NL1014358C2 - Channel system, esp. for high energy boilers, comprises discharge channel for combustion gases which are delivered by connector to discharge channel whose wall is lined with water-repellant agent - Google Patents

Abstract

The channel system(1) comprises a discharge channel(2) built materials such as concrete, chamotte or bricks while the water-repellent agent comprises a water-repellent impregnating agent to prevent water of condensation from being transported, as a result of capillary action of the wall of the discharge channel to an outer side of the discharge channel. The channel system also has an air supply(16) for supplying outside air to the discharge channel. The temperature of the combustion gases in the discharge channel is lowered, to about 50 degree centigrade, so that water vapor pressure in the discharge channel is lowered to prevent water vapor from being transported outside through the wall of the discharge channel and also to extend the life of the water-repellent impregnating agent. An Independent claim is also included for a method of adapting an existing channel system.

Description

Title: Duct system, especially for high-efficiency boilers

The invention relates to a duct system comprising a flue gas discharge channel of at least one combustion system and at least one connection for supplying the flue gases of the at least one combustion system to the discharge channel.

The invention also relates to a method for adapting an existing duct system comprising a flue gas discharge duct from at least one combustion system and at least one connection for supplying the flue gases from the at least one combustion system to the discharge duct, to obtain a channel system according to the invention.

Duct systems comprising architectural ducts for the discharge of flue gases are known and are used, for example, in conventional central heating boilers. These duct systems often consist of architectural materials such as concrete, chamotte or brick.

In the past, so-called shunt channels were used in most 20 cases in the past. These channels consist of a main channel with a secondary channel on each floor. Conventional central heating boilers were connected to the auxiliary channels. The flue gases are removed naturally. For this it is desirable that there is a thermal draft in the channel.

Water vapor is one of the products that is formed during the combustion of natural gas. This water vapor is passed through the flue system with the flue gases and can condense in the flue system. Since architectural materials from which duct systems are often built up have very small pores that connect the inner wall to the outer wall, this can result in condensation flowing through the capillary action of the inner wall to the outer wall of the duct system. The result of this is that the outer wall becomes soaked. A first adverse effect of this is that moisture problems arise in a house adjacent to the channel system. A second disadvantageous effect is that the architectural materials that make up the discharge channel are affected by the condensation. This happens partly because the condensation water is acidic. Fresh condensed water has a pH value of approximately 2.

The object of the invention is to meet the drawbacks mentioned and is characterized in that a wall of the discharge channel is provided with a water-repellent agent, such as a water-repellent impregnating agent or a water-repellent coating, to prevent moisture, due to the capillary action of the wall of the drain, is transported from the drain to an outside of the drain. The water-repellent agent prevents (condensation) water from entering the wall as a result of the capillary action. The adhesion effect for water has been converted into a cohesion effect. 20 The (condensation) water now remains in the form of drops on the inner wall of the channel. The (condensed) water may flow down.

Hydrophobizing is a process in which the wall of the drain is treated with water-repellent impregnating agent. Hydrophobing uses the capillary action of the wall, drawing the water repellant into the wall of the drain and then adhering to the pores of the wall. The application of water-repellent coatings takes place by means of surface treatments. If the agent comprises an impregnating agent, it does not form a vapor-inhibiting layer, so that in the direction of the discharge channel transport of moisture in the form of water vapor through the wall of the discharge channel can still take place. According to a preferred embodiment, the channel system is further characterized for this purpose in that the channel system is further provided with means for lowering the temperature of the flue gas in the discharge channel so that the water vapor pressure in. the drain is lowered. With this reduction of the water vapor pressure, a transport of water in the form of water vapor from the inner wall towards the outer wall of the discharge channel is prevented and it is even possible that a transport of water vapor from the outer wall to the inner wall takes place. This creates the possibility of realizing a channel system consisting of a building material with small pores, without this channel system showing any form of moisture to the outer wall. In the case where the water vapor pressure of the flue gas in the discharge channel is nevertheless higher than the water vapor pressure on the outer wall of the discharge channel, a transport of water vapor from the discharge channel to the outer wall will still occur. However, the extent to which this happens will be less than in a comparable situation where the described regulation to a lower water vapor pressure would not have been carried out. A further advantage of regulating the water vapor pressure is that the life of the water-repellent agent is extended due to the associated lower temperature of the flue gas in the exhaust duct.

