DE19756104C5 - Method for controlling the flow temperature of a central heating system or a heating circuit - Google Patents

Abstract

Method for regulating the flow temperature of a central heating system (2) or a heating circuit with arranged in different rooms, each with a decentralized individual room temperature controller, such as. B. a thermostatic valve (4) or the like having radiators (3), characterized in that, after a specifically controlled flow temperature change becomes effective, any changes resulting from the flow temperature change in the respective heating elements (3) absorbed from the supply network or given off to the environment are detected by temperature sensors (8) arranged on the radiators (3) and transmitted to a central evaluation unit (5) for evaluating the underlying change in flow temperature and, if necessary, for determining a subsequent change in flow temperature.

Description

The invention relates to a method for controlling the flow temperature of a central heating system or a heating circuit with arranged in different rooms, each having a decentralized individual room temperature controller, such. As a thermostatic valve or the like having radiators.

State of the art

From practice, methods are known in which the outside temperature, even taking into account heat storage effects through the masonry, is used as a reference. This has the disadvantage that the set flow temperature corresponds only very limited to the actual required flow temperature, since the outside temperature is only one possible factor that can affect the likely heat requirements of the user, and other possible factors are disregarded. In this respect, the outside temperature can only be regarded as an indication of possible, perhaps even likely heat demand curves.

In order to take better account of the heat demand characteristics, procedures have been developed in which the respective position of the individual thermostatic valves is used as a reference.

Such methods are for example in the DE 43 434 A1 and the DE 34 09 742 A1 known.

The disadvantage here is that corresponding sensors and lines are required for the detection of the respective position of the thermostatic valves. Due to this high cost of materials and installation costs during installation, the outside temperature is still used as a reference in practice, in large part, whereby the flow temperature is usually set higher than necessary, which is an unnecessary energy consumption.

task

The object of the invention is to provide a method for flow temperature control, which avoids the disadvantages mentioned and both inexpensive to apply or install is considered as well as the needs of each user.

This object is achieved by a method for controlling the flow temperature of a central heating system with arranged in different rooms, each having a decentralized individual room temperature controller, such. Example, a thermostatic valve or the like having radiators, which after taking effect of a controlled controlled flow temperature change any resulting changes in the respective absorbed by the radiators from the mains or delivered to the environment heat outputs of particular arranged on the radiators temperature sensors and to assess the underlying flow temperature change and optionally transmitted to a central evaluation unit for determining a subsequent flow temperature change. As a result, the individual heating requirements of the various radiator consideration is created, because it can be drawn conclusions on the different requirements situations of the respective radiator, since the effect of the flow temperature, ie the presence or absence of a resulting from the flow temperature change change the recorded or delivered Heat output and, where appropriate, the size of the change, is dependent on the valve position of the thermostatic valve. In this respect, no change means that the thermostatic valve is either closed, coming into the proportional range due to the effect of the flow temperature change or was already in the proportional range before the effect of the flow temperature change, which means that the space has at least the set and preselected temperature.

In contrast, the presence of a change due to the effect of the flow temperature change means that the thermostatic valve was fully opened before the impact and remains open during the impact. The heat demand is then greater than the heat provided, d. H. the flow temperature is too low (despite or due to the effect of the flow temperature change).

In this way, the amounts of heat requested by the users can be determined as coverable with the current flow temperature or not coverable, and it can be determined whether an increase in the flow temperature required or possibly a reduction of the flow temperature is possible or tried.

The magnitude of the change in relation to the underlying flow temperature change may be of interest for determining the transition from a fully open position of the valve to the throttled state (or vice versa), as compared to previous changes also related to the underlying flow temperature changes can be easily determined by means of interpolation, the optimum flow temperature value.

Preferably, changes of other sensor values, such. B. valve lift, pressure difference around the valve, thermostat position, heating medium temperature at the radiator inlet and outlet, room air temperature, etc. are detected by appropriately arranged sensors and for supplementary consideration in the assessment of the underlying flow temperature change and optionally in determining a further flow temperature change also to the central Evaluation unit to be transmitted, so that the actual circumstances and requirements even more considering evaluation of changes in the recorded or delivered heat outputs of the various radiators is possible.

