DE102014200646A1 - A method of controlling a cooling or heating capacity for a multi-source heating / cooling system - Google Patents

Abstract

The invention relates to a method for controlling a heating / cooling system with at least one source for providing a cooling and / or heat output for at least one heat sink, in particular a room of a building, a. wherein in a first step a request of the at least one heat sink for a heat output or cooling capacity is detected, b. wherein in a second step at least one boundary condition of the at least one source is detected, and c. wherein in a third step, depending on a strategy, an operating state of the at least one source is determined.

Description

The invention relates to a method for controlling a cooling or heat output according to claim 1 and a control device for carrying out the method according to claim 15.

State of the art

It is known in the art to use various heat sinks, e.g. Room of a building to forward different temperature requirements to a control unit. The control unit determines an operating parameter for the heat source or cooling source and controls the source accordingly, so that the heat sink is supplied with the desired heating or cooling capacity. In modern heat-cooling systems for supplying rooms with heat output or cooling capacity different heat sources or cooling sources are used to generate the heat and the cooling capacity. For example, a heat system as a heat source can have a solar system, a heat pump, a gas boiler or an electric heater. In previous systems, the heat sources are independently controlled to provide the heat output or cooling capacity needed for the heat sinks.

Disclosure of the invention

The object of the invention is to provide an improved method for operating a heating / cooling system with at least one source for supplying at least one heat sink with the desired heat output or cooling capacity.

The object of the invention is achieved by the method according to claim 1 and by the control device according to claim 15.

Further advantageous embodiments are specified in the dependent claims.

An advantage of the method described is that the sources are used according to their boundary conditions and depending on a selectable strategy in such a way that the heat sinks are supplied with a heat output and / or a cooling capacity. In a first step, a request of the heat sinks is detected, in a second step, at least one boundary condition of the at least one source is detected, and in a third step, depending on the strategy, an operating state of at least one of the sources is determined in order to heat sink the heat sink. or to provide heat output. In the second step, boundary conditions of at least two sources are preferably detected and taken into account in the third step in order to determine the operating state of at least one source, depending on the strategy.

In one embodiment, the second step senses at least one source as the operating condition, whether the source is in heating mode or in cooling mode, and wherein the third step determines whether the operating status of the source is dependent on the boundary conditions of the sources and the operating status of the source will be changed. Thus, an optimal adjustment of the operating state of the source or sources can be achieved to provide the heat sink with the desired heat or cooling capacity.

In one embodiment, the desired strategy is to increase the heat and / or cooling capacity, e.g. To provide cost-effective or efficient or with low exhaust emissions. In this case, for example, diagrams, characteristics or formulas are stored, which describe the operation of the sources depending on the desired strategy. From a comparison of the diagrams, characteristics and formulas it can be determined which of the sources can best deliver which heat and / or cooling capacity according to the desired strategy. For example, it may be advantageous to provide the heat or cooling power provided by a heat sink up to a desired temperature from the first source and above the desired temperature from a second source. In addition, it may be advantageous to provide a short-term and fast supply of the heat sink with the desired cooling and / or heat output with a first source and then a longer-term supply of the heat sink with a cooling and / or heat output from a second source.

In a further embodiment, two or more heat sinks can be provided, which are supplied by one or more heat sources with cooling and / or heat output. Depending on the boundary conditions of the sources, it may be advantageous, for example, to supply a heat sink from one source with a heat output and the other heat sink from another source with a heat output independently of the requests and boundary conditions of the heat sinks. In addition, it may be advantageous if one heat sink needs a heat output and the other heat sink requires a cooling power, for example to supply both heat sinks with a source with heat or cooling capacity. In addition, it may also be advantageous to provide both heat sinks with different sources with the heat output or with the cooling capacity.

An advantage of the method described is that the possibilities of the individual sources are optimally used depending on the requests and boundary conditions of the heat sinks or the heat sink according to the desired strategy.

