NL2020263B1 - Modular heating system for a home - Google Patents

Abstract

The invention relates to a modular heating system for a home, comprising a first module, arranged for heating water and a second module, adapted for ventilating and / or heating, for example, a room exit, the first module and the second module are arranged to be interconnected.

Description

Modular heating system for a home

The present invention relates to a modular heating system for a home. The invention also relates to the use of a modular heating system for heating and / or cooling a home. The invention further relates to a method for installing a modular heating system for or in a home.

There are agreements and objectives worldwide that strive for clean energy supplies. For example, there is the "Energy Agreement for Sustainable Growth" in the Netherlands. This Energy Agreement is aimed, among other things, at making society and the economy more sustainable, whereby making energy supply more sustainable is an important pillar. Among other things, this focuses on energy efficiency in residential construction. An example of this is the "zero on the meter" (NOM) concept, which attempts to achieve that the energy consumption of a home is zero on an annual basis. In other words, a NOM home is a home where the amount of energy used is equal to the amount of energy that is generated. The realization of an energy-neutral home is possible in several ways. For this purpose, for example, solar panels are used for energy generation, a heat pump for providing home and tap water heating, whether or not in combination with insulation facilities for the home that counteract energy losses. However, the realization of "zero on the meter" for an existing home is a greater challenge than the realization of this for new homes, which can be anticipated during construction. In addition, it is a challenge to offer a space and cost efficient solution for applying the required components that is not at the expense of the performance of the system.

An object of the present invention is to at least partially overcome the above disadvantages.

To this end, the invention provides a modular heating system according to claim 1. With the modular heating system according to the invention, a system has been obtained which can contribute in a practical manner to obtaining an energy-neutral home or at least one more energy-efficient home.

Because the modular heating system according to the invention comprises a first and a second ready-for-use module which are arranged to be mutually coupled, a large degree of freedom in arranging the heating system in the home can be obtained. The first housing and the second housing can be mechanically coupled in several mutual configurations. The mechanical coupling can take place by means of known mechanical coupling means, such as, for example, clamps, screws, bolts and / or Velcro. For example, it is possible that the first housing comprises at least one mechanical coupling element and the second housing at least one counter-coupling element adapted for cooperation with the at least one mechanical coupling element of the first housing. The possibility of mechanical coupling ensures that the mutual positioning of the first module and the second module can be determined to a large extent freely. Therefore, depending on the available space for placement of the system, a desirable orientation of the first and second module in the available space can be sought. The first module and the second module can hereby be positioned both horizontally and vertically relative to each other. The system can for instance be placed on a surface or floor surface, but the system can possibly also be placed against a wall. It is also conceivable and possible here for the heating system according to the invention to be placed at an angle (thus) diagonally. It is conceivable in this case that the modules are mounted against an inside of a sloping roof or possibly fitted in a sloping roof. Non-limitative examples of the possible mutual and spatial positioning of the first and second module are shown in the accompanying figures. An additional advantage of the modular heating system according to the invention is that the installation of it is relatively simple, because the modules are practically ready for use. The installation only requires placing the modules against each other or near each other, whereafter the modules are mechanically fixed or at least mechanically secured with respect to each other, and whereafter or for which the modules are electrically coupled to each other. The modules can also be coupled to each other on the air side. Special craftsmanship is not required when installing. The system is arranged to realize electrical coupling between the first module and the second module, and in particular between the heat pump and the second control unit. The second control unit is, after all, arranged for controlling the heat pump. The first control unit and the second control unit are positioned in the second module and not in the first module, because in this way the electronic components can remain separate from hydraulic components, which benefits the safety and reliability of the system. In this way the chance that the electronic components can come into contact with liquid, such as for example the delivery water, is minimized by, for example, a leak. A further advantage of accommodating the first and the second control unit in the second module is that through multifunctional use of the thermal energy of the heat recovery unit, the first and second control unit can be cooled by (cold) air from the heat recovery unit . In this way it contributes to the energy efficiency, in particular the internal energy efficiency, of the system. By using the modular heating system according to the invention, on the one hand - by means of the first module - heated release water can be realized which can subsequently be used effectively in the home, and on the other hand - by means of the second module - the air temperature in at least a part of the home. be regulated. Examples of release water are (i) tap water, such as drinking water or shower water, and (ii) heating water for heating the home, usually through central heating (central heating). The heat pump for heating the delivery water is, for example, an air / water heat pump. The refrigerant may be any refrigerant known to those skilled in the art. The compressor and the condenser are preferably, but not necessarily, movably, and in particular pivotably, incorporated in the first housing such that the compressor and the condenser can be positioned in a preferred position irrespective of the positioning of the first housing and / or stay. With the compressor and condenser it is generally important that both components are used in a (upright) upright orientation, in order to be able to guarantee the correct functioning of both components. This means, for example, that if the first module and in particular the first housing is positioned under a slope, the compressor and the condenser can remain positioned in a preferred position, usually thus a (upright) upright position. However, it is also conceivable that the compressor and / or the condenser (permanently in a single position) are incorporated in the first housing, whereby the orientation of the compressor and / or the condenser cannot thus be changed. Typically, such a fixed orientation of the compressor and / or condenser with respect to the first housing forces the first housing to be placed in a predefined preferred position, for example horizontal, vertical or diagonal, in a home, depending on the relative orientation of the compressor and / or condenser relative to the first housing.

