EP0120233A2 - Process for heat recovery during the heat treatment of metallic articles, and tunnel furnace therefor - Google Patents

Abstract

In a method for heat recovery in the heat treatment of metallic goods, the goods are moved through a preheating zone (6), a treatment zone (7), and a cooling zone (8), with heat from the cooling zone into the preheating zone against the flow of useful goods by means of a gaseous heat transfer stream is transmitted. In order to recover a substantial part of the useful heat that would otherwise have to be dissipated in the cooling zone for heating up the useful material, and this without any great expenditure on apparatus, the heat transfer medium in the cooling and in the preheating zone is forced to the useful material in countercurrent or cross-countercurrent by the in the form of Bulk or stacked goods are passed through and passed from the cooling zone into the preheating zone. The heat capacity flows of the bulk or stacked goods and of the heat transfer medium in the cooling and / or preheating zone are made approximately the same size, the two zones being dimensioned such that the degree of thermal exchange ε between the useful product and the heat transfer medium is in each case greater than 0.5.

Description

The invention relates to a method for heat recovery in the heat treatment of metallic useful material which is moved through a preheating zone, a treatment zone and a cooling zone, heat being transferred from the cooling zone into the preheating zone counter to the useful material flow by means of a gaseous heat transfer stream.

In addition, the invention relates to a continuous furnace set up for carrying out this method for the heat treatment of metallic useful goods, with a preheating zone, a treatment zone and a cooling zone, through the furnace chamber of which a transport device that promotes the useful goods extends and with a device to remove heat from the To direct the cooling zone into the preheating zone to transfer the gaseous heat transfer stream from the cooling zone into the preheating zone counter to the flow of useful goods.

The energy requirement for the heat treatment of steel and non-ferrous metal parts in continuous furnaces results essentially from two heat balance items, if of the only in the event of exhaust gas losses occurring in fuel-heated furnaces:

Energy requirement E = useful heat flow Q _N + wall heat flow Q _W.

The wall heat flow Q _w (wall loss) can be reduced by suitable furnace construction and insulation. The useful heat flow Q _N depends on the throughput, the treatment temperature and the heat capacity of the treated goods. When entering the cooling zone, the product has the temperature prevailing in the holding zone, which is reduced to ambient temperature by heat dissipation in the cooling zone. The heat dissipated in the process is generally lost because the equipment outlay associated with heat recovery in the heat treatment of metallic bulk or stacked goods previously appeared to be much too great.

It is known in practice to assign separate preheating and cooling chambers to the actual furnace and to transfer heat from the cooling to the preheating chamber counter to the flow of useful goods with a gas flow. In the case of continuous furnaces, however, gas-tight intermediate doors are required, which interrupt the transport of the goods and thus make the entire furnace operation more difficult. Apart from the expense of certain Oven t ^y pen (eg conveyor ovens) such a division into separate chambers separated impossible. There are also ovens for the treatment of metallic goods which have a combined preheating and cooling zone in which a flow of uncontrolled circulation of the atmosphere is to achieve heat transfer from the goods to be cooled to the goods to be preheated. However, this uncontrolled gas circulation only allows very incomplete heat recovery.

Finally, it is known (US Pat. No. 4,093,195) to provide, in a carburizing furnace having a heating zone, a carburizing zone and a diffusion zone, in each of these zones, at least one fan arranged on the side wall of the furnace, which produces a throughflow of the cooling material in countercurrent flow. However, each of these blowers is limited to the zone assigned to it by appropriate air guidance; it can only cause a uniform flow of the annealing material in the respective zone. Heat recovery is not possible with this carburizing furnace.

The object of the invention is therefore to recover a substantial part of the useful heat Q _N to be dissipated in the cooling zone for heating the useful goods with simple adaptation to different operating conditions (starting, empty driving, changing the throughput, etc.), without an excessive apparatus Effort would be required.

To achieve this object, in the method mentioned at the outset, the procedure according to the invention is such that the heat transfer medium in the cooling zone and the preheating zone in each case in countercurrent or in countercurrent to the material flow is forced by the material present in the form of bulk or stacked material _N u _t zgut guided and passed from the cooling zone into the preheating zone that the heat capacity flows of the bulk or stacked goods and the heat transfer medium in the cooling and / or preheating zone are made approximately the same size, and that the cooling and preheating zone are such be dimensioned such that the degree of thermal exchange ε between the bulk or stacked goods and the heat transfer medium is in each case greater than ε = 0.5.

