NL8601022A - METHOD OF DEPENDING ON OPERATION RESP. SWITCHING OFF BOILERS. - Google Patents

Description

NL 33.315-dV / lb »=

Method for commissioning or operating in a controlled manner depending on the output. shutdown of boilers.

The invention relates to a method for commissioning or operating in a controlled manner depending on the power. switching off boilers, each of which is connected to a common collective discharge pipe and a collective return pipe of a heating network.

Methods for switching heat generators on and off are known, in which the necessary switching criterion is derived from the deviations of the supply temperature from the desired value (German patent 3,112,220).

10 This does not guarantee that every boiler can function as much as possible in its optimal working area.

The efficiency of a heating boiler generally decreases with decreasing boiler load, but there are heating boilers, where the greatest efficiency is achieved below full load, while at full load the efficiency is smaller again.

The object of the invention is to provide a method in which at least two boilers can be switched on or off optimally with regard to energy consumption.

To this end, the method according to the invention is characterized in that a total power balance is determined from the product of the maximum power known from each boiler and the continuously measured switch-on ratio of the burner concerned, and on the basis of this boilers are switched on or off. switched off.

The invention is explained in more detail below with reference to the drawing, in which an exemplary embodiment is shown. Two heating boilers HK1 and HK2, connected in parallel, are connected to a common collection discharge line 1 and a collection return line 2 of a heating network (not shown in more detail). A first three-way mixer 4 and a first circulation pump 5 are installed in a return line 3 of the first heating boiler HK1.

A first bypass line 6 runs from the three-way mixer 4 to a discharge pipe 7 of the heating boiler HK1, the - V λ - *? .-2 three-way mixer 4 is hydraulically switched so that in one end position it blocks the supply from the collector return line 2 and in the second end position the bypass line 6. When the boiler HK1 is not in operation, the supply 5 from the collective return line 2 is shut off and the circulation pump 5 is switched off. The second boiler HK2 is connected in parallel to the first boiler HK1 and the configuration is similar to that of the boiler HK1. In a return line 8 of the heating boiler HK2, a second three-way mixer 9 and a second circulation pump 10 are installed. A second bypass line 11 runs from the second three-way mixer 9 to a discharge line 12 of the heating boiler HK2, the second three-way mixer 9 being hydraulically connected analogously to the first three-way mixer 4 in such a way that it supplies the collector return line 2 in one end position and its second end position blocks the by-pass 11. If the HK2 boiler is not in operation, the supply from the collective return line 2 is shut off and the circulation pump 10 is switched off.

The discharge pipe 7 of the boiler HK1 and the discharge pipe 12 of the boiler HK2 open into the collection discharge pipe 1; the collective return line 2 branches into the return line 3 of the boiler HK1 and the return line 8 of the boiler HK2.

A first burner 13 and a first boiler temperature sensor 14 are built into the heating boiler HK1, in a analogous manner a second burner 15 and a second boiler temperature sensor 16 are built into the heating boiler HK2. In addition, a first return temperature sensor 17 is mounted on the return line 3 of the HK1 30 boiler, and a second return temperature sensor 18 on the return line 8 of the HK2 boiler.

A control device 19 comprises a computer 20, as well as the necessary inputs and outputs for the measured value registration and for giving the necessary commands. The device also has two terminals 21 for a supply voltage.

Electrical connections of the control device 19 to the individual devices are shown in broken lines. Via a first control line 22, the circula .....

3 - pump pump 5 can be switched on or off, via a second control line 23 the circulation pump 10. Via a first measuring line 24 resp. a second measuring line 25, the values measured by the return temperature sensors 17 and 17 respectively. 18 measured temperatures 5 supplied to the control device 19. A further control line 26 supplies the control signals from the control device 19 to a first mixer drive 27, which controls the three-way mixer 4. Analogously, a further control line 28 supplies the control signals from the control device 19 to a second mixer drive 29, controlling the three-way mixer 9. Further measuring lines 30 and 31 provide the signals given by the boiler temperature sensors 14 and 10 respectively. 16 measured temperatures to the control device 19. Via another control line 32, the control device 19 gives commands to the burner 13; by means of a first message line 33, the burner 13 informs the control device 19 whether it is in operation or not. Similarly, the burner 15 is connected to the control device 19 by a further control line 34 and a second message line 35.

The method to be described here for commissioning or operating in a controlled manner depending on the power. shutdown of boilers is not only applicable for an installation according to fig. 1, but also for both boiler cascade installations with more than two boilers and for installations with deviating hydraulic switching.

Each combination of boiler and burner can deliver a certain maximum power in continuous operation.

The magnitude of this is entered into the computer 20 as a parameter, for example in the form of a potentiometer setting. However, it is also possible to replace the maximum power of each boiler with the ratio of the. enter the maximum power of the installed boilers. Furthermore, it is possible that the computer 20 is designed in such a way that it learns the ratio of the maximum powers of the boilers in a learning process on the basis of the switching on and off of the individual boilers and the power balances resulting therefrom. .