By using the heat recovery unit, at least one room can be ventilated in an energy-efficient way, and possibly heated or cooled. The second module is in particular designed to be linked to an (existing) ventilation system of a home, or a room departure. A further advantage of the modular heating system according to the invention is that no outdoor unit is required for the heat pump. The first fan which is arranged for sucking in air, and in particular outside air, is at least partially accommodated in the first housing, and is, like the further components of the system, preferably positioned inside the house. The modular heating system according to the invention can be used both in new-build or new-build homes and for existing buildings.

The first module is preferably adapted to be coupled, and in particular hydraulically coupled, to a water heating circuit for the home. The module can be connected both directly and indirectly to the water heating circuit of the house. A direct coupling means that the water heating circuit is directly connected to the condenser of the first module. An indirect coupling is understood to mean that the water heating circuit is coupled to the condenser of the first module through the intervention of at least one intermediate (heat transferring) liquid circuit. An indirect coupling can be particularly advantageous if heat delivered via the condenser first has to be stored in a heat buffer device before the heat is used efficiently. The first module is arranged for heating water, and in particular for supplying heat to water for the water heating circuit of the home. This may include the provision of heated water for radiators and / or convectors. The first module preferably comprises hydraulic connecting means for coupling the condenser to a water heating circuit for the home. The first module can herein for instance comprise an incoming liquid pipe and an outgoing liquid pipe, wherein each pipe is preferably provided with a coupling element for coupling the incoming and outgoing pipe with respectively an outgoing and incoming pipe of the water heating circuit of the house. The hydraulic connecting means are herein preferably at least partially flexible. In particular due to the movable nature of the compressor it is advantageous if the hydraulic connecting means are at least partially flexible. Among other things, this reduces the risk of wear of the hydraulic connecting means and the risk of leakage in the system.

In a possible embodiment variant of the modular heating system, the first control unit is integrated with the second control unit. An advantage of this is that only one control unit is required to control the various components of the system. This allows the system to be further simplified.

In a possible embodiment variant of the modular heating system, the first module comprises at least one support structure which is at least partially accommodated in the first housing and pivotally connected to the first housing for positioning the compressor and / or the condenser in a preferred position, preferably both , wherein a support platform of the support structure is adapted to support the compressor and / or the condenser, and wherein the support structure in a preferred position preferably spans a substantially horizontal plane. The supporting structure preferably also comprises one or more upright side walls connected to the supporting platform for bounding and securing compressor and / or condenser, wherein at least one side wall is pivotally (pivotally) connected to (a wall of) the first housing.

