CZ284683B6 - Device for the control of gas pressure in adjacent zones of continuous furnace - Google Patents

Abstract

The device for regulating the gas pressure in adjacent zones of the continuous furnace (10) comprises a first measuring point (12) for detecting the gas pressure (P1) at one end of the first zone (B) of the furnace, a second measuring point (14) for detecting the gas pressure (P2) at the beginning of the second zone (K) of the furnace immediately adjacent to the first zone (B) of the furnace, the supply device (28) for supplying gas to the second zone (K) of the furnace at a distance from the ripple measuring point (14), the extraction device (20) for suction gas from the second kiln zone (K) in the immediate vicinity of the second metering point (14) on the side facing away from the first measuring point (12), the sampling device (20) being controllable depending on the ratios (P1: P2) of the pressures between adjacent zones (B, K) of the furnace as a function of time at the measuring points (12, 14)

Description

Apparatus for controlling the gas pressure in adjacent zones of a continuous furnace

Technical field

The invention relates to a device for controlling the gas pressure in adjacent zones of a continuous furnace.

Within the scope of the invention, the term continuous furnace includes all kinds of continuously operating furnaces in which the products to be fired are fed to the furnace at one point, then passed through the furnace and removed at another point. Both the prior art and the invention will be explained in more detail with reference to a tunnel furnace for firing ceramic moldings, without thereby limiting the subject matter of the invention.

BACKGROUND OF THE INVENTION

The tunnel kiln is usually divided into three main zones, and this - considered in the direction of transport of the products to be fired - into the heating zone, the burning zone and the cooling zone.

As is clear from EP 0 348 603 B1, the main problem hitherto is to adjust the balance of the furnace gas flow, hereinafter referred to as gas, to the desired optimum value depending on the furnace and the products to be fired. The amount of gas and its temperature interact. The quality of the products to be fired depends entirely on the temperature course, the atmosphere in the furnace and the amount of gas in each of the furnace zones, as well as the respective gas flow rates during the furnace campaign.

DE 41 00 232 C2 discloses an apparatus for regulating the pressure of gas in the furnace space. However, it is primarily a matter of determining the actual gas pressure and subsequently controlling the amount of the off-gas stream. To this end, it is specifically proposed here to adjust the pressure of the gas by controlling the amount of cold air supplied to the exhaust gas duct.

For separating gas streams of different composition in different parts of the furnace, EP 0 199 032 B1 describes a device with means for discharging at least a part of the gas stream from the first part of the furnace directly in front of the second part of the furnace and parts of the furnace at an angle of 90 ° ± 20 ° to the original direction of flow. In other words, in this device, a so-called gas is formed between adjacent parts of the furnace. In this way, mixing of the gases in adjacent parts of the continuous furnace is prevented in particular.

The invention is based on the consideration that a similar effect, namely the separation of adjacent zones of a continuous furnace by gas, can be achieved in a completely different way, namely by regulating the gas pressure in the transition zone between adjacent zones.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a device by which an optimum gas flow balance between adjacent furnace zones can be achieved, adapted to the furnace and the products to be fired.

SUMMARY OF THE INVENTION

This object is achieved by a device for regulating the gas pressure in adjacent zones of a continuous furnace according to the invention, which comprises

- 1 CZ 284683 B6

- a first measuring point for detecting gas pressure at one end of the first furnace zone,

- a second gas pressure measuring point at the beginning of the second furnace zone immediately adjacent to the first furnace zone,

- a supply means for supplying gas to the second zone of the furnace at a distance from the second measuring point,

a sampling device for exhausting gas from the second furnace zone in immediate proximity to the second metering site on the side remote from the first metering site, the sampling device being controllable as a function of the pressure ratios between adjacent furnace zones determined over time at the metering locations.

In other words, the invention was directed to adjusting the same pressure ratios in the transition region between adjacent zones of a continuous furnace. The same pressure conditions in the adjacent zones then directly result in no gas exchange between the zones.

Next, a device is provided which is arranged in the transition region between the firing zone and the cooling zone of the tunnel furnace.

It is known that cold air is supplied to the furnace cooling zone. Depending on the temperature and the amount of cooling air, the pressure conditions in the cooling zone vary. The device according to the invention now ensures that varying pressure conditions in the cooling zone are not transferred to the adjacent firing zone. In this way, the individual zones of the continuous furnace, here the firing zone and the cooling zone, can be set individually, whereby optimized furnace flow and improved quality of the fired products can be achieved.

The interaction of the pressure measuring points with the adjacent gas extraction device is decisive for the good operation of the device according to the invention. For example, if the measured value, or pressure P2, increases in the second measurement point at the start of the cooling zone, while the measured value, or pressure P1, remains unchanged at the first measurement point at the end of the firing zone, the P1 / P2 pressure ratio drops to <1. . An increased amount of gas is taken from the furnace by the control device at the second measuring point, so that the pressure P2 drops again until the pressure ratio P1 / P2 is again set to 1.

