DE2626791A1 - Stopping compsn for blast furnace tap holes - contg refractory clay, high strength mineral aggregate, hydrocarbon binder and thermosetting resin - Google Patents

Abstract

Stopping compsn. for blast furnace tap holes comprises about 70-85% of a mineral consisting of a refractory clay, a high strength refractory aggregate and a material with a high carbon content, together with a polymerisable hydrocarbon binder obtd. from the distn. of crude petroleum oil and having a b.pt. of >200 degrees C, and a thermosetting resin which is stable at temps. of 200 degrees C and a hardener compsn. such that the onset of the curing reaction can be controlled to start at 130 degrees C. In contrast to known stopping agents, the present compsns. do not release noxious fumes in use. Suitable ingredients are non-paraffinic prods. obtd. from the distn. of crude oil, together with aminoplast resins, polyester resins, furan resins, epoxy resins, coumarone-indene resins, natural resins, phenolic resins, coal tar pitch, petroleum oil pitch etc.

Description

Tap hole dimensions for blast furnaces

The invention relates to a plugging compound for tap holes in blast furnaces, hereinafter referred to as the tap hole size.

It is known from US Pat. No. 2,709,659 to form such a Tap hole mass to use a product that is about 80% clay and brick dust as well as a binding agent, which consists of either 10 to 12 6.4 coal tar and 5 to 7% of an aldehyde, e.g., furfurylaldehyde, or 15 to 25% of one with an acidic or basic catalyst mixed phenolic resin is formed.

Unfortunately, this mass hardens in the cylinder of the tamping machine very quickly. This must therefore be taken apart after each tapping, whereby time losses occur. In the former case, the tar also burns, and harmful gases or vapors are formed in the vicinity of the tap hole. on the other hand the considerable percentage of light organic materials leads in practice serious disturbances, e.g. the formation of splashes, flames and the like.

From publications by Dr. Walter Horn in the magazine "Stahl und Eisen ", Volume 23, Pages 1497-1502, are still anhydrous tap hole compounds known, which consists of a mixture of 70 0% clay sand, 10% coal or coke and 20 ffi Tar.

But in any case, coking takes a long time, it develops a large amount of tar gases, and which leads to unburnt or hardened tar to dangerous casting impurities.

To eliminate the aforementioned disadvantages is from the US patent 3 607 809 a tap hole compound has become known, which is 70 54 from a mixture of Sand and clay consists in a proportion that the percentage of aluminum oxide is kept away from the eutectic. This mass also contains 10 ffi ground Coal or coke, a binder that only consists of 15 to 17 ffi of liquid tar and 3 to 4% of a thermostable liquid resin from the group that is up to 20,000 (3920F) the amino or phenoplasts are added, as well as' from 1 to 3/0 of a setting retarder.

At this mass, rapid coking was on the order of magnitude from 10 to 15 minutes, a small amount of harmful tar fumes and insignificant Deposits in the tamping machine, but never found any G'uB contamination.

These observations can be explained by the fact that certain Amino or phenoplasts form a carbon skeleton, inside which the Tar is burned.

However, there is still a certain gas formation in the coal tar at the moment of clogging, due to the fact that the excess tap hole mass falls into the hot tapping channel; through these gases becomes harassed the blast furnace personnel while cleaning the channel.

Accordingly, the invention is directed to a tap hole mass, with the at least as good results as with the previously mentioned anhydrous masses can be achieved and in which the development of harmful gases completely or to is suppressed for the most part.

The tap hole compound according to the invention is characterized in that they essentially consist of about 70 to 85% of a mineral filler, the refractory Clay, a refractory additive with high mechanical strength and a highly carbonized one Material, and consists of 15 to 30 efo of a hydrocarbon binder. While the mixing ratios of the clay, the refractory additive and the highly carbonized Material in the filler according to the conditions of the needle hole in wide Limits are changeable, it has been found to be advantageous to use the following Mixing proportions to be adhered to: 15 to 30% clay, 30 to 45 C / 70 more refractory Addition and 10 to 25% highly carbonized material.

