AT397854B - Method for controlling a boiler - Google Patents

Abstract

Method for controlling a boiler 1 heated by a burner 2, 122 and supplying a heating circuit in which a heating medium circulates, the burner 2, 122 being controlled as a function of the temperature of the heating medium. In order, in such a method, to reduce the energy consumption and switch-on frequency of the burner 2, 122, there is provision for reducing the rate of circulation of the heating medium in the heating circuit after the burner 22, 122 has been switched off or after the predetermined temperature (desired value) for the heating medium has been reached. <IMAGE>

Description

AT 397 854 B

The invention relates to a method for controlling a boiler heated by a burner, which supplies a heating circuit in which a heating medium circulates, the burner being controlled as a function of the temperature of the heating medium, and to a device for carrying out this method.

In a known method of this type, the circulating speed of the heating medium in the heating circuit is kept essentially constant, regardless of whether the burner is in operation or not. However, this results in a correspondingly high consumption of electrical energy for the operation of the pump. The energy requirement essentially depends on the speed of the pump or its delivery rate. With a lower selected speed of the pump, the energy consumption is lower, however, the burner is cycled frequently. This leads to correspondingly frequent cold starts and, in connection with this, to an increased pollutant emission due to the start-up emissions.

Methods are also known from DE-OS 38 38 477 and EP-PS 0 308 848 in which the circulating speed of the heating medium is varied during burner operation. The speed of the circulation pump is increased when the target value is approached.

The aim of the invention is to avoid these disadvantages and to propose a method of the type mentioned at the outset with which an energy saving and a low starting frequency of the burner can be achieved.

According to the invention this is achieved by the characterizing features of claim 1.

In this way, a high throughput of the heating medium is ensured during operation of the burner, which results in a correspondingly small temperature difference between the heating medium flowing into the boiler and the heating medium leaving the boiler. This prevents the heating medium from exceeding the envisaged temperature until the entire volume of the heating medium is approximately brought to the same temperature, which is only slightly below the predetermined flow temperature.

Lowering the speed of the pump during burner downtimes has the advantage of saving electrical energy. The uniform heating of the heating medium further reduces the number of times the burner is switched on for a predetermined time, which, when viewed over the entire operating time of the boiler, results in a correspondingly low switching frequency.

The circulating speed of the heating medium in the heating circuit when the burner is in operation is preferably regulated as a function of the temperature of the medium flowing into the boiler, the burner load, the intended maximum flow temperature according to a predetermined heating curve and the boiler efficiency, with a minimum circulating speed when the burner starts Heating medium is observed.

This mode of operation is also suitable for boilers with a modulating burner, i.e. Burners with constantly changing performance. The advantage of such a burner is that the performance of the burner can be adapted to the instantaneous heat requirement of the heating circuit. This reduces the number of burner cycles during a given observation period, and in the limit case that the burner output corresponds exactly to the heating circuit's heating requirement, the burner is not switched off at all.

According to a further feature of the invention it can be provided that the required pump speed is determined from the burner load, the flow and return temperatures and the throughput of the heating medium determined from the pressure loss across the pump.

In this way it is possible to take into account the current operating state of the heating circuit connected to the boiler when controlling the circulating speed of the heating medium in the heating circuit. This enables a particularly high degree of energy saving to be achieved.

Another object of the invention is to propose a device for carrying out the method according to the invention.

In a device for carrying out the method according to the invention with a boiler heated by a burner according to the preamble of claim 3, its features are proposed according to the invention.

It can be found with a very simple control system. It is sufficient to change the switching status of the burner with fuel, e.g. Gas to detect supplying valve, which is determined by the controller anyway. Due to the switching status of the valve and thus the burner, the motor of the pump is then switched to the higher or lower speed.

The motor can also be controlled depending on the switching status of the valve, the return temperature, the pressure difference across the pump or the flow temperature. In this way, the speed of the pump is not only determined depending on the switching status of the valve, but also on the current operating status of the heating circuit. On the one hand, this enables rapid heating of the heating medium and, on the other hand, avoids high burner switching times. 2nd

AT 397 854 B

If only one sensor is used to measure the temperature of the heating medium flowing into the boiler or the return temperature, the operating temperature of the burner and the boiler, as well as the heat requirement of the heating circuit, can be used to infer the flow temperature via the pressure difference across the pump. If a sensor that detects the flow temperature is also provided, the required pump speed can be inferred from a comparison of the flow temperature and the return temperature.

In any case, a very precise adjustment of the speed of the pump and thus the delivery speed is possible. The speed of the pump is reduced to a minimum in accordance with the method according to the invention after the burner has been switched off, this low speed being maintained until the burner is started again.

The invention will now be explained in more detail with reference to the drawing. 1 to 3 schematically show different embodiments of heating devices according to the invention.

In the embodiments according to FIGS. 1 and 2, an atmospheric burner 2 is provided for heating the boiler 1. This is supplied from a gas line 4 via a solenoid valve 3. The solenoid valve 3 is connected to a controller 6 via a line 5.

Arranged above the boiler 1 is a flow safety device 7, which emits a signal acting in the sense of closing the solenoid valve 3 when the usual flow of the exhaust gases flows from bottom to top, and an exhaust hood 9 leading to an exhaust pipe 8.

A feed line 10 and a return line 11 of a heating circuit, through which a heating medium flows, are connected to the boiler 1.

So far, the embodiments according to FIG. 1 and FIG. 2 correspond.

In the embodiment according to FIG. 1, a pump 12 is arranged in the flow line 10, which ensures the passage of the heating medium through the heating circuit, which has at least one heating element 14 as a consumer, and which is driven by an electric motor 13 that is easily switchable in its speed is. The controller 6 contains a speed switch 40 for the pump motor.

