DE3151418A1 - Low-temperature heating process, utilising the upper calorific value of fuels - Google Patents

Abstract

The invention relates to a heating process for utilising the upper calorific value of fuels, in particular for a low-temperature heater, in which fuel is burned in a heating device with formation of combustion gas and the combustion gases formed initially flow upwards or sideways in the heating device, and it is characterised in that the combustion gases are passed downwards in a part of their flow path with precipitation of condensate. The precipitation of condensate takes place on surface-coated heating surfaces which have, as the coating, preferably a corrosion-resistant dense metal, for example an electrodeposited layer of chromium-nickel or the like, but especially an electrodeposited gold layer. At the outlet, the combustion gases then have a temperature of only 40 DEG C to 45 DEG C.

Description

Description The invention relates to a heating method for exploitation the upper calorific value of fuels, especially for low-temperature heating, in which fuel is burned in a heating device with the formation of fuel gas and wherein the resulting fuel gases flow initially or sideways.

In heating technology, more and more filters are used to determine whether they are being used of all the energy present in the fuel. For good energy utilization boilers are known in which a partial condensation of the fuel gases on the upper, heating surface cooled by return water and another Weil condensation on the Outer wall takes place These known boilers are traversed from bottom to top and condensation occurs on extremely large areas.

It is the object of the invention to provide a heating method and a heating device indicate the heating devices compared to the known, nit partial condensation Utilize the fuel even further and achieve previously unattainable levels of efficiency enable. The upper calorific value of the fuel should be used to the full without corrosion damage due to the formation of condensate in the device appear.

The object is achieved in that the fuel gases in part of their Flow path are guided downwards with condensate separation. By a downward Leadership following the usual upward and zim part sideways guidance occurs advantageously such a considerable extension in a surprisingly small device of the heat exchange path, i.e. complete condensation with very simple means of the water vapor contained in the burner gas can be achieved. So is the invention with simple means a complete utilization of the upper heating element of the fuel achieved. At the same time, there is a good direct current flow of condensate and Fuel gas that leads to rapid condensate drainage and problem-free condensate removal leads. The cooled, condensate-free combustion gases escape advantageously from the lower ones Part of the heater.

In an embodiment of the invention it is provided that the condensate separation takes place on surface-coated heat exchange surfaces. The deposition of the Condensate on surface-coated heat exchange surfaces allows both the To design heat exchange areas optimally high loadable and small, as well as one Eliminate corrosion completely.

In a further embodiment of the invention it is provided that the heat exchange surfaces a corrosion-resistant, dense metal, e.g. galvanic, as a coating deposited chromium, nickel or similar layer, but in particular an electrodeposited one Have gold layer. For the coating of the heat exchange surfaces of the individual Internal parts of the heating device have proven themselves in various materials. as Non-corrosive, dense metal layers, e.g. chrome- or nickel layers, but in particular electrodeposited gold layers shown. In connection with a corrosion-resistant substrate material, e.g. a chrome-nickel-molybdenum steel of type 18/12/1 then results in a version which is absolutely corrosion-resistant even for heating oils with a higher sulfur content.

In an embodiment of the invention it is provided that the fuel gases at a temperature of 30.degree. to 00.degree. C., but in particular a temperature, at the outlet from 400 to 450 ° C. These lirennllas exit temperatures are special cheap and represent an optimum between the Main fuel of the heater and the energy utilization of the fuel.

In a further embodiment of the invention it is provided that the condensate Collected in the lower part of the heater and separated from the fuel gas naxh below is discharged. This is an advantageous, complete removal of the condensate from the fuel gas reached, which makes it possible to choose a cost-effective exhaust gas route and to do without a chimney, e.g. by using a fan! That's how it is an inexpensive, energy-saving heating renovation of old buildings without the installation of central, Heating systems connected to the existing chimney are possible.

In a further embodiment of the invention it is provided that the condensation energy is used in particular to preheat the heating return water. Through this Measure is ensured that, despite the low exhaust gas temperature, no undesirable Heat exchange from the return water in the exhaust gas can occur.

A heating device is provided to carry out the heating process, in which the combustion of the fuel in the lower part of an inner heat transfer and gas guiding body takes place, which is preferably designed as a junction cylinder and has a deflection device for the fuel gases on its upper side. Through this Heating device can advantageously be in an Icompakten unit, the dimensions of 400 to 500 lim in diameter and 1000 to 1200 mm in height need not exceed, the complete condensation of the fuel gases according to the invention with a heating power from 10 to 30 kW can be achieved. The exhaust gas temperature is no longer than 400 C to 450 C, at most 600 C.