A further elaboration of the invention is characterized in that the means for lowering the temperature comprise air supply means for supplying air to the exhaust duct, so that the temperature of the flue gases in the exhaust duct decreases.

In the case where the combustion system is not in operation, which is roughly 85% of the time on average over the entire heating season, the supplied air also absorbs and discharges moisture from the discharge channel.

35 Since the introduction of high-efficiency boilers in the early 1980s, it has not been permitted to connect these boilers directly to 1014358 4 conventional construction channels. This applies in any case if the channels consist of a material that contains small pores. The reason for this is that flue gases in high-efficiency boilers are cooled in such a way that 5 water vapor condenses in the boiler and in the drain. The result is that the drain becomes soaking wet inside and moisture penetration takes place. A possible solution for this is to replace the drain with a flexible plastic discharge pipe or with a metal discharge pipe in existing homes when replacing a conventional central heating boiler 10 with a high-efficiency boiler. Another possible solution is to connect the high-efficiency boiler to a separate duct system. This separate duct system can be installed both indoors and outdoors. A drawback of an external duct system is that provisions have to be made to prevent ice from condensation from forming. In that case, the duct system must, for example, be double-walled. One of the drawbacks of such elaborate channel systems is that these channel systems are expensive and do not look attractive. A separate indoor channel system has the drawback that installing it will cause a lot of inconvenience for the residents and it will be at the expense of the living space. Whatever the case, any of the measures described above are expensive. The method of the invention is therefore characterized in that an inner wall of the drain is provided with a water-repellent agent, such as a water-repellent impregnant or a water-repellent coating, to prevent moisture, in use, due to the capillary action of the wall of the drain, is transported from the drain to an outside of the drain.

In particular, it holds here that the channel system 35 is further provided with means for lowering the temperature of the flue gas in the discharge channel for decreasing the water vapor pressure in the discharge channel.

The invention is explained in more detail with reference to the drawing. Herein: figure 1 schematically shows a possible embodiment of the channel system according to the invention; figure 2 shows a section of the channel system according to figure 1 along the line AA; figure 3 shows an alternative embodiment of a part of the channel system according to figure 1; and figure 4 schematically shows an alternative embodiment of a channel system according to the invention.

In Figure 1, reference numeral 1 denotes a channel system according to the invention. The duct system 1 is provided with a discharge duct 2 for a flue gas of at least one combustion system 4.1 (1 = 1,2, ..., N). In this example, the discharge channel 2 is provided with a main channel 6 and on a plurality of secondary channels 8.1 (1 = 1,2, ..) located on different floors 3.1 (1 = 1,2, ..., N) of a house 20. ., N) each of which opens into main channel 6. The side channels 8.1 each preferably have a length of at least two meters. In this example, the secondary channels 8.1 form a shunt 10.I (1 = 1,2, ..., N).

25 Each side channel is equipped with a connection 12 for the connection of one of the combustion systems 4.1. Via this connection 12, the combustion system 4.1 supplies flue gas to the associated secondary channel 8.1.

In this example, the discharge channel 2 is constructed from 30 architectural materials such as concrete, chamotte or bricks. In this example, the inner wall of the discharge channel 2 has been treated with a water-repellent impregnating agent. This is called hydrophobing. As a result of the capillary action of the wall of the discharge channel, the impregnating agent is drawn into this channel wall and adheres to walls of pores in the channel wall. This water-repellent impregnating agent prevents moisture, as a result of the capillary action of the wall of the drain 2, from being transported from an inside of the drain 2 to an outside of the drain. In this example, both the main channel 6 and the secondary channels 8.I have been treated with the said water-repellent impregnating agent. If the space permits, it is of course also possible to treat an outside of the discharge channel 2 with the impregnating agent, which in the final product is mainly concerned with the impregnating agent that the impregnating agent in the pores of the wall 19 of the discharge channel has been drawn.

