RU2158197C1 - Method for mechanical treatment, mainly stone facing, of buildings and device for production of hot gaseous working medium in the form of supersonic stream used in the method - Google Patents

Abstract

FIELD: treatment and cleaning of facing surfaces of buildings, structures and various objects in construction and other fields of national economy. SUBSTANCE: the method consists in the fact that at a continuous feed of compressed air to the transportation flow solid particles of the working medium continuously form a suspension. The suspension is fed to the working member in the form of a nozzle in which it is influenced by an auxiliary flow of hot gaseous working medium in the form of a supersonic stream. The hot gaseous working medium, simultaneously with transfer of kinetic energy to suspended solid articles of the working medium, warms up and expands air in the suspension. Due to the excess of temperature of gaseous working medium relative to the suspension, the rate of flow and speed in the nozzle increases by hundreds of times and initiate the supersonic speed of outflow acting on the building stone facing. The device for production of hot gaseous working medium in the form of a supersonic stream has a body accommodating a combustion chamber, prechamber and concentrically positioned main and auxiliary air flow swirlers, injector and homogenizer of fuel-air mixture. The body is positioned in a housing enveloping it with formation of a cooling cavity. Installed on the outlet end of the body is a replaceable nozzle formed by a contraction and diffuser. The housing cooling cavity is connected through the swirler to the compressed air source and communicates with the combustion chamber. Ignition of liquid fuel is provided by an electric spark discharge initiated by the glow plug electrodes. EFFECT: enhanced rate of surface treatment and simultaneous reduction of consumption of working medium and provision of adjustment within a wide range of the rate of surface treatment and consumption of working medium. 4 cl, 3 dwg

Description

 The invention can be used for processing and cleaning surfaces of facings of buildings, structures and various objects in construction and other areas of the national economy.

 There is a known (ed. St. USSR N477831, class B 24 C 5/04, 1975) method for dynamically treating a surface, including the initial expansion of compressed air, accelerating it to supersonic speed and continuously supplying supersonic air flow under pressure of solid working particles substances with the formation of their suspension in the air, its acceleration and its impact on the treated surface.

 The disadvantage of this method is the low kinetic energy of the solid particles of the working substance, which reduces labor productivity and surface treatment quality and leads to rapid wear of the used components of the equipment used.

 Closest in their technical essence to the proposed method of machining, mainly, stone cladding of buildings is the well-known (patent of the Russian Federation N 2137593, CL 24 C 1/00) method of machining the surface, including the continuous supply of solid particles of a working substance under pressure transporting a stream of compressed air with the formation of a suspension, its supply to the working body, its acceleration in it by the action of an auxiliary flow of a gaseous working fluid, the flow rate and pressure of which exceeds the exhaust velocity and pressure of the slurry being accelerated to them, and the dynamic force effect the solid particles of the working substance to the treated surface.

 Closest in its technical essence to the proposed device for producing a hot gaseous working fluid in the form of a supersonic jet is the well-known (ed. St. USSR N309205, class F 23 D 11/10, 1967) device for burning liquid fuel containing a housing in the form of a closed cylindrical shell, inside which there is a combustion chamber with a prechamber, concentrically arranged air flow swirls and a nozzle connected respectively to a source of compressed air and a fuel line, and a fuel-air homogenizer mixture.

 The disadvantages of the known method of machining, mainly, stone cladding of buildings are the high consumption of the working substance and the insufficient speed of surface treatment, which is especially important with a large amount of the processed surface.

 The objective of the invention is to increase the speed of surface treatment while reducing the flow rate of the working substance, as well as providing the ability to widely control the speed of surface treatment and the flow rate of the working substance.

