EP1479973A2 - Method and device for controlling the tightness of a gas fired radiant tube - Google Patents

Abstract

The method involves monitoring the operation of the burner (12) and producing a burner signal (32) that can take the values BURNER OFF and BURNER ON, monitoring the burner's exhaust gas flow and deriving an exhaust gas signal (34) with EXHAUST GAS OFF and EXHAUST GAS ON states and combining the signals to output a fault signal (36) in the event of a combination that is not permitted. An independent claim is also included for the following: (a) an arrangement for monitoring the sealing of a radiation pipe heated by a gas burner.

Description

The invention relates to a method and a device for Monitoring the tightness of a burner fired by a gas burner Beam pipe.

Gas fired ceramic radiant tubes find in particular Industrial furnaces because of the long life a constantly rising Distribution.

A disadvantage of using ceramic radiant tubes is that in case of damage the jet breaks and immediately a large free cross-section is provided to the furnace room. A damage of the jet pipe is so far not easy recognizable and can lead to significant disadvantages in the process, because the furnace atmosphere is changed accordingly. Also surrender Significant safety problems.

If an industrial furnace has several jets and breaks This is not immediately recognized. The oven interior is mostly through the inlet and outlet not close to the Completed external environment so that no pressure increase occurs. If the furnace is filled with protective gas, the atmosphere becomes in the case of a jet pipe break, things changed can evolve creeping and only through constant analysis or other measuring methods can be detected. Besides that is not directly detectable, which jet pipe is broken is. Only by switching off the burner associated with the jet a limitation can be made. This costs time, since only on a reaction of the furnace atmosphere or an effect thereof must be serviced. Also, analyzes of inert gas components the jet pipe be very time consuming. Is located In the furnace room only air, so is a jet pipe break in the production process hardly noticeable.

All of these problems are detrimental to the use of ceramic Beamlines. In contrast, steel blast pipes are one exposed to greater corrosion and less temperature resistant. Damage to steel blast pipes usually develops as well insidiously.

From US-A-4 219 324 it is known to use a flame detector to monitor the operation of a burner. Further In this case, the composition of the exhaust gas flow is monitored to an error condition in the event of deviation from specified reference values determine.

From US-A-4 508 501 is also a for monitoring the Tightness of a radiant tube fired by a gas burner known, in which by a control of the burner, the oxygen content is monitored in the exhaust stream of the burner. at Deviation from a given setpoint becomes an error signal output.

Finally, it is known from JP-A-55066729 (Patent Abstracts of Japan), in which also the exhaust gas flow of the burner is monitored and derived from this a signal for monitoring becomes. Again, the exhaust gas composition is monitored.

In the prior art, monitoring requires tightness the jet pipe a complex monitoring of the gas composition, which is complicated and expensive and also the problem includes the aging of sensors.

The invention is therefore based on the object, a method and a device for monitoring the tightness of one of To create a gas burner fueled jet pipe, which a simple and inexpensive construction and a fast Response in case of error results.

This task is performed by a method of monitoring the Tightness of a radiant tube fired by a gas burner solved, is monitored at the switch-on state of the burner and a burner signal indicative of the on state is generated, the at least the conditions BURNER OFF when off Burner and BURNER ON with the burner switched on can take, in which also the exhaust gas flow of the burner is monitored and derived therefrom, an exhaust gas signal, the at least the conditions exhaust off if not sufficient Volume flow of flowing exhaust gas and exhaust gas on when properly can assume effluent exhaust gas, and wherein the burner signal and the exhaust signal are linked to one another at a not permissible combination of the burner signal and the exhaust gas signal to output an error signal.

The object of the invention is further achieved by a device for monitoring the tightness of a burner fired by a gas burner Beam tube solved, with a sensor for monitoring the Exhaust stream of the burner, which exceeds a predetermined Threshold a characteristic exhaust gas signal outputs and with a monitoring circuit, the exhaust signal and an indicative of the on-state of the burner Burner signal are supplied, and in an improper Combination of burner signal and exhaust signal an error signal outputs.

The invention is completely solved in this way.

If the burner is switched on, what by the burner signal is displayed, so must the flowing out of the jet pipe Exhaust gas with a characteristic for the burner exhaust gas flow stream. Remains this exhaust gas flow from or does not reach the necessary size, so is a leak to go out the beam pipe. By linking the Exhaust gas signal, which has a sufficient volume flow of the exhaust gas indicates, with the burner signal can be in this way a Leakage of the beam tube easily recognize.