Characterized in that the bulk or stacked goods in the cooling and in the preheating zone in each case forcibly in countercurrent or cross-countercurrent flow through the heat transfer medium, it is possible to transport a high proportion of the useful heat from the cooling zone into the preheating zone. The flow of heat is additionally supplied with heat as it flows through the treatment zone. The greater the degree of exchange ε, the greater the recovery benefit. In practice, therefore, values of the order of magnitude of ε = 0.7 and larger are sought for the degree of exchange.

The heat transfer medium can be passed from the cooling zone directly through the treatment zone into the preheating zone. However, it is also possible to guide it at least partially in a pipe from the cooling to the preheating zone, which makes it possible to find out what to do with a lower degree of exchange or to increase the energy recovery somewhat.

In particular when starting up, ie during the period in which no heat can be recovered from the cooling zone, the preheating of the bulk or stacked goods in the preheating zone also means no recovered heat is available yet. It may therefore be appropriate for the bulk or stacked goods to be additionally heated at least temporarily in the preheating zone.

The heat transfer medium can be guided in a circuit containing the cooling and / or the preheating zone, which is particularly important if the heat transfer medium is a valuable gas, for example a protective gas. The heat transfer medium is cooled at least at one point in the circuit before it enters the cooling zone. The flow of heat transfer medium can also be branched at the outlet from the cooling zone, a part of the heat transfer medium being returned to the cooling zone in the circuit.

The temperature of the heat transfer medium can be measured in the vicinity of the transition between the cooling zone and the holding zone, the throughput of the heat transfer medium through the cooling zone then being regulated as a function of this temperature. It is also possible, if necessary additionally, to measure the temperature of the heat transfer medium in the vicinity of the entrance to the preheating zone and to regulate the throughput of the heat transfer medium through the preheating zone as a function of this temperature.

The method allows a large part of the useful heat flow, which is otherwise uselessly dissipated in the cooling zone, to be recovered without great expenditure on apparatus, the practical experience being shown has that the recoverable portion is usually more than 50% of the useful heat flow. At the same time an automatic adaptation to different operating conditions of the heat treatment is possible.

The continuous furnace set up at the outset, which is set up for carrying out this method, is characterized according to the invention in that the preheating zone, the treatment zone and the cooling zone in the furnace chamber are arranged next to one another, that the cooling and the preheating zone force the heat transfer stream in countercurrent or in countercurrent in a substantially vertical direction to the useful ^g utstrom by the present in the form of bulk or stacked useful material conducting channels included that are disposed below the gas-permeable shaped transport means and which are closed at the top by gas-permeable charge carrier for the bulk or stacked.

No doors need to be present in the oven chamber between the preheating zone, the treatment zone and the cooling zone, which means that bulk or stacked goods are completely unhindered through the oven chamber. The channels in the cooling and in the preheating zone for the heat transfer flow force the forced flow through the bulk or stacked goods in countercurrent or cross-countercurrent, without requiring a large amount of equipment apart from blowers.

In one embodiment, the arrangement is such that the channels are delimited at the top by a batch support of the transport device, on which the batch carriers lie sealed next to one another.

In order to guide the heat transfer medium in a countercurrent flow, it is advantageous if at least one of the channels is divided into chambers in which an oppositely directed flow of the bulk or stacked goods with the heat transfer medium is generated by at least one blower conveying the heat transfer medium. The blower can be arranged in the region of a partition wall lying in the assigned channel between two chambers. In this way it is possible to create a suction and a pressure area below the transport device by means of a single blower in the two associated chambers, so that the bulk or stacked goods in these areas are also flowed through in the opposite direction. The blower can have a measuring device for the heat transfer throughput, which is associated with a cooperating, possibly automatic control device for the heat transfer flow, which allows the heat transfer flow to be set to the appropriate value in each case.

In order to enable a direct transfer of the heat transfer medium from the cooling zone via the treatment zone to the preheating zone, passages for the heat transfer medium can be arranged between the treatment zone and the cooling zone and between the preheating zone and the treatment zone. However, the cooling zone and the preheating zone may do so via a, preferably through the treatment zone extending, optionally containing control means pipelines ^g en be interconnected.

