DE102006026613A1 - Prevention method for drying-up of siphon of fuel-value-heater involves activating time measurement with the completion of heating process under certain heat output and also activating siphon-gap-filling program - Google Patents

Abstract

The method involves activating time measurement with the completion of heating process under certain heat output Pkond by which the dew point of the emissions is dropped. The siphon-gap-filling program is activated at the time when within a predetermined time tw, the fuel-value-heater (1) is not again operated with a heat output under certain heat output, flow temperature or exhaust gas temperature.

Description

The The invention relates to a method for preventing dehydration a siphon of a condensing boiler according to the preamble of the claim 1.

at Condensing boilers the exhaust gas is cooled so far that the contained in the exhaust gas Water vapor below the dew point, the usual fuel gas-air mixtures at about 57 ° C, condensed out. The condensate is collected and over a Siphon removed. The siphon's job is to exhaust outlet from this pipe too prevent.

at long downtime of the device or during operation of the condensing boiler at high heat outputs it can happen that no condensate arises while at the same time Condensate evaporates in the siphon. In extreme cases, this can lead to Exhaust gas exits through the open siphon.

To solve this problem is out of the DE 41 34 230 A1 It is known that at certain time intervals for a certain time the burner is operated in such a way that condensate is formed. This is done by reducing the heating power, optionally with increased volume flow of the cooling circuit. This ensures that new condensate accumulates and the siphon is filled.

Becomes always at certain intervals the siphon filling program carried out, so it may be that the siphon already at the beginning of the siphon filling program filled is and the filling process would be dispensable.

Of the Invention is based on the object of optimizing the method in such a way that it only performed will, if necessary. According to the features of the independent claim 1 will be below a certain one after completion of a heating process Heating power, at which the dew point of the exhaust gases is exceeded, activates a time measurement and activates the siphon filling program only if, within a predetermined time, the condensing boiler is not again with a heating capacity below this specific heating power is operated. This ensures that the siphon filling program stops when the device due to a requested heat output is operated in condensing heating mode and the siphon thus filled becomes. This ensures that the heater whenever possible with the need-based Heating power is operated.

alternative to the condition that the condensing boiler below a certain heating power, in which the dew point of the exhaust gas is reached, is operated, can be a criterion for the operation of the condensing boiler underrun a certain flow temperature or a certain exhaust gas temperature serve. It may also be possible be that at least two of the above conditions are met have to.

advantageous Embodiments emerge from the subclaims. So the timing is stopped, if the device is operated again below the predetermined heating power. After completion of the heating process with the predetermined heating power the time measurement is restarted. This concludes the case a that the heating power of a heating power below the certain limit heating power is increased above this heating power. The siphon filling program can either be at the next Heat request to be performed or independently from a heat request after termination of the predetermined time. In an advantageous embodiment is the siphon filling program performed with the minimum heating power of the condensing boiler. Becomes the volume flow through the heat exchanger of the condensing boiler elevated, so the condensation can also be favored.

The invention will now be explained in detail with reference to FIG. This shows 1 a heater for performing the method.

1 shows a condensing boiler 1 , About a fuel gas valve 35 is a fuel gas supply with a blower 13 which has an engine 3 has, connected. The pressure side of the blower 13 flows into a mixture chamber 5 , which is connected to a burner 7 borders. Below the burner 7 there is a heat exchanger 18 who in turn into a condensate and waste gas collector 8th empties. From the exhaust and condensate collector 8th go a line 10 into a siphon 9 , On the other hand, an exhaust pipe leads 11 in which is an exhaust gas temperature sensor 23 located to a fresh air / exhaust pipe connection 2 , A heating return line 14 leads through a pump 26 to the heat exchanger 18 and from the heat exchanger 18 in a supply line 20 in which is a flow temperature sensor 21 located. A regulation 22 is with the electrical components of the condensing boiler 1 connected.

During normal heating operation, the control gives 22 depending on the temperature of the flow temperature sensor 21 in the supply line 20 one Control signal both to the motor 3 of the blower 13 , as well as the fuel gas valve 35 , A fuel gas-air mixture is inside the blower 13 mixed, the burner 7 fed and between burners 7 and heat exchangers 18 burned. In the heat exchanger 18 The exhaust gases are cooled and the heat of the exhaust gas on the water cycle 14 . 20 transfer. The condensate runs into the siphon 9 ,

In the scheme 22 are the operating parameters for the operation of the condensing boiler 1 deposited. This also includes a predetermined heat output P _kond , in which with almost certain probability the exhaust gases in the heat exchanger 18 be cooled so that water vapor condenses out. If the heater is operated above the predetermined heating power P _kond , the seizure of new condensate is not ensured. To ensure condensate accumulation, the siphon filling program is carried out. For this the regulation starts 22 a time recording as soon as the last time the heater was operated with a heating power below the predetermined heating power P _con . If, within a predetermined period of time t _w, the predetermined heating power P _{kond falls below} again, then the time recording is stopped and, after the end of the heating process with low heating power, the time recording is restarted. If the heater is not operated again with low heat output within the predetermined period t _w , this is an indication that the siphon must be filled. Either after the predetermined time t _w or at the next Heizanforderung the siphon-filling program is passed through. For this purpose, regardless of the requested heating power, the heater is operated with a heat output below the determined heat load P _kond preferably with minimum power. At the same time the pump capacity 26 increases, the volume flow of the coolant through the heat exchanger increases 18 , which leads to increased condensation.