The duct system is further provided with means for lowering the temperature of the flue gas in the exhaust duct, so that the vapor pressure in the exhaust duct is reduced. In this example, the means for lowering the temperature include air supply means 16 for supplying air to the exhaust duct so that the temperature of the flue gases in the exhaust duct 2 decreases. The air supply means 16 in this example are provided with supply channels 18.1 (1 = 1,2, ..., N) for supplying air to each of the auxiliary channels 8.1. The supply channels 18.1 are additionally provided with a connection 20 for supplying air to the combustion systems 4.1 which, in use, are connected to the auxiliary channels 8.1 for dispensing. flue gases.

The operation of the channel system according to figure 1 is as follows.

In use, the combustion systems 4.1, in this example High Efficiency (HR) boilers, will draw in air for combustion via the supply channels 18.1. At the same time, the combustion means 4.1 will give off flue gases to the side channels 8.1 via the connections 12. As a result of the relatively low temperature of the flue gases, condensation of water in the discharge channel 2 can occur. Because the discharge channel is provided with the aforementioned 1 o 14358 7 water-repellent impregnating agent, the absorption of condensation water in the channel wall 19 of the discharge channel 2 (see figure 2) is prevented. The condensation water adheres to the inner wall of the channel in the form of drops.

5 When several drops are formed, the water even flows down into the drain 2.

Furthermore, cool air, in this case outside air, is supplied to the exhaust channel 2 via the supply channels 18.1. In particular, in this example, the air 10 is supplied to the exhaust channel 2 near the connection 12. All this has the consequence that the temperature of the flue gas in the discharge channel 2 will drop. As a result, the water vapor pressure in the discharge channel 2 will decrease. The latter has a number of 15 advantages.

At temperatures of flue gases such as those that occur in practice with HR boilers, the water vapor pressure in the discharge channel is higher than the water vapor pressure on the outside of the discharge channel, in particular in the home. As a result, in the permeable hydrophobized channel wall, transport of water vapor occurs from an inner wall 21 in the direction of an outer wall 22 of the discharge channel (see figure 2). A drop in temperature occurs in the wall 19 from the inside to the outside. When the maximum water vapor pressure is reached at a location in the wall, condensation of the water vapor occurs at that location. Further condensation occurs from the considered point to the outer wall 22. As a result, the outer wall 22 of the discharge channel can still become soaked.

However, because the temperature of the flue gas in the discharge channel is lowered, so that the water vapor pressure is also lowered, the transport of water vapor from the inner wall 21 through the wall 19 towards the outer wall 22 will decrease. As a result, the water vapor pressure can even be lower for a large part of the time than the water vapor pressure in the house. As a result, at least for a large part of the time, no transport of water vapor at all occurs from the inner wall 21 of the discharge channel in the direction of the outer wall 22 of the discharge channel. Transport 24 will occur earlier in the opposite direction (see figure 2). As a result, the outer walls 22 of the discharge channel do not get wet.

If water vapor is correctly transported from the outer wall 22 in the direction of the inner wall 21 as shown with reference to arrow 24 in figure 2, this is not a problem in itself. After all, the outer wall 22 does not get soaked and condensation water which may form on the inner wall of the discharge channel 2 cannot be transported back to the outer wall 22 thanks to the impregnating agent.

In particular, therefore, it holds that the means for lowering the temperature of the flue gas are designed such that the water vapor pressure in the discharge channel is lower than the water vapor pressure outside the discharge channel. A further advantage of lowering the temperature of the flue gases in the discharge channel 2 is that the impregnating agent will degrade less quickly. In the winter period, the temperature of the flue gases from the HR boiler can rise to 100 ° C. At this temperature, the impregnating agent could degenerate very quickly. In order to guarantee a lifespan of at least 10 years, it is preferable to keep the temperature of the combustion gases low. In the present embodiment, this is achieved by mixing the flue gases with outside air. Mixing the flue gases with outside air therefore has not only the function of reducing the water vapor pressure in the discharge channel 2, but also of preventing the impregnation agent from degrading relatively quickly as a result of high temperatures.