If the heat transfer medium is circulated, the inlet of the preheating zone and the outlet of the cooling zone are connected to one another by a valve-controlled return flow line for the heat transfer medium contains a blower and a cooler. From this return flow line, a tap-controlled branch line can branch off to the entrance of the cooling zone in order to be able to adjust the heat transfer rate as required. In addition, the continuous furnace in the area of the preheating zone can have an additional heating device which is effective at least during start-up.

Finally, the continuous furnace at the entrance to the cooling and / or heating zone can each contain a temperature measuring point, the measuring signals of which are fed to at least one controller which, by engaging at least one actuator through which the heat transfer medium flows, the heat transfer flow through the cooling zone and / or the preheating zone to one predetermined setpoint.

• Fig. 1 einen Durchlaufofen gemäß der Erfindung in einer Seitenansicht in schematischer Darstellung und im Längsschnitt,
• Fig. 2 den Durchlaufofen nach Fig. 1, geschnitten längs der Linie II-II der Fig. 1 in einer Seitenansicht und in schematischer Darstel- lun^g,
• Fig. 3 den Durchlaufofen nach Fig. 2, geschnitten längs der Linie III-III der Fig. 2 in einer Draufsicht und im Ausschnitt und
• Fig. 4 einen Durchlaufofen gemäß der Erfindung im Längsschnitt und in schematischer Darstellung sowie in einer Seitenansicht.

Exemplary embodiments of the subject matter of the invention are shown in the drawing. Show it:

• 1 shows a continuous furnace according to the invention in a side view in a schematic representation and in longitudinal section,
• Fig. 2 shows the furnace according to Fig. 1, taken along the line II-II of Fig. 1 in a side view and in a schematic representation lun ^g,
• Fig. 3 shows the continuous furnace according to Fig. 2, cut along the line III-III of Fig. 2 in a plan view and in section and
• Fig. 4 shows a continuous furnace according to the invention in longitudinal section and in a schematic representation and in a side view.

The continuous furnace shown schematically in the drawing in two different embodiments is used for heat treatment, for example for the annealing of metallic useful material made of steel or non-ferrous metals in the form of bulk or stacked goods. It has an elongated furnace chamber 1 made of heat-insulating material, the loading opening 2 and the discharge opening 3 of which are each closed by a door 4 and 5, respectively. The furnace chamber 1 contains a preheating zone 6, followed by a heating or treatment zone 7 and then a cooling zone 8. No doors are provided between these zones 6, 7, 8 in the embodiment shown, so that there is a direct connection between the corresponding furnace chamber parts. Through the pre-heating zone 6, the treatment zone 7 and the cooling zone 8 is a continuous, gas-permeable transport device 9 extends, for example in the form of a gasdurch- lässi ^g en conveyor belt, roller or impact hearth. Batch baskets 10 having a gas-permeable bottom are successively placed on this transport device 9 through the loading opening 2, while batch baskets are removed through the dispensing opening 3 in the same cycle, so that the bulk goods contained in the batch baskets 10 successively through the preheating zone 6, the treatment zone 7 and the cooling zone 8 is transported through. The side walls of the batch baskets 10 are gas impermeable.

The transport device 9 has a batch basket support 11 which is arranged in the region of the two mutually opposite inner walls of the furnace chamber 1 and consists essentially of two guide tracks on which the batch baskets 10 are transported abutting each other. Each batch basket 10 is provided with a gas-permeable bottom 12, while the batch basket support 11, with the batch baskets 10 thereon, seals a channel 13 arranged underneath, which extends over the length of the interior of the furnace chamber 1 and is shut off by transverse walls 14 against the treatment zone 7 and in Chambers 15, 16 is divided. The positions ^{p of} the batch baskets 10, which are moved in cycles, are each above the chambers 15, 16 which are adapted to their dimensions (cf. FIG. 3). In the vicinity of the exit of the cooling zone 8, a feed line 17 for a gaseous heat transfer medium opens into the chamber 15 located there. The feed line 17 contains a control valve 18, a blower 19 and a cooler 20; it is connected to a three-way control valve 21 and, together with a line 22 leading from the furnace chamber 1 in the vicinity of the entrance to the preheating zone 6, forms a return flow line for the heat transfer medium. A branch line 23 leads from the three-way control valve 21 and opens into the furnace chamber 1 in the vicinity of the entrance to the cooling zone 8. Air, exhaust gas or protective gas etc. can be used as the gaseous heat transfer medium.