The problem is solved in that in the proposed method of machining, mainly, stone cladding of buildings, including continuous supply under pressure of solid particles of the working substance into the transporting stream of compressed air with the formation of suspended matter, its supply to the working body, its acceleration in it by the influence of an auxiliary gaseous stream a working fluid having an outflow velocity and pressure exceeding the outflow velocity and pressure of the suspension dispersed by it, and the dynamic force action of solid particles working substance on the treated surface, the size of the solid particles of the working substance is 0.01 - 20.0 mm in diameter, and a supersonic jet of hot gases is used as an auxiliary flow of the gaseous working fluid, which simultaneously transfers kinetic energy to the suspended solid particles of the working substance and the expansion of air in suspension by mixing it with a supersonic jet of hot exhaust gaseous products of combustion, the temperature of which exceeds temperatures in the air in suspension by 350-900 ^o C, while the speed and pressure of a supersonic jet of exhaust gaseous products of combustion interacting with a suspension of solid particles of the working substance exceed the corresponding parameters of the latter, respectively, by 500-1100 and 75-125 times, and in the device for method of producing a hot gaseous working fluid in the form of a supersonic jet, comprising a housing inside which a combustion chamber with a pre-chamber is arranged, concentrically arranged air flow swirls and a nozzle connected respectively to a compression source air and a fuel line, and a homogenizer of the fuel-air mixture, is provided with a housing covering the housing and forming a cooling cavity and having a replaceable nozzle mounted on the outlet end of the housing, in the form of a conjugate curved surface of the confuser and diffuser, the diameter d _{cr of the} critical section of the replaceable nozzle being less than the cross-section diameter d the cross section of the combustion chamber is 1.2-2.5 times, and the cooling cavity is connected through an auxiliary swirler to a source of compressed air and communicates with the combustion chamber through images there are radial holes in the casing, while the diameter d _{1 of the} inner surface of the casing exceeds the diameter d of the surface of the combustion chamber by 1.2-1.7 times, the angle of coverage β of the confuser is 1.2 - 3.5 times less than the opening angle α of the diffuser of the replacement nozzle and the radius R of curvature of the interface surface of the confuser and the diffuser is equal to 0.5 - 2.5 of the diameter d _{cr of the} critical section of the replaceable nozzle.

 In addition, in the method of machining, mainly, stone cladding of buildings, the hardness of the particles of the working substance can be 5.5 to 12.5 HRC, and non-ferrous metallurgical slag can be used as solid particles of the working substance.

 When using a combination of essential features characterizing the claimed method and device, a technical result is achieved, which consists in providing stepwise dispersal of the solid particles of the working substance, and in the nozzle nozzle of the technological installation implementing the proposed method, it is possible to provide a sharp increase in pressure due to heating and expansion of air, in which particles of the working substance are mixed, miscible with the auxiliary flow of the working fluid in the form of a supersonic jet of exhaust gas various combustion products produced by burning fuel, which leads to a sharp increase in the kinetic energy of a working substance of solid particles emitted onto the surface.

The essence of the method of machining, mainly, stone cladding of buildings is that continuously feeding in the conveying stream of compressed air suspended in it solid particles of the working substance with a size of 0.01 - 20.0 mm in diameter in the working body in the form of a nozzle nozzle, accelerate them in it by the influence of an auxiliary flow of a hot gaseous working fluid in the form of a supersonic jet, which simultaneously with the transfer of kinetic energy to suspended solid particles of the working substance produces heating and Irene air suspension due to the temperature rise of gaseous working fluid with respect to the conveying flow temperature of 350 - 900 ^o C, at a velocity and pressure of the supersonic jet exhaust combustion gases, interacting with the conveying slurry of solid particles of the working substance stream of compressed air exceeds that parameters of the last, respectively, 500-1100 and 75-125 times.

 The technical essence of the invention is illustrated by drawings, where Fig. 1 schematically depicts a working body in the form of a nozzle - a nozzle of a technological installation used to implement a method of machining, mainly, stone cladding of buildings; figure 2 is a General view of a device for producing a supersonic jet of hot gases in section; figure 3 - on an enlarged scale shows the front of the device for receiving a supersonic jet of hot gases with a nozzle and swirls.

 The method of machining, mainly, stone cladding of buildings is implemented as follows.

