NL2035999B1 - Heating system and transition device - Google Patents

Abstract

_15_ Heating system and transition device A heating system comprises a heat pump (10) which is coupled to a heat supply system (60) for heat exchange contact. The heat pump is connected to the heat emission device (60) by means of a transition device (300). The transition device comprises a device housing with primary connections (31,32) for connecting the supply (10A) and return (10R) lines of the heat pump (10) and secondary connections (37,38) for connecting a supply (60A) and return (60R) line of the heat emission device (60) respectively, and in addition an electronic connection (E3) which is coupled to the control device (E1) of the heat pump for the exchange of control information. The connections (31,32,37,38) form part of a hydraulic installation (50) within the device housing (30) which comprises one or more components from a group of pipework, pumps, expansion vessels, buffer vessels and accessories such as electronic control valves, electronic sensors, filters, separators and fittings. Fig. 2

Description

Heating system and transition device

The present invention relates to a heating system comprising a heat emission device which is coupled for heat-exchanging contact with a heat supply installation comprising a heat pump with a control device and with a supply and return pipe for the heat-carrying medium, which heat-carrying medium provides the heat-exchanging contact with the heat emission device. The invention further relates to a transition device for use in such a heating system.

A heating system of the type described in the introduction is widely used for heating homes and other buildings. The heat delivery system is usually formed by a network of radiators or a system of underfloor heating pipes through which water at an increased temperature is passed to deliver heat to the environment, thereby heating the space in question. The heat delivery system used for this purpose often comprises a natural gas or oil-fired central heating boiler or a comparable combustion device that is based on the combustion of a solid fossil fuel such as coal, brown coal, wood (pellets) and the like. In the context of an energy transition to more sustainable energy management, a heat pump as part of the heat delivery system has become increasingly popular in recent years, whether it is to serve as an independent device for the delivery of heat or in a hybrid configuration with a traditional combustion device.

A heat pump transfers heat by means of work and can be used to heat buildings. The heat mentioned can be extracted from the outside air or from water, often groundwater but also surface water or process or installation water. In the first case, one usually speaks of an air/water heat pump; in the latter case of a water/water heat pump. An advantage of a heat pump is an extremely high energy efficiency. Provided that it is correctly dimensioned and installed, a heat pump can supply considerably more heat than is consumed in energy for the supply of the work mentioned.

This energy is usually supplied by an electrically powered liquid pump, which circulates a heat-carrying fluid, usually referred to as a refrigerant, in a thermodynamic cycle of compression and evaporation, transferring heat through a heat exchanger to the heat rejector.

The amount of heat that can be supplied in this way depends on the technology used and the temperature difference that must be overcome. In optimum situations, the amount of heat delivered can be up to five times more than the power consumed by the pump. With a suitable heat pump, buildings can therefore be heated particularly efficiently and in an environmentally friendly way.

The thermodynamic process of a heat pump is therefore more complex than that of a conventional combustion boiler. Not only does the electric pump have to be correctly matched to the power to be delivered by the heat pump, but the hydraulic installation applied on the water side also proves to be of crucial importance for achieving optimum energy efficiency. If pipe segments are incorrectly dimensioned or appendages and other components are incorrectly applied, a large part of the energy gain that could be achieved can be negated. Given this complexity, it is therefore not surprising that many installed heat pumps function far from optimally and in the worst case consume more energy than they deliver. In such cases, the traditional installer or plumber often lacked the required expertise.

The present invention therefore aims, among other things, to provide a heating system that meets this requirement, at least to a significant extent.

To this end, a heating system of the type described in the preamble according to the invention is characterised in that the heat pump is connected to the heat emission device by means of a transition device, which transition device comprises a device housing in which primary connections are provided for connecting the supply and return lines of the heat pump and in which secondary connections are provided for connecting a supply and return line of the heat emission device, as well as an electronic connection that is coupled to the control device of the heat pump for exchanging control information, whereby the primary connections and the secondary connections form part of a hydraulic installation within the device housing that comprises one or more components from a group of pipework, pumps, expansion vessels, buffer vessels and appendages such as electronic control valves, electronic sensors, filters, separators and fittings. In this way, the hydraulic installation applied on the water side between the heat pump and the heat emission device is largely, if not completely, accommodated in a transition device that can be used as a standard module.

The components of the hydraulic system housed therein are correctly assembled in advance and interconnected, tailored to the heat pump used. The installer therefore does not need to worry about this and only needs to connect the connections provided for this purpose on the appliance housing of the transition device. No specialist knowledge is required for this. By thus assuming a fully, or at least largely standardised hydraulic system, it is greatly promoted, if not guaranteed, that the heat pump will deliver optimum efficiency.

