DE3030565A1 - Boiler for domestic heating systems - has burner connected to and regulated by room temp. control using three=way valve - Google Patents

Abstract

The boiler, esp. a boiler with an oil burner, has a connected boiler circuit, which in turn is connected to a heating circuit for the heated medium. The heating circuit has an associated temp. control. The burner (4) for the boiler (1) is connected to the temp. control (14), esp. a room temp. control, and is regulated by it. The heating circuit (10) is connected to the boiler circuit (6) via a thermostatic three way valve (24). The valve blocks the connection to the heating circuit of the boiler at low medium temp., and frees the connection as the temp. rises. The temp. at which the connection is freed, is above the condensation temp. of the medium.

Description

Boiler for heating systems The invention relates to a heating boiler for heating systems with a boiler circuit connected to the boiler which is connected to a heating circuit for the heated medium, and with one of the Temperature controller assigned to the heating circuit, in particular heating boilers with oil burners.

In known heating systems, the boiler fulfills the function to heat a usually liquid medium, mostly water. As a rule If the boiler contains an oil burner, the heat is then transferred to the the boiler flowing water is transmitted. Then the heated water can then be fed to one or more radiators.

For a better understanding, known heating systems are shown in FIGS shown. In FIG. 1, the boiler 1 equipped with a burner 4 heats the water, which is led through pipes into a boiler circuit 6. To the boiler circuit 6 closes the actual heating circuit via a mixer 8 in a known manner 10 with a circulation pump 12 and the heater 16. To set the in the to A room temperature controller 14 is provided for the desired temperature to be heated, which is connected to the circulation pump 12. Finally, the boiler points 1 another boiler controller 2 to keep the boiler temperature more or less constant, regardless of which room temperature is currently desired. The one mentioned Boiler controller 2 affects the burner 4 in such a way that this when it reaches the the desired boiler temperature is switched off and if the value falls below the specified value Temperature switches on again.

The boiler 1 in FIG. 2 is also equipped with such a boiler controller 2 equipped to keep the boiler temperature constant. Differing from Fig. 1 is Here, a so-called weather-compensated control is proposed, in the case of the outside to be heated A weather sensor 20 is arranged in the room. This determines the respective heating temperature set according to the outside temperature.

The actual regulation is carried out by a motor-controlled mixing valve 22 with a drive 18 which is connected to the weather sensor 20.

The boilers described have in common that they are in both Cases are a heat generator that works with so-called on / off control and that over the entire heating period or over the entire year with a constant Boiler temperature of, for example, 80 "is operated.

The known boilers work quite satisfactorily and reliably in practice, but the efficiency must still be regarded as unsatisfactory, which is of course a disadvantage when the general desire for energy savings is taken into account. According to VDI guideline No. 2067, the annual operating efficiency is calculated using the formula: The following mean: = = annual operating efficiency 72k = boiler efficiency bVHa before = number of hours of full use in h / a = = loss of operational readiness ba = operational readiness time, duty cycle in h / a The boiler efficiency and operational readiness loss are determined by constructive factors, while the ratio of operational readiness to full use The boiler.

When calculating the annual efficiency, an operational readiness time is included assumed 365 r 24 h = 8760 h / a. The actual burner running time (number of full hours of use) is of course less, since the boiler is only switched on when the The temperature of 800 C already mentioned above is fallen below. One calculates in the formula with a number of full hours of use of 1700 h / a (VDI guideline 2067, Page 2). This means that the boiler is on standby for 7060 h / a (8760 - 1700) with the burner switched off.

It should also be mentioned that the above-mentioned long standby time b a = 8760 h / a comes about because the boiler also needs hot water then covers or keeps ready when the connected heating system - for example in summer - is switched off because there are other hot water consumers, e.g. shower or rinsing water, connected to the boiler.

It must also be taken into account that in the boiler the condensation temperature of the flue gases is not fallen below if possible should be because the condensation of the smoke gases is known to be harmful form sulphurous acids. The possibility of switching off the heating system during the downtimes in summer are therefore ruled out, since when the system is re-heated the large mass of the cooled heating water content the condensation temperature the flue gases would be undershot for a long time. The resulting Sulphurous acid then very easily leads to corrosion damage in the boiler. the end For these reasons, the boiler always works in conjunction with the boiler controller kept at a constant temperature, regardless of whether about the heating is switched on or off.

It has now been shown that the necessary measures described lead to considerable losses that worsen the annual operating efficiency. During the time in which the boiler is only on standby - i.e. during of the above-mentioned 7060 h / a - losses occur due to unused radiation Convection and internal cooling, which result in the inevitable loss of exhaust gas the warm gases escaping from the chimney by about 1.7 times.

The invention is based on the object to provide a heating boiler, at which these losses are reduced, and the annual operating efficiency thereby is increased.