The furnace chamber 1 is heated in the area of the treatment zone 7 by a heater schematically indicated at 24. In addition, an additional heater 25 is provided in the area of the preheating zone 6, the task of which will be explained in more detail.

The heat transfer medium flowing into the cooling zone 8 via the feed line 17 is forced in the manner shown in FIG. 1, the bulk material contained in the batch baskets 10, based on the an arrow at 26 indicated useful material flow to flow through in countercurrent, as illustrated at 27. For this purpose, a blower 28 is arranged between two adjacent chambers 15, 16, which is assigned to a side partition 29 in such a way that, as can be seen from FIG. 16 - pressurized with vacuum so that the bulk material in the batch baskets 10 flows through in the opposite sense.

During this flow through the bulk material, the heat transfer medium absorbs a substantial part of the useful heat contained in the bulk material located in the cooling zone 8; it is then passed directly into the preheating zone 6, where it is forced in a corresponding manner to flow through the bulk material contained in the batch baskets 10 again in cross-countercurrent 27 until, after cooling, it exits the preheating zone 6 via the line 22 and in the circuit again is fed back into the feed line 17.

The preheating zone 6 and the cooling zone 8 are dimensioned such that the ratio of the heat capacity flows of useful material and heat transfer gas is approximately 1 in continuous operation.

The so-called thermal degree of exchange c in the preheating and cooling zones depends on the batch area F, the heat transfer coefficient α, the heat capacity flow C and the number of flow passages (see e.g. VDI Heat Atlas, VDI-Verlag, Düsseldorf). The preheating zone 6, the cooling zone 8 and the heat transfer throughput through these zones are designed such that the greatest possible degree of heat exchange ε results, which is in any case greater than 0.5, but preferably greater than 0.7.

Under these circumstances, the heat transfer medium heated in the cooling zone 8 in the manner described can be flowed directly through passages 31, 32 through the treatment zone 7 from the cooling zone 8 into the preheating zone 6, which results in particularly simple structural conditions.

Below the transport device 9, a line 33 is also provided in the channel 13, which contains a control valve 340 and establishes a direct connection between the cooling zone 8 and the preheating zone 6 through the furnace chamber. This pipeline 33 also allows the heat transfer medium to be passed partially or completely from the cooling zone 8 into the preheating zone 6 if the degree of thermal exchange f is low. The energy recovery can also be increased somewhat by the pipeline 33.

If protective gas is used as the heat transfer medium, the heat transfer medium is circulated in the manner described via the lines 22, 17 by the blower 19 in a closed circuit, the cooler 20 allowing the heat transfer medium to be cooled to the desired temperature. The locks required in protective gas operation in the area of the loading and discharge openings 2 and 3 are not shown in detail.

If the bulk material is heat-treated without protective gas, for example with air as the heat transfer medium, the circuit at the location of the cooler 20 is opened at 200, the cooler 20 being omitted.

The cooling zone 8 contains a temperature sensor 34 near its entrance, the measurement signals of which are fed to a controller 35 which influences the peeling valve 18 and thus the heat transfer flow in the cooling zone 8, depending on the temperature prevailing at the transition between the cooling zone 8 and the treatment zone 7 regulates.

If the ratio of the heat capacity flow of useful material and heat transfer gas in the cooling zone 8 is "1 '', is the difference between the measured at 34 temperature and the measured at 35 Teme- _ra t _ur in the treatment zone 7 is equal to the difference between the heat carrier gas inlet temperature to the Mouth of the supply line 17 into the channel 13 and the temperature of the useful or bulk material when it emerges from the discharge opening 3. If these three temperatures are sufficiently constant, the temperature measured at 34 can be used directly as a control variable.

Another temperature measuring point is provided at 36 at the entrance to the preheating zone 6. The temperature sensor arranged at this point controls the heat carrier gas flow through the preheating zone 6 via a controller 37 and the three-way control valve 21. In continuous operation, the heat carrier flows entirely or for the most part through the preheating zone 6, while at. decreasing throughput or when emptying the heat transfer medium is entirely or partially conducted via the branch line 23 via the cooler 20 by lowering it to the desired temperature.

When the continuous furnace is started up, the heat carrier flow is shut off by the controller 35 via the control valve 18,
since none in the cooling zone 8 heated goods is included. Since the heating 24 of the treatment zone 7 is not sufficient for the nominal throughput in this case, the additional heating 25 is provided in the preheating zone 6 and then comes into action.

