CONTROLLABLE VARIABLE INERTIA FLUID HEATING AND STORAGE SYSTEM

Abstract

Controllable variable inertia water storage system for heating and/or cooling, comprising: a plurality of water storage volumes for storing and heating water, these being either a vessel comprising sub-volumes or independent multiple vessels, said volumes being interconnected in series; a water inlet and outlet connect to the interconnected volumes; an independent water heater and/or cooler for each volume. Method for operating said system comprising: defining target sub-temperatures for each volume, wherein said target sub-temperatures are sequentially higher for each volume, in the direction of the water flow from inlet to outlet; increasing the target sub-temperatures in periods of forecasted higher demand, and, inversely, decreasing the target sub-temperatures in periods of forecasted lower demand; heating the volumes up to the target sub-temperatures, when the user indicates so or when a source of heat is available.

Description

TECHNICAL FIELD

The present disclosure relates to water heating and storage systems, in particular to a controllable variable inertia multiple volume or segmented sub-volume system for water heating and storage.

SUMMARY

The disclosure comprises a controllable variable inertia water storage system for heating and/or cooling, comprising:

• • a plurality of water storage volumes for storing and heating water, these being either a vessel comprising sub-volumes or independent multiple vessels, said volumes being interconnected in series;
  • a water inlet and outlet connect to the interconnected volumes;
  • an independent water heater and/or cooler for each volume.

In some embodiments, said independent water heater and/or cooler for a volume is a heat exchanger for exchanging heat with a fluid fed by a heat or cool source.

In some embodiments, two or more of said volumes comprise, as said independent water heater and/or cooler, heat exchangers for exchanging heat with fluid fed by the same source of heat or cool.

In some embodiments, said source of heat or cool is a boiler, thermal solar panel, electric heater, combined heat and power cogeneration unit.

Some embodiments comprise further volumes which are not interconnected with said interconnected volumes, said further volumes comprising independent water inlet and outlet connections.

In some embodiments, said further volumes each comprises a water heater and/or cooler that is independent from the water heaters and/or coolers of said interconnected volumes.

In some embodiments, said volumes are thermally insulated, in particular between said volumes.

In some embodiments, the volumes are arranged linearly or radially, in particular concentrically.

In some embodiments, the serial interconnections between volumes are arranged such that water stratification by temperature is promoted.

In some embodiments, the serial interconnections between volumes comprise flow deflectors such that the disruption of water stratification by temperature is minimized.

In an aspect, a method for operating the system as any one of the above and below described, comprises the steps of:

• • defining target sub-temperatures for each volume, wherein said target sub-temperatures are sequentially higher for each volume, in the direction of the water flow from inlet to outlet; and wherein the target sub-temperature of the volume connected to the outlet is the target temperature of the water to be supplied;
  • increasing the target sub-temperatures in periods of forecasted higher demand, and, inversely, decreasing the target sub-temperatures in periods of forecasted lower demand;
  • heating the volumes up to the target sub-temperatures, when the system user indicates so or when a predefined source of heat is available.

Some embodiments comprise limiting the water temperature of each volume by controlling the heating with user-defined minimum and maximum temperature limits for each volume.

In some embodiments, the step of heating the volumes comprises first heating up to a predefined number of volumes that are closest to the water outlet; and sequentially heating up to a predefined number of other volumes that are next closest to the outlet, until all volumes reach the target sub-temperatures.

In some embodiments, the step of heating the volumes comprises first heating the volume that is closest to the water outlet; and sequentially heating the other volumes, one by one, that are next closest to the outlet, until all volumes reach the target sub-temperatures.

In some embodiments, the step of heating the volumes comprises first heating a predefined number of volumes that have the larger differences between current temperature and target sub-temperature; and sequentially heating predefined number of volumes that then have the larger differences between current temperature and target sub-temperatures, until all volumes reach the target sub-temperatures.

In some embodiments, the target sub-temperatures are increased or decreased according to the heat availability of the heat source.

In some embodiments, the system comprises a control module configured to operate any of the above or below described methods of operation.

In some embodiments, the control module comprises data connections, local or remote, for providing information on the system status and for receiving user configurations.

BRIEF DESCRIPTION OF DRAWINGS

The following figures provide preferred embodiments for illustrating the description and should not be seen as limiting the scope of invention.

