DE29618380U1 - Heater with a burner powered by a fuel-air mixture - Google Patents

Description

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R.29294-1
17.10.199S Se/Sm

ROBERT BOSCH GMBH, 70442 Stuttgart
10

Heating device with a burner fed by a fuel-air mixture
15

State of the art

The invention is based on a heating device according to the generic features of the main claim. In heating devices which use the condensation heat of the water vapor contained in the combustion gas or in which the exhaust gas is cooled to a value below the dew point temperature of approx. 55° C, the exhaust gas must be heated again after leaving the heat exchanger to a temperature behind the device of at least 8 0 ⁰ C so that the exhaust gas discharge remains free of condensate. In known heating devices of the generic type, a partial flow of the combustion gas is mixed with the exhaust gas emerging from the heat exchanger via a bypass in an unregulated manner, i.e. unaffected by the exhaust gas temperature. This means that when designing the device, an exhaust gas temperature above the limit of 80° C must be assigned to nominal load operation if this limit is to be guaranteed not to be undercut in minimum load operation.

Furthermore, heating devices of the generic type are known (AT 1358/93) in which the entire exhaust gas volume flow is passed through an annular space surrounding the combustion chamber with the combustion chamber wall as a heat transfer surface for the purpose of reheating.

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In this design, too, the ring heating is not specifically controlled, so that the same problems arise here as with the previously described device type.
5

DE-OS 40 27 569 describes a heating boiler that operates with variable output, in which the exhaust gas temperature in the flow direction behind the heat exchanger fins is regularly kept above the dew point. In the special case that the exhaust gas temperature in such a device drops below the dew point, a thermally controlled bypass line is provided, which raises the exhaust gas temperature so much that the exhaust gas discharge connected to the heat exchanger remains free of condensate. In contrast to such a heating boiler, the exhaust gas in the generic heating devices is deliberately cooled below the dew point in order to be able to use the heat bound in the water vapor of the exhaust gases or to be able to carry out low-temperature operation. The temperature of the exhaust gas exiting the heat exchanger is then raised to a value of at least 80° C by adding heat from the combustion gas.

Advantages of the invention

The measure according to the invention according to the features of the main claim enables the exhaust gas temperature to be kept as close as possible to the prescribed minimum temperature over the entire load range of the heater. If the exhaust gas temperature behind the heat exchanger is low at minimum load, a relatively large amount of heat is supplied from the combustion gases. As the load increases, the heat supply is deliberately throttled so that the resulting exhaust gas temperature exceeds the prescribed minimum value as little as possible.

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This means that the condensation heat of the water vapor is used optimally and the efficiency is further increased compared to, for example, a condensing boiler with uncontrolled reheating of the exhaust gas. It also means that conventional exhaust gas accessories for chimney or external wall devices can be used.

The features listed in the subclaims enable advantageous embodiments of the arrangement according to the main claim.

An arrangement that only differs slightly from a conventional combustion chamber design is obtained if the heat supply from the combustion gas used to reheat the exhaust gas takes place via a bypass channel connecting the combustion chamber with an exhaust gas chamber, the effective flow cross-section of which is controlled or regulated depending on the load and/or the temperature of the heated medium.

An alternative embodiment arises when the heat supply from the combustion gas takes place in a heat exchanger that is acted upon by the combustion gas, through which a partial flow of the exhaust gas flows and to which a controlled or regulated bypass is preferably assigned.

Exact control of the resulting exhaust gas temperature in the entire performance range of the heater can be achieved if the heat supply from the combustion gas is controlled or regulated depending on at least one state variable of the exhaust gas.

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This proposal can be easily implemented if the heat supply is controlled or regulated depending on the exhaust gas temperature.

Instead of the exhaust gas temperature or in addition to it, the moisture content of the exhaust gas can also be recorded and used to control or regulate the heat supply.

If the heat supply is controlled or regulated depending on the speed of a fan acting on the burner or the volume flow conveyed by the fan, heat and/or humidity-sensitive sensors and actuators in the exhaust gas path are unnecessary.

In heating devices in which the exhaust gas is reheated, as already mentioned above, by adding hot combustion gas via a bypass channel, or in which a heat exchanger through which a partial flow of the exhaust gas flows and which is acted upon by the combustion gas is bridged by a bypass, a simple design is obtained if the effective cross-section of a bypass channel is monitored by a valve element, preferably arranged at the junction of the bypass channel with the exhaust gas chamber, which valve element is influenced by at least one internal operating parameter.

The valve member can be influenced by mechanical and/or electrical or electronic components. For a mechanical solution, it is proposed that a heat-sensitive control member is designed as an elongated bimetal element, around which the exhaust gas flow flows, clamped on one side, to the free end of which the valve member is attached, preferably thermally insulated.