The at least one support structure can here be arranged for positioning both the compressor and the condenser and one of the components in a preferred position. If the support structure is adapted to position one of the said components in a preferred position, the first module preferably comprises a further support structure so that both components can be positioned in the preferred position. By using at least one support structure, it can be ensured in a relatively simple manner that the condenser and the compressor can be positioned and / or remain in the preferred position. The compressor and the condenser can, for example, be placed on the support structure, and in particular on the support platform. It is conceivable here that the support structure, and in particular the support platform, is provided with means for stabilizing and / or fixing the compressor and the condenser on the support structure. It is also conceivable that the compressor and the condenser are at least partially included in a part of the support structure, and in particular the support platform. It is advantageous if the supporting structure, and in particular the supporting platform, tension a substantially horizontal surface in a preferred position. This ensures that stable positioning of the compressor and condenser can be guaranteed. The support structure can, for example, be pivoted about an axis of rotation in the first housing, as a result of which the support structure can, for example, be pivoted under the influence of gravity to a preferred position, irrespective of the positioning of the first housing. The axis of rotation will generally extend in a substantially horizontal direction. The at least one support structure is preferably at least pivotable through an angle between -90 and 90 degrees, and preferably between -45 and 45 degrees, and more preferably between 0 and 45 degrees. The maximum pivot angle of the support structure with respect to the first housing is preferably limited. In this way, the modular heating system, and in particular the first module, can even be placed under an inclined slope whereby the chance of the heat pump operation, and in particular the compressor and condenser operation, being negatively influenced is minimized is becoming. In a possible further embodiment variant, the first module comprises at least one locking member for locking the position of the at least one support structure relative to the first housing. The support structure can be fixed in a preferred position by the use of at least one locking member. The support structure can, for example, be fixed in the preferred position after installation of the modular heating system. The at least one locking member can for instance be mechanically connected to the first housing, but it is also possible that the at least one locking member is mechanically connected to the at least one support structure. It is possible that the at least one locking member forms an integral part of the first housing or of the at least one support structure. It is also possible that the first module comprises a plurality of locking members for locking the position of the at least one support structure relative to the first housing.

In a possible embodiment variant, the evaporator is connected upstream by means of at least one flexible refrigerant line to the expansion valve and / or the condenser, and wherein the evaporator is connected to the compressor downstream by means of at least one flexible refrigerant line. Due to the freedom of movement of the compressor and the condenser relative to the first housing, the use of flexible refrigerant lines is advantageous for the durability and reliability of the system.

In a possible embodiment of the first module, the evaporator comprises an integrated heating circuit. The evaporator is designed for extracting heat from the extracted outside air by means of the refrigerant present in the evaporator. However, the intake of outside air can be of such a temperature that there is a risk that the evaporator freezes, which adversely affects the operation of the evaporator. The evaporator can therefore comprise an integrated heating circuit, so that freezing of the evaporator can be prevented and / or the evaporator can be defrosted if freezing has taken place.

In a possible embodiment variant, the second module is adapted to be coupled to at least one solar panel, and the second module comprises an inverter coupled to the first control unit and the second control unit, for the conversion of at least one solar panel coupled to the second module solar energy to electrical energy. The coupling of the modular heating system with at least one solar panel can further contribute to obtaining an energy-efficient system and / or obtaining "zero on the meter". The at least one solar panel can also be considered as part of the modular heating system according to the invention. The first control unit and the second control unit can here be arranged for controlling the inverter. It is also possible that the inverter is adapted to be coupled to a storage device for storing electrical energy. An example of this is a battery or a capacitor. It is possible that the second module comprises such an electrical energy storage device. It is also possible that the storage device is a separate storage device that may or may not be included in a separate housing that can be coupled to the modular heating system.

Preferably, the heat recovery unit comprises at least one filter for filtering the air flow to be passed through at least one airflow through the heat exchanger. Such a filter preferably relates to an air filter for filtering particles such as fine dust from the air stream. The use of at least one filter can, for example, contribute to a pleasant and responsible air composition of air in the home.