FIG. 1—Schematic representation of systems and sub-systems of the vessel of embodiments hereby described.

FIG. 2a—Schematic representation of integration of the mechanical and control system of embodiments hereby described with linear layout with a domestic generic water heating system.

FIG. 2b—Schematic representation of integration of the mechanical and control system of embodiments hereby described with linear layout with a domestic generic water heating system using a natural gas boiler and electric photo-voltaic cells.

FIG. 2c—Schematic representation of integration of the mechanical and control system of embodiments hereby described with linear layout with a domestic generic water heating system using solar panels and electric photo-voltaic cells.

FIG. 2d—Schematic representation of integration of the mechanical and control system of embodiments with linear layout with a domestic generic water heating system using a micro combined heat and power cogeneration unit (micro CHP).

FIG. 3a—Schematic representation of an alternative embodiment wherein one of the sub-vessels is not interconnected.

FIG. 3b—Schematic representation of an alternative embodiment wherein one of the sub-vessels is not interconnected and is heated/cooled independently.

FIG. 4—Schematic representation of layouts of the vessel with sub-volumes.

FIG. 5—Schematic representation of decision tree of the control system, highlighting the capability to handle dynamic loads on the energy availability and demands based in instantaneous or provisional data as well as the possibility of choosing the energy source.

FIG. 6—Schematic representation of the operative control module.

FIG. 7—Schematic representation of the decision tree of the operative control module.

Wherein in said figures the following elements are present:

• • 1—external agent(s) (human or not)
  • 2—hot water outlet (or inlet for cooling)
  • 3—cold water inlet (or outlet for cooling)
  • 4—thermal energy source
  • 5—valve assembly (one or more valves to control the hydraulic energy)
  • 6—sub-volumes
  • 7—energy exchange device for the thermal hydraulic energy source (or sink for cooling)
  • 8—energy exchange device for the electric energy source (or sink for cooling) or other energy source
  • 9—controller
  • 10—bi-directional data link between vessel and an external communication network
  • 11—communication network
  • 12—hydraulic actuators' signal
  • 13—temperature sensor
  • 14—micro cogeneration unit fuel
  • 15—micro cogeneration unit, including required piping subsystems and others not relevant for the disclosure
  • 16—electricity produced by the cogeneration unit, photovoltaic cells or other source
  • 17—electricity for auto-consumption
  • 18—electricity to supply or receive from the power grid
  • 19—local external agent (human or not) (can be a home user, or an automatic controller)
  • 20—remote external agent(s) (human or not)
  • 21—local communication network
  • 22—other communication network
  • 23—solar photovoltaic panel and control system
  • 24—solar thermal panel and control system
  • 25—boiler
  • 26—insulation
  • 27—energy being produced sensor (current and/or voltage based)
  • 28—initialization procedures
  • 29—machine status
  • 30—communication procedures
  • 31—is energy being supplied?
  • 32—want to force the vessel to heat?
  • 33—energize with how much energy?
  • 34—how to energize?
  • 35—use which energy source?
  • 36—energize which sub-volume?
  • 37—is none available?
  • 38—energize sub-volume with defined energy source
  • 39—vessel is already fully energized

DETAILED DESCRIPTION

The necessity to efficiently store and manage energy is a fundamental challenge to modern human life. The technology described in this document addresses this challenge allowing a more effective way to manage this energy not only in a transient load/unload state of the system but also in a stationary regime of usage. The new construction technology is enhanced by using advanced control systems, that will also be described in this document, and that allows to integrate different energy sources to collaboratively heat, or cool, the contents of a vessel in a cooperative way. These energy sources can be, for example, electricity, natural gas, biomass, pellets, among others. The vessel control system has a two-way communication mechanism such that it allows the exchange of information between the machine and an external agent.

In this document we will consider, for illustration purposes only, that the vessel is inserted in a standard domestic hot-water system using solar panels as the primal heat source. Other uses, e.g. industrial or commercial, may be contemplated.

Vessel or tank may be used interchangeably in the present disclosure, considering that the disclosure is straightforward to apply to both pressurized and unpressurized vessels.