In one embodiment, as a request of the heat sink, a cooling capacity or a heat output, in particular a desired room temperature, is taken into account in the control of the heat sources.

In one embodiment, a desired air humidity, in particular a range or a lower limit or an upper limit for a desired air humidity in the control of the heat sources is considered as a request of the heat sink.

In a further embodiment, the heat sink is embodied, for example, in the form of a room in a building, and the boundary condition is an outside temperature of the building and / or the weather, in particular sunshine, i. a direct solar radiation on a building wall or a window and / or a time of day and / or a season and / or averaged over a fixed period of time outside temperature and / or a current internal temperature and / or humidity in the room considered. At least one of these boundary conditions, in particular at least two of these boundary conditions and advantageously more than two of these boundary conditions can be taken into account in order to perform an optimal selection or control of the two sources for supplying the room with the required heat and / or cooling capacity.

Characteristics, diagrams or formulas are laid down for the abovementioned boundary conditions with which, depending on the boundary conditions of the heat sinks, the parameters, in particular the boundary conditions of the sources, can be determined as a function of the boundary conditions. Thus, an optimal adjustment of the utilization of existing sources for the provision of cooling and / or heat output is possible.

Depending on the chosen embodiment, it is considered as a constraint whether a source can provide cooling power and / or heat output.

In one embodiment, as a boundary condition for the sources, a characteristic curve and / or a characteristic map and / or a formula for providing the cooling and / or heat output as a function of at least one parameter is provided, the parameter being the following group: cost, efficiency , Exhaust gas production, outside temperature, time of the day, season, outside temperature. In this case, an operating point of the source, in particular the operating mode heating or cooling can be specified. By using at least one of these parameters, it is possible to optimize the utilization of the power of the sources.

In another embodiment, requests and / or boundary conditions of the heat sink are taken into account to decide whether a request for heat output or cooling power is sent to the heating / cooling system. In a further embodiment, boundary conditions of the sources are considered in order to determine an operating point, in particular an operating mode of at least one of the sources, depending on the request and to supply a cooling capacity and / or a heat output to the heat sink. In this way, a two-stage process is provided, with which an optimized provision of heat and / or cooling capacity is possible.

In a further embodiment, the boundary conditions and / or requests of the heat sink and / or the source are taken into account with a factor. In this way, it is possible to take into account the various requests and boundary conditions of the heat sinks and / or the sources so that an optimal utilization of the sources according to the desired strategy is possible, and also optimal provision of the refrigeration and / or heat sinks desired by the heat sinks Heat output is achieved.

In one embodiment, the sources are connected to the heat sink via a hydraulic piping system, taking into consideration boundary conditions of the piping system, in particular the presence of valves, mixers, the usability of piping in one or two directions, an operating mode of at least one of the sources and a mode of operation of the piping system for supplying the heat sink with heat or cooling power.

Depending on the chosen implementation, two types of sources can be used. The first type of source is configured to operate in either a heating mode or a cooling mode. The second type of source is configured to operate in a heating mode and in a cooling mode.

The invention will be explained in more detail below with reference to FIGS. Show it

1 a schematic representation of a building with several rooms, and

2 a schematic representation of a system for providing heat and / or cooling capacity.

1 shows a schematic representation of a building 1 in which several rooms 2 . 3 . 4 . 5 . 6 . 7 are provided. Each room represents a heat sink, ie for each room is of a heating / cooling system, ie of a thermosystem 8th depending on the request of the heat sink heat output or cooling capacity provided. The heating system 8th is for example in a basement of the building 1 arranged and has a first, a second and a third source 9 . 10 . 11 on. The three sources 9 . 10 . 11 represent thermal systems with which heat and / or cooling capacity can be generated. For example, the first source 9 a thermal solar system, the second source 10 a heat pump and the third source 11 to be a gas boiler. Each of the sources 9 . 10 . 11 has another controller 14 . 15 . 16 on, with which the operating point, in particular the operating mode eg cooling or heating of the sources 9 . 10 . 11 is controlled. There is also a control unit 12 provided with the other control units 14 . 15 . 16 the sources 9 . 10 . 11 communicates. The control unit 12 is also equipped with a memory 13 connected. In the storage room 13 programs, data, characteristics, diagrams and calculation methods are stored.