Otherwise, in which the second measured value, or pressure P2, decreases, i.e. the pressure in the cooling zone in the transition zone to the firing zone drops, the pressure ratio P1 / P2 increases to> 1. To increase the pressure, the sampling device is now throttled by means of the above-mentioned control device until the pressure at this point again corresponds to the pressure P1 and the pressure ratio P1 / P2 is again 1.

The amount of gas exhausted by the sampling device can be controlled by a suitable valve arranged in the sampling line.

Thereafter, the sampling device is controllable so that the pressure ratio P1 / P2, determined at a particular point in time, is maintained at a constant value of 1 by changing the amount of gas withdrawn in the second zone of the furnace. in case of deviations the described regulation is performed.

The cooling air supply device is spaced from the measuring points and the sampling device, for example at the end of the cooling zone. The following description of the exemplary embodiment will give specific information on the location of the cooling air supply device.

The arrangement of this supply device is, however, in principle arbitrary and can be arranged

And the respective supply lines at several locations, as also shown in the exemplary embodiment described below.

This also implies that an additional sampling device may be provided between the supply device and the sampling device to compensate for the balance of the gas flow in the second zone of the furnace.

For example, if the temperature and the amount of supply air remain constant while the amount of gas drawn by the first sampling device decreases, this immediately leads to an increased amount of gas being withdrawn from the second sampling device so that the pressure ratios in the sense described above remain constant. Then, in this exemplary embodiment, the second sampling device is also connected to both the measuring points and / or the first sampling device.

The second sampling device, like the first sampling device, is also controllable depending on the pressure ratio detected by the measuring points. The two sampling devices thus have a certain relationship.

For example, in order to effect intensive cooling, according to a further preferred embodiment of the invention, a downstream gas line and a gas supply line are provided downstream of said feed means through which larger amounts of gas can be supplied and withdrawn directly again. In this way, a rapid cooling device can be provided at a locally delimited location of the cooling zone. The pressure measuring device of the type described above remains independent of this.

The cooling capacity of said rapid cooling device can be controlled as a function of temperature, wherein a temperature sensor for measuring the temperature can be arranged in the furnace between the gas supply line and the gas extraction line.

A suitable temperature sensor may also be provided in the region of the first supply device.

A further optimization of the device is achieved in an embodiment in which the discharge device arranged at the measuring points is provided with a mouth of a pipe to which mixing air is supplied. By means of this mixing air it is also possible to reduce the amount of gas discharged from the furnace.

An essential advantage of the described apparatus is that it can be adapted to existing furnaces.

As a rule, a cold air supply is already provided in these furnaces. In this case, it is only necessary to provide two measuring points for measuring the pressure in the transition region between the firing zone and the cooling zone, as well as installing an adjacent furnace gas sampling line. Other features of the invention described above are possible but not necessary.

The device according to the invention does not have to be arranged only between the firing zone and the cooling zone of the continuous furnace, but also - if necessary - at every other location, but the principle remains unchanged.

The device according to the invention can also be used in roller furnaces, tunnel furnaces with kiln trolleys, furnaces with sliding plates or the like.

Of course, the device according to the invention is not limited to the kind of products to be fired.

It is only necessary to adapt the individual parts of this device to the size of the case.

-3 CZ 284683 B6

Further features of the invention are apparent from the dependent claims and from the description and drawings.

Overview of the drawings

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be explained in more detail by way of example with reference to the accompanying drawing, in which a cooling zone of a tunnel furnace with a connection zone to a firing zone with a device according to the invention for controlling gas pressure in both zones is schematically illustrated.

DETAILED DESCRIPTION OF THE INVENTION

The figure shows the rear of the tunnel furnace 10. The direction T of conveying the products to be fired is indicated by an arrow. At the point indicated by the dividing line L there is a transition zone 15 from the firing zone B to the cooling zone K. Directly in front of the end of the firing zone B, a first measuring point 12 for measuring the pressure is provided with a corresponding sensor. Immediately adjacent to it, a second pressure measuring point 14, which is also provided with a sensor, is arranged directly behind the dividing line L at the beginning of the cooling zone K. The gas pressure is measured at suitable locations in the firing zone B and the cooling zone K by means of sensors. From these pressure measuring sensors, the lines 20 lead to the evaluation unit 16 and from there to the computer 18.

In the transport direction T, downstream of the second measuring point 14, a sampling line 20 is provided to draw gas from the cooling zone K. From the computer 18, a conduit 22 is routed to the servomotor 24 to control the throttle 26 within the sampling line 20 as still described in more detail below.

