RU2633833C1 - Mobile plant for incineration of organic waste on polygons on reception of solid household wastes - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: in the mobile plant for incineration of organic waste consisting of a pyrolysis furnace body, a module for supplying air and energy carrier to furnace combustion chamber, containing an exhaust gas reclamation system, there is additionally a vehicle chassis with a control cabin, sprung against the chassis by the cabin depreciation system, on which a platform with vibration isolation system is disposed relative to the vehicle chassis, wherein the rotation of the furnace can be provided, for example, by gear or chain drive, the rotation of which is set from the shaft rotating the wheel on which it is fixed, wherein the shaft being is from the drive of electric or diesel engine, and in the center of the end surface of the housing there a seat for installing the burner is provided, and the outer tube of the burner is connected by means of a rotating detachable connection along the axis of symmetry of the cup with pipeline of feeding the fuel mixture to the burner.

EFFECT: increase the productivity of thermal neutralization and utilisation of organic waste both at the places of their direct location or collection, and with direct departure from there and waste disposal on the road.

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Description

The invention is intended for thermal disposal and disposal of organic waste at the places of their direct generation or collection, or with direct departure from there and waste disposal on the road. In particular, it can be used for thermal processing of bioorganic waste: agricultural production; livestock, poultry and fish farms, as well as certain types of medical waste from medical institutions.

Currently, there is a need for the disposal of these wastes in the field, at landfills for their collection, in places of their temporary accumulation and in remote medical institutions, in order to ensure the environmental safety of the environment and the population. For example, to disinfect the area in case of cattle death from an epidemic, where a mobile oven can be transported. Otherwise, the corpses of animals have to either be buried in burial grounds, which is prohibited, or burned in stationary installations where the corpses must be delivered by special transport. This requires significant financial costs and more time to neutralize the area and increases the risk of infection. Similar problems arise when the disposal of medical waste is necessary.

The closest technical solution to the claimed object is the installation according to patent RU No. 2198024, consisting of a pyrolysis type furnace body, a module for supplying air and energy to the furnace combustion chamber containing an exhaust gas utilization system.

A disadvantage of the known device is the inability to use in the field, the complexity of the process and the need to bring waste to the place of processing. The experience of using stationary furnaces for the disposal of organic waste by burning them also revealed their shortcomings that limit the term of their operational reliability. The use of stationary furnaces in rural areas is impractical because of their unprofitability. Since the reliability requirement is one of the main ones, we will consider a drawback, the elimination of which must be performed in the first place. The main disadvantage is the destruction of the furnace lining due to the uneven distribution of waste in the combustion chamber, and consequently, the thermal power in combination with the aggressive environment created by the burning of waste. The restoration of the lining is costly and time consuming. Typically, the cost of replacing the lining is about half the cost of the furnace. In addition, the process of destruction of the lining in a mobile furnace is accelerated due to the presence of vibrations during movement.

EFFECT: increased productivity of thermal neutralization and disposal of organic waste both at the places of their direct location or collection, and with direct departure from there and waste disposal on the road.

This is achieved due to the fact that in a mobile installation for burning organic waste, consisting of a pyrolysis type furnace body, a module for supplying air and energy to the combustion chamber of the furnace containing an exhaust gas utilization system, there is an additional vehicle chassis with a control cabin sprung with respect to the chassis with the cabin damping system, on which the platform with the vibration isolation system is located relative to the chassis of the vehicle, while the rotation of the furnace can be ensured, for example er, by means of a gear or chain transmission, the rotation of which is set from the shaft, the spinning wheel on which it is mounted, while the shaft rotates from the drive of an electric or diesel engine, and a seat for installing the burner is provided in the center of the end surface of the housing, and the outer nozzle of the burner connected via a rotary detachable connection along the axis of symmetry of the glass with the pipeline for supplying the fuel mixture to the burner.

