AT14475U1 - Mobile firing system - Google Patents

Abstract

The invention relates to a mobile combustion system (2) having a combustion chamber (4), a heat exchanger (10), a flue gas path (14) from the combustion chamber (4) through the hot side of the heat exchanger (10), a cooling air path (12) through the cold side the heat exchanger (10) and an electrical system control (26). A great robustness of the firing plant (2) can be achieved by at least a first and a second temperature sensor (28, 30, 32) converting a temperature into a mechanical movement.

Description

Description: The invention relates to a mobile combustion system with a combustion chamber, a heat exchanger, a flue gas path from the combustion chamber through the hot side of the heat exchanger, a cooling air path through the cold side of the heat exchanger and an electrical system control.

A mobile solid fuel burning plant can be used for hay drying, for drying a building or for heating a tent or a building. For this purpose, the solid fuel firing system is driven to the site, parked there and put into operation. For operation, solid fuel is burned in the combustion chamber, the heat released in the flue gas is passed through a heat exchanger. For cooling the heat exchanger, it is flowed through by a cooling air flow, which dissipates the heat from the heat exchanger and is passed in an air flow into the building, the tent, a Heutrocknungsraum or the like.

A mobile firing system is intended to be transported by means of a vehicle to its place of use, operated there and later transported to another site and operated there. Here, the mobile firing system is exposed to high mechanical stresses caused by lifting, depositing and transport on a vehicle with it. In addition, a mobile furnace is usually operated outside a building or tent, so that it is exposed to weather conditions, in particular large temperature fluctuations, which depend not only on the season, but also on the time of day.

It is therefore an object of the present invention to provide a mobile furnace, which is particularly robust.

This object is achieved by a mobile combustion system of the type mentioned, which according to the invention has a first and a second temperature converting the temperature into a mechanical movement temperature sensor.

The invention is based on the consideration that it requires to control the combustion in the combustion chamber of a temperature sensor, which measures a closely related with the combustion temperature as a controlled variable. Temperature sensors are usually operated with low voltage, ie with an operating voltage of 5 V, 10 V or the like. For operation, however, the mobile firing system is powered only by the usual power grid, so with 230 V AC or 370 V three-phase. It is therefore necessary to downsource the operating voltage in order to operate such temperature sensors can. As a result, electrical effort is necessary, which is prone to mechanical stress, in particular Rüttelbewegungen. To save this effort, it is desirable to use temperature sensors that are operable with normal AC voltage.

According to the invention, particularly simple temperature sensors are proposed which are either operable with conventional alternating voltage or rotary voltage or - particularly advantageous - are also usable without operating power supply. The heat can be used to expand a sensor material, and the expansion can be translated directly into mechanical movement of an element. A mechanical movement can be understood as the macroscopic movement of an element, whereby a molecular heat movement is not understood as a mechanical movement. The temperature is converted into a mechanical movement, if an element is present, which performs a change in temperature in particular directly caused by the change in temperature mechanical movement, and this is suitably scanned.

For example, there is the possibility that the temperature sensors have a sensor area which is filled with a fluid, ie liquid or a gas. The fluid expands according to the temperature to which the fluid is exposed so that the temperature is translated into mechanical movement of a fluid container or member. Such a movement can be scanned very easily, for example by a simple scanner or a switch for interrupting the closing of an AC circuit having the operating voltage of the entire furnace. It can be dispensed with both the Umspannung, as well as sensitive sensors.

The temperature sensors are suitably arranged in the flue gas path and serve for measuring the flue gas temperature. Flue gas temperature is a reliable parameter of combustion heat output. If the flue gas temperature is low, the heating power will also be low. If the flue gas temperature exceeds an upper limit, the heating power may be reduced to remain within a desired corridor. The setting of the heating power can be done by setting a fresh air supply into the combustion chamber and / or a fuel supply to the combustion chamber.

However, it is generally possible to arrange the temperature sensors in a location whose gas or element temperature is in a known relationship to the combustion performance, such as the outer wall of the combustion chamber, the heat exchanger or other suitable location.

The furnace is expediently a solid fuel burning plant, as a result, particularly large amounts of heat can be generated at low cost. The combustion chamber is thus provided for burning solid fuel. Wood is particularly favorable as solid fuel, such as wood chips or pellets.