This system comprises a primary fluid circuit that transports thermal energy from, for example, the solar panels to the hot water vessel. This technology can be applied to any other system where the user wishes to store thermal energy. This includes several other systems to heat or cool the inertial fluid not described in this document but which are known in the technical field.

The vessel is connected to one or more energy sources that heat the water in the vessel in a collaborative way, in the case considered, thermal energy and electric energy. This setup can be materialized for example by connecting the vessel to solar panels and photo-voltaic cells, or a micro combined heat and power boiler, or directly to the main power grid, among others.

The technology described can be used wherever one wishes to store thermal energy. To do so, and in the example taken for illustration purposes, the vessel is composed by smaller sub-volumes whose heating is done independently using both electric resistances and thermodynamic-hydraulic heat exchanger coils.

One of the main concepts consists of a disruptive solution with technology used by manufacturers of such vessels, increasing its added value and differentiation in comparison to other vessel technologies. This new innovation allows the vessel to:

• • 1. In specific conditions, to supply hot water during more time due to the compartmentalization of the vessel and the careful choice of what volume to heat in each instant;
  • 2. Have a bigger volume without the added loss of efficiency. Since the sub-volumes closest to the outlet have small dimensions, they can be heated in a short time. The other sub-volumes store extra energy beyond the minimum required energy for instantaneous use. This way, the system can function efficiently with low quality heat sources and can store more energy than a conventional vessel in the same conditions;
  • 3. Reduce complexity by avoiding usage of layouts for example fluid deflectors used in prior art vessels to promote liquid stratification;
  • 4. Store energy more efficiently in situations of lower solar radiation when connected to solar panels or photo-voltaic cells. This occur in countries with high latitudes like Germany and the United Kingdom;
  • 5. Interact with different energy sources heating each sub-volume independently with a multitude of heating systems, such as electric resistances and thermodynamic-hydraulic coils, among others;
  • 6. Choose the energy source to use in each instant by a control system that can use electric and hydraulic valves;
  • 7. Interact with the user and other external entities with interest in participate directly or indirectly in the way the vessel operates and choose the energy source. This is done by the vessel controller or by other remote access connection;
  • 8. Reduce transients in the operation of others systems that produce energy that are responsible for a loss in the efficiency of such systems. Being able to store a large amount of energy, the vessel can be a strategical energy buffer, increasingly storing energy from intermittent energy sources, like wind turbines and combined heat and power co-generation units.

The vessel hereby proposed according to some embodiments shares the same volume and shell common to other existing products in the market. The most differentiating aspects are:

• • 1. Holistic energy transfer system control. These energy transfer systems are thermodynamic-hydraulic heat exchanger coils and electric resistances which are installed each in one or more vessel sub-volumes;
  • 2. Vessel volume division, creating one or more independent sub-volumes that are connected between each other. This is done by associating smaller volume vessels in a single equipment or by placing internal divisions, which might be thermally isolated, inside a single larger vessel. The connections may be controllable, i.e., switchable between open and closed states. Other non-interconnected volumes may also be associated with the system.
  • 3. Integrated and intelligent vessel control system that chooses the heat source based in information that can be from within or outside of the vessel. This control actuates valves and electrical switches so that the chosen heat source is used.
  • 4. Connection of the vessel control system to information networks and domotics with active control functionalities so that external agents can influence the operation of the vessel.
  • 5. Compactness of the vessel system by integrating all sub-vessels, the control system and the heat transfer systems in a small package.

The embodiments hereby described comprise of a vessel to store a fluid. Applied to solar hot-water systems it addresses several problems that exist in the standard arrangement of such systems. The main characteristics of this new vessel technology are:

• • 1. Optimized heating, or cooling, of a liquid;
  • 2. Advanced control of the heating, or cooling, system;
  • 3. Communication between the vessel and an external agent (human or not human) to the system.

