NL8102249A - COMBUSTION DEVICE. - Google Patents

Description

«'V *« -1- 21894 / CV / rav

Short Designation: Combustion Device.

The invention relates to combustion devices for the combustion of solid fuel, for example wood, coke, coal and the like, provided with a first combustion chamber and a second combustion chamber, wherein both chambers have separate feeds for combustion air.

Attempts have been made with known combustion devices of the above type to achieve post-combustion of incomplete combustion gases by supplying secondary air to the combustion chamber. However, tests have shown that the intended effect is only very rarely obtained in small combustion plants, and that if result is obtained it is due to accidental advantageous conditions.

15 As a result of the signs of a future energy shortage, interest in using forest products as a source of domestic heating has increased. Demand will therefore arise for a combustion device which, without pollution of the environment, is capable of burning forest products and such fuels with the greatest possible efficiency and the best possible degree of controlled combustion.

It is a feature of this type of combustion devices that the fuel undergoes incomplete (pyrolytic) combustion at a relatively low temperature in a first chamber. In this process, 25 flammable (pyrolytic) gases are released with a value depending on the temperature and shape and composition of the fuel. The temperature in the first chamber depends on the value of the combustion taking place therein and consequently on the supply of primary air and the thermal insulation of the first chamber. The total potential energy scattering will therefore be the sum of the intensity of the primary combustion and the heating value of the pyrolytic gases. Controlled dispersion of energy at all times requires adjustment of the amount of primary air and the isolation of the primary chamber to the fuel in use.

In order to ensure complete combustion of the pyrolytic gases and thereby achieve high efficiency, it will be necessary to supply secondary air to the gases under controlled conditions of quantity, temperature and residence time.

8102249 -2- 21894 / CV / pl

Combustion can be effected effectively in a separate second chamber with suitable heat insulation and supply of air.

An object of the present invention is therefore to obtain a combustion device for burning solid fuel in which the combustion takes place in two phases, ie first in a first chamber and then in a second chamber in such a way that a high efficiency of the incinerator is obtained and the incinerator must further be designed to provide controlled combustion.

According to the invention, this can be achieved in that both chambers are thermally insulated in such a way that the production of pyrolytic gases in the first chamber takes place within a predetermined space, while the temperature in the second chamber is sufficiently high to allow a complete combustion of cause all pyrolytic gases. Usually, the highest temperature is required in the secondary chamber and this is an indication of better thermal insulation for this chamber than in the first chamber.

A further feature of the invention is that the second chamber is designed as a two-stage combustion chamber. The size of an optimal second chamber will depend on the energy distribution of the combustion device. A two-stage secondary chamber will thereby ensure good secondary combustion over a wide adjustment range, since the low-dispersion combustion will take place in the first stage and higher-dispersion combustion will be completed in the second stage.

A further feature of the invention is to provide a heat exchange surface between a secondary air inlet passage and an exhaust passage for the hot combustion gases of the second chamber to preheat the combustion air admitted to the second chamber.

A further feature of the invention is that the secondary air passage opens into the space between the first and the second chamber.

A preferred embodiment of the invention is characterized in that the secondary air passageway is located in the dividing wall between the first chamber and the second chamber, while the passageway is insulated against the first chamber and has a heat exchange surface to the second chamber. The result is pre-heating of the secondary air.

4 8102249 * r -3- 21894 / CV / pl

Yet a further feature of the invention is that a heat source is located in the second chamber or in the air supply passage to the second chamber, wherein the heat source is supplied with external energy and can for instance be formed by an electric heating element. In accordance with the invention, the energy distributed by this heat source can be controlled by: a) temperature in the second chamber, or b) the temperature rise in the second chamber, or c) the temperature in the first chamber, or to d) a combination of parameters a, b and c.

In order to lower the ignition temperature for the gases in the second chamber, it is a feature of the present invention that the second chamber may be equipped with a catalytic converter. An alternative to this feature is that the second chamber is equipped with plates, rods or the like which have a low thermal inertia, so that combustion of combustion gases will take place more easily than with a free gas atmosphere.

In order to ensure a self-regulating combustion process with high efficiency under all conditions, regardless of the type of fuel or the shape or varying drawing conditions, a feature of the invention may be that a fan is provided to ensure an even air supply to the combustion. In a favorable embodiment, the fan is driven by means of a thermoelectric element arranged on one of the walls in one of the combustion chambers, preferably the second chamber. The fan can be controlled by a thermostat.

The invention will be explained in more detail below with reference to a schematic embodiment of the construction according to the invention shown in the accompanying figure.

The exemplary embodiment of the combustion device shown comprises a first chamber 1 from which at least an upper wall 2 is insulated.

However, it is also possible to insulate the side walls if this will prove necessary for raising the temperature in the first chamber if a predetermined calorific value is required. Combustion air for the primary chamber is drawn through draw holes 4 in the front of the combustion device.