In FIG. 1 shows a general view of the installation; FIG. 2 is a transverse section aa of the furnace, in FIG. 3 is a diagram of a fuel burner.

A mobile unit for burning organic waste (FIGS. 1 and 2) at landfills for receiving solid household waste (MSW) consists of the following main units: the chassis of the vehicle 14 on the axles 19 of the wheelset 20 with the control cabin 17 sprung from the chassis 14 cab 18, on which is located the platform 16 with a vibration isolation system 15 relative to the chassis 14 of the vehicle. To reduce heat transfer from the furnace body, the diameter of the transmission gear of rotation can be increased by soldering the spokes 11 or increasing the diameter of the wheel 10. The rotation of the furnace can be achieved, for example, by a gear or chain transmission 7, the rotation of which is set from the shaft 3, which rotates wheel 12 on which it is fixed. The shaft 3 either rotates from the drive of an electric or diesel engine, or the rotation is transmitted to it from the shaft of the car engine, for example, similarly to the principle of transmission of rotation of the concrete mixer in the concrete mixer. In the center of the end surface of the housing 1, a seat is provided for installing the burner 4 (Fig. 3), and the outer nozzle of the burner 8 is connected via a rotary detachable joint 5 along the axis of symmetry of the cup to the pipeline 9 for supplying the fuel mixture to the burner 4.

The design of the furnace is a metal cup-like container, which is the housing 1 of the furnace, which may also contain a hinged lid for loading waste. The inner surface is made of heat-resistant steel, resistant to aggressive media, having screw projections 13 (like a screw) on the inner surface. They allow during rotation of the furnace to ensure uniform heating of the roof and adjacent end surfaces of the furnace, as well as to mix the waste in the combustion chamber to accelerate the process of burning waste. The outer surface of the furnace is made of heat-insulating materials. The shape of the furnace body can be, for example, cylindrical or in the form of another body of revolution, for example in the form of a concrete mixer concrete mixer. The housing 1 has a rotating connection with the supporting parts 2, mounted on a movable platform or on the chassis of the car. This can be realized, for example, by making the supporting parts 2 in the form of cylindrical tubes, inside which the furnace body 1 rotates on roller bearings.

The burner 4 of the fuel mixture (Fig. 3) consists of a cylindrical hollow body 21 with a channel 23 for supplying liquid and a coaxial sleeve 22 rigidly connected to the body with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve 24, the upper cylindrical stage 26 which is connected through a threaded connection with, coaxial with it, a Central core 27 having a Central hole 29, and installed with an annular gap 10 relative to the inner surface of the cylindrical sleeve 24.

The annular gap 30 is connected with at least three radial channels 25, made in a two-stage sleeve 24, connecting it with an annular cavity 28 formed by the inner surface of the sleeve 2 and the outer surface of the upper cylindrical stage 26, and the annular cavity 28 is connected with the channel 23 of the housing 21 for fluid supply.

A nozzle made in the form of a truncated cone 31 coaxial with the central hole 29 of the core and attached with its upper base to the base of the cylinder of the central core 27 and to the lower base of the truncated cone 31 is rigidly attached to the central core 27, in its lower part, by at least at least three spokes 33, a divider 32 is attached, which is made in the form of an end circular plate, the edges of which are bent towards the annular gap 30.

On the outer side surface of the truncated cone 31 there are screw grooves (not shown in the drawing), which contribute to a more intensive atomization of the liquid.

In the divider 32, which is attached to the lower base of the truncated cone 31, by means of at least three spokes 33, and made in the form of an end round plate, the edges of which are bent towards the annular gap 30, axisymmetrically to the Central hole 29 of the Central core 27, made throttle hole 34.

An option is possible when an external diffuser 35 is coaxially attached to the sleeve 22, rigidly connected to the housing 21, in its lower part, and to the lower base of the truncated cone 31 of the atomizer, rigidly attached to the central core 27, in its lower part, while on the outer side the surface of the truncated cone 31 has helical grooves, the inner perforated diffuser 36 is coaxially attached, so that the output sections of the outer 35 and the inner 36 of the diffusers are in the same plane.