Using a solar hot-water and/or photo-voltaic system for illustration purposes allows us to identify and present several characteristics of the new vessel technology:

We can identify 3 problems in solar hot-water conventional systems:

• • 1. In his daily life, a user knows that if he consumes the hot water from the vessel in the end of the afternoon, he might have no hot-water heated with the solar panels to use in the morning because the system will need time to re-heat the vessel with the morning sun. Therefore, he will need to change his routines and habits in order to take full advantage of the solar energy by planning the number, quantity and time of his hot water consumptions.
  • 2. As referred in the last item, heating the overall volume of a water vessel is very time-consuming. This is dependent on the volume of the vessel. A smaller vessel heats faster. However, has a lower hot-water “availability” since when hot water is removed from the vessel it is replenished with cold water from the main line, lowering the water temperature in the overall vessel. This way, the volume of available hot water to the user is different than the real volume of the vessel. This depends on several variables like water flow-rate as well as inlet and outlet water temperature.
  • 3. To solve the problems identified in the last items, we can be led to match bigger solar panels to vessels of smaller dimensions. In real working conditions, when the water in the vessel reaches a pre-determined temperature (between 70 to 90° C.), the circulation pump of the primary circuit halts so that the water in the vessel is not vaporized and so that the hydraulic equipments (valves, pumps, . . . ) are not damaged. After stopping, the circulation pump of the primary circuit will only be turned on after the primary circuit fluid lowers from a pre-determined value. In real working conditions it will only occur after sunset. By stopping the primary circuit it will continue to increase its temperature reaching very high temperatures and in specific occasions it can vaporize. This occurs when the hot water consumption is insufficient to drain the excess energy captured by the solar panels and it represents a waste of the solar energy captured that in extreme cases can even damage the solar panels and the primary circuit piping and fittings.

The new vessel under development addresses these issues by a system comprising a hot water storage vessel divided in an array of sub-volumes of smaller dimensions. By selectively, and according to methods of the disclosure, heating each of these sub-volumes, it is possible to control the quantity of water being heated and so, change the inertia mass of fluid being heated in each instant.

By changing the water quantity being heated in each instant, it is possible to make available a specified volume of water in shorter time than conventional systems and increasing the hot-water “availability” of the system. This way we reduce the burden of changing routines and habits for the end user of the hot-water.

This technology also enables to oversize the vessel for a specific heating system such that the situations mentioned in item 3) do not occur. With the current state-of-the-art technology oversizing the vessel increases the problems of items 1) and 2).

Improvements:

• • 1. Less time to heat a usable volume of water.
  • 2. It is possible to increase the overall vessel volume without compromising the time taken to heat the water in the vessel.
  • 3. Efficient usage of low power and intermittent energy sources.

To create new ways to use a hot water vessel:

• • 1. Use of the vessel as an energy reservoir which uses the most convenient energy source in each instant.
  • 2. Use of the energy reservoir by the user or other external entities or agents with different goals in sight, like, for example, to balance energy grids (of electricity, natural gas, . . . ), lowering heating costs, . . . .

The technology described comprises a water storage vessel composed by an array of smaller volumes arranged in a compact size or by subdividing a larger volume into smaller fractions by placing thermal insulated walls inside the vessel. Each sub-volume has independent heating elements (heating coils and electric resistances) that are holistically and independently controlled. By actuating in valves and the electronic circuits that control the heating coils and electric resistances of each sub-volume, it is possible to control the quantity of water being heated in each instant and so, vary the inertia of the system being heated.

Using this technology, a volume of water is heated in a fraction of the time required by conventional systems, increasing the usable/available hot water volume of a vessel and reducing the burden and behavioral changes imposed on users of solar hot water systems in order to take fully advantage of such systems. By carefully choosing the dimension of each sub-volume, this technology enables to use a vessel of bigger capacity increasing the energy storage capacity of the overall system.

The machine comprises the integration of two different systems: a mechanical system and a control system that controls and interfaces the machine with the external environment (cf. FIG. 1).

The mechanical system comprises a sub-system of inertial liquid storage and another sub-system for energy transfer. The first consists of several water storing vessels integrated, or not, see as mentioned above, in a single compact equipment. The second sub-system consists of several actuators and energy transfer equipments (e.g. valves, heat exchangers, electric resistances, . . . ) to enable the energy transfer into the vessel and each sub-volume of the first sub-system. These energy transfer equipments can be located inside or outside of each sub-vessel.

The choice of the sub-volume to heat and the energy transfer mechanism to use is decided by a control system that actuates valves and/or electronic circuits.

The control system consists of electronic control devices that, based on external and internal inputs, control the way the mechanical system operates.