The cross counterflow 27 in the cooling zone 8 and in the preheating zone 6 has in each zone at least two passages through the bulk material contained in the batch baskets 10. As already explained, one passage through the inflowing and the other passage through the extracted gas is realized, each fan 28 producing two such passages.

As can be seen from FIGS. 1, 3, each blower 28 is assigned a suction-side Venturi measuring nozzle 40, with which the heat carrier gas flow can be monitored and measurement signals can be generated which allow the heat capacity flow ratio of 1 between the flow of useful goods to be determined with the aid of sliders 400 and adjust the heat transfer flow. The slides 400 are controlled by servomotors 401.

While in the embodiment of the continuous furnace explained with reference to FIGS. 1, 2, 3, the heat transfer gas in the preheating zone 6 and in the cooling zone 8 is led in each case in the cross-countercurrent 27 to the useful material stream, there are also types of continuous furnaces in which this Bulk material in the preheating zone 6 and in the cooling zone 8 is flowed through by the heat transfer gas in a pure countercurrent. Such an embodiment is shown in FIG. 4. The same parts are designated by the same reference numerals with the embodiment according to FIG. 1, so that there is no need for a further explanation in this regard.

In this embodiment, the batch baskets 10 are transported in the preheating zone 6 and in the cooling zone 8 by the transport device 9 in a vertical direction downwards or upwards one above the other. The blowers 28 of FIGS. 1-3 can even be omitted. However, the increased effort for the 90 ° transport deflection to be effected by the transport device 9 must be accepted.

In the case of direct gas heating of the treatment zone 7, the exhaust gases are also introduced into the preheating zone 6 and cooled there.

Design example:

Annealing of cold-worked steel parts in bulk at 700 ° C, holding time 1 h, middle parts measuring 40 mm, bulk density of 3,000 kg / m ^3, surface area of the parts 0 ₀ 2 _m ² / _k g.

Cycle piercing furnace similar to Fig. 1, gross output 1000 kg / h, heat capacity flow of the goods 170 W / o K, cycle time 30 minutes, batch baskets L x W x H = .5 x 1 x.3 m, gross batches 500 kg, surface per batch 10 m ² .

Nitrogen as heat transfer medium 615 kg / h corresponding to 170 / ° K, mass flow density through the bulk material 0.35 kg / _m ² _s.

Pre-heating zone 6: 3 batch baskets with 30 m2, ε = 0.75 cross-counterflow with three passages. Good heating from 20 → 530 ° C, heat medium cooling from 700 → 1900 ° C

Treatment zone 7: 4 batch baskets (2 for residual heating) Good heating from 530 ° → 700 ° C Heat carrier heating from 535 ° → 700 ° C (heat carrier directly through the treatment zone

Cooling zone 8: 3 batch baskets with 30 m ² , = ₀ . ₇₅ cross-countercurrent with three passes, cooling well from 700 ° → 200 ° C heating medium heating from 35 ° → 535 ° C

• - Heizenergieersparnis von 45% mit Wärmerückgewinnung
• - Kühlwasserersparnis von 75% mit Wärmerückgewinnung
• - vergleichbare Investitionskosten, weil die Kosten für den Wärmeträgerkreislauf und die Gebläse durch die größere Heizung beim Ofen ohne Wärmerückgewinnung kompensiert werden.

That means:

• - Heating energy savings of 45% with heat recovery
• - 75% cooling water savings with heat recovery
• - comparable investment costs, because the costs for the heat transfer circuit and the blowers are compensated by the larger heating in the furnace without heat recovery.

Claims (20)

