ES2230961B1 - CALDERA BODY FOR CONDENSATION BOILER. - Google Patents

Abstract

Heating body for condensing boiler, where the device exchanged; thermal is constituted in two stages that, in relation to the downward circulation of combustion fumes (4), by means of a high temperature exchanger module (5) in copper, arranged closer to the origin of the fumes, and a heat exchanger module low temperature, or condenser module (6) also of copper, disposed further from the source of the fumes, with a surface anti-corrosion treatment; the high temperature exchanger module (5) receives combustion fumes (4) at about 700 ° C, giving them about 150 ° C to 200 ° C; these combustion fumes (4) at less than 200 ° C pass through the condenser module (6) cooled to about 60 ° C; The condenser module (6) receives the cold water which, circulating in the opposite direction to the combustion fumes (4), passes through the condenser module (6) passing to the high temperature exchanger module (5), where it leaves at the temperature of required service

Description

Boiler heating body condensation.

Field of the Invention

This invention concerns a condensing boiler used in heating and water heating apparatus and installations and using a ceramic burner arranged at the top of the boiler's combustion chamber, as well as a fan that forces the downward circulation of the combustion fumes that in their path give up their heat through a heat exchanger device that is internally traveled by the water to be heated
gives.

More particularly the invention relates to a particular conception of the heat exchanger device which will allow substantial yields with dimensions, weights and reduced manufacturing costs.

Prior art

The condensing boiler concept is itself known and is based on harnessing the latent heat of water condensation that occurs when water is precipitated in phase liquid flue from combustion when the temperature of these fall from the "dew point".

These condensing boilers were a alternative to conventional boilers that allowed to reach yields of 130% (in relation to the fuel used), compared to the 90% reached in the latter in which only the heat of combustion was used and, to avoid condensation of the water generated in the fumes of the combustion, these fumes left the boiler at temperatures by above 100ºC, that is to say with a very important amount of residual heat that was wasted for the intended purpose of sanitary water heating.

The reason that conventional boilers They will waste so much heat and, at the same time, a big problem of the current condensing boilers, resides in corrosion derived from the condensation of water from combustion fumes and which, in combination with sulfur and nitrogen oxides existing in these fumes, just producing sulfuric acid and nitric acid, as is known, of great corrosive power.

The corrosive power of sulfuric acid causes copper cannot be used in the construction of exchanger, when it turns out that copper is precisely a material suitable for this purpose, due to its high conductivity thermal

For this reason, in condensing boilers known, the exchanger is made of stainless steel or large thicknesses of an alloy aluminum-silicon. In both cases the conductivity thermal is much smaller than that of copper (of the order of the fifth part and half, respectively), so it is necessary to increase the exchanger size up to dimensions truly extraordinary for comparable results with one made of copper; this oversizing translates into exceptional weight and cost increases, as in Difficulty of space for installation. In the case of using aluminum-silicon alloy is used in large wall thicknesses so that it can withstand corrosion by the sulfuric acid for a period of time sufficiently long.

From an ecological point of view the boilers of  condensation are preferred to conventional ones because, although produce a liquid acid residual discharge, do not pour into the atmosphere oxides of sulfur and carbon that cause acid rain. Instead the liquid acid residue can be treated in sewage treatment plants

Explanation of the invention and advantages

Faced with this state of affairs, the present invention advocates a condensing boiler in which said heat exchanger device consists of two stages that, in relation to said downward circulation of the fumes of combustion, are materialized by an exchanger module high temperature, made of copper and arranged closer to the origin of the fumes, and a low heat exchanger module temperature, or condenser module, arranged further from the origin of the fumes, which has a superficial anti-corrosion treatment; in where, said high temperature exchanger module receives the combustion fumes at an approximate temperature of 700ºC and yields at a temperature much higher than that of water condensation and which is between 150ºC and 200ºC, while these fumes of combustion at less than 200 ° C pass through said condenser module and leave it cooled to an approximate temperature of 60 ° C and, in any case, lower than the water condensation temperature; Y wherein said condenser module receives the cold water that, circulating in the opposite direction to said combustion fumes, it crosses this condenser module and passes to said module high temperature exchanger, where it comes to temperature of service required.

This recommended constitution enables the Obtaining the high performance of boilers condensation without incurring the inconvenience of size, weight, cost and location difficulty suffered by current known constitutions thereof.

Indeed, by unfolding the process in two stages Cooling combustion fumes can be used the great conductivity of copper to build a module high temperature exchanger that is not subject to problems of corrosion because its outlet temperature is still very above the dew point; and on the other hand it takes advantage also the latent heat of condensation in one stage specifically entrusted to the condenser module and that is done already in the temperature environment of the change of state (condensation of water), that is, when combustion fumes have yielded the most of its heat (comparable to a boiler conventional).

For the same temperature range (initial and end) of combustion fumes and water flow to be heated, has verified that the heating body of a boiler of condensation according to this invention weighs between one and two tenths parts, and it costs between a third and half, in comparison with known condensing boilers.

On the other hand, the volume of the device is reduced accordingly, it is very directly related to the dimensions of the exchange device; so it improves substantially its location in the installation.

Regarding the ecological aspect this solution advocated complies in the same way as boilers known condensation; that is, producing a liquid residue acid that goes to the treatment plants, and emitting gases into the atmosphere clean of sulfur oxides, nitrogen and carbon.