Not infrequently, a heating system is accompanied by a provision for hot tap water, for example for a kitchen or bathroom. In order to also be able to provide for this, a special embodiment of the heating system according to the invention has the feature that a tap water provision is provided outside the transition device, in particular a boiler, whereby the device housing comprises connections for a hydraulic connection of a supply and return line of the tap water provision.

A-

In the absence of heat demand by the heat emission system or in the event of insufficient heat demand, there is a chance that the heat pump cannot get rid of the heat it needs to deliver and switches itself off, only to switch on again at even a small heat demand. This so-called "pinging" leads to reduced efficiency of the heat pump and also to premature wear, particularly of the pump. To prevent this, a buffer reservoir is preferably provided on the water side in which a surplus of heat can be stored, at least temporarily.

Such a reservoir can be included in the transition device, but then it may lead to a higher than ergonomically responsible weight. That is why a preferred embodiment of the heating system according to the invention has the feature that a buffer tank is provided outside the transition device between the primary connections, whereby the device housing comprises connections for a hydraulic connection of a supply and return line of the buffer tank. In this way, the buffer tank can be provided separately from the transition device, in order to spread its total weight and thus limit the load for an installer.

For a correct and optimal operation of the heating system, a balanced distribution of a primary circulation from the heat pump over the buffer tank and a secondary circulation through the heat emission device is important. With this in mind, a preferred embodiment of the heating system according to the invention has the feature that the primary circulation and the secondary circulation are hydraulically neutrally coupled to each other within the transition device.

In order to be able to monitor and possibly regulate, or even autonomously control, a correct mutual coordination between the said primary and secondary circulation, a further preferred embodiment of the heating system according to the invention has the feature that the hydraulic installation comprises at least one pump which maintains a primary circulation over the buffer tank between the primary connections and a secondary circulation over the heat emission device between the secondary connections, whereby a primary electronic flow sensor is included between the primary connections, an electronic signal of which can be obtained as a measure of the primary circulation, and whereby a secondary electronic flow sensor is included between the secondary connections, an electronic signal of which can be obtained as a measure of the secondary circulation.

The output signals of both sensors can be read manually to check the system, but can also be passed on to the control system so that the control system can correct them by means of controllable valves and/or control valves provided for this purpose in the hydraulic system.

In a special embodiment, the transition device offers a standardized hydraulic connection on the water side between a commercially available heat pump and an existing heat emission device. Preferably, an electronic coupling is also provided that actively couples the hydraulic installation with the control device of the heat pump. To this end, a further preferred embodiment of the heating system according to the invention has the feature that the electronic connection originates from an adapter unit within the transition device that electrically connects the hydraulic installation with the control device of the heat pump.

Preferably, the transition device offers the heat pump a complete system on the water side and electronically for coupling with the heat emission device, possibly supplemented externally with a buffer reservoir and/or a provision for hot tap water. In this context, a heating system according to the invention is therefore characterised in that the hydraulic installation within the device housing comprises a pipework in which at least a pump, an expansion vessel and various appendages such as electronic control valves, electronic sensors, filters, separators and fittings are included, and more particularly in that the heat pump is coupled to the heat emission device by means of only the transition device and, possibly, a buffer vessel provided externally of the transition device. In the latter case, the transition device offers, apart from interconnecting pipework, everything that is necessary to adequately and energetically optimally couple the heat pump to the heat emission device, such as a network of radiators and/or underfloor heating pipes.

The heating system according to the invention lends itself to various types of heat pumps. In this context, a special embodiment of the heating system according to the invention has the feature that the heat pump comprises an air/water heat pump or a water/water heat pump.

In light of the foregoing, a transition device for use in a heating system, comprising a device housing and a hydraulic installation at least substantially enclosed by the device housing, in which primary connections are provided for connecting the supply and return lines of a heat pump respectively and in which secondary connections are provided for connecting a supply and return line of a heat emission device respectively, and comprising an electronic connection for coupling to the control device of the heat pump for the purpose of control information, wherein the hydraulic installation within the device housing comprises one or more components from a group of pipework, pumps, expansion vessels, buffer vessels and appendages such as electronic control valves, electronic sensors, filters, separators and fittings.

The invention will be explained in more detail below by means of an exemplary embodiment and an accompanying drawing. The drawing shows:

Figure 1 shows an example of a heating system according to the invention;

Figure 2 shows an example of a transition device with a hydraulic installation for use in the heating system of Figure 1; and

Figure 3 is a rear view of the transition device of Figure 2.

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It should be noted that the figures are purely schematic and not always drawn to (the same) scale. In particular, for the sake of clarity, some dimensions may be exaggerated to a greater or lesser extent.

Corresponding parts are indicated in the figures with the same reference number.