Instead of the criterion of _{falling below} a predetermined heat output P _kond , the _{subcirculation of} a specific flow temperature T _{Vor, limit} or a specific exhaust gas temperature T _{exhaust gas, limit can be used} as a condition. In order to check a criterion, it can be provided that at least two or all criteria are reached (redundancy).

As already mentioned in the introduction, the dew point of the exhaust gas is one Condensing heater at about 57 ° C. Only when this temperature falls below can steam from condensed be, the amount of condensate increases, the lower the exhaust gas is condensed out.

If the flow temperature is more than 57 ° C, no water vapor can be condensed out in the heat exchanger. If the flow temperature is lower than the dew point temperature of the exhaust gas, water vapor may condense; However, depending on the basic conditions, this is not necessarily guaranteed. In modern heat exchangers 18 However, it can be assumed at flow temperatures below 45 ° C that sufficient condensation takes place. Captures the regulation 22 in stationary operation by means of a flow temperature sensor 21 measured temperature, which is smaller than a predetermined flow temperature T _{before, limit} , occurs in the condensation, the time detection for the triggering of the siphon filling program is stopped and restarted upon completion of the heating process. It is necessary that the device is in a stationary state, as at startup temperatures briefly occur which deviate significantly from the stationary measured temperatures. This also gives for the exhaust.

The exhaust gas is in the heat exchanger 18 not cooled homogeneously. Rather, the exhaust flowing directly along the heat exchanger walls is cooled more than the exhaust flowing through the middle of fins, nobles, or the like. Therefore, downstream of the heat exchanger 18 at exhaust gas temperatures at the exhaust gas temperature sensor 23 Condensate in the heat exchanger may have already formed above the dew point temperature. At exhaust gas temperatures downstream of the heat exchanger 18 below the dew point temperature, however, condensate must be in the heat exchanger 18 be incurred. Captures the regulation 22 in steady state operation by means of an exhaust gas temperature sensor 23 measured temperature, which is smaller than a predetermined exhaust gas temperature T _{exhaust, limit} , occurs at the condensation, the time detection for the triggering of the siphon filling program is stopped and restarted upon completion of the heating process.

Claims (6)

Method for preventing the drying of a siphon ( 9 ) of a condensing boiler ( 1 ), in which, in the presence of certain boundary conditions, a siphon filling program is activated, such that the condensing boiler ( 1 ) is operated for a certain period of time with a low heat output, at which the dew point of the exhaust gases is exceeded, so that the siphon ( 9 filled with exhaust gas condensate and is sealed against exhaust gas outlet, characterized in that at the end of a heating process below a certain heat output P _kond , in which the dew point of the exhaust gases is exceeded, a time measurement is activated and the siphon filling program is then activated, if within a predetermined time t _w the condensing boiler ( 1 ) not again with a heating power below the determined heat output P _kond , below a certain flow temperature T _{Vor, limit} and / or below a certain exhaust gas temperature T _{exhaust, limit was} operated. Method for preventing the drying of a siphon ( 9 ) of a condensing boiler ( 1 ) according to claim 1, characterized in that in the next operation of the condensing boiler ( 1 ) below the determined heat output P _kond , below a certain flow temperature T _{Vor, limit} and / or below a certain exhaust gas temperature T _{exhaust, limit} the time measurement is stopped and restarted at the end of the heating process. Method for preventing the drying of a siphon ( 9 ) of a condensing boiler ( 1 ) according to one of claims 1 or 2, characterized in that the siphon-filling program is activated at the next heat request after completion of the predetermined time t _w . Method for preventing the drying of a siphon ( 9 ) of a condensing boiler ( 1 ) according to one of claims 1 or 2, characterized in that the siphon filling program is activated independently of a heat request after completion of the predetermined time t _w . Method for preventing the drying of a siphon ( 9 ) of a condensing boiler ( 1 ) according to one of claims 1 to 4, characterized in that the siphon filling program is performed with minimum heating power P _min . Method for preventing the drying of a siphon ( 9 ) of a condensing boiler ( 1 ) according to one of claims 1 to 5, characterized in that the siphon-filling program with increased volume flow through the heat exchanger ( 18 ) of the condensing boiler ( 1 ) is carried out.