EP0057831A1 - Heating device - Google Patents

Abstract

A heating device is described, having a combustion chamber (1) for an oil or gas burner and a fan (3) for conveying air flowing to the combustion chamber (1) and against a heat exchanger (4), wherein, to increase the efficiency and provide a compact structure, a spherical combustion chamber (1) is used downstream of which a cylindrical heat exchanger (4) is installed, through which pass pipes (9) which are open at both ends, and whose diameter at least substantially corresponds to the diameter of the combustion chamber sphere (1). <IMAGE>

Description

The invention relates to a heating device, consisting of a combustion chamber for an oil or gas burner, a heat exchanger through which the hot gases emerging from the combustion chamber flow, a fan for conveying the air to be heated, the combustion chamber and heat exchanger flowing, and a combustion chamber, heat exchanger and fan surrounding casing .

Heaters of this type are used in a variety of ways, especially as air heaters. With increasing size, i.e. increasing performance, it is becoming increasingly difficult in the known devices to achieve good efficiency or to maintain the prescribed exhaust gas temperatures. In order to ensure the necessary heat exchange between the hot gases and the air to be heated, increasingly larger and thus also heavier heat exchanger arrangements are required, which lead to the fact that in many cases the simple mobility or transportability of the overall device equipped with the heating oil storage container is required becomes problematic or impossible.

The object of the present invention is therefore to design a device of the type specified at the outset in such a way that, with a compact and space-saving design, there is a substantial improvement in the efficiency and thus high-performance devices can also be built as devices which can be moved without problems.

This object is achieved according to the invention in that the combustion chamber is spherical and in that the cylindrical heat exchanger connected downstream thereof and in the air flow direction has a diameter of a plurality of tubes which are open at both ends has a diameter which at least essentially corresponds to the diameter of the combustion chamber ball.

By designing the combustion chamber in a spherical shape, it is possible, on the one hand, to heat exchange, i.e. to share in the transfer of thermal energy to the air conveyed by the blower and, on the other hand, to apply an air flow to the entire end face of the downstream heat exchanger and thus to all the pipes extending through the heat exchanger, thus ensuring maximum use of the entire heat exchanger, which in turn is used for As a result, the overall efficiency is significantly increased while maintaining the required low exhaust gas temperatures.

By designing the combustion chamber in a spherical shape, the effect of the air flow clinging to a ball can be exploited, which ensures that the slipstream effect which is always present behind the combustion chamber in known air heaters with a conventional combustion chamber is avoided, which leads to a highly uneven load and therefore poor utilization the downstream heat exchanger led.

The connecting channel between the interior of the spherical combustion chamber and the heat exchanger preferably runs at least substantially parallel to the longitudinal axis of the overall device and expediently extends from the top vertex region of the combustion chamber ball to the outer peripheral region of the heat exchanger. Within the spherical combustion chamber, the diameter of which is selected so that the flame can burn out clearly, there is an extremely even flame and thus heat distribution, which in turn has a favorable effect on the transfer of thermal energy to the air flowing around the ball and conveyed by the fan.

According to a special embodiment of the invention, the flow around the spherical combustion chamber can be further promoted in that at least one chicane is provided which extends inwards from the casing and leaves an annular passage space around the ball. The number of such baffles can be selected according to the respective circumstances and can also be determined experimentally.

The heat exchanger is preferably subdivided approximately in the middle by a wall in such a way that a passage for the hot air guided through the heat exchanger remains free on the bottom side, and thus a comparatively long flow path for the hot gases results without a disturbing back pressure being able to build up.

In order to prevent a too high proportion of radiant heat from the injection opening for the hot gases into the heat exchanger is transferred directly to the fume chimney provided at the opposite end, a curved baffle plate is arranged opposite this injection opening according to a further embodiment of the invention Umbrella function and on the other hand performs a streamlined deflection function and thus contributes to a more uniform heat distribution in the heat exchanger.

According to one embodiment variant, a radial fan is used as the fan, since a desired high dynamic pressure can be generated by means of such a radial fan. The burner air required for the respective burner can be derived directly from the blower, and it is also easily possible to connect the required oil pump on the combustion chamber side to the blower drive shaft if an oil burner is used.

An embodiment of the invention is explained below with reference to the drawing; the only figure of the drawing shows the basic structure of a heating device according to the invention in a highly schematic manner.

The most important component of the heating device shown is a spherical combustion chamber 1 with a burner 2, which can be an ^* oil burner or a gas burner. The location of this burner 2 depends on the existing structural conditions and is not of critical importance for the overall function of the combustion chamber.

The diameter of the combustion chamber 1 is chosen so that a clear burning out of the flame is ensured. A major advantage of a spherical combustion chamber is generally that it guarantees a surprisingly low-noise combustion, ensured by the soft flame and hot gas deflection on the inner wall, with extremely uniform wall heating.