The burner signal can be approximately from the on / off switch of the burner are derived, provided that they only indicate the switch-on state should. However, a derivative of a control is preferred of the burner, which is usually not just a power-on state of the burner, but also a correct one at the same time Work of the burner monitors what is caused by a signal BURNER ON is displayed. Alternatively, it is conceivable for generation the burner signal a separate monitoring device in Shape of a sensor, e.g. a flame sensor to provide.

The monitoring of the exhaust gas flow can be approximately through a volumetric Measurement, by a differential pressure measurement, by a flow velocity measurement with an inductive or ultrasonic method or monitored by a pressure probe measurement become.

A particularly simple embodiment results when the exhaust gas flow by means of a differential pressure method by constriction of the Flow cross section by means of a throttle device, in particular is monitored by means of a differential pressure diaphragm. It Then a differential pressure measurement between the input and the output of the throttle device are performed. Lies the measured differential pressure below a predetermined Threshold value, the received exhaust gas signal is turned OFF set. If the differential pressure is higher, then that is the case Exhaust gas signal exhaust gas ON.

As a threshold, in this case, for example, a value of 10 mbar, preferably of 5 mbar, more preferably of 3 mbar, in particular of 2 mbar, between input and output of the differential pressure diaphragm be used.

In an additional embodiment of the invention is also in the Combination BURNER OFF and exhaust ON an error signal issued.

Namely, an exhaust gas signal of sufficient size is measured, without that is characteristic of turning on the burner Signal BRENNER ON, so it can be assumed that at a broken jet pipe through an exhaust fan one way high volume flow through the leaking jet pipe from the furnace is sucked off, that the signal is emitted exhaust gas.

In addition, monitoring can also be performed if the burner is switched off and in cooling air mode for the Beam pipe for cooling the furnace chamber works, the cooling air Preferably, the burner operating as combustion air serves. This can also be in the off state of Brenners running fan supply the cooling air. possibly can be mounted on the burner a separate cooling air line be guided over the additional cooling air into the jet pipe is to achieve a stronger furnace cooling.

The function of the cooling air and possibly the additional cooling air can be monitored and derived therefrom cooling air signal and possibly additional cooling air signal associated with the exhaust gas signal be an error signal in case of an impermissible combination issue.

It is understood that the above and the following yet to be explained features not only in each case specified combination, but also in other combinations or be used alone, without the framework of to leave the present invention.

Fig. 1

eine vereinfachte Darstellung eines Industrieofens mit einem Brenner und einem Strahlrohr in Form eines Mantelstrahlrohres und einer zugeordneten Einrichtung zur Überwachung der Dichtheit des Strahlrohres; und

Fig. 2

eine mögliche Ausführung einer Schaltung mit Leuchttaster zur Anzeige und Quittierung einer Meldung, die eine Undichtheit des Strahlrohres anzeigt.

Further features and advantages of the invention will become apparent from the following description of preferred embodiments with reference to the drawings. Show it:

Fig. 1

a simplified representation of an industrial furnace with a burner and a jet pipe in the form of a radiant tube and an associated means for monitoring the tightness of the jet pipe; and

Fig. 2

a possible embodiment of a circuit with illuminated button for displaying and acknowledging a message indicating a leakage of the jet pipe.

In Fig. 1 is an industrial furnace, which is gas-fired Beam pipe is heated and with a monitoring device according to the invention for monitoring the tightness of the jet pipe is equipped, shown schematically and in total with the Numeral 10 designates.

The industrial furnace 10 has a merely schematic with a dash-dotted line indicated furnace chamber 11, the is heated by a gas burner 12. The gas burner 12 has a projecting into the oven chamber 11 jet pipe 14 in Shape of a jacket tube. The returned via the jet pipe 14 Exhaust gases arrive via a purely schematic indicated output of the jet pipe 14 in an exhaust pipe 18th and are directed into an exhaust passage 20.

According to the invention is now to monitor the tightness of the Beam pipe 14 of the flowing over the exhaust pipe 18 exhaust gas volume flow monitored and with one of the burner control 28th derived burner signal that is working properly of the burner indicates linked. Is the burner working properly? and results in no exhaust gas flow, which is the characteristic Size for the type of burner used is so assume that there is a leakage of the jet pipe.

For this purpose, a differential pressure diaphragm 22 is in the exhaust pipe 18 inserted. At the input and output of the differential pressure diaphragm, i.e. immediately before and behind, is a pressure measuring device 24 connected via measuring lines 26. Results in properly working burner 12 a differential pressure Ap sufficient size of e.g. 2 mbar, it can be assumed that no leakage of the jet pipe 14 is present. Otherwise, an error signal is generated. This is a monitoring circuit provided, which only schematically with the Paragraph 38 is indicated. The monitoring circuit 38 becomes the from the pressure measuring device 24 obtained exhaust gas signal 34 and the burner signal 32 obtained from the burner controller 28 fed. From the monitoring circuit 38 is an output signal 36 generates, in the simplest case, only the states OK or FAIL.