The furnace is a mobile furnace, so it is intended for transport and use at several locations. For this purpose, it expediently comprises a support frame, on which the entire furnace system can be lifted by means of a forklift or a cable suspension and, for example, parked on a loading area.

The system control is expediently used to control the operation of the furnace, in particular for controlling the combustion in the combustion chamber. This regulation can be done by controlling an air supply and / or a fuel supply into the combustion chamber of the combustion chamber. Accordingly, the plant controller has connections to an air blower, a fuel delivery, a valve or the like. The system control can be a high-voltage control, ie with an operating voltage of at least 110 V, which can be dispensed with Umspannaufwand.

In an advantageous embodiment of the invention, the electrical system control is prepared to use the mechanical movement to control the heating operation, ie in particular the combustion in the combustion chamber. The firing system can be easily controlled and robust.

For measuring the temperature, the temperature can be measured and output as such, for example, as the current temperature-indicating information, so that a temperature profile is readable. In contrast, the temperature sensors can be kept particularly simple if they each have a switch which switches when a limit temperature is reached. The temperature sensors can be very robust and the firing system can be reliably operated even under hard mechanical load. The switch is expediently actuated directly by heat generated by the movement, so that it is possible to dispense with the electronic readout of the sensor. Although this does not always make it possible to read the instantaneous temperature, it is sufficient to have at least two limit temperatures for a simple control of the combustion or of the heating operation, so that a heating power can be increased or reduced if the temperature reaches one of the limit temperatures ,

Advantageously, the two temperature sensors are set so that their temperature limits are different from each other. A limit temperature can be used in this way as an upper and a lower limit temperature, between which the flue gas temperature is at least substantially maintained. When the upper limit temperature is reached, a heating power can be reduced and a heating power can be increased when a lower limit temperature is reached.

In a particularly advantageous embodiment of the invention, the temperature sensors are safety temperature limiter. Such are available in various designs on the market cheap, and they are very robust. Safety temperature limiters have a sensor area or sensor whose medium expands when the temperature rises. The expansion causes via a mechanism expediently switching a switch. Switching a plurality of contacts in a thermostat switch of the safety temperature limiter is particularly advantageous. Thus, for example, a first circuit to the contacts 1 and 2 and a second placed on the contacts 1 and 3, wherein the thermostat switch switches depending on the extent of the liquid between the contacts 2 and 3, the contact 1 so either with the contact 2 or the contact 3 connects. According to the switch position, a control element, such as a fan, a valve, a fuel supply or the like can be switched on or off. It is advantageous if both temperature sensors have a switch which is arranged in a 230 V AC circuit.

The limit temperature of the safety temperature limiter can be suitably adjusted, for example by means of a screwdriver. If, for example, a limit value of the temperature or the extent is exceeded, the thermostat switch can be actuated via a transmission mechanism and a circuit can be opened or closed. When again below the limit by at least 5%, in particular at least 10% of the switching value, the thermostat switch can switch back again. This can be done manually, it being expedient if this happens automatically. In this respect, it is advantageous if the safety temperature limiter is a self-releasing safety temperature limiter. The thermostatic switch is thus designed to automatically switch back to its normal position when the temperature has passed the limit in the other direction, with a hysteresis of a few Kelvin is possible.

In order to avoid overheating of the furnace, it is advantageous if a third temperature sensor is present, which is set to a limit temperature which is higher than limit temperatures to which the first two temperature sensors are set. The third and higher limit temperature can be used to switch off the firing system, so that in addition to the regular temperature control nor a safety temperature shutdown is present, which intervenes in case of damage.

In a further embodiment of the invention, it is proposed that the electrical system control is prepared to use switching pulses of the second temperature sensor as the upper and switching pulses of the first temperature sensor as the lower operating temperature limit. The two temperature sensors can be used to control the combustion operation of the furnace.

Conveniently, a switching pulse of a third temperature sensor is used as Abschalttemperaturgrenzwert to stop the plant operation. For this purpose, the electrical system control is expediently also prepared. Switching off the firing system can be done by switching off a secondary air blower. As a result, the combustion of necessary oxygen is removed, so that the flames are very quickly smaller and the heating power collapses.