Drawings and references

To better understand the nature of the present invention, in the accompanying drawings we represent a preferred form of industrial realization, which is exemplary merely illustrative and not limiting.

Figure 1 is a sectional view illustrating schematically the constitution of a condensing boiler according to the invention.

The following are indicated on it references:

one.-

Ceramic burner

2.-

Combustion chamber

3.-

Blower fan

4.-

Combustion fumes

5.-

High exchanger module temperature

6.-

Low exchanger module temperature or condenser module

7.-

Fuel mixture

8.-

Acidic liquid residue

9.-

Waste gas

10.-

Cold water inlet

eleven.-

Communication channel between modules (5) and (6)

12.-

Hot water outlet

13.-

Air entrance

14.-

Gas inlet

Exhibition of a preferred embodiment

With regard to the figure and references indicated above, a preferred embodiment for a condensing boiler of those used in water heating apparatus and installations and using a ceramic burner (1) arranged high above is illustrated in the attached drawing from the combustion chamber (2) of the boiler, as well as a blower fan (3) that introduces the air (13) that the combustible mixture (7) forms with the gas (14); which forces the downward circulation of combustion fumes (4) that in their path give up their heat through a heat exchanger device that is internally traversed by the water to be heated.
tada

The constitution according to the invention is illustrated  schematically in figure 1, where it is shown that said heat exchanger device consists of two stages that, in relation to said downward circulation of the fumes of combustion (4), are materialized by a module high temperature exchanger (5), made of copper and arranged closer to the source of the fumes, and a module low temperature exchanger, or condenser module (6), arranged further from the origin of the fumes, which has a anti-corrosion surface treatment; where, said module high temperature exchanger (5) receives fumes from combustion (4) at an approximate temperature of 700 ° C and yields to a temperature much higher than that of water condensation and that is between 150ºC and 200ºC, while these fumes of combustion (4) at less than 200 ° C pass through said condenser module (6) and leave it cooled to an approximate temperature of 60 ° C and, in any case, lower than the condensation temperature of the Water; and wherein said condenser module (6) receives the cold water that, circulating in the opposite direction to those fumes of combustion (4), crosses this condenser module (6) and passes to said high temperature exchanger module (5), where it comes from at the required service temperature.

As indicated in Figure 1 the mixture fuel (7) reaches the ceramic burner (1) that ensures a complete combustion producing combustion fumes (4) that they are forced to move down the action of the blower fan (3); these combustion fumes (4) at 700 ° C cross the high temperature exchanger module (5) giving heat until its temperature reaches about 150ºC, this temperature at which the heat exchanger module goes through low temperature, or condenser module (6), where these fumes from combustion (4) is cooled to 60 ° C producing condensation of the water that is combined with the gaseous oxides of sulfur and carbon to form the acidic liquid residue (8) that is collected inferiorly and is sent to the water purifier while the rest of the combustion fumes (4) are sent to the atmosphere already clean of such oxides that would be responsible for the pernicious acid rain. At the same time, the water travels inverse, accessing the condenser module (6) by the input of cold water (10), running this condenser module (6) where receives the latent heat of condensation due to precipitation of water by the consequent cooling of the fumes of combustion (4); through the duct (11) this water accesses the high temperature exchanger module (5) where you receive the rest of heat and is served for use by the hot water outlet (12).

According to a preferred mode of execution of the invention, said high temperature exchanger module (5) and  said capacitor module (6) are integrated forming a unit compact exchanger.

According to another embodiment of the invention, said high temperature exchanger module (5) and said module capacitor (6) are constituted as separate elements attachable with each other.

Claims (3)

1. Heating body for condensing boiler, of the boilers used in water heating and heating equipment and installations and using a ceramic burner (1) arranged at the top of the combustion chamber (2) of the boiler, as well as a blowing fan (3) that forces the downward circulation of combustion fumes (4) that in its path give up its heat through a heat exchanger device that is internally traversed by the water to be heated, characterized in that said exchanger device thermal is constituted in two stages that, in relation to said downward circulation of combustion fumes (4), are materialized by a high temperature exchanger module (5), made of copper and arranged closer to the source of the fumes, and a low temperature exchanger module, or condenser module (6), also of copper, arranged further away from the source of the fumes, which has a treatment superficial anti-corrosion; wherein, said high temperature exchanger module (5) receives combustion fumes (4) at an approximate temperature of 700 ° C and yields them at a temperature much higher than that of water condensation and which is comprised between 150 ° C and 200 ° C, at time that these combustion fumes (4) at less than 200 ° C pass through said condenser module (6) and leave it cooled to an approximate temperature of 60 ° C and, in any case, lower than the water condensation temperature; and wherein said condenser module (6) receives the cold water that, circulating in the opposite direction to said combustion fumes (4), passes through this condenser module (6) and passes to said high temperature exchanger module (5), of where it leaves at the required service temperature. 2. Heating body for condensing boiler, according to the preceding claim, characterized in that said high temperature exchanger module (5) and said condenser module (6) are integrated forming a compact exchange unit. 3. Heating body for condensing boiler, according to the first claim, characterized in that said high temperature exchanger module (5) and said condenser module (6) are constituted as separate elements that can be coupled together.