DE2730412A1 - METHOD AND DEVICE FOR TRANSPORTING GASES - Google Patents

Description

Method and device for transporting gases

The invention relates to a decay and a device for Transport of gases, preferably hot air, especially in the cement industry.

It is known to use piston and centrifugal machines for conveying gases. Piston machines are unsuitable for the transport of hot gases. In the cement industry, centrifugal machines are only used up to gas temperatures of about 400 ^° C. because of the high pressure jumps required and the abrasive dust content of the gases. Technical solutions for significantly higher temperatures do not exist under these conditions. Furthermore, the use of jet devices for the transport of cool and / or hot air began to be used, whereby the propellant jet was generated by combustion of e.g. , DT-PS 963 549, uJJ 71.1 281, UB 741 151, UB 743 432, GB 747 5b1 and GB 761 726. It has already been proposed to expand such blowers by adding fuel to the propellant jet, preferably oil, to burners according to DT-PS 928 117 and GB 805 543.

The multitude of pre-school camps is offset by the fact that Conveying units for hot gases around 700 ° C, especially for hot air, which also contains dust, as in the cement industry, are not in use in practice. The complexity of the situation has hitherto prevented a tβchnisoii usable solution, In connection with the development of the calciner tecimik which the Deacidification of the limestone with separate heat supply between

709886/0612 _ _g

Raw meal and sintering unit aims are interested in the transportation of about 700 ⁰ C hot cooler air parallel to the sintering unit for Kalzinierbrenner. This hot KUhlerluft containing clinker dust, which is abrasive and at temperatures above about 1 350 ⁰ C partially melts, thus causing caking. To blend a common technical solution, the hot KUhlerluft with cold air until it reaches a mixing temperature of about 350 ⁰ C and then to transport ordinary with hot gas blowers satisfied nictit because of heat loss. One reason for failure of hot dusty gas conveyors is closely related to the selection of construction material for the conveyer. Even firescale resistant metals tolerated in continuous operation hardly temperatures over 1100 ⁰ C. However, the gas temperature of the blowing jet is at least at 1500 ⁰ C. Added to this is that the usual building materials, melting, and thus the sticking of Feststoffstäubea, promote, for example, clinker dust.

The aim of the invention is to create a method and the associated device that enables the transport of over 400 ⁰ C hot, dust-laden, preferably clinker-laden, air, the device being a technically useful solution with regard to oxidation, thermal shock resistance, abrasion and caking prevention of dust particles must have.

The invention is based on the object, a method and the To develop associated device for the transport of hot, dust-laden air.

According to the invention, the object is achieved in that a jet apparatus is used to convey the hot, dusty air which consists of the components vibrating fire device with expiring propellant nozzle, catching nozzle or venturi nozzle and mixing tube. The vibrating fire device is used to generate the propulsion jet. It can be operated with gaseous, liquid or solid fuels. The required combustion air enters the Rocking fire device through mechanical or aerodynamic valves. The combustion is pulsating, which is the self-priming

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the combustion air allows. The propulsion jet emerging from the vibrating fire device is picked up by a collecting nozzle. The surrounding air to be conveyed is entrained as a drag jet. With the correct dimensioning of the propellant and catching nozzle and their geometric arrangement to one another, the mass of the drag jet can be a multiple of that of the propellant jet. It is advisable to install the said jet device in the gas delivery line. In this case, the combustion air required to operate the vibrating fire device is, for example; taken directly from the air or hot air to be conveyed by the aerodynamic valves. The valves of the vibrating fire device are designed in such a way that they cause the combustion air to be drawn in by itself. It has been found that with this arrangement of the transport device, dust load numbers of »u ^ 0.2 are possible without instability of the vibrating combustion occurring. The dust load number / U is defined as the quotient of the mass flow of the solid to the mass flow of the air to be transported. A variant consists in the combustion air to produce \ of the driving beam by the swinging fire unit to the ^atmosphere; entnenmeu. If there are no valves available that allow the combustion air to be drawn in by itself, aerodynamic valves that are not optimized are sufficient if the combustion air is supplied by means of a fan. It has been found that this arrangement is particularly suitable for conveying hot gas or hot air if their dust load numbers are u> 0.2. The best here: thermal devaluation of the hot conveying air by the cold combustion air for the rocking fire device can be reduced if technical oxygen or oxygen-enriched wind is used instead of atmospheric air.