In a possible variant embodiment, the modular heating system according to the invention also comprises a third module, arranged for storing energy, comprising a third housing, at least one heat buffer device at least partially included in the third housing for storing heat generated by the first module and delivering heat to release water, in particular a water heating circuit of the house, the first module and the third module being arranged to be mutually coupled, such that the first housing and the third housing can be mechanically coupled, and the condenser and the at least one buffer device can be thermally coupled. The heat buffer device can for instance comprise a hot water storage, wherein heat can be stored in the buffer device which can be used at a later moment. An example of such a heat storage is a boiler, in particular an indirectly fired boiler. It is also possible that the buffer device comprises a buffer vessel. The use of a heat buffer device can contribute to the efficient use of thermal energy that is generated in the heating system. For example, supplying the buffer device with energy can be done at night. It is possible to use the buffer device as heat storage or as cold storage. When the buffer device is used as cold storage, this energy can be used to cool the home. The mechanical coupling between the first and the third housing can be obtained in the same or comparable manner as the above described mechanical coupling between the first and the second housing. An embodiment variant is possible in which the condenser is adapted to transfer heat from the refrigerant to an intermediate liquid medium, such as water, wherein the intermediate liquid medium is conducted via at least one line through at least one compartment of the heat buffer device, wherein at least one compartment is provided with at least one supply and at least one outlet for delivery water, and wherein the at least one compartment is partially filled with a phase transition material. An embodiment variant of the modular heating system is also possible, for example, wherein the heat buffer device comprises a plurality of possibly interconnected compartments, each compartment being partially filled with a phase transition material, and wherein each compartment is adapted to store heat emitted by the intermediate liquid medium, and for releasing stored heat to the release water. With such a configuration, it is possible to use the energy of, for example, the first compartment while a second compartment is being charged.

In a possible embodiment variant, the buffer device comprises a phase transition material, in particular a phase transition material with a phase transition temperature between 50 and 70 degrees Celsius. For example, a phase transition material is used with a phase transition temperature of 58 degrees Celsius. Through the use of a phase transition material, energy can be stored and used efficiently. Phase transition materials (in English: Phase Change Materials (PCM)) use the latent heat of a phase transition from the PCM to release melting energy during the solidification of the PCM and to absorb melting energy during the melting of the PCM, whereby PCM can be considered as a thermal battery. Because the melting heat of materials is much higher than the specific heat, a much higher specific energy density can be achieved by making use of latent heat than storage using sensible heat. This results in a more compact storage. Depending on the temperature level of heat / cold storage, a suitable PCM with an appropriate melting temperature must be found in order to store heat or cold for use at a later time. Typical examples of PCMs are paraffins, salt hydrates and acid fats. PCMs are usually incorporated in a plastic housing that as such forms a PCM panel. The heat buffer device can be provided with separate (loose) spheres or balls that are each filled with PCM.

In a possible embodiment variant of the modular heating system, each housing comprises at least one bottom panel and at least one upright side wall, wherein the housing of at least one module comprises a, preferably thermally and / or sound-insulating, closing element for being able to close off substantially completely of the housing. Being able to close off at least one module can, from a safety point of view, contribute to the safety of the modular heating system, since with such a configuration, for example, a child cannot come into physical contact with one or more components in the module. Also, substantially complete closure of at least one module can positively contribute to the aesthetic aspect of the modular heating system. The thermal closure of the module (s) can contribute to the insulation of the modular heating system, so that the risk of heat loss can be reduced. The use of a sound-insulating sealing element can make a positive contribution to the system because it can reduce the chance that a user of the home will be inconvenienced, for example due to noise from the heat pump.

The present invention also relates to the use of a modular heating system for heating and / or cooling a home according to an embodiment of the modular heating system described above.

The invention also relates to a method for installing a modular heating system for a home that has already been described above, comprising the mechanical coupling of the first housing and the second housing and the electrical coupling of the heat pump and the second control unit. The method can also comprise air-side coupling of the first and second housing. The method may also comprise hydraulically coupling the first housing and the third housing.