Figure 1 shows a schematic representation of a heating system according to the invention in which a heat/air heat pump 10 is used as a heat supply device. The heat pump 10 is a commercially available device from a renowned brand, such as ACOND, Domusa, Nube or Mitsubishi

Electric. In this example, model R290 from the pro series of ACOND is used for use in a 100 dwelling for heating, cooling and preparation of hot tap water.

A preparation of hot tap water is realized by means of an indirectly heated boiler 20 with for example a capacity of 150-300 liters. The system is also equipped with a buffer tank 40. The whole also includes, in addition to its own control

E1 from the heat pump 10, an external control system E3,E6. Centrally in the home 100, a part of the control E6 is mounted with an operating screen on which the entire installation is visible and can be operated. At least a number of rooms in the home 100 are considered separate temperature zones and individual temperature sensors T1-T6 are placed in them for this purpose on which the relevant zone is controlled. These sensors T1-T6 are each connected separately or via a common bus to the control £3, £6.

The house is optimally insulated in terms of energy and thermal insulation according to the latest standards and is heated by means of a heat emission device 60. This device 60 can comprise one or more radiators, but will often, as here, at least partly be designed as underfloor heating in the form of a hot water pipe system integrated into a floor of a room. The heat emission device is connected to the heat pump 10 for heat-exchanging contact via a supply pipe and return pipe 60A,60R for hot water. A nominal hydraulic diameter of these pipes is DN32 and in this case a maximum heat pump capacity of the heat pump 10 is approximately 20 kW (dT=10K).

In accordance with the present invention, the supply and discharge lines 60A, 60R do not run directly to the heat pump, but are connected to a transition device 30, which is provided with connections 37, 38 intended for this purpose. The transition device 30 accommodates a complete or almost complete hydraulic installation 35 that hydraulically connects the heat emission device 60 to the heat pump 10. The device comprises an aluminium frame with a steel plating as a device housing of the order of 600x500x1300 millimetres (width x depth x height), in which all the necessary hydraulic and electronic components, including an electronic adapter unit £3, which electrically connects the hydraulic installation 50 to the control device E1 of the heat pump and to the other installation components

E6 in a building connects to achieve a correct and optimally performing heat pump installation. In the given example, only the buffer reservoir 40 and the hot water supply 20 are provided externally of the appliance 30, but the appliance 30 contains apart from that within a common appliance housing 35 the entire hydraulic installation 50 as shown schematically in figure 2 by way of example.

Figure 2 shows a heat pump installation with a high temperature air/air heat pump 10, an electric additional heater 70, a tap water boiler 20, a central heating buffer 40, a low temperature delivery group 60 and a high temperature delivery group 60". The low temperature delivery group 60 supplies, for example, underfloor heating in the home, while the high temperature delivery group 60' is intended for radiator heating.

Between the heat pump 10 and the heat emission device 60,60" in the dwelling 100 there is a hydraulic installation 50 which, in accordance with the invention, is fully incorporated within an independent transition device 30. The transition device is connected by means of conventional pipes to the heat pump 10, the boiler 20, the buffer tank 40 and the heat emission device 60,60". For this purpose, standard hydraulic connections 31-38 are provided externally on the transition device 30 for respective circulations of heated water or another suitable heat-carrying fluid. These connections are schematically indicated at the designated location in the overview of figure 2 and are located on the rear of the device 30 as shown in figure 3. After installation of heat pump 10, boiler 20, transition unit 30 and buffer tank 40, the installer only needs to connect the individual components 10,20,30,40 of the system to the transition unit 30 at the rear in the usual manner. This results in an extremely short installation time and error-free connection for an average installer because the transition unit has always been pre-tuned to the specific type, brand and model of heat pump 10, for example: - A low-temperature air/water heat pump with boiler valve, buffer connections and mixed emission group for underfloor heating or convectors; - A high-temperature air/water heat pump with primary pump, boiler valve, electric element, mixed emission group for underfloor heating and mixed emission group for radiators; - A low-temperature water/water heat pump with passive cooling exchanger, boiler valve, buffer connections and mixed emission group for underfloor heating or convectors; and/or - A low temperature water/water heat pump with active and passive cooling exchanger, four-pipe change-over emission group for underfloor heating and four-pipe change-over emission group for convectors.

The hydraulic installation of figure 2 comprises, in addition to an electrical connection box £3, within the transition device 30 all the usual hydraulic components necessary to connect the parts of the complete installation, such as flexible or rigid piping, a primary circulation pump P1, a set of secondary circulation pumps

P2,P2', an expansion vessel 80 of 18 litres and appendages such as various electronic control valves, various temperature sensors Tn and pressure sensors Pn, a dirt filter/air vent 91, a dirt separator with magnet 92, a boiler valve 93 (three-way) and various fittings. In addition, an electric heating element 95 is included in the installation to keep the whole frost-free at all times. In order to promote a correct balance between the circulation through the expansion vessel 40 and the heat emission device 60,60", a hydraulically neutral distribution bar 96,96' is provided between the primary circulation and the secondary circulation within the transition device 30. The primary circulation and the secondary circulation each comprise a flow sensor Q1 and Q2,Q2' respectively, with which these circulations can be measured and, if necessary, manually adjusted.