A particularly simple control of the firing system can be achieved when the electrical system control is prepared to turn on the cooling air blower when you turn on the first temperature sensor. The switching is to be understood in this case that a temperature of the first temperature sensor exceeds its limit, which is expediently the lower temperature limit. From the exhaust gas temperature is thus apparent that the heating power is now sufficient to dissipate heat from the heat exchanger. The cooling air flow is started by the cooling air blower and the heat is blown out of the furnace. In particular, when the first temperature sensor is switched on after starting the operation of the firing system, the fuel supply can be switched from a heating mode to a regular operating mode.

For this purpose, the system control is expediently prepared so that it controls the fuel supply according to a first switching on the first temperature sensor.

Turns on the second temperature sensor, so this is a sign that the flue gas temperature exceeds the upper limit. The electrical system control is expediently prepared to switch off a fuel supply, so that the supply of fuel into the combustion chamber is prevented.

If the exhaust gas temperature falls below the lower temperature limit value, then the first temperature sensor switches off, for example. The heating power is too low to dissipate heat from the furnace in regular ventilation mode. Accordingly, the electrical system control is expediently designed to switch off the cooling air blower when the first temperature sensor is switched off. Advantageously, a secondary air blower for supplying combustion air to the combustion chamber continues to operate, the electrical system control is thus prepared to continue to operate the secondary air blower.

The previously given description of advantageous embodiments of the inventions contains numerous features that are given in the individual subclaims partially summarized in several. However, those skilled in the art will conveniently consider these features individually and summarize them to meaningful further combinations. In particular, these features can be combined individually and in any suitable combination with the firing system according to the invention.

The above-described characteristics, features and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of an embodiment which will be explained in connection with the drawings. The embodiment is illustrative of the invention and does not limit the invention to the combination of features set forth therein. In addition, suitable features of the embodiment may also be considered explicitly isolated and combined with any of the claims.

1 shows a mobile solid fuel firing system with a housing, a combustion chamber and a heat exchanger and FIG 2 shows a temperature sensor in the exhaust path of the mobile Festbrennstofffeuerungsan position of FIG 1, which is connected to an electrical system control.

1 shows a furnace 2 in the form of a mobile solid fuel burning plant, which is prepared for transport to several different sites. The furnace 2 comprises a combustion chamber 4 which is mounted in a frame 6 having at its lower end insertion openings 8 for inserting the fork of a forklift. In the schematic and greatly simplified illustration shown in FIG. 1, only the components essential to the invention are shown, and other essential elements have been omitted for the sake of clarity. The furnace 2 has a rated power of 150 kW in this embodiment and is fueled with solid fuel, such as wood chips, wood pellets and the like.

The resulting from the combustion hot exhaust gases are discharged upwards in an exhaust path 14 from the combustion chamber 4 and supplied in an exhaust gas stream to a heat exchanger 10 of the furnace 2 from above. The exhaust gas is passed in a first train from top to bottom and then in a second train from bottom to top through the heat exchanger 10 and then blown upwards.

To remove the heat of combustion from the exhaust gas flow, a cooling air flow is guided in a cooling air path 12 in a countercurrent flow to the exhaust gas flow 14. The cooling air is sucked in as outside air by a cooling air blower 16 directly from the surroundings of the furnace 2 and blown through the two trains of the heat exchanger 10 in countercurrent to the exhaust stream 14. The heated in the heat exchanger 10 cooling air flow 12 then strikes the outer shell of the combustion chamber 4 and flows around the combustion chamber 4. On the other side of the combustion chamber 4, the air is blown in this embodiment through an outlet opening 18 from the furnace 2 and is there with the rated power of 150 kW available, eg for the heating of the building. The combustion chamber 4 is cooled by the cooling air flow 12 so that its outside temperature remains relatively cool and suitable for mobile use.

As shown in FIG 1, the cooling air flow 12 flows around not only the combustion chamber 4 per se, but also an exhaust passage 20, through which the exiting the combustion chamber 4 hot exhaust gas is fed into the heat exchanger 10. The arranged above the combustion chamber 4 part of the exhaust passage 20 is in this way an additional heat exchanger for transporting the heat of combustion in the cooling air or useful air for the Fleizung. By this additional heat exchanger, the exhaust gas is cooled by at least 50 ° C.

In the exhaust duct 20, a flue gas fan 22 is arranged, which sucks the flue gas from the heat exchanger 10. This results in the heat exchanger 10, in the exhaust passage 20 between the combustion chamber 4 and the heat exchanger 10 and in the combustion chamber 4 itself a suppression of about 30 mbar. By this suppression prevents flue gas from the furnace 2 can escape to an undesirable location. In addition, this can be achieved in case of failure of the flue gas blower 22, an immediate interruption of the secondary air supply.