The invention will be elucidated on the basis of non-limitative exemplary embodiments shown in the following figures. Herein: figure 1 shows a schematic representation of a possible embodiment variant of a modular heating system according to the invention; figure 2a shows a first view of a schematic representation of a possible embodiment variant of a first module for a modular heating system according to the invention; figure 2b a second view of the first module as shown in figure 2a, figure 2c a third view of a simplified embodiment of the first module as shown in figures 2a and 2b; Figure 2d is a fourth view of the module as shown in Figure 2c; figure 2e a fifth view of the module as shown in figures 2d and 2e; figure 3 shows a schematic representation of a possible embodiment variant of a second module for a modular heating system according to the invention; figure 4 shows a schematic representation of a possible variant embodiment of a third module for a modular heating system according to the invention; figure 5a shows a schematic representation of a first possible arrangement of a modular heating system according to the invention; figure 5b shows a schematic representation of a second possible arrangement of a modular heating system according to the invention; figure 5c shows a schematic representation of a third possible arrangement of a modular heating system according to the invention; figure 5d shows a schematic representation of a fourth possible arrangement of a modular heating system according to the invention; figure 6 shows a diagram of the connections of the components in the first module; and Figure 7 is a diagram of the heat recovery unit in the second module.

Identical reference numbers in the figures refer to identical or corresponding parts.

Figure 1 shows a schematic representation of a possible embodiment variant of a modular heating system (1) according to the invention for a home. The embodiment variant of the modular heating system (1) shown comprises a first module (2), a second module (3) and a third module (4). The first module (2) is adapted to heat water and comprises a first housing (5) and a first fan (6) received in the first housing (5) for sucking in air, in particular outside air, and one in the first housing (5) received heat pump (7) for extracting heat from the air drawn in by the first fan (6), and delivering extracted heat to release water to be used in the home, such as tap water and / or heating water from heat to water. The heat pump (7) comprises a circuit in which a refrigerant can be pumped around, the circuit successively comprising an evaporator (8), a compressor (9), a condenser (10) and an expansion valve (11) in the flow direction of the refrigerant. The compressor (9) and the condenser (10) are herein movably accommodated in the first housing (5). That the compressor (9) and the condenser (10) can remain positioned in a preferred position irrespective of the positioning of the first housing (5) is shown in more detail in figures 2c-e. In the embodiment shown, the first module (2) is hydraulically coupled to the third module (4). However, it is also possible that the first module (2) comprises hydraulic connecting means for coupling the condenser (10) to a water heating circuit of the house. In the embodiment shown, the third module (4) is arranged for coupling to a water heating circuit of the house. The second module (3) is designed for ventilating and / or heating, for example, a room departure. The second module (3) comprises a second housing (12) and a heat recovery unit (13) accommodated in the second housing (12). The heat recovery unit (13) comprises a heat exchanger (14) for transferring thermal energy from a first air stream to be discharged from the house to a second air stream to be led into the house, a second fan (15) for generating the first air flow and passing the first air flow through the heat exchanger (14) and a third fan (16) for generating the second air flow through the heat exchanger (14). The second module (3) also comprises a first control unit (17) received in the second housing (12) and coupled to the heat recovery unit (13) for controlling the heat recovery unit (13) and one in the second housing ( 13) incorporated second control unit (18) for controlling the heat pump (7). The second control unit (18) is hereby electrically coupled to the water pump (7) of the first module (2). The second module (3) is adapted to be coupled to at least one solar panel (not shown. The second module (3) therefore comprises an inverter (19) for converting solar energy into electrical energy. The modular heating system (1) ) comprises a third module (4) adapted for storing energy The third module (4) comprises a third housing (21) and a buffer device (22) accommodated in the third housing (21). for storing heat generated by the first module (2) and delivering heat to a hydraulic circuit of a home.The first control unit (17) is adapted to control the buffer device (22). buffer device (22) and the first control unit (17) Furthermore, the first module (2) and the second module (3) are mutually coupled by mechanical coupling.The first module (2) is also mechanically coupled to the third module (4) . Furthermore, there is a hydraulic coupling between the condenser (10) of the second module and the buffer device (22) of the third module (4).

