RU2185581C2 - Adjusted cooled gate valve for gas duct - Google Patents

Abstract

FIELD: non- ferrous metallurgy; copper-refining anode furnaces with gas-discharge passage. SUBSTANCE: adjusting cooled gate valve includes supply and discharge collectors, swivel flat tube panel fitted with dispensing and accumulating collectors made in form of double pipes and connected respectively to supply and discharge collectors by means of flexible metal- reinforced hoses; it is also provided with electric actuating mechanism. Ratio of length of flexible metal-reinforced hoses to distance between collectors to which they are connected is 10:9. At points of connection with flexible metal-reinforced hoses, dispersing and accumulating collectors are provided with guide chute-shaped lug-type unit; radius of curvilinear section of lug is equal to (5-6)d, where "d" is inner diameter of metal-reinforced hose and ratio of length of rectilinear section of lug to length of its curvilinear section is equal to 1(1-1.2). EFFECT: enhanced reliability of connection of collectors with flexible metal-reinforced hoses due to selection of optimal length of hoses and availability of special fittings at points of connection of flexible hoses which excluded bending of lower part of hoses below permissible limit. 1 dwg

Description

 The invention relates to non-ferrous metallurgy, in particular, to refining reflector furnaces with a gas exhaust device.

 Known designs of reflective furnaces containing a melting bath, arch, cooled walls, vertical and horizontal exhaust ducts (flues). Between the vertical and horizontal flues, the gas exhaust duct is equipped with an adjustable cooled gate, the design of which is a rotary panel of pipes welded together, the ends of which are welded into the upper and lower manifolds. The upper manifold is made in the form of a “pipe in pipe”, wherein the outer pipe is connected to the lower collector. The ends of the upper collector, which is simultaneously the axis of rotation of the gate, are used to supply boiler water and drain the steam-water mixture. They are connected to the distributing and collecting manifolds using stuffing box seals (O.N. Bagrov. Evaporative cooling of furnaces in non-ferrous metallurgy.- M .: Metallurgy, 1979, pp. 73-74, Fig. 44).

 The disadvantages of this design are that the stuffing box seals are not sufficiently reliable in operation design of the evaporative cooling unit. The packing is designed to prevent leakage of liquids (gases, water vapor, etc.) from pipelines and compensate for their linear changes. In the described construction, the packing must not only prevent leakage of superheated water or steam-water emulsion during axial movement of pipes inside the upper manifold relative to each other, but also, most importantly, during rotation, which is mandatory in the technological mode of operation of the adjustable gate. Since the stuffing box seal of the collector accepts not only axial compensation, but should also provide a seal when the gate is turned, i.e. It works simultaneously to compensate for linear elongations and for torsion, rapid wear of the sealing gasket, depressurization of the assembly as a whole is observed, which creates difficulties in operating the gate (leaks, short service life, difficulty in maintenance, etc.) and leads to unreliability of its operation.

The closest to the claimed invention in terms of technical nature and the achieved result is the design of the gate (application for the grant of a patent for invention 98120592 dated 11/03/1998, MKP6 F 27 B 3/00, decision on the grant of a Russian patent dated 12/15/1999 "Gate of a flue of a reflective furnace" ), which is a rotatable flat cooled panel of pipes connected to it by distributing and collecting collectors made in the form of "pipe in pipe", and an electric actuator. The cooled gate panel is made of the “pipe in pipe” type, the distributing and collecting collectors are rigidly connected to each other and on each side are equipped with two fittings for supplying and discharging the cooling medium installed in the plane of the cooled panel and at an angle of 90 ^° to the axis of the collectors. The inlet and outlet manifolds are equipped with flexible metal sleeves, while the flexible metal sleeves of the inlet and outlet manifolds are connected respectively to the nozzles of the distributing and collecting manifolds.

 In the described device, the distributing and collecting manifolds, made by the type “pipe in pipe” and which are the shaft on which the gate rotates, are rigidly connected to each other by means of end caps for welding. The creation of such a rigid structure prevents the leakage of superheated water and steam-water mixture. This allows you to ensure sufficiently reliable operation of the gate, facilitates its maintenance and operation, increases its resistance.

The connection of the distributing and collecting manifolds with flexible metal sleeves for supplying and discharging the cooling medium using fittings that are installed in the plane of the cooling panel and at an angle of 90 ^° to the axis of the collectors, when opening (turning) the gate during the melting process, allows the sleeves to bend in one plane.