The clay component of the filler has either a single one Clay or a mixture of clays, the melting point being above 14500C and the alumina content is between 4 and 42%. For example, the clay component, which forms 25% of the tap hole mass, be a clay mixture that 20 parts of clay with one Alumina content of 30% and a melting point of 16400C and 80 parts of clay with has an alumina content of 8% and a melting point above 145,000.

The refractory additive is a highly stable, inert, granular material on, for example, high-density silica, chamotte, corundum, magnesia, dolomite, Silicon carbide, Bauxite, mullite, sillimanite, etc. For example the refractory additive, which forms 41 o / o of the tap hole mass, can be made of chamotte exist, with a grain size of 2 mm, an alumina content of 42 z'9 and a melting point of 1770 ° C. The highly carbonized material is powdered or granular material consisting primarily of carbon, for example from lignite, hard coal, coke dust, graphite, crushed waste electrodes Carbon, etc. An example of the highly carbonized material that makes up 15% of the tap hole mass Matters is anthracite with 4 / volatile ingredients and 6 egg ash.

The hydrocarbon binder consists of a hydrocarbon derivative with an initial distillation temperature above 2000C and is from a group selected those from saturated or produced by distillation of crude oil unsaturated hydrocarbons, a thermosetting resin that enhances its stability maintained at temperatures above 2000C, or a combination of these Hydrocarbon derivatives and the thermosetting resin. The hydrocarbon derivatives preferably have a viscosity between 20 and 100 centipoise at 100 ° C. That thermosetting resin is so composed that the beginning of the setting process of the mixture can be adjusted from 130 ° C upwards. Therefore, for example the resin composition, an accelerator, a moderator or an inhibitor for the rate of polymerization, for example by free radicals such as acid anhydrides, amines, hydroxyl, which act as accelerators, or by hydroquinone, cobalt phthalate, etc., which act as inhibitors.

Furthermore, the hydrocarbon binder is both a thermosetting agent Resin as well as a hydrocarbon derivative, their proportions are selected in such a way that that when the mixture is used, curing is obtained which is more or less is fast, as a punctuation of the characteristics and operation of the blast furnace. Therefore, the range of proportions of the two components becomes corresponding to the following three Conditions selected: 1. Very rapid cure 45 to 85% thermoset resin 15 to 55% hydrocarbon derivative 2. Rapid curing 20 to 45 ß thermosetting Resin 55 to 80 c, hydrocarbon derivative 3. Medium cure 5 to 20 ffi thermosetting Resin 80 to 95% hydrocarbon derivative, for example, is made for a fast hardening tap hole mass the hydrocarbon binder, the 17 of the Tap hole dimensions consists of 5 ß thermosetting resin and 12 ff hydrocarbon derivative. Therefore the proportions of the thermosetting resin and the hydrocarbon derivative are related in the hydrocarbon binder such as 30 to 70 r.

In addition to the hydrocarbon binder, which acts as the first binder can be viewed, the tap hole mass according to the invention can also have a second Have binder made of a highly carbonized solid material with high coking capacity exists and which with the first binder at temperatures between 130 and 2000C should mix. The combination of the components of the composition is such, that the initial temperature can be set so that the tap hole mass sets at a temperature of 130 ° C or at a temperature higher than Function of the voltages is determined, resulting from the changeable operating conditions result in which the tap hole size is to be used.

The proportions of the components in the tap hole mass can be within of the following limit values vary, not as a limitation but as an example are specified.

Mineral component - 70 to 85% IChydrocarbon binder - 5 to 20 y Second binder - 0 to 15% This tap hole size is characterized by the following advantages: 1. Since there are no volatile components are contained, the plasticity of the mass remains essentially during storage unchanged, so that any trouble during mass injection be avoided; 2. The tap hole compound does not harden within the cylinder Tamping machine from where the temperature is roughly between 60 and 800C; 3. against it will the setting of the tap hole mass in the tap hole in which the temperature exceeds 2000C, accelerated, so that the tamping machine can be removed after just 10 minutes can; 4. the chemical setting of the binder prevents the formation of gas inclusions, as they have been created with previously known tap hole dimensions, a phenomenon which occurs because of the evaporation and subsequent cracking of the tar component such known masses; 5. the binding of the tap hole mass with the inherent one On the one hand, speed leads to a maximum yield the coking of the organic substances and, on the other hand, a very satisfactory one Resistance to erosion by the cast iron and slag; 6. at The release of dangerous vapors from the tap hole compound will set completely or largely prevented.