The control system chooses in each instant which sub-volume to heat and with which energy source using information from local sensors placed in the vessel and information acquired from communication networks with external entities (sensors, operators, servers, machines, . . . ) that can interact with the vessel and influence its operation.

These decisions (which sub-volume to heat and with which energy source) are based on intelligent algorithms that take into account the instantaneous balance of energy demanded from and supplied to the vessel as well as historical data to predict the future trend of these energy parcels and optimize the overall system performance.

The control system can interact with services facilitated by other entities, namely “cloud based services” or other proprietary services and networks. The capability to communicate in small or large scale networks enable new advanced features. When integrated in a domotics system, the vessel can communicate with other equipments such as outside meteorological devices as well as work together with other house heating devices and other appliances.

When connected to the Internet, the system can take advantage of “cloud-based” M2M (Machine-to-Machine) services. Examples of possible features are usage data collection for service providers and end-users, firmware upgrades, integration with intelligent grid management systems, etc. . . .

The control system can be developed as integrated part of the vessel or as an external add-on to the vessel allowing it to have the functions described.

In terms of the mechanical system, the vessel of the embodiments hereby described stores thermal energy dynamically, adapting the quantity of fluid to heat, or cool, to the heating, or cooling, power being delivered to the machine by the heat exchanging circuits, the user energy demands as well as external inputs.

By incorporating an intelligent control that will be presented below, the heat exchangers on the corresponding smaller sub-volume are triggered. By heating, or cooling, smaller sub-volumes the instantaneous temperature change rate is increased in that sub-volume leading to a faster heating of the water that is available to the user.

These smaller sub-volumes are connected between each other in such a way to promote a continuous discrete pre-heating, or pre-cooling, from the intake of the fluid to be heated, or cooled, to the outlet of the vessel. This is possible by connecting the hot-pipe of a sub-volume to the cold-pipe of the adjacent sub-volume.

The layout of the connections between sub-volumes was thought such that it promotes stratification in each sub-volume. The linear arrangement of the sub-volumes can be seen as a way to impose discrete forced stratification in the vessel.

In terms of the control system, the operation of the control module is shown in FIG. 6. The main purpose of this module is to determine which sub-volume to heat, or cool, and with which energy source. In order to do so, it relies on instantaneous as well as provisional computed data based on the history of energy consumption, energy availability and other data pertinent for its operation (for example, meteorological forecasts, user or external agents needs and preferences, etc. . . . ).

The control system is designed to answer three simple questions:

• • 1. How to heat, or cool, the vessel?
  • 2. Which energy source shall be used?
  • 3. Which sub-volume should be energized?

FIG. 7 shows how the decision tree is arranged in order to answer the previous questions.

After an general initialization procedure (28), the control system interacts with the sensor groups (13) and (27) to acquire information regarding the instantaneous system status, including controls via a user interface.

The communication procedures (30) that follow manages the dialog between the vessel control system and other external agents (1), (19) and (20). This is done using a general communication network (10), (21) and (22). This interaction allows the control system to communicate its current status as well as other computed and sensed quantities, and also to receive information affecting its operation. Such information can include, among other things, meteorological actual readings and forecasts, overriding commands, maintenance instructions and firmware updates or upgrades, . . . ).

With this information, two parallel lines of decision leading to two different questions arise (31) and (32). If a agent (1), (19) or (20) has asked the vessel to heat with a determined amount of energy and/or power and/or source at a specific time and/or time interval (32), the vessel will compute the heating power required and perform such action (34-39). On the other hand of the parallel branch, if there is energy being delivered to the vessel (31), the control system will also act in such a way to store that energy accordingly (34-39).

The question of how to energize the vessel (34) defines set-point temperatures in each sub-volume. These are the target temperatures to reach in each sub-vessel. By increasing the target temperatures each sub-vessel is capable of increasing its energy storage capacity. This is particularly important in the sub-volume closer to the outlet and in a situation when hot water is being consumed from the vessel.

On the other hand, a lower target temperature lowers the energy storage capacity which is particularly important to reduce the thermal losses from the vessel. The target temperatures are defined based on historical and provisional data pertaining to energy demanded from and energy supplied to the vessel. When no energy demands are forecast in a near future, the vessel operates with lower target temperatures.