At a distance from the sampling line 20, a cold air supply line 28 flows into the cooling zone K. The amount of cold air supplied is also regulated by the valve 30 controlled by the servomotor 32, here in dependence on the temperature of the furnace prevailing in this part 30 of the cooling zone K. This temperature is determined by a temperature sensor 34 arranged in the direction

T is conveyed upstream of the supply line 28, wherein the temperature value is fed to a temperature regulator 36 which, depending on the measured temperature, emits a signal to the servomotor 32 and thereby regulates the amount of cold air supplied.

A further sampling line 38 is arranged between the sampling line 20 and the inlet line 28, the design of which essentially corresponds to that of the sampling line 20. Even with the other sampling line 38, the exhaust gas quantity can be regulated by a throttle valve 40 in the form of a valve. 46, signals from the flow controller 44 are received, wherein the flow controller 44 is connected via line 48 to the computer 18.

At the end of the tunnel furnace 10, i.e. at the end of the cooling zone K, a sampling line 50 and a supply line 52 are provided, the supply line 52 at the end of which is intended for the supply of cold air and the upstream sampling line 50 is provided for exhausting gas. The drawing shows that the sampling line 50 and the supply line 52 are arranged close together and between them a temperature sensor 54 is arranged which, at this point in the furnace space, always measures the actual temperature, which is passed to the temperature controller 58 via line 56. by means of conduit 62, it controls the servomotor 60, the servomotor 60 controlling the respective valve 64 in the supply line 52 and thereby the supply of cold air.

The sampling line 50 is formed correspondingly and is provided with a valve 66 which is actuated by a servomotor 68 to adjust it to a desired position, the servomotor 68 receiving signals via line 70 from a flow controller 72 which in turn is connected to a temperature controller 58 by a line.

-4GB 284683 B6

The device works as follows.

By means of the first measuring point 12, the actual pressure P1 is continuously measured at the end of the firing zone B. Analogously with the second measuring point 14, the actual pressure P2 is continuously measured at the beginning of the cooling zone K. The evaluation unit 16 evaluates the pressure values P1 and P2 in the computer 18. If, for example, due to the increased amount of cold air supplied by the supply line 28, the pressure P2 exceeds the pressure P1 so that the throttle 26 is opened by the servomotor 24, then the gas withdrawal from the cooling zone K increases and the pressure P2 drops. As soon as the pressure P1 is equal to the pressure P2, the actuator 24, and therefore the throttle 26, returns to its original position. Thus, the pressure conditions at the end of the firing zone B are brought into line with the pressure conditions at the beginning of the cooling zone K, so that no gas exchange occurs between the two zones B, K.

Otherwise, the procedure is reversed as described above.

If desired, the computer 18 may be designed not only to close or open the throttle 26, but also to close and open the valve 40 in the downstream manifold 38 to withdraw increased gas from the cooling zone K or to reduce the gas. .

The inlet duct 50 and the take-off duct 52 at the end of the cooling zone K serve for the so-called shock cooling of the fired products so that the fired products can be removed directly from the means on which they were laid during firing. In this case, cold air is supplied through the supply line 52, depending on the temperature measured by the temperature sensor 54, and is taken off directly before the supply line 52, so that an increased gas exchange and thus an increased cooling effect is achieved at this point.

Claims (6)

PATENT CLAIMS An apparatus for regulating gas pressure in adjacent zones of a continuous furnace (10), comprising a first metering point (12) for detecting gas pressure (P1) at one end of the first furnace zone, a second metering point (14) for detecting a gas pressure (P2) at the beginning of the second furnace zone immediately adjacent the first furnace zone, a supply device (28) for supplying gas to the second furnace zone at a distance from the second metering point (14), a furnace zone in immediate proximity to the second measurement site (14) on the side remote from the first measurement site (12) and a computer (18) connected to the first measurement site (12) and the second measurement site (14) and comprising an evaluation unit ( 16). Device according to claim 1, characterized in that the sampling device (20) is formed by an exhaust duct in which a controllable valve (26) is arranged. Apparatus according to claim 1 or 2, characterized in that a further sampling device (38) is provided between the supply device (28) and the sampling device (20) for balancing the gas flow balance located in the second zone of the furnace. Apparatus according to one of Claims 1 to 3, characterized in that a gas supply line (52) and a sampling line (50) are arranged immediately downstream of the supply device (28) in the direction of the furnace passage. gas. - 5 CZ 284683 B6 Device according to one of Claims 1 to 4, characterized in that a duct for a controllable mixing air supply is provided in the sampling device (20) arranged at the measuring points (12, 14). 5 Device according to one of Claims 1 to 5, characterized in that the first measuring point (12) is assigned to the firing zone (B) and the second measuring point (14) is assigned to the cooling zone (K) of the continuous furnace.