At the bottom of the appliance 30 there is a filling and draining facility and a drip tray 41 in which leaking water can be collected during maintenance and service. By means of a set of plastic adjustable feet 42 the appliance can be placed level, see figure 3. The appliance is vapour-tight insulated and is enclosed by a corrosion-resistant plating of durable (powder-coated) steel, stainless steel, plastic or aluminium, which is mounted on an aluminium base frame.

Because the transition device is a prefabricated product, assembly on site is quick and easy. The chance that the assembly will go well the first time is therefore many times greater than if the installer has to carry out the entire hydraulic installation on site independently. All components are integrated in the device: hydraulic, electronic and control technology. This means that installers spend less time on engineering and work preparation. As much as possible has also been prepared in terms of electrical engineering. The entire heat pump installation can be completed in one go without the need for additional specialists on site.

The transition device also enables installers to offer the heating system as standard packages. This makes the process from advice and sales to commissioning easier and clearer; both for the installer and for the end user. Due to its modest dimensions, the transition device also enables a compact and flexible installation of the heat pump in a residential or commercial building.

Although the invention has been explained in more detail above by means of only a single embodiment, it should be clear that the invention is by no means limited to this. On the contrary, many variations and manifestations are possible for an average skilled person within the scope of the invention.

Claims (10)

Conclusions: 1. Heating system, comprising a heat emission device which is coupled for heat-exchanging contact with a heat supply installation, comprising a heat pump with a control device and with a supply and return line for the heat-carrying medium, which heat-carrying medium provides the heat-exchanging contact with the heat emission device, characterised in that the heat pump is connected to the heat emission device by means of a transition device, which transition device comprises an appliance housing in which primary connections are provided for connecting the supply and return lines of the heat pump respectively and in which secondary connections are provided for connecting a supply and return line of the heat emission device respectively, as well as an electronic connection which is coupled to the control device of the heat pump for the exchange of control information, the primary connections and the secondary connections forming part of a hydraulic installation within the appliance housing which comprises one or more components from a group of pipework, pumps, expansion vessels, buffer vessels and appendages such as electronic control valves, electronic sensors, filters, separators and fittings. 2. Heating system according to claim 1, characterised in that a hot water supply is provided outside the transition device, in particular a boiler, the device housing comprising connections for a hydraulic connection of a supply and return line of the hot water supply. 3. Heating system according to claim 1 or 2, characterised in that a buffer tank is provided outside the transition device between the primary connections, the device housing comprising connections for a hydraulic connection of a supply and return line of the buffer tank. 4. Heating system according to claim 3, characterised in that the primary circulation and the secondary circulation are hydraulically neutrally coupled to each other within the transition device. 5. Heating system according to claim 4, characterised in that the hydraulic installation comprises at least one pump which maintains a primary circulation over the buffer tank between the primary connections and a secondary circulation over the heat emission device between the secondary connections, wherein a primary electronic flow sensor is included between the primary connections, an electronic signal of which can be retrieved as a measure of the primary circulation, and wherein a secondary electronic flow sensor is included between the secondary connections, an electronic signal of which can be retrieved as a measure of the secondary circulation. 6. Heating system according to one or more of the preceding claims, characterised in that the electronic connection originates from an adapter unit within the transition device which electrically connects the hydraulic installation to the control device of the heat pump. 7. Heating system according to one or more of the preceding claims, characterised in that the hydraulic installation within the appliance housing comprises a pipework in which at least one pump, an expansion vessel and various accessories such as electronic control valves, electronic sensors, filters, separators and fittings are included. 8. Heating system according to one or more of the preceding claims, characterised in that the heat pump is coupled to the heat emission device by means of only the transition device and, if necessary, a buffer tank provided externally to the transition device. 9. A heating system according to one or more of the preceding claims, characterised in that the heat pump comprises an air/water heat pump or a water/water heat pump. 10. Transition device for use in a heating system according to one or more of the preceding claims, comprising a device housing and a hydraulic installation at least substantially enclosed by the device housing, in which primary connections are provided for connecting the supply and return lines of a heat pump respectively and in which secondary connections are provided for connecting a supply and return line of a heat emission device respectively, and comprising an electronic connection for coupling to the control device of the heat pump for the purpose of control information, wherein the hydraulic installation within the device housing comprises one or more components from a group of pipework, pumps, expansion vessels, buffer vessels and appendages such as electronic control valves, electronic sensors, filters, separators and fittings.