This target temperature increases gradually each time the vessel becomes fully energized up to the maximum operational temperature of the vessel. When a demand is forecast, the vessel energizes increasing its target temperatures. In this case the sub-volumes closer to the outlet will experience a bigger increase in target temperature, and in such a way that before the estimated demand time starts, there is enough energy in the sub-volumes closer to the outlet to supply it. This mode of operation is herewith called ECO MODE.

The user, or agent, ((1), (19), (20)) is free to opt-out of this procedure (ECO MODE) or to limit the automatic calculation of target temperatures by defining minimum and maximum limits for the target temperatures and for each sub-volume. This new mode of operation is herewith called POWER MODE.

The decision of which energy source to use (35) is based on availability, demand and user, or agent ((1), (19), (20)), preferences. The availability and demand are accessed by the sensor groups (13) and (27). The user, or agent, preferences are known from the user interface as well as from the communication connection described (10), (21) and (22).

The decision of which sub-volume to energize (36) is based on the target temperatures defined for each sub-volume. The sub-volume closer to an outlet will be energized first until it reaches its target temperature. Then, the adjacent sub-volume will be energized and so on until the last sub-volume is fully energized. Note that, in ECO MODE, each time the vessel is fully energized, the target temperatures are increased. This procedure continues until the maximum operating temperature for the vessel is reached.

Following FIG. 7, and having answered all questions, the control module performs the required actions, energizing the system (38).

The control system has an interface that permits several levels of interaction:

• • 1. Domotics network integration—by interacting with other devices inside the house (using technologies such as KNX, or others) allows extending the reach of the vessel energy monitoring and control, optimizing its operation. It is also possible to control and monitor the vessel by using other domotics integrated components from the house.
    • With the domotics network integration it is possible to collect data such as inside and outside house temperature, occupancy, and other occupants habits, . . . and adjust the behavior of the vessel accordingly, i.e. adjusting to weather, occupancy, etc. . . . as described in the operation of the ECO MODE of operation and the “How to energize the vessel?”question.
  • 2. Interaction with other energy systems, collaborating in the same task of energy management in such a way to decide which is the best energy source/system to use to heat the vessel. For example, natural gas boiler, solar thermal system, electric resistances, . . . .
  • 3. The integration with a communication network, for example the internet e.g. world wide web (WWW), allows to access a global level of information, exterior to the vessel and the house where it is installed in like actual and provisional meteorology as well as other data relevant to its operation.
  • 4. The integration with an external communication network allows the vessel to interact with a centralized system that can retrieve history energy consumption patterns, diagnose malfunctions and perform maintenance procedures remotely as well as interact and condition the operating procedure of the vessel by interacting in the decision of the energy to use and when to use it, etc. . . .
  • 5. Interaction with energy production equipments that see advantages in using the energy storage/buffer characteristics of the vessel of the embodiments hereby described. For example, to reduce transients in the operation of micro-CHP (combined heat and power boilers) and other energy producing equipment.
  • 6. Use of the electrical energy produced by co-generation boilers and micro co-generation boilers, photo-voltaic cells, and/or other electricity producing systems to heat the water in the vessel. This way, the heating speed is increased and the auto-consumption of the produced electric energy is promoted.

In terms of construction, the vessel is composed of several sub-volumes. By integrating each smaller sub-volume in a single vessel the system is more compact. Each sub-volume has independent heat exchangers that promote the energy exchange between the primary circuit and the fluid that is inside the vessel.

The sub-volumes can be, in a preferred embodiment, radially or linearly arranged, as shown in FIG. 4. The radial topology is thermodynamically more efficient since the surface between each sub-volume and the outside is minimized. This topology is characterized by large heat transfer surfaces between each sub-vessel level. These levels are arranged with a decreasing temperature with the radial distance to the center. Since the most external sub-volume is at a lower temperature, the heat losses are minimized. In the radial layout, the connections between each sub-volume are more complex to design and the overall vessel is more complex to build. The radial construction does not require 360°—embodiments may be fully concentrical or only partially so, arranged as radial ‘sectors’.

The linear arrangement is not as thermal efficient as the radial arrangement. However, it allows a faster, simpler and more economical construction and maintenance.