1 0 U358 9

By continuously supplying outside air, during the period that the combustion systems 4.1 are not in operation, the condensation drops and the condensation water will be absorbed in the outside air flowing past. This prevents accumulation of 5 condensed water in the drainage channel 2. Roughly speaking, the combustion means 4 have been in operation for the entire heating season, only about 15% of the time. During the remaining 85% of that time, the condensation water contained in the discharge channel 2 is absorbed into the outside air flowing past. This prevents accumulation of condensation water.

Figure 3 shows an alternative variant that could also be used in the system according to figure 1. 15 parts corresponding to Figure 1 are provided with the same reference numbers.

According to the variant according to Figure 3, the air supply means 16 comprise at least supply channels 18.1 for supplying air to the exhaust channel 2. The supply channels 18.1 functionally correspond in this respect to the supply channels 18.1 as discussed in relation to Figure 1. However, the device is further provided with second supply channels 24.1 which are arranged separately from the supply channels 18.1. The supply channels 24.1 are each arranged to be coupled, in use, to the combustion systems 4.1 for supplying combustion air to these combustion systems 4.1. Both the first supply channels 18.1 and the second supply channels 24.1 are in open communication with the outside air and in this example have therefore been led outside through an outer wall 25 of a house for the purpose of receiving air. In particular, the supply channels 18.1 and / or the supply channels 24.1 can each still be provided with an injector. This also applies for the supply channels 18.1 of the embodiment according to figure 1. These supply channels also supply air from an outside of the house and extend for this purpose through the outside wall of the house.

The operation of the channel system according to Figure 3 further corresponds entirely to the operation of the channel system 5 according to Figure 1.

Figure 4 shows a third variant of a channel system according to the invention, in which parts corresponding to Figures 1 and 3 are provided with the same reference numbers. In this example, the combustion systems 4 are supplied with outside air for combustion via the second supply channels 24.1. The flue gases are supplied via the secondary channels 8.I to the main channel 6. However, in this example the aforementioned first supply channels 18.1 are missing. In this example, the temperature of the flue gases in the discharge channel 2 is therefore also lowered in another way. For this purpose, the main channel 6 is provided with air supply means 16 for supplying air to the main channel 6. The main channel 6 is directed substantially vertically, the air supply means 16 being arranged to supply air near a bottom side of the main channel.

In this example, the air supply means 16 consist of a simple opening at the bottom of the main channel 6, through which outside air is supplied to the bottom of the main channel. This cool outside air will decrease the temperature of the flue gases in the main duct, as a result of which the water vapor pressure in the main duct will be reduced. This decrease in the temperature of the flue gases can be such that the water vapor pressure in at least parts of the discharge channel 2 is lower, or is lower for a certain period, than the water vapor pressure outside the discharge channel 2. In particular, the water vapor pressure in the discharge channel lower than the water vapor pressure in the house shown in Figure 4. Therefore, in this example, the

temperature of the flue gas in the secondary channels 8.I

, j 14 358 11 is not lowered. This in itself need not be a problem since these side channels can be formed by plastic or metal pipes. Only the main channel 6 can for instance be manufactured from the above-mentioned architectural materials such as concrete, chamotte or bricks. In this case, therefore, only the main channel 6 is provided with the said water-repellent impregnating agent.

According to the invention, existing channel systems 10 can be easily adapted to obtain channel systems as discussed with reference to Figures 1-4. In the case of the channel system according to figure 1, an inner wall 21 of the discharge channel is provided with the water-repellent agent, such as a water-repellent impregnating agent. This water-repellent impregnation agent will be incorporated in the pores of the wall of the discharge channel 2 to obtain the system according to figure 1. If the secondary channels 8.I are also made of building materials such as concrete, chamotte or bricks, the inner walls of these channels will also be provided with said water-repellent impregnating agent.