 The disadvantage of this design is that during the rotation of the cooled gate the lower part of the metal sleeve "sags" under the influence of gravity of the metal sleeve filled with a cooling medium (water or steam-water emulsion), and at a distance of 200-300 mm from the lower fitting, the sleeve bends with a radius (1.5-2.0) d (where d is the inner diameter of the sleeve), which leads to the formation of a "fistula" and the failure of the metal sleeve. If the length of the metal sleeve is reduced, it may break. The service life of this design is 6-8 months, after which it is necessary to replace metal hoses, which can be done only when the anode furnace is stopped, which is associated with a loss in copper production and the need for costs for the purchase of new metal hoses.

 The analysis of the analogue and prototype described above revealed that none of them achieves the desired result - the creation of a regulated cooled gate of the gas duct, ensuring reliable connection of collectors with flexible metal sleeves by choosing the optimal length of metal sleeves and supplying distributing and collecting manifolds at the places of flexible connection metal sleeves, special devices that prevent bending of the lower part of the sleeves with a radius less than acceptable.

 The authors of this application for the invention created the design of the gate of the flue with the achievement of the specified technical result. It, like the prototype design, contains inlet and outlet manifolds, a rotatable flat cooled panel of pipes, equipped with distributing and collecting manifolds made as a “pipe in pipe” and connected by flexible metal sleeves respectively to the inlet and outlet manifolds, and an electric actuator mechanism.

 The flue gas gate device differs from the prototype device in that the ratio of the length of the flexible metal sleeves and the distance between the collectors to which they are connected is 10: 9, and at the points of connection with the flexible metal sleeves the distributing and collecting manifolds are equipped with guiding gutter devices of the petal type, in which the radius of the curved section of the petal is (5-6) d, where d is the inner diameter of the metal sleeve, and the ratio of the length of the rectilinear part of the petal to the length of its curvilines ynogo portion is 1: (1-1.2).

 The inventive device of the gate of the flue reflective furnace meets all the criteria of patentability.

 It is new, because similar solutions known from the prior art do not have an identical set of features, as evidenced by the above analysis of known structures.

 The invention proposed for patent protection has an inventive step, because its essence for a specialist does not explicitly follow from the prior art, i.e. no solutions have been identified that have signs that match the distinguishing features of the claimed design, and therefore, the fame of the distinctive features to the technical result indicated by the applicant cannot be confirmed.

 The claimed invention is industrially applicable, because it can be used in the production of refined copper in the conditions of Uralelectromed JSC for its intended purpose, i.e. for regulation of technological melting modes. Not a single feature taken separately, nor the totality of the features of the invention contradicts the possibility of their application in industry and does not prevent the achievement of the technical result perceived by the applicant.

The implementation of the task is provided due to the fact that in the inventive device according to the technology of the exhaust pipe, the rotation value of the gate is ± 26 ^o from the vertical axis and is taken from the condition of the minimum resistance of the exhaust pipe of the anode furnace. When the gate is turned 26 ^o from the vertical axis, the metal sleeves are bent and significant loads arise at the points of their attachment to the collectors, which lead to the formation of a “fistula” and failure of the metal sleeve, and, consequently, of the entire installation as a whole. In order to avoid this negative effect in the inventive device and to ensure the fulfillment of the task underlying the claimed invention, the ratio of the length of the flexible metal hoses and the distance between the collectors to which they are connected is 10: 9 in the regulating cooled flue of the gas duct. This ensures a sufficient length of the metal sleeves, which prevents them from breaking when the gate rotates 26 ^o from the vertical axis. In addition, the choice of the optimal length of metal sleeves provides a smooth bending of a heavy metal sleeve filled with water or a steam-water emulsion in its lower part at the place of attachment to the collector. The radius of such a bend should be (5-6) d, where d is the inner diameter of the metal sleeve. A decrease in this value leads to a decrease in sleeve resistance due to the formation of a "fistula" at the attachment point, and, consequently, depressurization of the attachment point and failure of the gate. An increase in the length of flexible metal hoses unnecessarily burdensome the device as a whole and increases its dimensions, which reduces its operational reliability.

In addition, to ensure reliable connection of the distributing and collecting manifolds with flexible metal sleeves, it is envisaged to provide these collectors with gutter-shaped devices of the petal type. The radius of the curved section of the petal is (5-6) d, where d is the inner diameter of the metal sleeve, and the ratio of the length of the rectilinear part of the petal to the length of its curved section is 1: (1-1.2). The installation on the distributing and collecting manifolds in the attachment points of the metal sleeves of the petal-type gutter-type devices allows for smooth bending of the metal sleeve and preventing bending of its lower part with a radius less than permissible, which together with the optimal length of the metal sleeve ensures an increase in its durability and reliable connection with collectors . With a decrease in the radius of the curved section of the lobe less than 5d at the junction of the metal sleeves with the collectors at a gate rotation of ~ 26 ^o (due to the requirements of the technology) "fistulas" are formed, as a result of which the installation fails. The increase in the radius of the curved section of the petal over 6d leads to an unjustified increase in the dimensions of the installation, which, in turn, leads only to high costs for its maintenance.