In a further embodiment of the device it is provided that un the inner warning transition and gas guide body arranged a heat exchanger enveloping body which, like the inner heat transfer and base body, is cylindrical or centrally symmetrical is formed and the inner heat transfer and gas guide body is preferably coaxial encloses. This ensures good heat transfer over long distances in contact all parts of the fuel gases with the heat exchange surfaces guaranteed.

In a further embodiment of the invention it is provided that at least the outer wall of the inner heat transfer and gas guide body as well as the inner wall of the heat exchanger casing has a corrosion protection layer. Through the Corrosion protection layer, it is possible to prevent the condensate from separating to master the significant corrosion problems that occur. In particular, heating oil contains a not inconsiderable amount of sulfur, chlorine etc., which together with the water, which is separated out as condensate, forms acids that are normal Would destroy boiler steel quickly. A corrosion protection layer can corrosion of the surfaces on which condensate is deposited can be reduced.

In an embodiment of the invention it is provided that the corrosion protection layer is a galvanically applied layer and that material of the corrosion protection layer Chromium, nickel or the like, but especially gold.

A galvanically applied layer can with the current level of Galvanization technology have an absolutely impermeable and pore-free surface. if as corrosion protection material chrome, nickel or similar corrosion-resistant materials earth used, but especially if gold is used, also results in the case of thin layers that only consist of relatively few atomic layers, one complete freedom from corrosion for years of trouble-free operation guarantees. So are the previous ones Concerns of the professional world against the Utilization of the upper calorific value, i.e. the condensation energy in the combustion gases, lapsed and it can be economically beneficial from the top Calorific value of fuels, both gas and oil or even coal, Be made use of.

It is stipulated that the basic material for the internal heat transfer around the gas guide body and the coaxial heat exchanger shell made of stainless steel is.

Stainless steels can be combined well with the aforementioned dense layers galvanize and then also offer corrosion protection, such as the corrosion protection layer should be mechanically damaged.

In a further embodiment of the invention it is provided that the inner Heat transfer and gas guide body as well as the outer heat exchanger enveloping body are designed as smooth-surfaced cylinders. The outer heat exchanger casing should have a preferably smooth, closed top surface, which acts as a deflection device serves for the fuel gases and closes the heat exchanger casing in a gas-tight manner at the top. This results in a particularly favorable, smooth, compact shape of the invention Heating device parts for the application of galvanic layers, sprayed Layers or similar particularly favorable form. So is not just of material, but The special training also ensured that the necessary freedom from corrosion is achieved.

To complete the invention it is further provided that the lower part of the heating device has a condensate collecting chamber with a gas-tight one Has condensate discharge line So is for the absolutely necessary discharge of the condensate provided, with a condensate discharge line serving as a gas False air intake etc. is excluded. The condensate self can easily be discharged into the sewage system after appropriate dilution will.

The invention is explained in more detail with reference to a drawing that shows a schematic Ausrfihrunt) shows and from the further advantageous details can be taken are.

In the drawing, 1 denotes the burner, which is shown schematically with his Flame 2 is shown, which has a temperature of approximately 10,000 C. Dic fuel gases 5 rise into the space formed by the inner heat passage and gas guide body 4 5 and are deflected according to the arrow 5 '. You can do this as needed Flow through gas guide body 14, which give it additional swirl.

The inner diameter of the heat transfer and gas guide body is 150 to 250 mm depending on the output of the heating device. So he is very beneficial small. The thickness of the heat transfer and gas guide body 4 is 10 to 20 mm. The diameter of the outer heat exchanger casing 6 is 250 to 350 mm.

During operation, they form predominantly on the outer wall of the heat exchanger casing Condensate droplets 6 ″, also on the lower part of the heat transfer and gas guide body 4. The condensate droplets 6 "and 7" advantageously flow in cocurrent with the fuel gases from their precipitation areas and are collected in the lower part of the heater and discharged through the line 12 according to the condensate discharge arrow 12 '.

The fuel gas, which is cooled down to 300 to 600 C, preferably 400 C is, occurs according to the arrow 8 'through the exhaust pipe 8 from the lower part the heater off. The return water from the heating system passes through the pipe 9 according to the arrow 9 'initially in the heat exchanger shear shell 6 and, after it has flowed through it, via the pipe connections in the lower part of the heating device is fed to the heat transfer and gas guide body 4, which it flows through from top to bottom in order to reach the maximum temperature of approx. 80 ° C to exit through the line 10 according to the arrow 10 '.