Figures 2a-e show schematic representations of a first module (2) according to the invention. Figures 2a and 2b both show a different appearance of the first module (2). Figures 2c-e each show a further view of the first module (2) as shown in figures 2a and 2b in a simplified embodiment, wherein the hydraulic connections between the components, among other things, have been omitted.

Figures 2a and 2b show the first module (2) comprising a first housing (5). The first housing (5) comprises a bottom panel (23), a plurality of upright side walls (24) and a top panel (25). The panels (23, 24, 25) comprise a plurality of feed-through openings (26) for feeding through, for example, electrical or hydraulic auxiliary components. The second module (3) comprises a fan (6) and a heat pump (7). The heat pump (7) comprises an evaporator (8), a compressor (9), a condenser (10) and an expansion valve (11). The evaporator (8) is connected by a flexible refrigerant line to the condenser (9) and to the compressor (10). The first module (2) further comprises a support structure (27) received in the first housing (5) for positioning the compressor (9) and the condenser (10) in a preferred position. In the embodiment shown, the support structure (27) comprises a support platform (27a) adapted to support the compressor (9) and the condenser (10). The supporting structure (27) and in particular the supporting platform (27a) herein extends a substantially horizontal plane. The support structure (27) is received by means of a rotatable connection (28) in the first housing (5), such that the support structure (27) is pivotable about an axis of rotation in the first housing (5).

Figures 2c, 2d and 2e show different positions of the first housing (5), the support structure (27) being in a pivoted state. The first module (2) comprises a locking member (29) for locking the position of the support structure (27) relative to the first housing (5).

Figure 3 shows a schematic representation of a possible embodiment variant of a second module (3) for a modular heating system according to the invention. The second module (3) is here substantially the same as the second module (3) as shown in the modular heating system (1) of Figure 1. The same reference numerals therefore refer to the same components.

Figure 4 shows a schematic representation of a possible variant embodiment of a third module (4) for a modular heating system according to the invention. The third module (4) is here substantially the same as the third module (4) as shown in the modular heating system (1) of Figure 1.

Figures 5a-d show possible arrangements of the modular heating system (1) according to the invention in a house (30). In the figures shown a suitable orientation of the first module (2), second module (3) and third module (4) has been found based on the available space for placing the system (1). In the embodiments shown, the third module (4) comprises two buffer devices (22) accommodated in the third housing (21). In all the arrangements shown, the modular heating system (1) is arranged in such a way that it provides inspection options for a user or a fitter because the modules (2, 3, 4) are positioned such that an inspection side of the module (2, 3, 4 ) are remote from a wall (32, 33) of the home (30). The first module (2) is mechanically coupled in both figures to both the second module (3) and the third module (3).

Figure 5a shows here a schematic representation of a first possible arrangement of the modular heating system (1). The first module (2), second module (3) and third module (4) are each positioned on a floor surface (31) of the house (30). The modules (2, 3, 4) here have a horizontal mutual positioning.

Figure 5b shows a schematic representation of a second possible arrangement of the modular heating system (1). The first module (2) and the third module (4) are herein positioned on the floor surface (31). The second (3) module is mechanically connected to the first module (2) and placed on top of the first module (2). In the embodiment shown, each module (2, 3, 4) is placed against a side wall (32) of the house.

Figure 5c shows a schematic representation of a third possible arrangement of the modular heating system (1). The first module (2), second module (3) and third module (4) are hereby positioned at an angle. In particular, the first module (2), second module (3) and third module (4) are positioned against a slanted inner side of a roof surface (33). The modules (2, 3, 4) again have a horizontal mutual positioning. The modules (2, 3, 4) can be attached to the inside of the roof surface (33) by means of known fixing means. The support structure (27) is pivoted in the figure with respect to the first housing (5). The supporting structure (27) is then substantially parallel to the floor surface (31).