 The optimal ratio of the length of the rectilinear part of the petal to the length of its curvilinear section is 1: (1 ÷ 2) and is selected taking into account the length of the metal arms described above and the rotation value of the gate. A decrease in this ratio will lead to disruption of the work of flexible metal hoses due to the formation of "fistulas", and an increase in the declared value is impractical, since it leads to unreasonably high costs for the construction of the installation.

 Based on the foregoing and taking into account the disclosed causal relationship between the totality of the features of the claimed invention and the technical result obtained with their help, it can be argued that the problem underlying the creation of a regulating cooled flue gas gate has been completely solved, since the use of the invention allows for reliable connection of gate collectors with flexible metal sleeves by choosing the optimal length of metal sleeves and supplying distributing and collecting manifolds the connection points of flexible metal hoses special devices which prevent the bending radius of the bottom of the sleeves less acceptable.

 The essence of the invention is illustrated in the drawing, which shows a General view of the regulating cooled gate of the duct (side view).

 The regulating chilled flue of the gas duct includes an inlet 1 and an outlet 2 collectors, a rotary flat cooled panel 3 of pipes, equipped with a distributing 4 and collecting 5 collectors made in the form of a pipe in pipe and connected with flexible metal sleeves 6 respectively to the inlet 1 and the outlet 2 collectors , and an electric actuator (not shown). The ratio of the length of the flexible metal hoses 6 and the distance between the collectors 1 and 4, 2 and 5 to which they are connected is 10: 9. At the junctions with flexible metal sleeves 6, the distributing 4 and collecting 5 collectors are equipped with guiding devices of the petal type 7, in which the radius of the curved section of the petal - R is (5-6) d, where d is the inner diameter of the metal sleeve 6, and the length ratio L of the rectilinear part of the petal to the length of its curved section l is 1: (1 ÷ 1.2).

 Regulating cooled gate flue works as follows.

 The regulation of technological modes of melting in the anode furnace is carried out by rotating the flat cooled panel 3 gates around the axis connected to it distributing 4 and collecting 5 collectors made by the type "pipe in pipe". Since the gate of the flue works in the high temperature zone, the panel 3 of the gate is also cooled by the type of "pipe in pipe". The gate is cooled by connecting it to the evaporative cooling system through the inlet 1 and outlet 2 collectors and flexible metal sleeves 6, connected respectively to the distributing 4 and collecting 5 collectors. The cooling medium is supplied through one of the flexible metal hoses 6 to the distributing 4 collector in the inner pipes of the cooled panel 3, then the steam-water mixture through the outer pipes of the cooled panel 3 rises into the collector 5 and through another flexible metal sleeve 6 into the outlet 2 collector.

 When you open (turn) the cooled panel 3, carried out during the melting process, the flexible metal sleeves are bent. To ensure a given bending radius of the lower part of the metal sleeves 6, equal to (5 ÷ 6) d, distributing 4 and collecting collectors in the places of their attachment with metal sleeves 6 are provided with guiding grooved devices of the petal type 7. Moreover, in the guiding grooved devices of the petal type 7, the petals have a straight and curved section. The radius R of the curved section of the petal is (5 ÷ 6) d, and the ratio of the length L of the rectilinear part of the petal to the length l of its curved section is 1: (1 ÷ 1.2). In addition, guiding gutter-shaped devices of the petal type, located in the plane of bending of the metal sleeves 6, when opening (turning) the cooled panel 3 of the gate during melting, completely eliminate the torsion of flexible metal sleeves 6.

Claims (1)

 Regulating cooled flue gas gate, including inlet and outlet manifolds, a rotatable flat cooled panel made of pipes, equipped with a distributing and collecting manifold made in the form of a pipe in a pipe and connected by flexible metal sleeves respectively to the inlet and outlet collectors, and an electric actuator, characterized in that the ratio of the length of the flexible metal hoses and the distance between the collectors to which they are connected is 10: 9, and at the junctions with the flexible the distributing and collecting manifolds are equipped with metal sleeves with guiding gutter devices of the petal type, in which the radius of the curved section of the petal is (5-6) d, where d is the inner diameter of the metal sleeve, and the ratio of the length of the rectilinear part of the petal to the length of its curved section is 1: ( 1-1.2).