The fuel for the burner 1 is supplied through the line 11 and the insulation 15 shields the heating device from outside (at) and causes it advantageously only has an outside temperature that is approximately room temperature is equivalent to.

The burner device according to the invention is particularly suitable for boilers from 10 to 30 kw heating output, i.e. for heating 1 to 2 fan houses thought. Without departing from the spirit of invention, however, it can also be used for can be used for heating individual apartments or larger houses. What all types of use have in common is that it is not only the upper calorific value of the fuel is fully utilized, but also the temperature range between 1000 C and 40 ° C of the fuel gas. This results in a previously unattained high level of efficiency a heating device without the service life of the Heater goes down. Appropriate material and construction precautions are required for this met Blank page

Claims (15)

Annex to the patent application from Klaus Hermann, 5840 Schwerte low-temperature heating process with utilization of the upper calorific value of fuels. Claims 1. Heating method for utilizing the upper calorific value of fuels, especially for low-temperature heating, in which in a Heating device with fuel gas formation fuel is burned and with the resulting Fuel gases in the pickling device initially flow upwards or sideways, d a d u r c h g e -k e n n n z e i c h n e t that the combustion gases are in part of their flow path are led downwards with condensate separation. 2. Heating method according to claim 1, d a d u r c h g ek e n n z e i c Ii n e t that the condensate separation on surface-coated heat exchanger surfaces takes place. 3. Heating method nacii claim 2, d a d u r c h g e -k e n n z e i c h n e t that the heat exchanger surfaces have a corrosion-resistant coating dense metal, e.g. an electrodeposited chrome-nickel or similar. Layer, in particular however, have an electrodeposited gold layer. 4. Heating method according to claim 1, 2 or 3, d a d u r c h g e k d n n z e i c h n'e t that the combustion gases have a temperature of 300 when they exit up to 600 C, but in particular a temperature of 400 to 450 C on Wei-Seil. 5. Heating method according to claim 1 2, 3 or 4, -d a -d u r c h r, c i; Note that the condensate is collected in the lower part of the heating device and is discharged downwards separated from the fuel gas. 6. Meizverfahren according to claim 1, 2, 3, 4 or 5, d a -d u r c h g e k e nn n n e i n e t that the condensation energy is used in particular for preheating is used by heating return water. 7. Heating device for carrying out the heating process according to a of claims 1 to G d a d u r c L1 g ek e n n z e i c h n et that the combustion of the fuel in the lower part of an inner heat transfer and gas guide body (4) takes place which is preferably designed as a hollow cylinder and on its Top has a deflection device for the fuel gases. 8. Heating device according to claim 7, d a d u r c h g e -k e n n z e 1 c h n e t that urt the internal heat transfer and gas guide body (4) is a heat exchanger Enveloping body (6) is arranged, which like the inner heat transfer and gas guide body (4) is cylindrical or central-syrmetrical and the inner Heat transfer and encloses the gas guide body (4) preferably coaxially. 9. Heating device according to claim 7 or 8, d a d u r c 10 g e k e n n z e i h n e t that at least the outer wall of the inner heat transfer and Gas guide body (4) as well as the inner wall of the heat exchanger enveloping body (6) a Has corrosion protection layer. 10. Heating device according to claim 9, d a d u r c h g e -k e n n z It is clear that the corrosion protection layer is a galvanically applied layer is. 11. Heating device according to claims 9 or 10, d a -d u r c h g e e no indication that the limaterial of the anti-corrosion coating is chromium, nickel or the like, but especially gold. 12. Heating device according to claim 7, 8, 9, 10 or 11, d a d u r c h e k e 11 n z e i n e t that the basic material for the internal heat transfer - and gas guide body (4) and the heat exchanger casing (6) made of stainless steel is. 13. Heating device hach one of the preceding claims, d d a it is indicated that the inner heat transfer and gas guide body (4) as well as the heat exchanger casing (6) designed as a smooth-surfaced cylinder is. 14. Heating device according to one of the preceding claims, d a it is indicated that the heat exchanger enveloping body is preferably a has smooth closed top surface, which acts as a deflection device for the fuel gases serves and closes the heat exchanger enveloping body gas-tight at the top. 15. Heating device according to one of the preceding claims, d a d u r c h h e e n n n e i n e i n e t that it has a condensate collecting chamber in the lower part having a gas-tight condensate discharge line (12). - Description -