This uniform wall heating in turn makes it possible to achieve an optimal transfer of heat to the air conveyed by means of a blower 3 and blown against the spherical combustion chamber.

The air flow nestles against the combustion chamber due to the spherical shape of the combustion chamber and covers practically the entire surface of the combustion chamber.

The combustion chamber is followed by a heat exchanger 4, which is connected to the combustion chamber 1 via a channel 5, which leads from the apex region of the spherical combustion chamber to the peripheral region of the combustion chamber-side end face of the heat exchanger 4.

The heat exchanger 4 has a centrally arranged wall 6, which extends to near the floor and leaves a passage there, so that there is a relatively long, substantially U-shaped flow path to the exhaust port 8 for the hot gases entering via the channel 5.

In order to avoid that the exhaust pipe 8 or. the area of the heat exchanger assigned to this exhaust pipe 8 is heated too much by radiant heat and thus the exhaust gas temperature is increased in an undesirable manner, a curved deflecting and shielding plate 7 is provided opposite the mouth of the channel 5.

The heat exchanger 4 extends in a known manner a multiplicity of tubes 9 which are open at both ends and through which the amount of air conveyed by the blower and which has already been heated by the flow around the combustion chamber wall, and which emit thermal energy to this amount of air.

The entire arrangement of fan 3, combustion chamber 1 and heat exchanger 4 is surrounded by a cover 11 forming a guide channel, which is preferably hexagonal in cross section. The free flow cross section between ball combustion chamber 1 and cladding 11 is reduced in the area of combustion chamber 1 by at least one baffle 10 in such a way that the air flow nestling against the ball surface is promoted.

If an oil burner is used, the required pump 12 is preferably driven by the fan drive.

Since, due to the design of the heating device according to the invention, it is more compact and, due to the optimal use of the heat transfer possibilities, even with larger outputs weight-saving construction is possible, a required reservoir 13 for oil in the device without problems, preferably attached to the underside, without the mobility and handling of the overall device being impaired too much.

The main reason that despite the performance improvement achieved can be used with a comparatively small heat exchanger is that all exchanger tubes 9 can be charged essentially uniformly, because the tubes actually lying in the slipstream of the combustion chamber due to the spherical shape which nestles the air flow, can be fully loaded, as indicated in the drawing by arrows.

The use of the spherical combustion chamber is not limited to the heating device described, but can, for example, also be used advantageously in all those cases in which low-noise but nevertheless complete combustion is important.

Claims (12)

1.Heating device, consisting of a combustion chamber for an oil or gas burner, a heat exchanger through which the hot gases emerging from the combustion chamber flow, a fan for conveying the air to be heated, the combustion chamber and heat exchanger flowing in, and a combustion chamber, heat exchanger and fan surrounding casing characterized in that the combustion chamber (1) is spherical and that the cylindrical heat exchanger (4) connected downstream thereof and in the air flow direction has a diameter of at least substantially the same diameter as the combustion chamber ball, through a plurality of tubes (9) which are open at both ends. 2. Device according to claim 1, characterized in that the blower (3), spherical combustion chamber (1) and heat exchanger (4) follow one another in an axially aligned manner and that the covering (11) surrounding them forms an air duct. 3. Device according to claim 1, characterized in that the connecting channel (5) between the interior of the spherical combustion chamber (1) and the heat exchanger (4) runs at least substantially parallel to the longitudinal axis of the device and opens in the region of the outer circumference of the heat exchanger. 4. The device according to claim 3, characterized in that the connecting channel (5) leads from the region of the apex of the combustion chamber ball (1) to the heat exchanger (4). 5. Device according to one of the preceding claims, characterized in that a hot gas deflection wall (6) is provided at least substantially in the middle of the heat exchanger (4) and transversely to its longitudinal axis. 6. The device according to claim 5, characterized in that opposite to the hot gas inlet opening in the heat exchanger (4) a curved baffle plate (7) extending to the deflection wall (6) is provided. 7. The device according to one or more of the preceding claims, characterized in that a baffle (10) reducing the free flow cross section is arranged between the casing (11) and the spherical combustion chamber (1). 8. The device according to claim 7, characterized in that the baffle (10) engages around the ball combustion chamber (1) and leaves an annular air passage on the ball side. 9. The device according to claim 7 or 8, characterized in that the baffle (10) with respect to the center of the spherical combustion chamber (1) is offset in the direction of the heat exchanger (4). 10. The device according to one or more of the preceding claims, characterized in that the fan (3) is designed as a radial fan. 11. The device according to claim 10, characterized in that a branch tunnel for the combustion air required by the burner (2) is provided in the peripheral region of the radial fan (3). 12. The device according to one or more of the preceding claims, characterized in that the flame axis is directed at least substantially diametrically and the flame obliquely downwards, and that the smoke outlet leading from the ball combustion chamber is arranged in relation to the burner in the upper region of the ball combustion chamber.

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