According to the invention, the transmission of the values detected by the temperature sensors can be effected by at least one temperature sensor and a radio transmitter containing electronic heat cost allocators, so that by using already existing installations, an additional material and assembly costs are eliminated.

The transmission of the values detected by the temperature sensors or other sensors formed as passive surface-wave sensors can advantageously be carried out by interrogation by radio, so that an energy supply of the sensors is eliminated and thus no corresponding maintenance activities are required.

In a preferred method, the transmission of the values detected by the temperature sensors designed as active surface wave sensors or the further sensors can be transmitted by transmitting the values by radio, so that the transmission range can be increased and sufficient even in a multi-storey house, in a block of flats or the like.

According to the invention, the transmission of the detected values can be event-dependent and / or interval-based, for. B. at certain minimum changes, at certain times, etc., so that the transmission frequency can be adapted to the conditions and requirements in the specific application and unnecessary power consumption causing unnecessary transfers are avoided.

Preferably, the power supply of the active surface acoustic wave sensors by energy storage, such. As batteries, batteries or the like, or by power generators, such as. As solar cells, piezoelectric elements, pyroelectric elements, inductor device with magnet and electric coil, thermocouple, etc., or these components containing arrangements are made so that the most cost-effective for the specific application, power can be selected.

Also, when measured by means of a current-generating sensor, such. B. a piezoelectric element or the like, the transmission of the respective detected value by the value itself be activated, so that z. B. when a certain measured value is exceeded, the transmission is automatically activated and at the same time also supplied with energy.

According to the invention, at specific time intervals and / or when the central heating system is activated, a selectively controlled flow temperature change can take place for a check measurement of any resulting changes in the heat outputs taken up by the radiators from the pipe network or emitted to the environment, so that a regular check is made the flow temperature just set takes place or when commissioning the central heating system a requirement-oriented adjustment of the flow temperature is effected.

Advantageously, extreme values can be filtered out of the detected changes in the heat outputs taken up by the radiators from the line network or emitted to the environment, or an evaluation of the changes, for example, can be made. B. the frequency or size accordingly, so that on the one hand from misconduct resulting coated heat requirements can have no or only weak influence and on the other hand, a certain satisfaction limit z. B. depending on percentage or temperature differences can be adjusted.

In a preferred method, after reaching an adjustable upper temperature limit or lower limit regardless of the effects of the previous flow temperature change no further rectified flow temperature change done, so that regardless of exceeding a normal level or below a normal level sinking heat requirements, an over or under a certain flow temperature is avoided, which saves both energy and in extreme cases prevents damage to the central heating due to excessive temperatures or ensures minimum availability.

According to the invention can be carried out at a settable minimum or maximum number of detected changes in each of the radiators from the line network or delivered to the environment heat outputs no more rectified flow temperature change, so that one of the number of heat requirements dependent control for any further flow temperature increases or subsidence z. B. to ensure a certain actual existing minimum availability.

Preferably, the range between the last and the penultimate flow temperature change can be examined with narrower change steps, so that a rough classification of the suitable flow temperature range and then a more accurate determination of the optimum flow temperature takes place in different process sections first.

embodiment

In the following the method of the invention will be explained with reference to an embodiment of the invention shown in the drawing. The single figure shows a control device 1 for the flow temperature of a central heating system 2 with radiators 3 , as a decentralized individual room temperature control thermostatic valves 4 exhibit.

The control device 1 consists of a central evaluation unit 5 which is a radio transmitter / receiver 6 and on the radiators 3 arranged electronic heat cost allocators 7 , the temperature sensors designed as passive surface wave sensors 8th have and a mixing valve 9 for adjusting the flow temperature by mixing from a boiler 10 originating hot water from a return line 11 originating colder return water.

When commissioning the central heating system 1 and / or at certain time intervals is from the central evaluation unit 5 a targeted flow temperature change by controlling the mixing valve 9 caused. This change can be made both up and down. After the flow temperature change becomes effective, the temperature sensors are activated 8th a measurement of the respective of the radiators 3 received or delivered to the environment heat outputs by means of the radio transmitter / receiver 6 from the evaluation unit 5 be queried and compared with the respective corresponding values before the flow temperature change becomes effective. Depending on the setting of the evaluation unit 5 Then, a corresponding evaluation of the measured values and, where appropriate, the determination of a subsequent flow temperature change, which then also by controlling the mixing valve 9 is realized.

