DE20102875U1 - Device for neutralizing condensate water in boiler systems - Google Patents

Description

(18 570)

Device for neutralising condensate water accumulating in boiler systems

The innovation relates to a device for neutralising condensate water accumulating in heating boiler systems, in particular condensing boiler systems, according to the preamble of claim 1.

When operating heating boilers, especially condensing boilers, acidic condensate forms on the heat exchanger surfaces of the heating gas flue pipes at low exhaust gas temperatures. This condensate is aggressive towards some materials used in wastewater pipes and must therefore be neutralised before being discharged into normal household wastewater.

According to DE 198 01 066 Cl, several device variants of neutralization devices or systems are known. What these devices have in common is that the condensate is fed via a supply line to a container filled with neutralization agent, remains in contact with the neutralization agent for a certain period of time and then leaves the container via a discharge connection.

Magnesium oxide is often used as a neutralizing agent. This is stored in the container in the form of a granulate bed and over which the acidic condensate flows. Metal ions and other substances initially dissolved in the condensate, which were washed out of the heat exchanger material by the condensate, are deposited on the surface of the neutralization granulate and in this way practically isolate the granulate balls, so that the exchange of substances between the condensate and the granulate increases as the neutralization process progresses.

is increasingly hindered, even though the amount of neutralizing agent would actually have been usable for a considerably longer period without the contamination by the metal ion deposits. Moreover, the contamination of the neutralizing agent usually takes place relatively evenly throughout the volume of the granulate bed.

The aim of the innovation is to avoid this disadvantage, i.e. to ensure in the case of a neutralization device in the simplest possible way that the amount of neutralizing agent used is available for the neutralization process for as long as possible.

This object is achieved with a neutralization device of the type mentioned at the outset by the features mentioned in the characterizing part of claim 1.

According to the innovation, the condensate flows through the supply connection into a neutralization tank that has at least two chambers, both of which are filled with neutralizing agent. It is now important that the condensate initially only reaches the first chamber due to appropriate flow guidance and there releases the metal ions in particular to the granulate in a first neutralization process. Only then, and this is what is meant by the term "serial" (in series), does the condensate water reach the second chamber, in which the granulate remains free of metal ion deposits for a considerably longer time due to the "pre-filtering" in the first chamber.

The wording "at least two chambers" expresses the fact that, of course - and this is preferred - three or more chambers in succession

can be connected in order to increase the service life of the neutralizing agent. The total amount of granulate corresponds approximately to that which is accommodated in a single chamber in the prior art. As mentioned, magnesium oxide granulate is preferably used as the neutralizing agent.

Tests have shown that with this segment-like arrangement, the granulate is increasingly less protected in the flow direction chamber by chamber, i.e. the device has a considerably longer service life and thus longer maintenance intervals.

An advantageous development of the device is that each chamber has an inlet and an outlet and is filled with neutralizing agent up to a certain fill level and that both the inlet and the outlet are arranged geodetically above the fill level, with a condensate guide pipe leading from the inlet to the chamber floor area. This design means that condensate flowing into the chamber is first guided into the lower chamber area. From there it then rises within the chamber due to the inflowing condensate and under reaction contact with the neutralization granulate up to the outlet, which (depending on the number of chambers) leads either to the next neutralization stage (chamber) or to the discharge connection.

To further extend the service life, it is planned that either a sludge chamber and/or a dirt chamber filled with activated carbon can be installed upstream of the at least two chambers. While the sludge chamber serves to separate out coarse contaminants, the activated carbon ensures that the remaining hydrocarbons and other dirt particles in the condensate water are bound.

The innovation and its advantageous developments according to the dependent claims 2 to 5 are explained in more detail below with reference to the drawing of an embodiment.

It shows

Fig. 1 shows a perspective view of a neutralization device with sludge and dirt chamber as well as a three-stage magnesium oxide neutralization and

Fig. 2 in side view and in section the device according to Fig. 1.

Fig. 1 shows in perspective and partly in section a possible embodiment of the novel device for neutralizing condensate water accumulating in heating boiler systems, in particular in oil condensing boilers. The device consists of a container I ₁ provided with inlet 2 and outlet connection 3, which can be filled with neutralizing agent 4 for neutralizing the condensate water flowing from the inlet 2 to the outlet connection 3.

For this device, it is now essential that the container 1 has at least two (three are shown), each of which can be filled with neutralizing agent, which are provided with a flow guide 5 which conducts the condensate water serially through the chambers 11, 12, 13.

It is further provided (see also Fig. 2) that each chamber 11, 12, 13 has an inlet 51 and an outlet 52 and is filled with neutralizing agent 4 (preferably magnesium oxide granulate) up to a certain filling level H.

and that both the inlet 51 and the outlet 52 are arranged geodetically above the filling level, with a condensate guide pipe 53 leading from the inlet 51 to the chamber floor area.

The same arrangement of inlets and outlets and condensate guide pipes is also provided for the sludge chamber 6 and dirt chamber 7 upstream of the three chambers 11, 12, 13, whereby the former is designed as a pure "settling chamber" for the rough pre-cleaning of the condensate and the latter is filled with activated carbon in particular for the binding of hydrocarbons.

In an alternative embodiment, not shown, it is provided that each chamber has an inlet and an outlet and is filled with neutralizing agent up to a certain fill level, and that the inlet is arranged in the chamber floor area and the outlet above the fill level. In this case, so that the condensate also flows from bottom to top through the chambers, the chambers must either be designed to rise in steps towards each other or a corresponding condensate guide pipe is provided between the individual chambers, which connects a higher outlet of a first chamber with a lower inlet of a second chamber.

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List of reference symbols

1 container 2 Supply connection 3 Discharge connection 4 Neutralizing agent 5 S tflow guidance 6 Mud chamber 7 Dirt chamber 11 chamber 12 chamber 13 chamber 51 Intake 52 Sequence 53 Condensate guide pipe

Claims (5)

1. Device for neutralizing condensate water accumulating in heating boiler systems, in particular condensing boiler systems, comprising a container ( 1 ) provided with an inlet ( 2 ) and outlet connection ( 3 ), which can be filled with neutralizing agent ( 4 ) for neutralizing the condensate water flowing from the inlet ( 2 ) to the outlet connection ( 3 ), characterized in that the container ( 1 ) has at least two chambers ( 11 , 12 ), each of which can be filled with neutralizing agent, which are provided with a flow guide ( 5 ) which conducts the condensate water serially through the chambers ( 11 , 12 ). 2. Device according to claim 1, characterized in that each chamber ( 11 , 12 ) has an inlet ( 51 ) and an outlet ( 52 ) and is filled with neutralizing agent ( 4 ) up to a certain filling level and that both the inlet ( 51 ) and the outlet ( 52 ) are arranged geodetically above the filling level, with a condensate guide pipe ( 53 ) leading from the inlet ( 51 ) to the chamber floor area. 3. Device according to claim 1, characterized in that each chamber ( 11 , 12 ) has an inlet ( 51 ) and an outlet ( 52 ) and is filled with neutralizing agent ( 4 ) up to a certain filling level and that the inlet ( 51 ) is arranged in the chamber bottom area and the outlet ( 52 ) is arranged above the filling level. 4. Device according to one of claims 1 to 3, characterized in that the at least two chambers ( 11 , 12 ) are optionally preceded by both a sludge chamber ( 6 ) and/or a dirt chamber ( 7 ) filled with activated carbon. 5. Device according to one of claims 1 to 4, characterized in that the neutralizing agent ( 4 ) is formed from magnesium oxide granules.