Example 1. Before starting the operation of the installation (not shown conditionally in the drawings), solid particles of a working substance 3-5 mm in diameter and with a hardness of 8-9 HRC are poured into its hopper. Then, after turning on the source of compressed air for continuous formation in the pipeline 1, connected to the working body in the form of a nozzle-nozzle 2, suspensions into it are simultaneously fed from the hopper under pressure the above solid particles of the working substance and a transporting stream of compressed air having a pressure of 6 bar , in an amount of 8.5 m ³ / min, which interact with each other. The resulting suspension continuously flows at a speed of 0.75 m / s under a pressure of 1.75 MPa into the working body in the form of a nozzle-nozzle 2. In the cavity of the nozzle-nozzle 2, the suspension entering its working cavity 3 is exposed to a supersonic jet formed by an auxiliary a stream of hot gaseous working fluid, which flows out of a replaceable nozzle of the device for receiving a flow of a gaseous working fluid in the form of a supersonic jet of hot gases. A supersonic jet of a hot gaseous working fluid simultaneously with the transfer of kinetic energy of the suspension warms up and expands the air in it due to the temperature of the gaseous working fluid being higher than the temperature of the suspension by 400 ^o C. By setting such a ratio of the temperatures of the interacting suspensions and the hot gaseous working fluid and speeding and the pressure of the latter above the speed and pressure of the suspension, respectively, 700 and 90 times, provide the kinetic energy of the solid particles of the working fluid substances ejected from the nozzle-nozzle 2, necessary for processing the stone cladding of the building with a speed of 3.5 m ² / min and the consumption of solid particles of the working substance up to 8 kg / m ^{2 of the} cleaned surface of the stone cladding.

Example 2. Before the installation starts (not shown conditionally in the drawings), solid particles of non-ferrous metallurgy slag with a size of 8-15 mm in diameter and a hardness of 9-10 HRC are poured into its hopper. Then, after turning on the source of compressed air for continuous formation in the pipeline 1, suspended in the form of a nozzle-nozzle 2, suspended, the above solid particles and a transporting stream of compressed air having a pressure equal to 10 bar are simultaneously fed from the hopper under pressure , in the amount of 9.5 m ³ / min, which interact with each other. The resulting suspension continuously enters at a speed of 0.95 m / s under a pressure of 2.5 MPa into the working body in the form of a nozzle-nozzle 2. In the cavity of the nozzle-nozzle 2, the suspension entering its working cavity 3 is exposed to a supersonic jet formed by an auxiliary a stream of hot gaseous working fluid, which flows out of the replaceable nozzle of the device to obtain a flow of a gaseous working fluid in the form of a supersonic jet. A supersonic jet of a hot gaseous working fluid simultaneously with the transfer of kinetic energy of the suspension warms up and expands the air in it due to the temperature of the gaseous working fluid being higher than the temperature of the suspension by 600 ^o C. Setting such a temperature difference between the interacting suspensions and the hot gaseous working fluid and speeding and the pressure of the latter above the speed and pressure of the suspension, respectively, 1000 and 100 times provide the kinetic energy of the solid particles of colored slag m metallurgy ejected from the nozzle-nozzle 2, necessary for processing at a speed of 4.5 m ² / min of stone cladding of the building and the consumption of solid particles of non-ferrous metallurgy slag up to 10 kg / m ^{2 of the} cleaned surface of the stone cladding.

A device for producing a hot gaseous working fluid in the form of a supersonic jet consists of a cylindrical body 4 with a combustion chamber 5 located therein, a pre-chamber 6 and concentrically arranged main 7 and auxiliary 8 air flow swirls and nozzles 9 connected, respectively, to a source of compressed air ( in the drawings, conditionally not shown) and the fuel line 10, and the homogenizer 11 of the fuel-air mixture. The housing 4 is located concentrically in the enclosing casing 12, which forms a cooling cavity 13. At the output end of the housing 4 there is a replaceable nozzle 14, which is formed by a conjugate curved surface of the confuser 15 and the diffuser 16, the radius of the critical section of which is less than the cross-sectional diameter d of the housing 4 in 1.2-2.5 times. The cooling cavity 13 of the casing 12 is connected through an auxiliary 8 swirl with a source of compressed air and communicates with the combustion chamber 5 through the radial holes 17 formed on the surface of the casing 4. The inner diameter d _{1 of the} casing 12 is 1.2-1.7 times greater than the diameter d of the casing 4 and the closing angle β of the confuser 15 and the opening α of the diffuser 16 of the replaceable nozzle 14 are 10-25 ^° and 15-30 ^° , respectively, the radius R of the interface of the confuser 15 and the diffuser 16 being 0.5-2.5 of the critical cross-section diameter d _cr replaceable nozzle 14. Ignition of fuel providing is an electrospark discharge initiated by the electrodes of the spark plug 18.