40 At a given load in the heating circuit - 4 - • · the burner is switched on 13 resp. 15 of the operating boiler HK1 resp. HK2 - or possibly also both - switched on and off by control device 19 with a switch-on ratio ε corresponding to the load. The control device 19 can determine from the information present on the message lines 33 and 35 whether the burners 13 and 13, respectively. 15 are in operation, determine the switch-on ratio ε1 for burner 13 and the switch-on ratio ε2 for burner 15. From the product of the maximum power and the continuously determined switch-on ratios ε1 for the burner 13 or 13, each of the boilers HK1, HK2 is known. ε2 for the burner 15 periodically approximately the instantaneous power is determined. From this, a total power balance is determined, which is to be understood so that the currently required power is compared with the power capacity of the individual boilers. On the basis of this comparison, the computer 20 can take into account whether the heating boiler must be switched on or off, taking into account the optimum switching point from an energy point of view.

The optimum switching point from an energy point of view can be calculated in known manner from the fuel requirement curve of the individual heating boilers and the boiler combination.

It is only useful to switch on a boiler if the load after switching on is so high for a longer period that the energy gain due to the higher efficiency after switching on a boiler is greater than the energy required for heating the bee. boiler to be switched. In order to reduce the likelihood that a boiler will be switched on even with only a short-term load increase, a relatively long switch-on waiting period must be selected, during which the load must have been above the optimum switch-over point before an energy point has been reached. The next boiler is switched on.

When switching off one boiler, on the other hand, the load must have been below the energy optimum switch-over point for a switch-off delay before the boiler is switched off.

40 The computer 20 can switch the heating boilers on or off in a fixed order. However, it is also possible to program the computer 20 so that it selects the boiler based on the total power balance, which can provide the heat requirement with the greatest possible efficiency for a longer period of time. In installations with more than two boilers, the computer 20 can also switch on or off more than one boiler, taking into account the greatest possible efficiency.

For energy-optimal operation, the development of the boiler efficiency as a function of the load on each boiler must be taken into account. The development of the efficiency of the individual heating boilers can be taken into account in various ways. It is possible to record in a memory added to the computer 20 the course of the efficiency curves as a function of the load, for instance such that for each heating boiler a number of value pairs is recorded, between which the computer 20 can interpolate. From the efficiency curves of the individual heating boilers, the computer 20 can calculate the energy-20 optimum switching points itself. Another solution consists in calculating the data for the installed boilers in a known manner in the energy-optimal switch-over points for the individual boilers for commissioning the system and in the computer 20 and 20 respectively. enter the memory of these energy-optimal switching points.

The relatively long switch-on waiting time must then be regarded as too long if the boiler in operation is operating at "full load" and can no longer cover the power requirement 30. Therefore, at full load operation, instead of the switch-on waiting time, block turn-around time, which is considerably shorter to ensure that the required discharge temperature is maintained.

35 Since large loads can temporarily occur in a heating circuit, for example in the case of switching from a night program with a reduced room temperature to a day program with a comfort temperature adjusted to the comfort level, in many cases 40 it is not useful just to cover these short-term load peaks - start a subsequent boiler, in the case of an installation with more than two boilers, even several. Such a load peak is reflected in the drop below the desired discharge temperature 5 and can moreover also be recognized from the fact that the boiler currently in operation is running at full load. In the event that the temperature falls below the desired discharge temperature, the blocking period is provided, which for the time being prevents the next boiler from switching on. For this purpose, the boiler temperature of the boiler in operation or the temperature at the common discharge pipe 1, if a temperature sensor is fitted there, can be measured and one can then be prevented when the next boiler is switched on after expiry of the blocking period, when the course of time of the temperature falling below the desired temperature is such that the desired value will presumably be reached again within a predetermined time.

It is advantageous to periodically detect the course of the temperature during the switch-on blocking period. Depending on the actual value of the discharge resp. boiler temperature falls below the desired value, the shorter the blocking period; the smaller the difference between the desired and actual value, the greater the blocking period. The blocking period therefore becomes variable.

Furthermore, it is economically advantageous for the upstream decision to also take into account the temperature of the boiler which may be put into operation. Accordingly, both the blocking period and the switch-on waiting time also depend on the temperature difference between the boiler in operation and the boiler to be switched on. The blocking period and the switch-on waiting time are smaller the smaller this temperature difference. This ensures that a boiler that is still warm is switched on again more quickly than a completely cooled boiler.