Depending on the selected embodiment, the control unit 12 Part of the thermosystem 8th especially one of the sources 9 . 10 . 11 or it may be in one of the rooms 2 . 3 . 4 be installed, for example in the form of a central controller in one unit. The control unit 12 can also be part of an external device, such as a mobile phone or computer.

In every room 2 to 7 can each have a sensor 18 and an input device 17 be provided. The sensor 18 is provided to measure, for example, the temperature and / or humidity in the room. The input device 17 is provided so that by a user of the room, for example, a desired room temperature and / or a desired humidity can be entered. The input device 17 is also adapted to the input data to the controller 12 forward.

Furthermore, each room can have a calculation unit 19 feature that in conjunction with the sensor 18 and the input device 17 stands. The calculation unit 19 is designed, for example, depending on the actual temperature of the room and / or the humidity of the room and / or by a user via the input device 17 desired temperature and / or desired humidity to determine a specific heat and / or cooling capacity or a temperature profile and to the control unit 12 forward. The calculation unit 19 can in the determination of the desired temperature, humidity or the determination of the desired heat or cooling capacity as a boundary condition of the room other parameters such as an outside temperature outside the room or outside the building, a weather, ie direct sunlight, rain, snow, clouds , take into account a time of day, a season and / or an average outside temperature in determining the desired temperature, humidity or the desired cooling and heating capacity.

Thus, the calculation unit 19 in each case for the corresponding heat sink, ie the corresponding room to calculate an optimal control of the temperature of the room or the heat sink supplied heat output or cooling capacity and to the control unit 12 to transfer. The calculation unit has this 19 over a second memory 20 , are stored in the characteristic curves, maps, calculation methods to a function of at least the current room temperature, the desired room temperature and at least one boundary condition such as the humidity in the room, the outside temperature, the weather, the time of day, the season, the average outside temperature Target temperature or a course of the target temperature or to determine a desired cooling capacity or heat output.

Depending on the chosen embodiment can be from any input device 17 each room a corresponding information and / or from each calculation unit 19 each room a corresponding desired cooling capacity or heat output to the controller 12 be transmitted. Depending on the chosen embodiment, the calculation units 19 also be waived.

2 shows a schematic representation of a control system with a thermal system 8th , the three sources 9 . 10 . 11 and that of the controller 12 to be controlled. Depending on the selected embodiment, more or fewer sources may be provided. As an example, there are three heat sinks 2 . 3 . 4 schematically represented, for example, represent the rooms of a building. Depending on the chosen design, more or fewer heat sinks may be provided. The operation is based on the first heat sink 2 explains, with the heat sinks 2 . 3 . 4 have the same facilities. The calculation unit 19 the first heat sink 2 detected, as already stated, via the input device 17 Inputs of a user, for example, a desired temperature, a desired temperature profile, a desired humidity or other specifications may have. In addition, the calculation unit records 19 over the sensor 18 as boundary conditions for the first heat sink 2 For example, the current room temperature, the current humidity, an outside temperature and other boundary conditions. The calculation unit 19 determined based on the available data request for a specific heat and / or cooling capacity for the first heat sink 2 , The request is sent to the controller 12 transmitted. This is the calculation unit 19 via a control line 26 with the control unit 12 in connection. The control unit 12 in turn is via a second control line 28 with the sources 9 . 10 . 11 connected. Depending on the chosen embodiment, the connection may also be wireless. In an analogous way are also calculated by the calculation units 19 the second and third heat sink 3 . 4 a request for a specific heat and / or cooling capacity to the controller 12 transmitted.

In a further embodiment, the input device 17 be waived, the desired temperature and / or humidity is preset, for example.