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As further advantageous embodiments for the heat-sensitive control element, a spiral-shaped bimetal element or an expansion element can be provided.
5

The heat-sensitive control element can be arranged both upstream and downstream of the inlet of the bypass channel in the exhaust gas chamber. In the case of electronic control or regulation, a temperature sensor and possibly a humidity sensor can be arranged downstream of a flow safety device or, in the case of an external wall device, at the end of an exhaust pipe.

drawing

Eight embodiments of the invention are shown schematically in the drawing and explained in more detail in the following description. Figures 1 to 8 each show the parts of a heating device of interest here according to one of the embodiments.

Description of the embodiments

The heating device according to Figure 1 has a burner 1, to which a fuel gas-air mixture is fed by a fan (not shown). The burner 1 is located at the upper end of a combustion chamber 2, which is closed off at the bottom by a heat exchanger 3 of known design. Downstream of the heat exchanger 3 there is an exhaust gas chamber 4, at the lowest point of which a condensate drain 5 is provided. The exhaust gas chamber 4 is designed downstream as an exhaust pipe 6, which leads upwards to a chimney or external wall connection (no longer shown).

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A bypass channel 8 is connected to the combustion chamber 2 and opens directly into the exhaust pipe 6, bypassing the heat exchanger 3. The opening is monitored by a valve cone 9 which is attached in a thermally insulated manner to the free end of a bimetallic strip 10 clamped on one side. This is arranged in front of the opening of the bypass channel 8 in the exhaust pipe 6 in such a way that it is swept lengthwise by the exhaust gas emerging from the heat exchanger 3.

The bimetal strip 10 is designed in such a way that it deforms clockwise as it heats up, whereby the valve cone 9 increasingly narrows the opening cross-section of the bypass channel 8. When the heater is operating at minimum load, the bimetal strip 10 assumes the initial position shown, in which the opening cross-section is narrowed the least and a relatively large amount of gas from the combustion chamber 2 is mixed with the exhaust gas flow rising in the exhaust pipe 6. When the heater is operating at nominal load, the valve cone 9 has throttled the admixture from the combustion chamber 2 to such an extent that the resulting exhaust gas temperature does not significantly exceed the prescribed minimum value of 80 ⁰ C.

In the other embodiments, identical or equivalent parts are identified by the same reference numerals as in Figure 1. In the heater according to Figure 2, the heat-sensitive control element for the bypass channel 8 is a bimetal spiral 12 clamped on one side, to the free end of which the valve element designed as a cap 14 is attached, which closes the bypass channel 8 more or less depending on the load. The mode of operation is the same as in the previously described embodiment.

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In the embodiment according to Figure 3, the heat-sensitive control element is designed as an expansion element 16, which is fastened in the exhaust pipe 6 by a corresponding holding device. The expansion element 16 is connected at its free end via a working piston 20 to the valve element designed as a valve cone 9, which closes the bypass channel 8 more or less depending on the load operation of the heater. The expansion element 16 works in a manner known per se: If the exhaust gas temperature in the exhaust pipe 6 increases, the expansion filling melts, with its volume increasing significantly. This increasingly narrows the opening cross-section of the bypass channel 8. When the exhaust gas temperature drops, a return spring 22 causes the working piston 20 to move back.

In the heating device according to Figure 4, the fuel-air mixture is supplied to the burner 1 by a fan 24, the speed or delivery volume of which is controlled according to the heat requirement of the device. The opening of the bypass channel 8 into the exhaust pipe 6 is monitored by a valve closing element 26, which is mechanically coupled to an adjustment device 28. This is pneumatically actuated by a control pressure, which is derived from the delivery volume flow of the fan 24 in a pressure generator 30 in the delivery line 32. This and the control pressure increase with increasing heat requirement, whereby the adjustment device 28 increasingly closes the opening of the bypass channel 8 as desired. The arrangement could also be such that the speed of the fan 24, which is controlled depending on the heat requirement, is electronically evaluated and transmitted as an electrical control signal to a correspondingly designed adjustment device.

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In the heater according to Figure 5, the exhaust pipe 6 opens into an exhaust box 34 designed as a flow protection device, in the outlet area of which a sensor 36 measuring the moisture content of the outflowing exhaust gas and a sensor 38 detecting the exhaust gas temperature are arranged. The sensor signals are transmitted via an electronic evaluation circuit 40 to a correspondingly designed adjustment device 42 for the valve closing element 26 monitoring the bypass channel 8.

The heating devices according to Figures 6 to 8 differ from the previously described designs in that the reheating of the exhaust gas takes place in a heat exchanger which is acted upon by the combustion gas and through which a sub-quantity of the exhaust gas flows which is controlled or regulated depending on the load or the temperature of the heated medium.