The exhaust gas signal 34 obtained from the pressure measuring device 24 likewise, in the simplest case, only the states EXHAUST EXHAUST ON or EXHAUST OFF. Likewise, the burner signal 32 preferably designed as a binary signal, the only accept the conditions BURNER ON and BURNER OFF can.

It is understood that the connections of the exhaust signal 34 and the burner signal 32 through the monitoring circuit 38 either by a conventional, hard-wired circuit or by a digital switching logic can be done in the The simplest case, for example, executed by means of TTL logic modules is.

The output 36 obtained in response to the various possible combinations of the burner signal 32 and the exhaust signal 34 could then be represented by a truth table, for example, as shown in Table 1 below. Brenner signal exhaust signal output Status 0 0 0 0 1 0 (1) 1 0 1 1 1 0

The input signals have a "0" for the status OFF or LOW, so BURNER OFF or EXHAUST OFF and a "1" for the state ON or HIGH, so BURNER ON or exhaust gas ON.

The output signal is a "0" for the state OK or OK, while a "1" indicates an error.

In the simplest embodiment of the circuit is only at Combination BURNER ON and exhaust OFF an error signal generated, i. issued a logical "1". In an alternative Execution will be additional for the combination BURNER OFF and exhaust ON to output an error signal, what through the logical "1" displayed in brackets for this combination is.

In the latter case, it must be assumed that with a broken jet pipe through an exhaust fan such a high volume flow is sucked out of the furnace chamber, that the signal ABGAS ON is generated.

Become burners via the associated jet pipe for cooling used by furnace chambers, what with the cooling air (combustion air) and / or by additional cooling air via a separate burner attached cooling air duct can be done so can a Monitoring also done in this case.

For cooling, simply the cooling air flow (combustion air volume flow) be used, even when not switched on Burner is running. This in turn can be done with a differential pressure measurement be monitored to a signal COOL AIR ON or COOLING AIR to produce, whereby the flow of cooling air or the missing flow of cooling air is indicated. In appropriate In this way, the flow of additional cooling air can be monitored be a signal ZUSATZKÜHLLUFT ON or

SUPPLEMENTARY COOLING AIR to generate, which is a flow of additional cooling air or indicates a lack of flow of additional cooling air.

In addition to Table 1, Table 2 shows possible states that may result when the burner is switched off in cooling mode. In a manner corresponding to Table 1, in the case of the cooling air signal, a "1"("0") means the signal COOLING AIR ON (COOLING AIR OFF) and, for the auxiliary cooling air signal, a "1"("0") the signal AUC. COOLING AIR ON (ADDITIONAL COOLING AIR OFF). Brenner signal Cooling air signal Additional cooling air signal exhaust signal output 0 1 0 1 0 0 1 0 0 1 0 1 1 1 0 0 1 1 0 1 0 0 1 1 0 0 0 1 0 1

It is understood that the purely exemplary by way of Fig. 1 and Tables 1 and 2 shown monitoring the tightness a jet pipe not only in a furnace at a single radiant tube, but also in ovens with multiple radiant tubes can be used. This can be with every jet pipe a pressure monitoring will be carried out and the obtained Exhaust gas signals can be monitored by means of individual monitoring circuits or by means of a single monitoring circuit with the relevant burner signals are linked.

It is further understood that the inventive method and the inventive device for monitoring any Beam pipes can be used. So it can, for example, coat-jet pipes, P-beam tubes and double P-beam tubes monitored become. But even with through and U-beam tubes that can inventive principle can be used. In this case, the exhaust gas flow at the exit of the passage of the U-tube by means of Differential pressure and the pressure measuring device monitors.

One possible embodiment for the monitoring circuit 38 with conventional components is shown in Fig. 2. With this Monitoring circuit 38 only then becomes an error signal output when the combination BURNER ON and EXHAUST OFF is obtained. In addition, however, here is a light button intended to display and acknowledge the error message.

The monitoring circuit 38 may, for example, in a separate Housing be housed, in addition to each assigned Burner is housed.