Each sub-volume has one or more energy transfer systems which can be located inside or outside each sub-volume. These energy transfer systems can be connected to other equipments that supply energy to the vessel. For example, boilers, solar panels, photo-voltaic cells, co-generation or micro co-generation boilers, . . . .

Embodiments may comprise one or more interconnected sub-volumes, or optionally some additional not interconnected sub-volumes, of small dimensions with independent energy exchanger mechanisms and integrated control.

In some embodiments each sub-vessel is insulated from the other sub-vessels.

Embodiments may comprise integrated connection of sub-volumes of reduced capacity with the purpose of storing energy for domestic or industrial applications.

In some embodiments each sub-volume may have one or more system for energy transfer independently and holistically controlled.

In some embodiments the energy exchanger mechanisms can be hydraulic, electric or using other technology.

Embodiments may comprise integrated radial or linear sub-vessels;

Embodiments may comprise radial volume system layout as a way to promote efficiency, simplicity, more economic construction and maintenance, and system compactness.

Embodiments may comprise intelligent system control with forecast of the energy supply as well as user energy demands;

Embodiments may comprise connection of the vessel to information networks, as domotics domestic, industrial or others;

Embodiments may comprise connection of the vessel to communication networks as a way to access generic and relevant decision support information for the optimization of the operation of the vessel;

Embodiments may comprise connection of the vessel to communication networks as a way to interact with other services such as monitoring, control, diagnostic and maintenance services.

Embodiments may comprise choosing in each moment the energy source to heat, or cool, the vessel contents by an appropriate control and communication strategy.

Embodiments may comprise communication between the vessel and different thermal and electric energy producing equipments (such as boilers, solar panels, photo-voltaic cells, electric resistances, co-generation and co-generation boilers, . . . ).

Embodiments may comprise control system as an integrated module or an external add-on module to the vessel.

It is to be noted that the energy exchanger is configured in the present figures for co-current or parallel flow, but counter-current flow is also an alternative.

The disclosure is reversible in terms of cold or hot operation. For example, for cold operation, the volume closest to the outlet will be the volume with the lowest target sub-temperature. Water is disclosed as an exemplary fluid, but other liquid fluids may be used for heating/cooling in the system. The volumes being interconnected in series means that the volumes are connected in a ‘daisy-chain’ or where the output of a precedent volume is connected to the output of a subsequent volume.

The above described embodiments can be combined.

The following dependent claims set out particular embodiments of the invention.

Claims

1. A controllable variable inertia water storage system for heating and/or cooling, comprising: wherein the control module comprises data connections, local or remote: wherein the data connections are one or more of domotics data connection, machine-to-machine—M2M—data connection, service providers' data connection, and/or energy providers' data connection.

a. a plurality of water storage volumes for storing and heating water, these being either a vessel comprising sub-volumes or independent multiple vessels, said volumes being interconnected in series;

b. a water inlet and outlet connect to the interconnected volumes;

c. an independent water heater and/or cooler for each volume;

d. a control module configured to operate the method of any of the claims 18-22.

a. for providing information on the system status and for receiving user configurations; and/or

b. for exchanging heat availability with heat source devices;

2. The system according to claim 1, wherein said independent water heater and/or cooler for a volume is a heat exchanger for exchanging heat with a fluid fed by a heat or cool source.

3. The system according to claim 2, wherein two or more of said volumes comprise, as said independent water heater and/or cooler, heat exchangers for exchanging heat with fluid fed by the same source of heat or cool.

4. The system according to claim 1, wherein said source of heat or cool is a boiler, thermal solar panel, electric heater, combined heat and power cogeneration unit.

5. The system according to claim 1 comprising further volumes which are not interconnected with said interconnected volumes, said further volumes comprising independent water inlet and outlet connections.

6. The system according to claim 1, wherein said further volumes each comprises a water heater and/or cooler that is independent from the water heaters and/or coolers of said interconnected volumes.

7. The system according to claim 1, wherein said volumes are thermally insulated, in particular between said volumes.

8. The system according to claim 1, wherein the volumes are arranged linearly or radially, in particular concentrically.

9. The system according to claim 1 further comprising one or more additional independent water heaters and/or coolers for each volume.