In the device according to figure 3, however, only the main channel 6 and the part of the secondary channels 8.1 which extends parallel to the main channel 6 (and also forms the said shunt) consist of the said building materials such as concrete, chamotte or bricks. In this case, therefore, only these parts of the drainage channel on the inner wall are provided with the impregnating agent. The part of the secondary channel 8.1 which extends horizontally in the drawing is a separate conduit which is for instance made of plastic or metal.

In the embodiment variant according to Figure 4, only the inner wall 21 of the main channel 6 is also provided with the water-repellent impregnating agent.

10 1 4 358 12

Furthermore, in any of the aforementioned embodiments, it is possible that instead of a water-repellent impregnating agent, a water-repellent coating can be applied on the inside 21 of the discharge channel 2. Such variants are each considered to fall within the scope of the invention. In the above, the drainage channel was discussed on the basis of a stacked house. However, such a system can also be used in a single-family home. In that case there is generally only a combustion system and possibly a secondary channel. In particular, the secondary channel and the main channel 6 form a discharge channel 2 made of the same material, so that in fact there are no further secondary channels. If the space permits, it is of course also possible to treat an outside of the discharge channel 2 with the impregnating agent, which in the final product is mainly concerned with the impregnating agent that the impregnating agent in the pores of the wall 19 of the drain is drawn. Such variants are each considered to fall within the scope of the invention.

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Claims (30)

