage through heat loss from unused heated water to the environment.
It will be appreciated that this technique takes account of the fact that a tank cannot be heated to readily provide only a fraction of its volume of hot water, as heating takes place evenly due to convection in the tank.
For example, if the hot water demand for a period is 1.5 tanks, the system will provide a full tank at the start of the period and when the tank level reaches half it will reheat the tank to full, ensuring that the tank is empty at the end of the period. As another example, if the tank level is below the estimated current demand (for example 70% and the estimated demand is 100% before the next inactive period), it would be preferable to heat the tank now, to maximise the energy savings through the inactive period by minimising the tank temperature during that period.
When the water in the tank is being heated, the system may also be configured to recursively learn the hot water heating rate by using the average temperature reported by the three sensors placed on the tank. The heating rate is learnt by determining how much time is taken to reach to the desired temperature from the current average temperature. The learnt heating rate information is used to provide feedback to the user regarding the progress of heating (which is continually updated). The estimated time of arrival to a full tank may be presented to user on a display device in the manner shown in
The system may also be arranged to incorporate a buffer volume or a “safety net” whilst learning the demand for any period. It may add a contingency of say 30% onto the demand estimated to cover the risk of the user running out of hot water next time. The contingency may then be dropped incrementally (for example by 5% every week) to a minimum (such as 10%), if the hot water consumption remains within the estimated demand. The system may also be configured to detect erratic water consumption. In that event, it may raise the contingency incrementally, for example by 5%.
Although the embodiment of the invention depicted in
The “useful” or “effective” height of the tank should be divided equally into bands numbering the same as the number of sensors, and a sensor should preferably be placed close to the middle of each band. So for two sensors, if the useful tank height was 100 cm, it would be divided into two bands each of 50 cm. A sensor would be placed in the middle of each band, that is, at the 25 cm and 75 cm points. Placing them at 33 cm and 66 cm would mean that when the hot water level is at the top or bottom of the useful height, it is 33 cm away from the nearest sensor, but if the sensors are placed at 25 cm and 75 cm, the level can never be more that 25 cm away from the nearest sensor.
As another illustration, if four sensors are employed, the useful height should be divided into four bands, with sensor placements at 12.5 cm, 37.5 cm, 62.5 cm and 87.5 cm from the lowest heating point.
Nevertheless, the sensors do not have to be placed exactly at the ideal locations. The de-stratification modeling works most accurately when the sensors are placed at the recommended locations. However, the modeling will still function, albeit perhaps with reduced accuracy, if they are not placed evenly. This could aid installation where it might not be possible to place the sensors accurately. Preferably, the actual locations of the sensors are fed back into the de-stratified modeling, so that the impairment to the level estimation is kept to a minimum.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1019758.0 | Nov 2010 | GB | national |
| 1019918.0 | Nov 2010 | GB | national |
| 1111538.3 | Jul 2011 | GB | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/GB11/52281 | 11/21/2011 | WO | 00 | 6/19/2013 |