To solve this problem is in the preamble of the claim 1 prerequisite boiler provided that the boiler or its burner is connected to and controlled by the temperature controller, and that the Heating circuit connected to the boiler circuit via a thermostatic three-way valve is what the connection to the heating circuit and thus to the boiler at low Locks temperatures of the medium and releases them with increasing temperature.

In the invention, the surprising route is taken on to do without the well-known boiler controller and the boiler to the temperature controller to be connected through which the burner is switched on and off. So far one had it always avoided to control the boiler by the temperature controller, because then Yes, because of the missing boiler controller, the boiler temperature is no longer at a constant Value is held. But this has always been seen as an important prerequisite otherwise when it is reheated after a long period of standstill of the heating the harmful flue gas condensation already mentioned above occurs in the boiler.

Despite the control of the boiler by the temperature controller such harmful flue gas condensation is avoided in the invention. For this purpose, the thermostatic three-way valve is connected to the boiler circuit, whereby the three-way valve connects to the heating circuit at low temperatures blocks the medium to be heated and only releases it at higher temperatures. if therefore the boiler is put into operation after a long period of standstill of the heating system, is the thermostatic three-way valve because of the cooled liquid medium closed, so that the cooled medium initially exclusively in the boiler circuit can flow. Since the volume of the medium in the boiler circuit is equal to that of the heating circuit is negligibly small, it will heat up very quickly in the boiler circuit, so that flue gas condensation hardly occurs in the boiler room.

The three-way thermostatic valve can be of conventional design, as it is provided, for example, in motor vehicles with water cooling. the Effect of such a valve is known to be that a previously blocked Path is slowly released as the temperature of the flowing medium increases. Therefore, when the medium in the boiler circuit has warmed up sufficiently, the Connection to the heating circuit released so that the medium is in the heating circuit can now gradually heat up. Despite the large mass of the heating medium occurs no flue gas condensation, as the thermostatic three-way valve the Connection from the boiler to the heating circuit is only enabled if the temperature is above the condensation temperature.

In the boiler according to the invention is therefore in connection with the thermostatic three-way valve created a so-called "bypass", which the in the boiler circuit Medium warms up very quickly, and only then the heating circuit is connected to the boiler.

The aforementioned temperature controller is an expedient embodiment of the invention the room temperature controller, which was previously connected to the heating circuit in known heating systems was connected. It is in for heating systems with weather-compensated control It is also advantageously possible to control the heating circuit by means of the outside sensor - As in Fig. 2 in a known manner - to make the motor-controlled mixing valve influenced. In this case, the actual control of the boiler takes place through the boiler controller. The motor-controlled mixing valve switches the burner via a Limit switch off. If the demand of the heating circuit is covered, no heat is in the Boiler circuit generated.

The annual operating efficiency is determined by the boiler according to the invention increased to a decisive extent. This is due to the fact that the boiler is due to control by the temperature controller is now actually only switched on is when hot water is required, while in the known boiler this is independent from the operating state of the actual heater always at a constant temperature was held. In the formula for the annual efficiency already mentioned at the beginning In the boiler according to the invention, the quotient ba / bVHa is approximate towards 1, so that the annual operating efficiency is approximately equal to the boiler efficiency will. This leads to an optimal value for the annual efficiency. The enormous energy savings achieved in this way is due to the fact that the boiler is no longer at such times where there is actually no need for heat, but only switched on when heating energy is actually required.

The invention is illustrated below with the aid of the drawings Execution methods explained in more detail. 1 and 2 each show a known one Heating boilers for different heating systems, Fig. 3 shows a first embodiment of the invention, FIG. 4 shows another embodiment of the invention, FIG Another embodiment and FIG. 6 shows a partial representation of a heating boiler with a thermostatic three-way valve in the heating circuit.

After the known heating boiler according to FIGS. 1 and 2 above has already been explained in more detail, those shown in FIGS. 3 - 6 are shown below Embodiments described, wherein corresponding parts with the same Reference numerals are named.

In Fig. 3, the boiler circuit 6 is connected to the heating boiler 1, a thermostatic three-way valve 24 and a boiler pump 26 as a circulation pump includes. The heating circuit 10 is connected to the heating 16 via the three-way valve 24 tied together. In an unconventional way, the burner 4 of the boiler 1 is direct controlled by the room temperature controller 14. The burner 4 is therefore controlled by the room temperature controller 14 on or

switched off.

The boiler circuit 6 as well as the thermostatic used in a new way Three-way valve 24 are particularly clear in the partial illustration according to FIG. 6 to recognize. It is assumed in the following that the burner 4 is switched off, because the room temperature controller 14 is turned down so far that the heater 16 stays cold. If the room temperature controller 14 is now set to a higher temperature the burner 4 turns on and, as a result, it becomes in the boiler circuit 6 heated water flowing in the circuit under the action of the boiler pump 26. the corresponding amount of water in the boiler circuit 6 is relatively small, so that the flue gas condensation in the boiler 1 can be neglected.