10. The system according to claim 1, wherein the serial interconnections between volumes are arranged such that water stratification by temperature is promoted.

11. The system according to claim 1, wherein the serial interconnections between volumes comprise flow deflectors such that the disruption of water stratification by temperature is minimized.

12. The system according to claim 1, wherein the control system can interact with services facilitated by other entities, namely “cloud based services” or other proprietary services and networks, such that when integrated in a domotics system, the vessel can communicate with other equipments such as outside meteorological devices as well as work together with other house heating devices and other/appliances.

13. The system according to claim 1 adapted for connection to the Internet so that the system can take advantage of “cloud-based” M2M Machine-to-Machine service, in particular usage data collection for service providers and end-users, firmware upgrades, integration with intelligent grid management systems.

14. The system according to claim 1, wherein the control system is an integrated part of the vessel or as an external add-on to the vessel.

15. The system according to claim 1, wherein the control system is configured to determine which sub-volume to heat, or cool, and with which energy source, by relying on instantaneous as well as provisional computed data based on the history of energy consumption, energy availability and other data pertinent for its operation, in particular for example, meteorological forecasts, user or external agents needs and preferences.

16. The system according to claim 1, wherein the control system is configured to determine energy source to use based on availability, demand and user, or agent preferences, wherein the availability and demand are accessed by the sensor groups and the user, or agent, preferences are known from the user interface as well as from the communication connection described.

17. The system according to claim 1, wherein the control system is configured to:

a. by interacting with other devices inside the house, extend the reach of the vessel energy monitoring and control, optimizing its operation; also to control and monitor the vessel by using other domotics integrated components from the house;

b. by communicating with a domotics network, collect data such as inside and outside house temperature, occupancy, and other occupants habits and adjusting the behavior of the vessel accordingly, i.e. adjusting to weather, occupancy;

c. by communicating with other energy systems, cooperate in energy management in such a way to decide which is the best energy source and/or system to use to heat the vessel;

d. connect with a communication network, for example the internet e.g. world wide web (WWW), to allow access to information, exterior to the vessel and the house where it is installed, in particular actual and provisional meteorology;

e. integrate with an external communication network allowing the vessel to interact with a centralized system that can retrieve history energy consumption patterns, diagnose malfunctions and perform maintenance procedures remotely as well as interact and condition the operating procedure of the vessel by interacting with the control system;

f. interact with energy production equipments to complement the characteristics of the vessel, in particular to reduce transients in the operation of micro-CHP (combined heat and power boilers) and/or other energy producing equipment.

g. use the electrical energy produced by co-generation boilers and micro cogeneration boilers, photo-voltaic cells, and/or other electricity producing systems to further heat the water in the vessel.

18. A method for heating and/or cooling water utilizing the system of claim 1 comprising the steps of:

a. defining target sub-temperatures for each volume, wherein said target sub-temperatures are sequentially higher for each volume, in the direction of the water flow from inlet to outlet; and wherein the target sub-temperature of the volume connected to the outlet is the target temperature of the water to be supplied;

b. increasing, the target sub-temperatures in predefined periods or periods of forecasted higher demand, and, inversely, decreasing the target sub-temperatures in other predefined periods or periods of forecasted lower demand;

c. heating the volumes up to the target sub-temperatures, when the system user indicates so or when a predefined source of heat is available.

19. The method according to claim 18 further comprising limiting the water temperature of each volume by controlling the heating with user-defined minimum and maximum temperature limits for each volume.

20. The method according to claim 18, wherein the step b) of heating the volumes comprises first heating up to a predefined number of volumes that are closest to the water outlet; and sequentially heating up to a predefined number of other volumes that are next closest to the outlet, until all volumes reach the target sub-temperatures.

21. The method according to the previous claim 20, wherein the step b) of heating the volumes comprises first heating the volume that is closest to the water outlet; and sequentially heating the other volumes, one by one, that are next closest to the outlet, until all volumes reach the target sub-temperatures.

22. The method according to claim 18, wherein the step b) of heating the volumes comprises first heating a predefined number of volumes that have the larger differences between current temperature and target sub-temperature; and sequentially heating predefined number of volumes that then have the larger differences between current temperature and target sub-temperatures, until all volumes reach the target sub-temperatures.