In a further embodiment, the calculation unit 19 be waived and the input of the user in the input device 17 be from the input device 17 as a request to the controller 12 transmitted. In addition, individual or all known boundary conditions of the heat sink 2 to the control unit 12 be transmitted.

In the storage room 13 of the control unit 12 is at least one strategy for operating the sources 9 . 10 . 11 stored. The strategy may be, for example, to provide the request of the heat sinks quickly, efficiently, inexpensively, with the highest comfort, at the lowest cost, with the lowest pollutant emissions, with the highest efficiency of the source.

In addition, the control unit 12 over an entrance 27 with additional data or boundary conditions such as the outside temperature, an average outside temperature, a season, an operating state of the first, the second and / or the third source 9 . 10 . 11 , a constraint for operating the source 9 . 10 . 11 provided.

For example, it may be at the entrance 27 to act around a sensor input. In addition, the entrance 27 the data is obtained externally, eg via an internet service.

The operating status of the source 9 . 10 . 11 For example, it may be a certain operating point or an operating mode such as a cooling operation or a heating operation. Depending on the embodiment selected, the source may be configured to operate only in a cooling mode or only in a heating mode. Furthermore, the source may be configured to operate in a cooling mode or in a heating mode.

As a boundary condition for the sources 9 . 10 . 11 Parameters can be taken into account that affect the operation of the source 9 . 10 . 11 influence or limit. For example, as a parameter in a solar thermal system, the weather, ie the presence of sunshine or a cloudy or outdoor temperature are taken into account. In addition, the efficiency can be taken into account with a heat pump as the operating state. Furthermore, for example, in the case of a source in the form of a gas boiler, the gas price can be taken into account. In addition, when using an oil heater, the storage tank or the oil price can be taken into account. In addition, for example, in the formation of a source as a thermal energy system can be considered whether a power is required instead of the heat or cooling capacity.

Each of the sources 9 . 10 . 11 can directly or via switching valves, mixers, pumps with hydraulic lines with a heat exchanger 29 the heat sinks 2 to 7 be connected. In addition, it can be taken into account as a parameter for the heat sink, in which way the heat exchanger 29 is trained. For example, the heat exchanger may be in the form of a floor heating, a wall heating, a radiator or a heat exchanger with fan. Furthermore, the source 9 . 10 . 11 also be designed only as an electric heater or cooling device that in the heat sink 2 . 3 . 4 is arranged.

Alternatively, each of the existing sources may be associated with each of the existing heat sinks or with all the heat sinks simultaneously. Likewise, the existing sources may be associated with only a portion of the existing heat sinks. The existing hydraulics are taken into account by the strategy.

Each calculation unit 19 may have its own control method, depending on an input of a user or a predetermined target temperature regardless of boundary conditions according to predetermined procedures, characteristics and / or diagrams, a request for the supply of heat or cooling capacity by the thermal system 8th ,

In addition, the calculation unit 19 Limit values for the boundary conditions, in particular working conditions have. The limits are used to avoid frequent switching between different requests Switching between requesting a heat output or requesting a cooling capacity. In addition, for example, a time factor can be taken into account as a damping factor, which specifies that only after certain periods of time, such as 15 minutes, a renewed request to the control unit 12 may be transmitted.

A boundary condition for a heat sink is, for example, the type of heat exchanger present 29 the heat sink 2 . 3 . 4 , The heat exchanger 29 can, as stated above, be designed as a radiator, as underfloor heating, as an air heater, as an electric heater or as an electric cooling or as an electrical air conditioner. Depending on the existing conditions, the calculation unit determines 19 for example, as a request a certain water temperature, for operating the underfloor heating or the radiator of the heating / cooling system 8th should be delivered. The calculation unit 19 thus performs a local determination of an optimal request request.

The control unit 12 on the other hand, global control leads the one from the thermosystem 8th provided heat output or cooling capacity. In this case, the requests are at least one, preferably all heat sinks and the operating conditions of the sources 9 . 10 . 11 considered, for example, to determine an operating state of at least one source, in particular of all sources or to perform a change in the operating state of the sources or at least one source. A change in the operating state may be, for example, that a source is switched from a heating mode to a cooling mode.