The motor 13 is connected to the controller 6 via lines 16.

Furthermore, a temperature sensor 17 is arranged in the flow line 10 and is connected to the controller 6 via a line 18. The controller 6 is also connected via a line 15 to an outside temperature sensor 19. On the basis of an entered heating curve, the controller 6 determines a specific target temperature for the heating medium as a function of the outside temperature and other parameters, such as the time and day.

If the temperature of the heating medium falls below the target value specified by the controller 6 by a certain amount, for example 7 ° K, the solenoid valve 3 opens and the burner 2 starts. At the same time, the motor 13 is subjected to a signal which switches it to a higher speed, so that the pump 12 is operated at a higher speed when the burner 2 is in operation. After reaching the temperature of the heating medium specified by the control 6, the solenoid valve 3 closes, the motor 13 simultaneously being switched back to a lower speed.

As a result, the heating circuit is flowed through at a lower speed during the standstill breaks of the burner 2 than when the burner 2 is in operation. This ensures that the difference between the temperature of the heating medium flowing to the boiler 1 and the medium flowing out of the boiler 1 when in operation located burner 2 can be kept low, whereby the entire volume of the heating medium can be brought almost to the predetermined flow target temperature until the controller 6 closes the solenoid valve 3. On the other hand, the flow of heat from the heating circuit is only insignificantly reduced due to the slow flow in the burner style. Due to the uniform heating of the heating medium, there are correspondingly long time intervals before the burner 2 is restarted.

In the embodiment according to FIG. 2, the pump 12 is arranged in the return line 11 and driven by a motor 131 which is infinitely variable in its speed. The pump arrangement in the flow 10 is also possible. As shown in FIG. 1, this motor 131 is connected to the solenoid valve 3 and the controller 6 via the lines 15, 16. The controller 6 is also connected to a flow temperature sensor 20 via a line 18.

In the embodiment according to FIG. 2, the heating circuit has a bypass line 21, which is controlled by an admixing valve 22 and which enables an admixture of flow heating medium to the heating medium flowing in the return line 11.

In this embodiment, the controller 6 operates the pump 12 at a low speed when the burner is started, and with increasing flow temperature, which is detected by the temperature sensor 20, the speed of the pump increases continuously with increasing flow temperature. If the intended flow temperature is reached by the continuously variable power, the solenoid valve 3 switches off. Simultaneously 3

Claims (3)

AT 397 854 B tig, this also applies a signal to the motor 131, which brings it to a low speed. The speed control 41 is part of the control 6. In the embodiment according to FIG. 3, instead of an atmospheric burner 2, a forced draft burner 122 is provided, the performance of which can be modulated by the control 6 via a line 23. The pump 12 is arranged in the feed line 10 and driven by a continuously variable motor 131, which is supplied with corresponding control signals from the controller 6 via the line 16. The controller 6 is connected via the line 24 to a pressure sensor 25 which detects the pressure difference across the pump 12. Furthermore, the controller 6 is connected to a changeover valve 26 via a line 31, which enables the heating medium flow to be switched over to the heat consumer 14, which is provided with a thermostatic valve 27 which releases the flow cross-section to a greater or lesser extent, or to a boiler 28. The primary circuit 29 of the boiler 28 is connected in parallel to the radiator 14, the secondary circuit of this boiler 28 being formed by the container 30 through which the process water to be heated flows, which flows in via the connection 32 and via the line 33 with a tap, not shown connected is. Furthermore, the controller 6 is connected via a line 34 to a sensor 35 which detects the temperature of the process water and a sensor 20 for the boiler flow temperature via the line 18. In this embodiment, if necessary, the burner 122 is started with the power specified by the controller 6, corresponding to the current heating curve, by the controller 6, according to the current heating curve, the speed of the pump 12 being kept at the minimum speed. As the temperature of the heating medium rises, there is an increase in the pressure difference across the pump 12 due to the thermostat valve 27 during heating operation in which the heating element 14 is flowed through, the speed of the pump 12 being increased. In hot water operation, in which the boiler 28 has heating medium flowing through it, the pump speed is controlled as a function of the temperature of the hot water. Depending on the predetermined heating curve, depending on the current temperature of the heating medium, the target temperature and the pressure difference across the pump 12, the current throughput of the pump 12 is inferred and the control of the speed of the pump 12 is a target throughput by the pump 12 set, which prevents the burner 122 from being switched off prematurely when the heat is continuously supplied by the burner 122, the output of the burner 122 also being able to be varied. After reaching the intended temperature of the heating medium, the burner 122 is switched off and the speed of the pump 12 is reduced to the minimum speed. 1. Method for controlling a boiler heated by a burner, which supplies a heating circuit in which a heating medium circulates, the burner being controlled as a function of the temperature of the heating medium, characterized in that the circulation speed of the heating medium in the heating circuit, according to Switching off the burner (2, 122) or after reaching the specified temperature (setpoint) of the heating medium is reduced. 2. The method according to claim 1, characterized in that the required pump speed is determined from the burner load, the flow and return temperature and the throughput of the heating medium determined from the pressure loss across the pump (12). 3. Device for performing the method according to claim 1 with a boiler heated by a burner, to which a heating circuit is connected, which has a temperature sensing the temperature of the heating medium and in which a pump with a continuously variable in its speed or switchable Motor is driven, is arranged, the burner being supplied with fuel via a valve acted upon by a control system, characterized in that the motor (13, 131) is connected to the control system (6) and, depending on the degree of opening or the switching state of the valve (3 ) its speed is continuously varied or switched. Including 2 sheets of drawings 4