A secondary air supply opens into the upper part of the combustion chamber 4 and comprises a number of openings arranged around the combustion chamber 4, each with a pipe through which fresh air is sucked from the outside through the negative pressure in the upper part of the combustion chamber 4. In the event of a breakdown of the electrical system of the furnace 2, the operation of the flue gas blower 22 also ends. The suppression in the combustion chamber 4 breaks down and the oxygen supply of the secondary air supply is stopped. The flames in the combustion chamber 4 decrease rapidly and there remains a pile of coke, whose heat radiation is low. Since the decrease in the heating power of the fire is very fast, the overheating of the flue gas is low.

To operate the furnace 2, this includes an unillustrated fuel storage and a fuel supply 24 with a funding that promotes fuel from the fuel storage in the combustion chamber 4, in which the fuel is burned.

In addition, the mobile furnace comprises an electrical system control 26 which is connected by signal technology both with the fuel supply 24 and with the flue gas blower 22 and is designed to switch these two units, so on and off.

In addition, the system controller 26 is electrically connected to three temperature sensors 28, 30, 32, which are partially disposed in the flue gas path 14 above the combustion chamber 4, as shown in FIG 1 can be seen. The temperature sensor 30 is shown in more detail in FIG.

2 shows the temperature sensor 30 and the system controller 26 in a schematic representation. The temperature sensor 30 is a safety temperature limiter and designed identically as the temperature sensors 28 and 32. It comprises a temperature sensor or a sensor element 34, which is arranged in the exhaust gas path 14, that is, within the exhaust gas guide 20. Arranged directly on the sensor element 34 is a transmission gear 36 for translating a mechanical movement generated by the sensor element 34 into a translational movement, which is transmitted via a linkage 37 to a switch 38.

The switch 38 is connected to two circuits 40, 42, so that it at a

Switch between these circuits 40, 42 switches back and forth, so opens a circuit 40, thereby closing the second circuit 42 or vice versa. The two circuits 40, 42 each extend through the electrical system controller 26 and are scanned there or used for system control. The two circuits are 230 V AC circuits.

The system controller 26 in turn is connected in an analogous manner with the two other temperature sensors 28, 32, as indicated in FIG 2 only. In addition, it is connected to the cooling air blower 16, the flue gas blower 22 and the fuel supply 24, as shown in FIG 2 also indicated only schematically.

The temperature sensors 28, 30, 32 with their sensor element 34 scan the flue gas temperature in the flue gas stream 14. According to the flue gas temperature, which they themselves at least substantially assume, a liquid expands or contracts in its interior, this volume increase being converted by the transmission gear 36 into a greater translational movement. If the exhaust gas temperature exceeds a limit value, then the switch 38 is actuated and switched on when exceeding it and when it drops below the limit value - a flysteresis of about 5 K is neglected in the following-switched off. When switching on the circuit 42 is closed and the circuit 40 is opened and opened when switching off the circuit 42 and the circuit 40 is closed. A manual actuation of the switch 38 after switching on or off is not necessary because the temperature sensors are self-unlocking safety temperature limiter.

The performed by the system controller 26 control of the system 2 is done in the following manner. When firing, the flue gas is cold and all three temperature sensors 28, 30, 32 are switched off. The fuel supply 24 leads a lot of fuel to the combustion chamber 4, which is ignited there. If the exhaust-gas temperature now exceeds a first temperature limit to which the first temperature sensor 28 is set, it switches on. The opening and closing of the circuits 40, 42 is converted by the system control into switching pulses. Using this, the cooling air blower 16 is turned on and the fuel supply 24 is switched from a Anheizmodus to a regular operating mode in which the fuel supply is reduced relative to the Anheizmodus.

Exceeding the exhaust gas temperature a second temperature limit to which the second temperature sensor 30 is set, the corresponding opening and closing of the circuits 40, 42 is used by the electrical system control to turn off the fuel supply 24, so that the supply of fuel in the combustion chamber 4 is stopped. As a result, the heating power is reduced and the exhaust gas temperature drops below the second temperature limit again and the second temperature sensor 30 switches off. The fuel supply 24 is switched back to the regular operating mode. When switching off the mobile combustion system 2, for example by a manual intervention of an operator, the fuel supply 24 is also switched off and the heating power decreases and the exhaust gas temperature finally drops below the first temperature limit. The first temperature sensor 28 turns off, causing the electrical system controller 26, the cooling air blower 16 turns off.