The sources are used in accordance with the boundary conditions and depending on the given or selectable strategy in such a way that the heat sink is supplied with a desired heat output and / or a cooling capacity. In this case, a request of the heat sink is detected. In addition, boundary conditions of the two sources are detected and, depending on the strategy, an operating state of at least one source is determined in order to supply the heat sink with a cooling or thermal power. For this purpose, corresponding characteristic curves, diagrams and / or calculation methods are in the memory 13 which determine the operating state of the source depending on the boundary conditions of the source and the request of the heat sink.

For example, it is detected by at least one source as the operating state whether the source is in heating mode or in cooling mode. Then, depending on the boundary conditions of the sources and the operating state of the source, it is decided whether the operating state of the source is changed or not. In this way, all sources can be controlled by the controller 12 be checked and optimally controlled. Thus, an optimal adjustment of the operating state of the source or sources can be achieved to provide the heat sink with the desired heat or cooling capacity.

For example, thresholds for switching between providing heat power or providing cooling power, switching frequencies, a maximum or minimum operating temperature during the cooling mode or the source heating mode, etc. may be used as boundary conditions of the sources. In addition, the control unit 12 Limits for boundary conditions of the sources 9 . 10 . 11 , in particular working conditions of the sources. The limit values are used to avoid too frequent switching between different operating states, in particular switching between a heat output or a cooling output. In addition, for example, a time factor can be taken into account as a damping factor, which stipulates that only after certain periods of time, such as an hour or a day between a cooling mode and a heating mode, the source may be switched back and forth.

Furthermore, as a boundary condition, the control unit 12 Use a time-averaged outdoor temperature that determines whether a source operates in a heating mode or in a cooling mode. For example, at an outdoor temperature averaged over a day that is above a predetermined reference value, at least one source may be switched from a heating operation to a cooling operation.

The control unit 12 can pursue various strategies to provide a desired heat or cooling capacity for at least one heat sink. The strategy can be predetermined or selected or set by a user using an input device. The strategy may take into account the type of source, boundary conditions of the sources and / or boundary conditions of the thermosystem, such as the structure of the hydraulic line system, to control the operating state of at least one source.

For example, a majority decision can be used as a strategy. In this case, depending on whether more sinks want a cooling capacity or a heating power, the at least one source or all sources are switched to a heating mode or a cooling mode. Another strategy may be the strategy of joint agreement. Thereby, an operating state of the source, i. switching from a cooling mode to a heating mode, or vice versa, is performed only when all the wells are in an altered mode, i. request a cooling capacity instead of a heat output.

Another strategy is to prioritize a selected operating mode. If, for example, the heat mode is prioritized, all sources are in a cooling mode and, for example, a temperature of 5 ° C is reached during the night, then the system automatically switches to a heat mode, to the thermosystem 8th protect against frost. In another embodiment, a strategy is selected that is dictated by the outside temperature. In this case, it is predetermined as a function of the outside temperature whether the at least one source is operated in a heating mode or in a cooling mode. To avoid too frequent fluctuations, for example, time-averaged outside temperatures or different switching points spaced by a few degrees Celsius are used to switch back from the cooling mode to the heating mode and from the heating mode to the cooling mode. For example, when an outside temperature of 23 ° C. is exceeded, a cooling mode is switched to a heating mode and an outside temperature of 17 ° C. is fallen below. The outside temperature can be averaged over one hour, for example. In addition, the distance between two switching points may also have a different value, for example 3 ° C. In addition, a strategy can be used that consists of a combination of the strategies described.

Furthermore, a strategy may be laid down in such a way that a source of a basic supply, such as e.g. a heat pump is provided, that another source is preferably used, e.g. a solar thermal plant and that a third source of rapid temperature change, e.g. a gas boiler is used. In addition, it can be provided that unneeded sources are used to generate electricity.