A duct system comprising a flue gas discharge duct from at least one combustion system and at least one connection for supplying the flue gases from the at least one combustion system to the discharge duct, characterized in that a wall of the discharge duct is provided with a water-repellent agent, such as a water-repellent impregnating agent or a water-repellent coating, to prevent moisture, as a result of the capillary action of the wall of the drain, from being transported from the drain to an outside of the drain. 2. Duct system according to claim 1, characterized in that the duct system is further provided with means for lowering the temperature of the flue gas in the exhaust duct, so that the water vapor pressure in the exhaust duct is reduced. 3. Duct system according to claim 2, characterized in that the means are arranged to reduce the water vapor pressure in at least a part of the discharge channel such that this water vapor pressure is lower than the water vapor pressure outside the discharge channel. 4. Duct system according to claim 2 or 3, characterized in that the means for lowering the temperature comprise air supply means for supplying air to the exhaust duct, so that the temperature of the flue gases in the exhaust duct decreases. 5. Duct system according to claim 4, characterized in that the air supply means are arranged to supply the air at least near the connection to the exhaust duct. A duct system according to any one of the preceding claims 4 or 5, characterized in that the air supply means are provided with at least one supply duct for air, the supply duct being coupled to both the combustion system and the discharge duct. 7. Channel system according to claim 4 or 5, characterized in that the air supply means are provided with at least a first supply channel and wherein the channel system further comprises at least a second supply channel, wherein the second supply channel is adapted for supplying air to the combustion system and wherein the first supply channel 10 is coupled to the exhaust duct for supplying air to the exhaust duct. 8. Channel system according to any one of the preceding claims, characterized in that the channel system is provided with a main channel and a plurality of side channels, each of which opens into the main channel and which are each provided with a connection of said at least one connection for a combustion system . 9. Channel system according to claim 4 or 5, characterized in that the channel system is provided with a main channel and a plurality of secondary channels, each of which opens into the main channel and which are each provided with a connection of said at least one connection for a combustion system. each side channel being provided with the air supply means for supplying air to each side channel. 10. Duct system according to claim 9, characterized in that the air supply means are provided with supply ducts for supplying the air to each of the secondary ducts and for supplying air to the combustion systems which, in use, are connected to the secondary ducts. 11. Duct system according to claim 9, characterized in that the air supply means comprise at least first air supply ducts, the duct system further comprising second air supply ducts, the second supply ducts each being arranged, in use, to be coupled to the combustion systems for supply air = .M4358 of air to the combustion systems, each auxiliary duct being coupled to one of the second supply ducts for supply of air to the auxiliary ducts. 12. Channel system according to claim 4, characterized in that the channel system is provided with a main channel and a plurality of side channels, each of which opens into the main channel and each of which is provided with a connection of said at least one connection for a combustion system, wherein the main channel is provided with 10 air supply means for supplying air to the main channel. 13. Channel system according to claim 12, characterized in that the main channel is directed substantially vertically, the air supply means being arranged to supply air near a bottom side of the main channel. Channel system according to any one of claims 8-13, characterized in that at least one wall of the main channel is provided with the water-repellent agent. A duct system according to any one of the preceding claims, characterized in that the discharge duct is substantially built up from at least one of the following materials: impregnated concrete or concrete with a coating, impregnated chamotte or chamotte with a coating, impregnated bricks or bricks provided with a coating. 16. Method for adapting an existing duct system comprising a flue gas discharge duct from at least one combustion system and at least one connection for supplying the flue gases of the at least one combustion system to the discharge duct to obtain a duct system according to one of the preceding claims, characterized in that an inner wall of the discharge channel is provided with a water-repellent agent, such as a water-repellent impregnating agent or a water-repellent coating, to prevent, in use, moisture, due to the capillary action of the wall. 14 358 of the drain, is conveyed from the drain to an outside of the drain. 17. A method according to claim 16, characterized in that the channel system is further provided with means for lowering the temperature of the flue gas in the discharge channel for decreasing the water vapor pressure in the discharge channel. 18. A method according to claim 17, characterized in that the means are arranged to reduce the water vapor pressure in at least a part of the discharge channel such that this water vapor pressure is lower than the water vapor pressure outside the discharge channel. 19. A method according to claim 17 or 18, characterized in that the means for reducing the water vapor pressure comprise air supply means for supplying air to the exhaust channel, so that the temperature of the flue gases decreases. 20. A method according to claim 19, characterized in that the air supply means are arranged to supply the air near the connection to the discharge channel. 21. Method as claimed in any of the foregoing claims 19 or 20, characterized in that the air supply means are provided with at least one supply channel for air, the supply channel being coupled to both the combustion system and the exhaust channel. 22. A method according to claim 19, characterized in that the air supply means are provided with at least a first supply channel and wherein the channel system further comprises at least a second supply channel, the second supply channel being adapted for coupling to the combustion system for supplying air to the combustion system and wherein the first supply channel is coupled to the exhaust duct for supplying air to the exhaust duct. 23. Method of the preceding claims 16-22, characterized in that the channel system is provided with a main channel 14 14 358 and a plurality of secondary channels which each open into the main channel and which are each provided with a connection of said at least one connection for a combustion system. 24. A method according to claim 19 or 20, characterized in that the channel system is provided with a main channel and a plurality of side channels which each open into the main channel and each of which is provided with a connection of said at least one connection for a combustion system. each side channel being provided with the air supply means for supplying air to each side channel. 25. Method according to claim 24, characterized in that the air supply means are provided with supply channels for supplying the air to each of the side channels and for supplying air to the combustion systems which, in use, are connected to the side channels. 26. A method according to claim 24, characterized in that the air supply means comprise at least first air supply channels, the channel system further comprising second air supply channels, the second supply channels each being arranged, in use, to be coupled to the combustion systems for supplying air to the combustion systems, each side channel being coupled to one of the second supply channels for supplying air to the side channels. 27. Method according to claim 19, characterized in that the channel system comprises a main channel and a plurality of side channels, each of which opens into the main channel and each of which is provided with a connection of said at least one connection for a combustion system, the main channel being provided with air supply means for supplying air to the main channel. 28. A method according to claim 27, characterized in that the main channel is oriented substantially vertically, wherein the air supply means are arranged to supply air near a bottom side of the main channel. 29. A method according to any one of claims 23-28, characterized in that at least one inner wall of the main channel 5 is provided with the water-repellent agent. 30. A method according to any one of the preceding claims 16-29, characterized in that the discharge channel is substantially built up from at least one of the following materials: impregnated concrete or concrete provided with a coating, impregnated chamotte or chamotte provided with a coating , impregnated bricks or bricks with a coating. \ 0 14 358