As described above, in order to determine the boiler output, the ignition ratios ε1, ε2 of the burners 13, 15 are required. The most important calculation basis is always the newest value of the switch-on * * \

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* · Sm * m-Λ - 7 - have positions ε1, ε2 available. The switch-on ratios ε1, e2 are therefore continuously determined on the basis of the duration of the two last operating states of the burner, respectively. the burners, i.e. z. from a 5 in-out cycle, according to the formula time (in) ε = -— time (in) + time (out)

The last determined values of ε1 and ε2 are retained as the calculation basis until the next switching event, but at most until the switch-on ratios ε1 and ε2 obtained from the time of the current switching state and the duration of the immediately preceding switching state are obtained from the two previous, closed switching states have reached certain values again. If no new switching event has occurred until then, new switch-on ratios ε1 and ε2 are periodically calculated from the duration of the previous switching state and the current duration of the current switching state and these new switch-on ratios ε1 and ε2 are used to calculate the instantaneous boiler output. . This ensures that the instantaneous boiler output is determined from the current data.

Furthermore, the computer 20 to prevent boiler corrosion is programmed in such a way that a once switched-on boiler reaches a minimum temperature with certainty and remains operational for at least one switching cycle, before, for example, the boiler goes outside again due to a very rapid drop in a load peak. business.

The exemplary embodiment explained relates to two or more heating boilers with one-stage burners. However, the method is also suitable for use with boilers with two-stage burners, the described switch-on and switch-off commands of the control device 19 relating to operation with only one or both burner stages.

Boilers with a modulating burner can also be used in the described method. Instead of determining the switch-on ratios, the computer 20 then determines the opening positions of the mechanism, which determines the fuel-air quantity according to the boiler power. For this purpose, a potentiometer can be used, which is adjusted by the said mechanism.

The described method makes it possible to control a boiler cascade installation in a simple manner, in which, in addition to optimum efficiency, the requirements for preventing boiler corrosion as a result of operation at too low boiler temperature can also be taken into account.

This method is also applicable in the operation of 10 cascades with other heat or cold generators, the power of which cannot be constantly regulated, for example two- or multi-stage heat pumps or chillers.

.vi

Claims (8)

1. Method for commissioning or operating in a controlled manner depending on the output. shutdown of boilers, each connected to a common collective discharge pipe and a collective return pipe of a heating network, characterized in that, from the product of the maximum power known from each boiler (HKT, HK2) and the continuously measured switch-on ratio (ε1, ε2 ) of the respective burner (13, 15) a total power balance is determined and on the basis of this heating boilers (HK1, HK2) are respectively switched off. Method according to claim 1, characterized in that the total power balance is determined by means of a computer (20), which boilers (HK1, HK2) respectively in a boiler cascade. turns off. Method according to claim 1, characterized in that the total power balance is determined by means of a computer (20), which, on the basis of the balance values, selects the boiler (s) (HK1, HK2) which, for a longer period of time, the greatest possible efficiency 20 can meet the heat requirement. Method according to claim 2 or 3, characterized in that the total power must have been above an energy-optimal switch-over point for a predetermined switch-on waiting time before switching on a next boiler (HK2; HK1). Method according to claim 2 or 3, characterized in that the total power must have been below the energy-optimal switching point for a predetermined switch-off blocking time before a heating boiler (HK2; HK1) is switched off. 6. A method according to any one of claims 2 or 3, in which a subsequent heating boiler is switched on as a result of the drop of the actual discharge temperature below the desired discharge temperature only after a blocking period has elapsed and only then is carried out, if a minimum requirement is required within the blocking period. temperature increase is not achieved, characterized in that the development of the discharge temperature during the blocking period is periodically detected and the blocking period is shorter the smaller the difference between the desired and actual value of the discharge temperature and the longer, the greater the difference between the set and actual value of the discharge temperature. Method according to claims 4 to 6, characterized in that the switch-on waiting time and the blocking period are also made dependent on the temperature difference between the boiler in operation (HK1; 10 HK2) and the boiler to be switched on (HK2; HK1) and the smaller the selected, the smaller the temperature difference. Method according to one of Claims 1 to 7, characterized in that the switch-on ratio (ε1, ε2) of each burner (13, 15) is calculated continuously from the duration of the two last elapsed operating states of the boiler ( HK1, HK2) additional burner (13, 15), ie from an in-out cycle, according to the formula time (in) 20 ε * - time (in) + time (out) and the last determined value (ε1, ε2 ) is retained as the calculation basis until the next switching event, but at the most so long, until the switch-on ratio (ε 1, ε2) obtained from the two previously closed switching devices is obtained from the duration of the current switching state and the duration of the immediately preceding switching state. positions has reached a certain value again, and that a new switch-on ratio (ε1, ε2) is then periodically calculated from the duration of the previous switching state and the hitherto valid duration of the current switching state and this new switch-on ratio (et, ε2) is used for the calculation of the instantaneous power. · '· ·' - Λ 'V *'> ί. .