The monitoring circuit 38 has an input 56 for the from the burner control 28 received burner signal (220 V signal) the states BURNER ON or BURN OFF take on can. This input 56 is connected to a relay K1, the with its control circuit 40 at the other end to the neutral conductor N. connected via port 64. Likewise to the Neutral N is a relay K2 connected to its control circuit 42, in series with the make contact 41 of the relay K1 and in series with the pressure measuring device 24, the over the connections 58 and 60 are connected and the one over Line 50 with the 220 received from the burner control 28th V-phase connected via the connector 62 connected is. The pressure measuring device 24 opens the in Fig. 2 schematically indicated normally closed contact when the differential pressure the preset threshold of e.g. Exceeds 2 mbar.

Parallel to the control circuit 42 of the relay K2 is an indicator lamp 44 connected, with one end to the neutral is located and with its other end via the control circuit 43 of the Relay K2 and a button 46 with the line 50 and the connection 62, that is connected to the 220V phase. By a Line 48 between the control circuit 42 and the circuit 43 of the relay, the indicator lamp 44 is parallel to the control circuit 42 of the relay K2 connected.

If the burner signal BRENNER ON is received and the exhaust gas signal is missing, i.e. opens the normally closed contact of the pressure measuring device 24 the connection between the circuit 41 of the relay K1 and the line 50 not, it will be lit by the Indicator lamp 44 is displayed, and there is an error signal on Output 66 output. The error signal can be activated by the button 46 be acknowledged.

Claims (13)

Method for monitoring the tightness of one of Gas burner (12) fired jet pipe (14), in which the Work of the burner (12) is monitored and a burner signal (32) is generated, the at least the states BURNER OFF with the burner switched off (12) and BURNER ON with the burner (12) can take, at further monitoring the exhaust flow of the burner (12) and from which an exhaust gas signal (34) is derived which is at least the conditions EXHAUST OFF if not sufficient Volume flow of flowing exhaust gas and exhaust gas on when properly can assume effluent exhaust gas, and in which the Burner signal (32) and the exhaust gas signal (34) with each other linked to an inadmissible combination the burner signal (32) and the exhaust gas signal (34) Output error signal (36). Method according to Claim 1, in which the burner signal (32) derived from a controller (28) of the burner (12) becomes. Method according to Claim 1 or 2, in which an error signal (36) is output when the signal BURNER ON and EXHAUST OFF is obtained. The method of claim 1, 2 or 3, wherein the jet pipe (14) for cooling a furnace chamber fired therefrom Cooling air is supplied, the flow is monitored and of which a cooling air signal COOLING AIR ON or COOLING AIR OFF is derived and in an inadmissible combination with the exhaust signal (34) and the burner signal (32) an error signal (36) is output. The method of claim 4, wherein the jet pipe to the Cooling of the furnace chamber additional cooling air is supplied, whose flow is monitored and of which an additional cooling air signal ADDITIONAL COOLING AIR ON or ADDITIONAL COOLING AIR derived being, with an inadmissible combination with the burner signal, the exhaust gas signal and the cooling air signal an error signal is output. Method according to one of the preceding claims, in which the flow monitoring by a volumetric measurement, by a differential pressure measurement, by a flow velocity measurement by an inductive method or ultrasonic method or monitored by a pressure probe measurement becomes. The method of claim 6, wherein the flow by means of the Wirkdruckverfahrens by constriction of the flow cross-section by means of a throttle device, in particular monitored by means of a differential pressure diaphragm (22) becomes. Method according to claim 7, wherein when the measured Differential pressure falls below a predetermined threshold, the signal (34) is set to "OFF". Method according to Claim 8, in which the threshold value Value of 10 mbar, preferably 5 mbar, more preferred of 3 mbar, in particular of 2 mbar, as between entrance and output of the differential pressure orifice measured pressure difference Δp is used. Method according to one of the preceding claims, in which with the combination BURNER OFF and exhaust ON an error signal (36) is output. Device for monitoring the tightness of one of a Gas burner (12) fired jet pipe (14), with a Sensor (24) for monitoring the exhaust gas flow of the burner (12), which exceeds a predetermined threshold outputs a characteristic exhaust gas signal (34) for this, and with a monitoring circuit (38) which detects the exhaust signal (34) and on for the on state of the burner (12) indicative burner signal (32) are supplied, and the at an inadmissible combination of burner signal (32) and exhaust signal (34) outputs an error signal (36). Apparatus according to claim 11, wherein in the exhaust gas flow a Throttle device, in particular a differential pressure diaphragm (22) is provided, wherein the sensor (24) as a differential pressure gauge for measuring the differential pressure between the Input of the differential pressure diaphragm (22) and the output of Differential pressure diaphragm is formed. Apparatus according to claim 11 or 12, wherein the monitoring circuit (38) in combination BURNER ON and EMISSION OFF outputs an error signal (36).

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