 A device for producing a hot gaseous working fluid in the form of a supersonic jet works as follows. From the fuel tank and the source of compressed air (not shown conditionally in the drawings) fuel, for example, liquid hydrocarbon fuel, and compressed air are supplied to the nozzle 9, and the amount of fuel supplied is regulated by the pressure of the compressed air in the fuel tank. The compressed air entering the nozzle, passing through the main swirler 7, swirls and mixes with the fuel coming at high speed from the nozzle 9, and forms a fuel-air mixture with it, which, passing through the homonizer 11 into the pre-chamber 6, is homogenized, i.e. . acquires uniformity of composition. In the pre-chamber 6, the homogenized fuel-air mixture is ignited by means of a spark electric discharge initiated on the electrodes of the electro-spark plug 19. Simultaneously with the supply of compressed air through the main e-swirl 7, it also passes through the auxiliary swirl 8 into the cooling cavity 14 formed from the casing 13, from which through radial openings 17 in the housing 4 - into the combustion chamber 5. The products of combustion of liquid fuel formed in the combustion chamber 5 are mixed with the compressed air coming from the cooling cavity 13 and the latter is heated, which causes its expansion, i.e. a sharp increase in pressure in the combustion chamber 5. Due to the increased pressure in the combustion chamber 5, hot gases at the exit of the interchangeable nozzle form a supersonic jet acting on the suspension in the cavity 3 of the nozzle nozzle 2.

The claimed method of machining, mainly, stone cladding of buildings and a device for producing a hot gaseous worker in the form of a supersonic jet, using the energy of combustion of fuel, allows you to clean the surface with a speed of 3 - 5 m ² / min at a flow rate of solid particles of the working substance up to 10 kg / m ^{2 of} the surface to be cleaned, while the productivity of known installations does not exceed 0.03 m ² / min at a flow rate of solid particles of the working substance of about 30 kg / m ² . The advantage of the claimed lies in the ability to widely regulate the performance and consumption of solid particles of the working substance.

Claims (4)

1. A method of machining predominantly stone cladding of buildings, comprising continuously supplying solid particles of a working substance under pressure into a conveying stream of compressed air to form a suspension, supplying it to a working body, dispersing it therein by an auxiliary stream of a gaseous working fluid having an outlet velocity and pressure exceeding the flow rate and pressure of the suspension dispersed by it, and the dynamic force action by the solid particles of the working substance on the surface to be treated, from characterized in that the size of the solid particles of the working substance is 0.01 to 20.0 mm in diameter, and a supersonic stream of hot exhaust gaseous products of combustion is used as an auxiliary flow of the gaseous working fluid, which simultaneously produces kinetic energy to suspended solid particles of the working substance heating and expansion of air in suspension by mixing it with a supersonic jet of hot exhaust gaseous products of combustion, the temperature of which exceeds temperatures near air in suspension by 350 - 900 ^o C, while the speed and pressure of a supersonic jet of exhaust gaseous products of combustion interacting with a suspension of solid particles of the working substance exceed the corresponding parameters of the latter by 500 - 1100 and 75 - 125 times, respectively.  2. The method according to claim 1, characterized in that the hardness of the particles of the working substance is 7.5 to 12.5 HRC.  3. The method according to claim 1 or 2, characterized in that the solid particles of the working substance use non-ferrous metallurgical slag. 4. A device for producing a hot gaseous working fluid in the form of a supersonic jet, comprising a housing inside which there is a combustion chamber with a prechamber, concentrically arranged air flow swirls and a nozzle connected respectively to a source of compressed air and a fuel line, and a homogenizer of the air-fuel mixture, characterized in that it is provided with a housing covering the housing and forming a cooling cavity and a replaceable nozzle mounted at the output end of the housing in the form of a conjugate erhnostyu converging tube and diffuser, with the diameter d _cr interchangeable nozzle critical section is less than the diameter of the combustion chamber cross-sectional area d of 1.2 - 2.5, wherein the cooling cavity is connected through an auxiliary swirler source of compressed air and communicates with the combustion chamber formed through the housing radial holes, while the diameter d _{1 of the} inner surface of the casing exceeds the diameter d of the surface of the combustion chamber by 1.2 - 1.7 times, and the closing angle β of the confuser is less than the opening angle α of the diffuser of the replacement nozzle by 1.2 - 3.5 times, and the radius R of curvature of the interface surface of the confuser and the diffuser is 0.5 to 2.5 diameters d _{cr of the} critical section of the replaceable nozzle.

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