The use of several jet devices is also possible to solve the task at hand. Depending on the dust content of the pumped The blasting devices are air or the pressure jump to be achieved parallel or one behind the other.

The transport of hot air happens to them in many cases Use as combustion air. Therefore, the completion of the blasting device to a burner should be aimed for. To this end solid, liquid or gaseous fuel is added to the gas flow. The place of addition is largely free and can be

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see «the limits of the mixing tube of the jet device and the root of the gorge vary in the combustion chamber. The burner described works directly in the case of the calcining technique of the cement burning process into the reactor room

Of crucial importance for the operational safety of the killer unit or burner is the control of the dust carried along. This problem can be solved in terms of device technology or material as proposed. The device-related variant exists in a reversal of the usual sequence of propulsion and towing jet in jet devices. Then the rocking fire device is in the ifördergasleitung installed so that the propulsion jet to be promoted Towing stream envelops. A contact of the hot dust particles with the walls therefore occurs only to a limited extent, so that caking largely omitted. The material variant is based on the correct choice of building material. It was found, that clinker dust caking or smelting on zirconium silicate or Molyoandisilizid take place only to a small extent. Depending on the contact possibility of the components with the dust of the conveyed Gases are the rocking fire device with combustion chamber, aerodynamic Valves, resonance pipe, propellant nozzle as well as collecting nozzle and mixing pipe or parts of the conveying gas line made of zirconium silicate or Molybdenum disilicide manufactured. Instead of zirconium silicate or molybdenum disilicide, other ceramic materials are also suitable, as long as they withstand the prevailing conditions of temperature, temperature change, strength, etc., for example aluminum oxides, Magnesium aluminate etc. if they are provided with a protective layer of zirconium silicate or molybdenum disilicide. The protective layer is applied using known technologies, for example in the plasma spray process.

Zirconium silicate is made from sulfur dioxide that comes from combustion comes from the fuel, not attacked under these conditions.

The invention is intended below on the basis of some exemplary embodiments are explained in more detail. ± n the corresponding drawing pointer:

Yy ¹ Xg. 1 blasting device for transporting castings with little dust content with a vibrating fire device within the gas pipe.

* Q-9886/06

Pig. 2 blasting device for the transport of very dusty hot air, completed to the burner, with rocking fire equipment outside the conveying gas line.

rig. 3 jet device for transporting dusty gases with enveloping effect,

yig. 4 jet devices for the transport of gases containing dust Envelope effect in parallel connection.

The vibrating fire device, consisting of combustion chamber 4 with aerodynamic valves 6 and nozzle 2 in the conveying gas line 1, works according to Example 1 and Pig.1. The aerodynamic valves 6 are designed in such a way that they enable the combustion air required for operating the vibrating fire device to be drawn in from the hot air to be conveyed. Via the nozzles for the fuel ί>, ul is preferably fed to the vibrating fire device. The combustion gases expelled from the resonance tube 3 or the propellant nozzle 2 entrain the hot air to be conveyed and thus cause it to be transported further. The device is able ^{to promote 700 0} C hot air with dust load numbers / U £ 0.2 if the components of the jet device exposed to the hot clinker dust, including the collecting nozzle 7 and the mixing tube 8, are made of zirconium silicate.

This .fördereinrichtung works without moving parts. The warm6 losses are minimal, as the air to be conveyed absorbs the heat given off by the swingarm fire device,

According to Example 2, two or more jet devices are from Tjp of Fig. 1 for generating a high pressure jump one behind the other switched,

According to Example 3 and Fig. 2, the rocking fire device is located with the exception of the propellant nozzle 2 outside of the .Kördergasleitung 1. The combustion air for the rocking fire device is via the aerodynamic valves 6 optionally brought up by a fan. Instead of the atmospheric air, you can also use more technical ones Oxygen or oxygen-enriched wind can be used.