In the case of the hydrocarbon binder, which consists of a thermosetting resin and a hydrocarbon derivative, the resin can be selected from the following group: 1. Formophenol resins of the formula: An example of a suitable formophenolic resin is Cascophen (Borden Chemical Company, USA); 2. Furan resins of the formula: Examples of suitable furan resins are Duralon (US Stoneware Co.) and furfuryl alcohol (Rhone Poulenc France) g 3. Aminoplast resins including: a) Ureaformaldehyde resins of the formula: b) melamine-formaldehyde resins of the formula: An example of a suitable aminoplast resin is Cibamine (Ciba, Switzerland); 4. Polyester resins of the formula: An example of a suitable polyester resin is Norsodyne (CDF Chimie France); 5. Epoxy resins of the formula An example of a suitable epoxy resin is Epikote (Shell); 6. Indene coumarone resins of the formula: An example of a suitable indene coumarone resin is Necires (NCC Holland); 7. of course resins, e.g. cellobon (Graham, France).

The hydrocarbon derivatives can be taken from the following groups become: 1. Distillation products of crude oil, in particular: a) a non-paraffinic one Extract obtained by treating the distillates of the crude oil under vacuum with a selected solvents, for example phenol, nitrobenzene or purfural obtained will; b) a bituminous binder made by direct distillation is obtained from crude oil and its temperature value at which the distillation begins, above 2500C at a pressure of 760 mm of mercury.

2. Natural oils such as linseed oil and castor oil.

If a second tie is used, this is marked that it is solid at 200C and has a substantial and high carbon content Has coking ability. For example, it can be selected from the following groups his: 1. Pitch obtained by distilling tar with a Kramer and Sarnow - Softening point above 7500, with a fixed carbon content above 30 % and a viscosity of 20 to 100 centipoise at 10,000.

2. Pitch obtained by distilling crude oil with a Kræmer and Sarnow - softening point above 10,000, with a fixed carbon content above 30% and having a viscosity of 20 to 100 centipoise at 10,000.

The following are some examples of tap hole compounds according to the invention listed: Example 1 30 íá clay 37% sand 7% pitch 12% porous, ground brown coal 90 phenol formaldehyde resin 5% liquid polyepoxy resin Example 2 30% sand 25% clay 5% petroleum pitch 15% ground coal 10% corundum 9% furan resin 6 o / o liquid coumarone resin Example 3 45% sand 25% clay 5% solid coumarone 10 ground brown coal 10 phenolic resin (resole formaldehyde) 5% castor oil example 4 40% clay 15% sand 10% silicon carbide 15% amorphous carbon 10% form phenolic resin 5% petroleum oil Example 5 20% clay 55% amorphous carbon 5% graphite 12% furfuryl resin 4% liquid coumarone resin Example 6 30% clay with an alumina content of 18% 35 % Sand with a silica content of 98% 20% porous, ground brown coal with 25 0% volatiles 15% petroleum oil distillation products as above specified Example 7 35% chamotte with 42% clay 30% clay rit 1c; Alumina 20% brown coal with 25% volatile components 15% distillation products of petroleum oil those given above, in addition to compound 1: lit epoxy resin example 8 35% calcined bauxite with 88% alumina 25% clay with 22% alumina 10% coal with 4% volatile components 15% brown coal with 25 - volatile components 15% distillation products of petroleum oil as given a @ above, in connection with @ ecires resin (indene coumarone resin from H.C.C., Holland) Example 9 15% clay with a Alumina content of 30% 50% magnesia with 80 (MgO 10% lignite with 25% more volatile Components 10% graphite 15% distillation products from petroleum oil as stated above, in conjunction with cascophene resin (formphenol resin, manufactured by Borden Ghemical Co., USA) Example 10 30% clay with an alumina content of 25% 20% corundum with an alumina content of 99% 15% silicon carbide 15% stone cone with 4% volatile components 5% coal tar 15% distillation products of petroleum oil as stated above, in connection with Epikote- @ arz (@ ox @ harz der irma Shell) Die Examples listed are non-limiting embodiments of the invention Tap hole dimensions.