Figure 5d shows a schematic representation of a fourth possible arrangement of the modular heating system (1). The first module (2), second module (3) and third module (4) are hereby positioned as on a slope as in Figure 5c, the first module (2), second module (3) and third module (4) being a slanted inner side of a roof surface (33) is placed. The modules (2, 3, 4) have a vertical mutual positioning. The support structure (27) is also pivoted relative to the first housing (5) in this figure. The support structure (27) is substantially parallel to the floor surface (31) such that the compressor and condenser positioned on the support structure (27) can remain in a preferred position regardless of the inclined positioning of the first housing (5).

Figure 6 shows a diagram, in particular a principle diagram, of the connections of the components in the first module. The diagram differs in particular from a conventional connection diagram of a heat pump and fan in that flexible refrigerant pipes are used between, for example, the evaporator and the expansion valve and between the evaporator and the compressor. Due to the freedom of movement of the compressor relative to the first housing, this is desirable and advantageous. The pipes for directly or indirectly connecting the condenser with a water heating circuit for the home are also flexible. Figure 6 also shows that the (outside) air drawn in via the first fan is filtered by means of an air filter before it is passed through the evaporator of the heat pump. Optionally, as also shown in Figure 6, the sucked in (outside) air can be pre-heated by means of a pre-heating circuit. Water is pumped through the preheating circuit and led through the evaporator or at least along an air line through which the sucked in (outside) air is led, whereby the water is also heated by means of an electric heating element. The process diagram shown in Figure 6 also shows the use of several temperature sensors (T) and pressure sensors (P), on the basis of which the second control unit (not shown) can control the heat pump.

Figure 7 shows a diagram, in particular a principle diagram, of the heat recovery unit in the second module. In the embodiment shown, the heat recovery unit comprises a (high efficiency) counterflow plate exchanger. The diagram shows that the air from the first air stream and the second air stream is filtered through separate air filters before they are passed through the heat exchanger. The temperature of the second air stream can be regulated here. The first airflow is removed from the house by means of a second fan and after filtering is passed through the plate exchanger (blown) and subsequently released outside the house. A third fan sucks at least a part of the second air stream after filtering through the plate exchanger, whereby any remaining fraction of the second air stream can be guided around the plate exchanger via a bypass valve. Optionally, the second air flow can be additionally heated by means of a post-heater before the second air flow is led into the home. The process diagram shown in Figure 7 also shows the use of several temperature sensors (T) and pressure sensors (P), on the basis of which the first control unit (not shown) can control the heat recovery unit.

It will be clear that the invention is not limited to the exemplary embodiments shown and described here, but that within the scope of the appended claims, countless variants are possible which will be obvious to those skilled in the art.

Claims (18)