The combustion gases from the primary chamber 1 are fed through an opening 5 at the rear wall 3 into the second chamber 6. This chamber is designed as a two-stage chamber in which the combustion, if the energy dispersion is low, occurs in stage 1, while combustion will be completed in stage 2 if energy dispersion is high. Combustion air for the second chamber is supplied through a draw opening 7 in the front of the combustion device in a passage 8 in the top wall 2 of the first chamber. The supply of combustion air is adjusted so that the primary air and the secondary air are controlled simultaneously. The passage 8 is insulated from the first chamber in the manner shown in the figure, but equipped with a heat exchanger surface 9 to the outlet passage 10 of the second chamber. The second chamber has good thermal insulation, so that it is sufficient. high temperatures (750-100 ° C) are obtained. To ensure ignition with a complete combustion of the combustion gases in the second chamber, ie the temperature will be higher than the ignition temperature for the gases, a heating element 12 with external energy supply can be used. The heating element 12 can, as shown, be formed by an electric heating element, but the heating element can also be formed by an oil burner, a gas burner and the like. The heating element may be arranged in the secondary air supply passage 8 instead of in the second chamber itself. As already mentioned above, the second chamber can be provided with a catalytic surface, for example a platinum or rhodium composition, so that the ignition temperature for the combustion gases is lowered. The second chamber can also be equipped with plates, rods or similar members, which have a certain thermal inertia, so that the ignition of the combustion gases will take place more easily than in a free gas atmosphere. It is noted that the application of a heating element, a catalyst rods or the like with thermal inertia can be done alone or in combination.

The hot gases from the second chamber 6 are vented through an outlet 10 and return to the leading edge of the top wall 11 and flow through a passage 13 at the top of the top wall 11 to the chimney 14. From the outlet of the passage 10 to the chimney 35 distributes the combustion gases the greatest possible amount of heat and passage 13 is therefore equipped with a heat exchanger for transferring the heat to the environment.

The chimney 14 may be provided with a fan 15, which can be powered by electric current from a thermocouple 16 located on the hot wall surface of the passageway 81 02 2 49 * * · * -5- 21894 / CV / mv The thermocouple will generate an electric current, which depends on the temperature difference between the hot side of the wall and the environment. The fan 15 can be controlled by a thermostat, so that the supply of combustion air is made dependent on a desired room temperature. Starting a cold combustion device can be carried out • with the help of an auxiliary battery if the thermocouple does not generate electricity, while natural draft through the chimney can also be used.

10 The external supply of energy to the second chamber will not be required at all times. To control this supply of energy the following parameters must be taken into account: a) the temperature in the second chamber. If this temperature falls below 800 ° C, the supply of external energy is required if flue gas still flows from the first chamber. A temperature sensor may then be provided in the second chamber.

b) temperature rise from inlet to. exhaust in the second combustion zone. A positive value, which is not due to the supply of energy, indicates that combustion gas still to be burned flows.

C) the temperature in the first room. A low limiting value indicates that the combustion device has run out of fuel and consequently there is no need for external energy supply.

By combining these parameters in the form of, for example, electrical signals from thermocouples, thermistors or similar devices, it is possible to obtain a fully automated and complete combustion of all flammable gases.

-CONCLUSIONS- 81 02 2 4 9

Claims (13)

1. Combustion device for combustion of a solid fuel such as wood, coke, coal and the like, comprising a first combustion chamber and a second combustion chamber, each of which has a separate supply for combustion air, characterized in that both chambers (1, 6 ) are thermally insulated, preferably in such a way that the secondary chamber is better insulated against heat than the primary chamber. Combustion device according to claim 1, characterized in that the second chamber is designed as a two-stage chamber, such that complete combustion can take place within a wide range of energy distribution. Combustion device according to claim 1 or 2, characterized in that a heat exchange surface (9) is arranged between an inlet passage (8) for secondary air and an outlet passage (10) for the hot combustion gases of the secondary chamber (6). ) to preheat the combustion air for the secondary chamber. Combustion device according to one of the preceding claims, characterized in that the passage (8) for air supply to the secondary chamber (6) opens into the space (5) between the primary chamber (1) and the secondary chamber (2). . Combustion device according to one of the preceding claims, characterized in that the air passage (8) for air supply to the secondary chamber (6) is arranged in a dividing wall (2) between the first chamber (1) and the second chamber (6). ) and the secondary chamber outlet (10), and includes a heat exchange surface to the outlet (10). Combustion device according to any one of the preceding claims, characterized in that the volume, the insulation and the supply of combustion air to the primary chamber (1) are sized to result in an even combustion value and pyrolysis in order to obtain a correctly adjusted amount to produce unburned gases, (CO), which is vented to the second chamber (6). Combustion device according to any one of the preceding claims, 35dB, characterized in that the volume, the insulation and the supply of secondary air to the second chamber (16) are sized to obtain ignition and complete combustion of the pyrolytic gases. 8. Combustion device according to one of the preceding claims, 81 02 2 4 9 «- - - -? 21894 / CV / mv, characterized in that the secondary chamber (6) or the secondary air supply passage (8) is equipped with a heating source (12) with external energy supply. Combustion device according to any one of the preceding claims, characterized in that the second chamber (6) is equipped with a catalyst, so that the ignition temperature for the gases in this chamber is lowered. Combustion device according to any one of the preceding claims, characterized in that the second chamber (6) is equipped with plates, rods or similar members which have a certain thermal inertia, so that the combustion of combustion gases will take place more easily than with a free gas atmosphere. Combustion device according to any one of the preceding claims, characterized in that a fan (15) is arranged to ensure a uniform air supply to the combustion, so that a controlled combustion is obtained. Combustion device according to claim 11, characterized in that the fan (15) is driven by means of a thermocouple (16) mounted on one of the walls in one of the combustion chambers or at the outlet of the second room (6). Combustion device according to any one of the preceding claims 8-12, characterized in that the heating source (12) is controlled by: a) the temperature in the second chamber (6), or b) the temperature rise in the second chamber (6) , or c) the temperature in the first chamber (1), - or d) a combination of the above parameters a, b or c. Eindhoven, May 1981.8102249