Depending on the control strategy z. B. first set a determination of the optimal flow temperature range, which is achieved with relatively large flow temperature change steps and only in a second section then takes place with smaller change steps, a determination of the exact optimum flow temperature. In the evaluation of the temperature sensors 8th detected measured values can z. B. other sensor readings are also taken into account, but it can also extreme measurements are less taken into account or taken entirely out of the evaluation or it can also be created a satisfaction profile in which it is determined that a certain percentage of sufficient heating effects by the respective radiators 3 , Which show up by the absence of a resulting change, as is considered sufficient for an optimal flow temperature and inasmuch as no increase in the flow temperature is required.

Claims (14)

Method for controlling the flow temperature of a central heating system ( 2 ) or a heating circuit arranged in different rooms, each having a decentralized individual room temperature controller, such. B. a thermostatic valve ( 4 ) or the like having radiators ( 3 ), characterized in that after effecting a specifically controlled flow temperature change any resulting from the flow temperature change changes of the respective of the radiators ( 3 ) absorbed from the mains or delivered to the environment heat outputs of the radiators ( 3 ) arranged temperature sensors ( 8th ) and for assessing the underlying flow temperature change and optionally for determining a subsequent flow temperature change to a central evaluation unit ( 5 ). A method according to claim 1, characterized in that changes of other sensor values, such. B. valve lift, pressure difference around the valve, thermostat position, heating medium temperature at the radiator inlet and outlet, room air temperature, etc. are detected by appropriately arranged sensors and for supplementary consideration in the assessment of the underlying flow temperature change and optionally in determining a further flow temperature change also to the central Evaluation unit ( 5 ). Method according to claim 1 or 2, characterized in that the transmission of the temperature sensors ( 8th ) detected values by in each case at least one temperature sensor and a radio transmitter containing electronic heating costs he ( 7 ) he follows. Method according to Claim 1 or 2, characterized in that the transmission of the temperature sensors formed by the passive surface wave sensors ( 8th ) or other sensors detected values by interrogation by radio. Method according to Claim 1 or 2, characterized in that the transmission of the temperature sensors formed by the active surface wave sensors ( 8th ) or the other sensors detected values by transmitting the values by radio. Method according to Claim 3 or 5, characterized in that the transmission of the detected values takes place on an event-dependent and / or interval basis, e.g. B. at certain minimum changes, at certain times, etc. A method according to claim 5 or 6, characterized in that the energy supply of the active surface wave sensors by energy storage, such. B. batteries, accumulators or the like. Method according to one of claims 5 to 7, characterized in that the energy supply of the active surface wave sensors or the energy storage by power generators, such as. As solar cells, piezoelectric elements, pyroelectric elements, inductor device with magnet and electrical coil, thermocouple, etc. or these components containing arrangements takes place. Method according to one of claims 3 or 5 to 8, characterized in that when measured by means of a current-generating sensor, such. B. a piezoelectric element or the like, the transmission of the respective detected value is activated by the value itself. Method according to one of claims 1 to 9, characterized in that at certain time intervals and / or upon activation of the central heating system ( 2 ) a selectively controlled flow temperature change for a taking place after the effect of the flow temperature change verification measurement of any resulting changes in each of the radiators ( 3 ) taken from the mains power supply or delivered to the environment heat outputs. Method according to one of claims 1 to 10, characterized in that from the detected changes of each of the radiators ( 3 ) extremes are recorded from the line network or delivered to the environment heat outputs or an assessment of the changes z. B. the frequency or the size is done accordingly. Method according to one of claims 1 to 11, characterized in that, after reaching an adjustable upper temperature limit or lower limit regardless of the effects of the previous flow temperature change no further rectified flow temperature change takes place. Method according to one of Claims 1 to 12, characterized in that, in the case of an adjustable minimum or maximum number of detected changes, each of the radiators ( 3 ) received from the mains or delivered to the environment heat outputs no further rectified flow temperature change takes place. A method according to claim 12 or 13, characterized in that the range between the last and the penultimate flow temperature change is examined with tighter change steps.

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