As long as the water in the boiler circuit 6 has not yet been heated, it flows it because of the then closed thermostatic three-way valve 24 by the Pipes 32, 30 and 38 in the circuit, in Fig. 6 for the sake of clarity only one part of the boiler circuit 6 is shown, the other part of which is is located in the boiler room bounded by the boiler wall 28.

As the temperature rises, the thermostatic three-way valve begins 24 to open, whereby the heated water passes through the pipe 34 to the heater 16 and flows back into the boiler circuit 6 via the pipe 36. That way it becomes Water in the heating circuit 10 is gradually heated. The thermostatic Three-way valve 24 ensures that the condensation temperature of the flue gas is not fallen below, because when the water in the boiler circuit 6 cools down again due to the large amount of water in the heating circuit 10, closes the three-mege thermostatic valve 24. Thus it is in connection with the control of the burner 4 through the room temperature controller 14 and through the use of the thermostatic Three-way valve possible to actually only use boiler 1 to be switched on when there is a need for hot water. This becomes the annual operating efficiency increased considerably. Nevertheless, the harmful flue gas condensation occurs not open because the thermostatic three-way valve 24 connects to the boiler circuit 6 to the heating circuit 10 only releases when the water is sufficiently heated. Only then can water through the pipe 34 to the heating circuit 10 and from there through the Flow back pipe 36.

In Fig. 4, a heating boiler 1 for a heating system is shown, which works with a weather-compensated control. The outside sensor is located here 20 outside the room to be heated, so that the temperature as a function of can be controlled according to the prevailing external conditions. The outside sensor 20 is connected to a mixer drive 18, which has a motor and the motorized mixing valve 22 controls. The circuit within the heating circuit 10 is maintained by the circulation pump 12. Even with this heating system the boiler 1 is dispensed with by means of that shown in FIGS Rather, it is used to keep the heating controller continuously at a constant temperature the burner 4 is controlled by the outside sensor 20, which specifically takes place that a limit switch of the motor in the mixer drive 18, the boiler or the Burner 4 switches on or off when the heater 16 is put into operation target. The thermostatic three-way valve 24 here serves the same purpose as already described with reference to FIG. When the burner 4 is switched on, it is initially the relatively small amount of water in the heating circuit 6 is warmed up, and only when that Thermostatic three-way valve 24 opens, the water is also heated in the heating circuit 10, which also includes a circulating pump 12 here. One Falling below the condensation temperature is in turn avoided by what is known per se Three-way valve 24, which is used here in a novel way in a boiler is, the connection from heating circuit 6 to heating circuit 10 is only released when the water has a certain minimum temperature.

The illustration in Fig. 5 shows a heating system that without the motor-controlled mixing valve 22 according to FIG. 4 works and in its heating circuit 10 a heating circuit pump 40 is switched on. The outside sensor 20 is with a Flow sensor 42 connected in the heating circuit 10, and the burner 4 is directly through the outside sensor 20 controlled. Otherwise, the heating system corresponds to that in Fiy. 4th

Overall, the measure, which has always been deliberately avoided so far, leads to the Do not connect boiler 1 to the room temperature controller to increase the annual operating efficiency 14 or the outside sensor 20 to be connected, in conjunction with the thermostatic Three-way valve 24 in a surprisingly simple manner and avoiding the harmful Flue gas condensation results in considerable energy savings.

Claims (6)

Claims: 1 0 boilers for heating systems, with an on The boiler circuit connected to the boiler, to which a heating circuit for the heated medium connects, and with a temperature controller assigned to the heating circuit, in particular heating boilers with oil burners, characterized in that the heating boiler (1) or whose burner (4) is connected to the temperature controller (14, 20) and is controlled by this, and that the heating circuit (10) via a thermostatic Three-way valve (24) is connected to the boiler circuit (6), which is the connection to the heating circuit (10) and thus to the boiler (1) at low temperatures of the Locks the medium and releases it as the temperature rises. 2. Boiler according to claim 1, characterized in that the temperature in which the thermostatic three-way valve (24) is the connection to the boiler circuit (6) releases is selected so that that from the heating circuit (10) into the boiler (1) flowing medium is above the condensation temperature of the medium. 3. Boiler according to claim 1 or 2, characterized in that the temperature controller is a room temperature controller (14). 4. Boiler according to claim 1 or 2, characterized in that the temperature controller is an outside sensor located outside the heated room (20) in a heating system with weather-compensated control. 5. Boiler according to claim 4, characterized in that the heating circuit (10) a mixing valve controlled by the outside sensor (20) via a drive (18) (22) is arranged, and that the boiler (1) is switched on or off by the drive (18). is turned off. 6. Boiler according to one of the preceding claims, characterized in that that a boiler pump (26) is provided as a circulation pump in the boiler circuit (6). -Description-