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The completion of the transport device to a burner is done in such a way that into the mixing tube 8 via fuel supply for example, oil entered in more or less sprayed irorm will. The burner acts in the reactor space 10, for example in Germany Calcining reactor. The components exposed to the hot dust are, such as propellant nozzle, venturi nozzle 7 and mixing tube 8 are made of aluminum oxide manufactured and provided with a protective layer of zirconium silicate. This device variant is particularly suitable for promoting iase with high dust load.

According to Example 4 and Jrig. 3 the conveyor gas line 1 is up to Venturi nozzle 7 introduced into a rocking fire device. The components exposed to hot dusts such as conveying gas line 1, venturi nozzle 7 and mixing tube 8 are made of the sintered spinel magnesium aluminate (MgO.AIpO,) and wear a protective layer of molybdenum disilicide. Due to the enveloping effect of the propellant gas jet, the Device especially for the transport of gases with high numbers of dust loads.

According to example 5 and FIG. 4, two vibrating fire devices are used to generate propulsion jets. The material for the components that are used with the are exposed to hot clinker dust, such as the mouths of the conveying gas line 1, mouth of the resonance tube 3, Venturi nozzle 7 and mixing tube 8, is zirconium silicate. Due to the enveloping effect of the propellant gas jet, the device is particularly suitable for the transport of large Gas quantities with high dust concentrations.

The advantages of the proposal according to the invention are that for the first time a solution is offered which allows hot gases, preferably hot air with temperatures of over 400 ^° C., which can also be dust-laden, to be conveyed. This allows heat devaluations caused by Versciuiitt hot cooler exhaust air by cold air at 400 ⁰ C can be avoided.

The inventive use of zirconium silicate or Mol ^ Bdändisilizid as tree sterial can be caked on or Avoid melting of clinker dust particles largely, so that the device for continuous operation under technical Conditions suitable.

703886/0612

Claims (7)

Claim 1. A method for transporting gases, preferably dust-laden, in particular hot air laden with clinker dust, by means of a jet device, the propulsion jet of which is generated by pulsating combustion by means of a vibrating fire device, characterized in that the combustion oxygen for its operation is up to dust load numbers of the hot air to be conveyed of / U ^ Ο, έ is taken from the hot air via aerodynamic valves and with dust load numbers of / U> 0.2 the combustion oxygen is taken from the atmosphere or comes from largely pure oxygen or oxygen-enriched air. 2. Device for performing the method according to claim T, characterized in that the components of the jet apparatus, such as vibrating fire device with combustion chamber (4), resonance tube (3), aerodynamic valves (6), fuel nozzles (5) and propellant nozzle (2) and catch BSW. Venturi nozzle (7) and mixing tube (8) are arranged completely or partially within the conveying gas line (i). 3 · Device according to claim 1 and 2, characterized in that the propulsion nozzle (2) of the rocking fire device is arranged within the hot gas delivery line (1) that the propulsion jet generated by the vibrating fire device from the to promoting hot air is enveloped or, conversely, that the propellant nozzle (2) of the swing fire device outside the hot gas delivery line (1) is arranged so that the propulsion jet generated by the vibrating fire device envelops the hot air to be conveyed. • J0Ö88670812 4. Apparatus according to claim i to 3, characterized in that when using several otstrahlapparaten, the tJtrahlapparate are arranged in parallel or one behind the other _# . . 5. Apparatus according to claim 1 to 4, characterized in that the transport device to a burner is completed by adding one or more fuel feeders (9) within the range of the irlammenwurzei of the ÄrennKammer (4) to the end of the mixing tube lü; arranged are. b. Device according to claims 1 to 5, characterized in that axs are building material for the elements of the beam apparatus Zirconium silicate or other ceramic material that is provided with a zirconium silicate protective layer is used will. 7. Apparatus according to claim 1 to 6, characterized in that as a building material for the elements of the jet apparatus Molybdenum disilicide or other ceramic material which is provided with a molybdenum disilicide protective layer, is used·