I. Process for heat recovery in the heat treatment of metallic useful goods, which is moved through a preheating zone, a treatment zone and a cooling zone, heat being transferred from the cooling zone into the preheating zone counter to the useful material flow by means of a gaseous heat transfer stream, characterized in that the heat transfer medium in the cooling and the preheating zone each in countercurrent or cross-countercurrent to the 0 material flow is forcibly guided through the material in the form of bulk or stacked goods and conducted from the cooling zone into the preheating zone such that the heat capacity flows of the bulk or stacked goods and the heat transfer medium 5 of the cooling and / or preheating zone are made approximately the same size, and that the cooling and preheating zone are dimensioned such that the degree of thermal exchange E between the bulk or stacked goods and the heat transfer medium is in each case 0 greater than ε = 0.5 is. 2. The method according to claim 1, characterized in that the heat transfer medium is passed directly from the cooling zone through the treatment zone into the preheating zone. 3. The method according to any one of the preceding claims, characterized in that the heat transfer medium is at least partially conducted in a pipe from the cooling to the preheating zone. 4. The method according to any one of the preceding claims, characterized in that the bulk or stacked goods in the preheating zone is at least temporarily additionally heated. 5. The method according to any one of the preceding claims, characterized in that the heat transfer medium is guided in a circuit containing the cooling and / or the preheating zone and that the heat transfer medium is cooled at at least one point in the circuit before entering the cooling zone. 6. The method according to claim 5, characterized in that the heat transfer medium branches at the outlet from the cooling zone and at least a part of the heat transfer medium in the circuit is returned to the cooling zone. 7. The method according to any one of the preceding claims, characterized in that the temperature of the heat transfer medium is measured in the vicinity of the transition between the cooling zone and the treatment zone and the throughput of the heat transfer medium through the cooling zone is controlled as a function of this temperature. 8. The method according to any one of the preceding claims, characterized in that the temperature of the heat transfer medium is measured in the vicinity of the entrance of the preheating zone and the throughput of the heat transfer medium through the preheating zone is regulated as a function of this temperature. 9. Continuous furnace for the heat treatment of metal goods according to the method according to one of the preceding claims, with a preheating zone, a treatment zone and a cooling zone, through the furnace chamber of which a transport device which promotes the goods extends, and with a device for heat from the cooling zone to pass gaseous heat transfer streams into the preheating zone from the cooling zone into the preheating zone in opposition to the useful cut stream, characterized in that the preheating zone (6), the treatment zone (7) and the cooling zone (8) are arranged one after the other in the furnace chamber (1) that the cooling and the preheating zone (8, 6) contain the heat transfer flow in countercurrent or cross-countercurrent in a substantially vertical direction to the product flow through the product in the form of bulk or stacked product conductive channels (13) which are arranged under the gas-permeable transnort device (9) and the above s are sealed off by gas-permeable batch carriers for the bulk or stacked goods. 10. Continuous furnace according to claim 9, characterized in that the channels (13) above by a Batch support (11) of the transport device (9) are limited, on which the batch carriers lie sealed next to one another. 11. Continuous furnace according to claim 10 or 11, characterized in that at least one of the channels (13) is subdivided into chambers in which, through at least one fan (28) which promotes the heat transfer medium, produces an oppositely directed flow through the bulk or stacked material with the heat transfer medium becomes. 12. Continuous furnace according to claim 11, characterized in that the fan (28) is arranged in the region of a partition (29) lying in the associated channel (13) between two chambers. 13. Continuous furnace according to claim 12, characterized in that the fan (28) has a measuring device (40) for the heat transfer throughput, which is associated with a cooperating with it, optionally automatic control device for the heat transfer flow. 14. Continuous furnace according to one of claims 9 to 13, characterized in that between the treatment zone (7) and the cooling zone (8) and between the preheating zone (6) and the treatment zone (7) passages (31, 34) for the heat transfer medium are. 15. Continuous furnace according to one of claims 9 to 14, characterized in that the cooling zone (8) and the preheating zone (6) via a preferably through the treatment zone (7), optionally, pipe (33) containing control means (340) are connected to one another. 6. Continuous furnace according to one of claims 9 to 15, characterized in that the input of the preheating zone (6) and the output of the cooling zone (8) are connected to one another by a valve-controlled return flow line (22, 17) for the heat transfer medium, which is a blower ( 19) and a cooler (20). 17. Continuous furnace according to claim 16, .d characterized in that valve-controlled branch line (23) branches off from the return flow line to the entrance of the cooling zone (8). 18. Continuous furnace according to one of claims 9 to 17, characterized in that it has an additional heating device (25) which is effective at least during the start-up operation in the region of the preheating zone (6). 19. Continuous furnace according to one of claims 9 to 18, characterized in that it contains a temperature measuring point (34 or 36) at the entrance to the cooling and / or the preheating zone (8 or 6), the measuring signals of which at least one controller (35 or 37) are supplied, which, by engaging at least one actuator (18 or 21) through which the heat carrier flows, regulates the heat carrier flow through the cooling zone and / or the preheating zone to a predetermined desired value. 20. Continuous furnace according to claim 16, characterized in that the return flow line has an interruption instead of the cooler.

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