Claims (18)

P a t e n t a n s p r ü c h e 1. Tap hole dimensions for blast furnaces, thereby it is indicated that they essentially consist of about 70 to 85% of one mineral filler, the refractory clay, a refractory additive with high mechanical strength and a highly carbonized mineral, and from one Molmierisbaren hydrocarbon binder consists, which is a by distillation Hydrocarbon derivative obtained from crude oil with an initial boiling point above 2000C and a thermosetting resin that can be used at temperatures of about 20000 is stable and its composition is such that the setting screen on the Range above 1300C is adjustable. 2. taphole compound according to claim 1, characterized in that g e -k e n n z e i c h n e t that the hydrocarbon binder has a first binder and the tap hole mass have a highly carbonized second binder that is solid at 200C, a high Has coking ability and becomes with the first binder at temperatures between 130 and 2000C mixed. 3. tap hole mass according to claim 1 or 2, characterized in that g e k e n n z e i c ii n e t that the hydrocarbon derivative from non-paraffinized distillation extracts of the crude oil is selected. 4. tap hole mass according to one of claims 1 to 3, characterized g e k It is noted that the hydrocarbon derivative is made from residues of the direct Distillation of crude oil is selected and an initial boiling point above 2000G having. 5. tap hole mass according to one of claims 1 to 4, characterized g e k It should be noted that the hydrocarbon derivative is a kinoplast resin. 6. tap hole mass according to one of claims 1 to 5, characterized g e k It is noted that the first binder of the carbon fiber derivative is a Is polyester resin. 7. taphole material according to one of claims 1 to 6, aeabove g e k It should be noted that the hydrocarbon derivative is a furan resin. 8. tap hole mass according to one of claims 1 to 7, characterized g e k It is noted that the hydrocarbon derivative is an epoxy resin. 9. tap hole mass according to one of claims 1 to 8, characterized g e k It should be noted that the hydrocarbon derivative is a coumarone-indene resin is0 10. tap hole compound according to one of claims 1 to 9, through this NOTICE that the hydrocarbon derivative is a natural resin is. 11. taphole material according to one of claims 1 to 10, characterized g e It should be noted that the thermosetting resin is a phenolic resin. 12. taphole compound according to one of claims 2 to 11, characterized g e does not indicate that the second binder is a pitch of coal tar. 13. taphole compound according to one of claims 2 to 12, characterized g e does not indicate that the second binder is a pitch of petroleum oil. 14. Tap hole dimensions for blast furnaces, g e k e n n n z e i c h -n e t through 30% refractory clay, 35% sand, 20% ground, porous brown coal and 15% petroleum oil with a phenolic resin. 15. Tap hole dimensions for blast furnaces, g e k e n n n z e i c h -n e t through 35 refractory clay, 30, sand, 20 ° o brown coal and 15% petroleum oil with an epoxy resin. 16. Tap hole dimensions for blast furnaces, g e k e n n n z e i c h -n e t through 35 calcined bauxite, 25 Vo clay, 10 0 fatty coal, 15% ground brown coal and 15% petroleum oil with an indene oumarone resin. 17. Tap hole dimensions for blast furnaces, g e k e n n n z e i c h -n e t through 15% clay, 10 a brown coal, 50% magnesia, 10% graphite and 15% petroleum oil with a phenolic resin. 18. Tap hole dimensions for blast furnaces, g e k e n n n z e i c h -n e t through 30% clay, 20% corundum, 15% silicon carbide, 15% fatty coal, 5% pitch of coal tar and 15 ffi petroleum oil with an epoxy resin.