The described method has the advantage that the calculation unit 19 for each sink an optimal request to the control unit 12 transmitted. The control unit 12 knows the conditions of the available sources and their operating status. In addition, for the control unit 12 a strategy for operating the sources. This allows the controller 12 depending on the given strategy and the sources available, provide optimal provision of the heat or cooling capacity as a function of the requested heat or cooling capacity. This procedure optimizes the operation of the sources.

Claims (15)

Method for controlling a heating / cooling system with at least one source for providing a cooling and / or heat output for at least one heat sink, in particular a room of a building, a. wherein in a first step a request of the at least one heat sink for a heat output or cooling capacity is detected, b. wherein in a second step at least one boundary condition of the at least one source is detected, c. wherein in a third step, depending on a strategy, an operating state of at least one source is determined. The method of claim 1, wherein the second step detects at least one source as the operating condition, whether the source is in heating or cooling mode, and wherein at least one of the at least one source and the operating condition of the at least one Source is decided whether the operating state of the source is changed. Method according to one of the preceding claims, wherein the predetermined strategy is to provide the heat and / or cooling power cost and / or efficiently and / or with low exhaust emissions and / or with high comfort and / or as quickly as possible. Method according to one of the preceding claims, wherein as a request of the heat sink, a cooling capacity or a heat output, in particular a desired room temperature or humidity, in particular a range or lower limit or an upper limit for a desired humidity is used. Method according to one of the preceding claims, wherein an ambient temperature and / or the weather, in particular a direct sunlight and / or a time of day and / or a season and / or a time-averaged outside temperature and / or an internal temperature in the heat sink and / or a humidity in the heat sink taken into account. Method according to one of the preceding claims, taking into account as a boundary condition of the source, whether a source can provide a cooling capacity and / or a heat output. Method according to one of the preceding claims, wherein as boundary condition for the sources a characteristic curve, a characteristic field or a formula for the provision of the cooling and / or heating power is used as a function of at least one parameter, the parameter being the following: cost, efficiency, generation of exhaust gas, outside temperature, time of day, season, an average outside temperature, speed of provision, comfort. Method according to one of the preceding claims, wherein requests and / or boundary conditions of the heat sink are taken into account in order to decide whether a request for heat output or cooling power is sent to the heating / cooling system. A method according to claim 8, wherein boundary conditions of the sources are taken into account in order to determine an operating point, in particular an operating mode of at least one of the sources and to deliver a cooling capacity and / or a heat output to the heat sink, depending on the request. Method according to one of the preceding claims, wherein requests and / or boundary conditions of the heat sink and / or boundary conditions of the sources are taken into account with a factor, and wherein at least two requests and / or two boundary conditions of the heat sinks are taken into account in order to determine an operating mode of the sources. Method according to one of the preceding claims, wherein the at least one source are connected via a hydraulic line system with one or more heat sinks, wherein boundary conditions of the piping system, in particular the presence of valves, of mixers or the usability of lines in two directions are taken into account Establish the mode of operation of the sources and a mode of operation of the use of the pipe system of the heat sink with heat or cooling capacity. Method according to one of the preceding claims, wherein at least one second heat sink is provided, wherein inquiries and / or boundary conditions of the second heat sink are taken into account to decide whether a request for heat output or cooling power is sent from the second heat sink to the heating / cooling system and wherein boundary conditions of the sources are taken into account in order to establish an operating point, in particular an operating mode of the two sources and to deliver a cooling capacity and / or a heat output to the heat sinks, depending on the requests of the two heat sinks. Method according to one of claims 8 to 12, wherein temporally averaged boundary conditions of the at least one source are taken into account, depending on the request of at least one heat sink to determine operating modes of the sources and to provide a cooling capacity and / or a heat output to the heat sinks. The method of any one of the preceding claims, wherein the at least one source is configured to operate in either a heating mode or in a cooling mode or in a heating mode and in a cooling mode. A controller adapted to carry out a method according to any one of the preceding claims.

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