In the heater according to Figure 6, the exhaust space 4 is connected via the exhaust pipe 6 to a heat exchanger 44, which is arranged in the combustion chamber 2 and is exposed to the hot combustion gases. The exhaust space 4 is also connected via a bypass channel 46 to an exhaust pipe 48, which leads from the heat exchanger 44 into the exhaust box 34. The flow cross sections of the exhaust pipe 6 and the bypass channel 46 are monitored by valves 50, 52, the flap-shaped closing elements of which are each influenced by a bimetal element exposed to the exhaust gas temperature.

The valves 50, 52 and the flow cross sections of the exhaust pipe 6 and the bypass channel 46 are designed and dimensioned in such a way that, depending on the exhaust gas temperature, a greater or lesser proportion of the exhaust gas volume flows through the heat exchanger 44 and is heated there. In extreme cases, i.e.

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Minimum load, the valve 52 can close the bypass channel 46, so that the entire exhaust gas volume flows through the heat exchanger 44 and the resulting temperature of the incoming exhaust gas reaches the prescribed minimum value. 5

The heating device according to Figure 7 differs from the previously described device only in that the heat exchanger for the exhaust gas is not arranged in the combustion chamber 2, but is integrated into the heat exchanger 3 for the medium to be heated.

In the heater according to Figure 8, an annular space 54 leads from the exhaust gas chamber 4 into the exhaust gas box 34, which surrounds the combustion chamber 2 and the heat exchanger 3 at a radial distance. The exhaust gas chamber is also connected to the exhaust gas box 34 via a bypass channel 46. The flow cross sections of the annular space 54 and the bypass channel 46 are monitored by valves 56, 58, 60, the closing elements of which are influenced by bimetal elements exposed to the exhaust gas temperature.

The annular space 54, together with the combustion chamber wall 62 serving as a heat transfer surface, forms a heat exchanger for an exhaust gas flow, the proportion of which in the total exhaust gas volume is controlled in the desired direction by the valves 56, 58, 60.

The subject matter of the invention is not limited to use in heating devices with condensing technology, but can also be used in so-called low-temperature heating systems, where due to low flow and return temperatures, particularly in the partial load range, there is a risk of the exhaust gas falling below the dew point in the exhaust gas discharge.

Claims (10)

•# · ·1&Igr;* - 10 - R. 29294-1 17.10.1996 Se/Sm ROBERT BOSCH GMBH, 70442 Stuttgart Claims 1. Heating device with a burner fed by a fuel-air mixture, a combustion chamber and a heat exchanger in which the combustion gas cools below the dew point of the water vapor at least in the lower power range of the device, furthermore with a device arranged in the exhaust gas path for raising the exhaust gas temperature to a value permissible for chimney or external wall connection by supplying heat from the combustion gas, characterized in that the heat supply from the combustion gas is controlled or regulated depending on the load and/or depending on the temperature of the heated medium. 2. Heating device according to claim 1, characterized in that the heat supply from the combustion gas used to reheat the exhaust gas takes place via a bypass channel (8) connecting the combustion chamber (2) to an exhaust gas chamber (6), the effective flow cross-section of which is controlled or regulated. 3. Heating device according to claim 1, characterized in that the heat supply for reheating the exhaust gas takes place in a heat exchanger (44, 54) acted upon by the combustion gas, through which a partial flow of the exhaust gas flows - 11 - R.29294-1 and to which a controlled or regulated bypass (46) is preferably assigned. 4. Heating device according to one of claims 1 to 3, characterized characterized in that the heat supply is controlled or regulated depending on at least one state variable of the exhaust gas. 5. Heating device according to claim 4, characterized in that the heat supply is controlled or regulated depending on an exhaust gas temperature. 6. Heating device according to one of claims 1 to 4, characterized in that the heat supply is controlled or regulated depending on the moisture content of the exhaust gas. 7. Heating device according to one of claims 1 to 3, characterized in that the heat supply is controlled or regulated depending on the speed of a fan (24) acting on the burner or the volume flow conveyed by the fan. 8. Heating device according to claim 2, characterized in that the effective flow cross-section of the bypass channel (8) is monitored by a valve member (9, 14, 26) preferably arranged at the junction of the bypass channel (8) with the exhaust gas chamber (6), which is influenced by at least one internal operating parameter. 9. Heating device according to claim 8, characterized in that a heat-sensitive control element (10) is an elongated bimetallic element, around which the exhaust gas flows, clamped on one side, to the free end of which the valve element (9), preferably thermally insulated, is attached. R.29294-1 10. Heating device according to claim 2, characterized in that a heat-sensitive control element is an expansion element around which the exhaust gas flows and which is fastened to a holding device (18).