A modular heating system for a home, comprising: a first module, arranged for heating water, comprising - a first housing, - a first fan, at least partially included in the first housing, for drawing in air, in particular outside air, - a heat pump at least partially accommodated in the first housing for extracting heat from the air drawn in by the first fan, and delivering extracted heat to release water to be used in the home, such as tap water and / or heating water, wherein the heat pump at least comprises: o a circuit in which a refrigerant can be pumped around, the circuit comprising successively in the flow direction of the refrigerant: an evaporator for extracting heat from the air drawn in by the first fan, in particular sucked in by the refrigerant outside air, a compressor for compressing the refrigerant, a condenser for he t transferring heat from the refrigerant to the release water, and an expansion valve, for reducing the pressure of the refrigerant, the compressor and condenser being movably, in particular pivotably, incorporated in the first housing such that the compressor and condenser can be positioned in a preferred position irrespective of the positioning of the first housing, and a second module, arranged for ventilating and / or heating, for example, a room exit, comprising: - a second housing, - an at least heat recovery unit partially included in the second housing, comprising: o a heat exchanger, for transferring thermal energy from a first air stream to be discharged from the house to a second air stream to be led into the house, o at least one second fan for the generating the first air flow and passing the first air flow through the heat exchanger, and o at least one third vent ilator for generating the second air flow and passing the second air flow through the heat exchanger, - a first control unit, at least partially received in the second housing and coupled to the heat recovery unit, for controlling the heat recovery unit, and - a second control unit for controlling the heat pump, at least partially accommodated in the second housing, the second control unit being adapted to be coupled to the heat pump, the first module and the second module being arranged to be mutually coupled, such that: the first housing and the second housing can be mechanically coupled, and - the heat pump and the second control unit can be electrically coupled. Modular heating system according to claim 1, wherein the first module is adapted to be coupled, in particular hydraulically coupled, to a water heating circuit for the home. Modular heating system according to claim 1 or 2, wherein the first module comprises hydraulic connecting means for coupling the condenser to a water heating circuit for the home. Modular heating system according to claim 3, wherein the hydraulic connection means are at least partially flexible. Modular heating system according to one of the preceding claims, wherein the first control unit is integrated with the second control unit. Modular heating system as claimed in any of the foregoing claims, wherein the first module comprises at least one support structure at least partially received in the first housing and pivotally connected to the first housing for positioning the compressor and / or the condenser in a preferred position , wherein a support platform of the support structure is adapted to support the compressor and / or the condenser, and wherein the support structure in a preferred position preferably spans a substantially horizontal plane. Modular heating system according to claim 6, wherein the at least one support structure is at least pivotable with respect to the housing over an angle between -90 and 90 degrees, preferably between -45 and 45 degrees, more preferably between 0 and 45 degrees. A modular heating system according to claim 6 or 7, wherein the first module comprises at least one locking member for locking the position of the at least one support structure relative to the first housing. A modular heating system according to any one of the preceding claims, wherein the evaporator is connected upstream by means of at least one flexible refrigerant line to the expansion valve and / or the condenser, and wherein the evaporator is connected to the compressor downstream by means of at least one flexible refrigerant line. Modular heating system according to one of the preceding claims, wherein the second module is adapted to be coupled to at least one solar panel, and wherein the second module comprises an inverter coupled to the first control unit and the second control unit, for the conversion of at least one solar panel coupled to the second module absorbed solar energy into electrical energy. A modular heating system according to any one of the preceding claims, wherein the heat recovery unit comprises at least one filter for filtering the air flow to be passed through at least one airflow through the heat exchanger. 12. Modular heating system as claimed in any of the foregoing claims, comprising a third module, arranged for storing energy, comprising - a third housing, - at least one heat buffer device at least partially included in the third housing for storing the first module generated heat and the release of heat to release water, in particular a water heating circuit of the house, the first module and the third module being arranged to be mutually coupled, such that: - the first housing and the third housing can be mechanically coupled and - the condenser and the at least one buffer device can be thermally coupled. A modular heating system according to claim 12, wherein the condenser is adapted to transfer heat from the refrigerant to an intermediate liquid medium, such as water, wherein the intermediate liquid medium is conducted via at least one conduit through at least one compartment of the heat buffer device wherein the at least one compartment is provided with at least one supply and at least one outlet for delivery water, and wherein the at least one compartment is partially filled with a phase transition material. Modular heating system according to claim 13, wherein the heat buffer device comprises a plurality of compartments, optionally interconnected, wherein each compartment is partially filled with a phase transition material, and wherein each compartment is adapted to store heat released by the intermediate liquid medium, and for delivering stored heat to the release water. The modular heating system of claim one of claims 13-14, wherein the phase transition material has a phase transition temperature that is between 50 and 70 degrees Celsius. Modular heating system according to one of the preceding claims, wherein each housing comprises at least one bottom panel and at least one upright side wall, wherein the housing of at least one module comprises a, preferably thermally and / or sound-insulating, closing element for inserting into essentially completely close off the housing. The use of a modular heating system for heating and / or cooling a home according to any one of the preceding claims. A method for installing a modular home heating system according to any one of the preceding claims, comprising mechanically coupling the first housing and the second housing and electrically coupling the heat pump and the second control unit.