During all of these modes of operation, the flue gas fan 22 remains in operation, so that the secondary air supply to the combustion chamber 4 is maintained. However, if the exhaust gas temperature exceeds the third limit temperature to which the third temperature sensor 32 is set due to an operation error or other irregularity, the opening and closing of the circuits 40, 42 is used by the electric system controller 26 to shut off the flue gas blower 22. The suppression in the combustion chamber breaks down and thus also the oxygen supply, so that the combustion of the oxygen runs out. As a result, the combustion also collapses and the combustion heat output rapidly drops to a very small value. As a result, the flue gas temperature drops below the third limit again. However, the third temperature sensor 32 is not automatically unlock the safety temperature limiter, but must be manually unlocked, so be turned off. This will be done by an operator who has examined the error that caused the temperature to exceed the third limit.

By such a control of the system 2 with the three temperature sensors 28, 30, 32, a very simple, inexpensive and robust system control can be achieved. REFERENCE LIST 2 Combustion system 4 Combustion chamber 6 Frame 8 Insertion opening 10 Heat exchanger 12 Cooling air flow 14 Exhaust gas flow 16 Cooling air blower 18 Outlet opening 20 Exhaust duct 22 Flue gas fan 24 Fuel supply 26 System control 28 Temperature sensor 30 Temperature sensor 32 Temperature sensor 34 Sensor element 36 Transmission 37 Linkage 38 Switch 40 Circuit 42 Circuit

Claims (12)

Claims 1. Mobile combustion plant (2) with a combustion chamber (4), a heat exchanger (10), a flue gas path (14) from the combustion chamber (4) through the hot side of the heat exchanger (10), a cooling air path (12) through the cold side of Heat exchanger (10) and an electrical system control (26), characterized by at least a first and a second temperature in a mechanical movement converting temperature sensor (28, 30, 32). 2. Furnace (2) according to claim 1, characterized in that the electrical system control (26) is prepared to use the mechanical movement to control the heating operation. 3. Furnace (2) according to claim 1 or 2, characterized in that the temperature sensors (28, 30, 32) each have a switch (38) which switches on reaching a limit temperature. 4. Furnace (2) according to claim 3, characterized in that the two temperature sensors (28, 30, 32) are set so that their temperature limits are different from each other. 5. Furnace (2) according to any one of the preceding claims, characterized in that the temperature sensors (28, 30, 32) are Sicherheitsstemperaturbegrenzer. 6. Furnace (2) according to one of the preceding claims, characterized in that both temperature sensors (28, 30, 32) have a switch which is arranged in a 230 V AC circuit (40, 42). 7. Furnace (2) according to any one of the preceding claims, characterized in that the temperature sensors (28, 30, 32) having a liquid-filled sensor portion (34) and a switch (38) which is arranged to the liquid that he when the liquid expands above a volume limit. 8. Furnace (2) according to any one of the preceding claims, characterized by a third temperature sensor (32) which is set to a limit temperature which is higher than limit temperatures to which the first two temperature sensors (28, 30) are set. 9. Furnace (2) according to one of the preceding claims, characterized in that the electrical system control (26) is prepared to use switching pulses of the second temperature sensor (30) as upper and switching pulses of the first temperature sensor (28) as the lower operating temperature limit. 10. Furnace (2) according to one of the preceding claims, characterized in that the electrical system control (26) is prepared to use switching pulses of a third temperature sensor (32) as Abschalttemperaturgrenzwert to terminate the plant operation. 11. Furnace (2) according to any one of the preceding claims, characterized by a cooling air blower (16) for driving a cooling air flow through the cooling air path (12), wherein the electrical system control (26) is prepared, the cooling air blower (16) when switching on the first Turn on the temperature sensor (28). 12. Furnace (2) according to any one of the preceding claims, characterized by a cooling air blower (16) for driving a cooling air flow through the cooling air path (12), wherein the electrical system control (26) is prepared, the cooling air blower (16) when the first Turn off temperature sensor (28) and continue to operate a secondary air blower (22) for supplying combustion air to the combustion chamber (4). For this 1 sheet drawings