The burner 4 of the fuel mixture operates as follows.

Liquid under pressure is supplied into the cavity of the nozzle body 21 and then flows in two directions: first, into the annular cavity 28 through radial channels 25, then into the annular gap 30 between the nozzle and the central core 27. At inlet pressures of more than 0.2 MPa, the liquid accelerates with the formation of a liquid film, which does not come off its outer surface and acquires rotational motion on the helical outer surface of the truncated cone 31.

The second direction in which the liquid enters is through the channel 23 for supplying liquid into the cavity of the central hole 29 of the central core 27, and then through the cavity of the truncated cone 31 enters the divider 32, which is made in the form of an end round plate, the edges of which are bent towards the annular the gap 30, while there is a multiple crushing of droplet fluid flows flowing in these directions.

The presence of gas inclusions in a liquid additionally perturbs its surface, which leads to wave formation and volumetric crushing of the liquid film. The loss of mechanical energy during external acceleration (on the external conical surface) is reduced compared with the same acceleration in a closed channel.

Mobile installation for burning organic waste is as follows.

In the center on the opposite end surface of the glass of the housing 1, which is a hinged lid of the furnace, a hole is made for rigidly securing the pipe pipe 6 in it to exhaust combustion products. Loading the furnace with waste can be done by opening the furnace lid, for which the pipe nozzle is disconnected from the fixed pipe 6. After loading the furnace, the lid on the body closes tightly and hermetically and the pipe pipe is connected to the outlet pipe using a rotating connection. Through the pipeline 6, the combustion products enter either the treatment filter with the outlet to the atmosphere, or before that to the afterburner (not shown in the drawing).

Waste is burned in the furnace during its rotation, which allows in case of emergency epidemiological situations or during radioactive contamination of the area to quickly remove organic waste hazardous to human health from the scene, disposing of it on the road directly by car or a mobile platform, for example, a railway carriage. Since the device excludes the use of the lining in the furnace and due to the rotation of the furnace there is a uniform distribution of thermal power on its inner surface, thermal stress jumps in the material of the furnace body are eliminated, which increases its operational life and practically eliminates the need for repair, since the inside of the furnace there are no nodes other than the casing, which are exposed to a corrosive temperature environment.

Claims (1)

A mobile unit for burning organic waste, consisting of a pyrolysis-type furnace body, a module for supplying air and energy to the furnace’s combustion chamber, containing an exhaust gas utilization system, and consists of the following main units: vehicle chassis with a control cabin, suspension system damped relative to the chassis the cabin on which the platform with the vibration isolation system is located relative to the chassis of the vehicle, while the rotation of the furnace can be provided, for example, by means of a charger chat or chain transmission, the rotation of which is set from the shaft, the spinning wheel on which it is mounted, while the shaft rotates from the drive of an electric or diesel engine, and in the center of the end surface of the housing there is a seat for installing the burner, and the outer nozzle of the burner is connected by means of a rotating detachable connection along the axis of symmetry of the glass with the pipeline for supplying the fuel mixture to the burner, while the design of the furnace is a metal glass-like container, which is a body m of the furnace, which may also contain a hinged cover for loading waste, and the inner surface is made of heat-resistant steel resistant to aggressive media with screw protrusions on the inner surface, the fuel mixture burner contains a hollow body with a nozzle and a central core, the body is made with a channel for fluid supply and contains a coaxial sleeve rigidly connected with it with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve, the upper cylindrical step of which is connected by means of a threaded connection with a central core coaxial with it having a central hole and installed with an annular gap relative to the inner surface of the cylindrical sleeve, the annular gap being connected to at least three radial channels made in a two-stage sleeve connecting it to an annular cavity formed by the inner surface of the sleeve and the outer surface of the upper cylindrical stage, and the annular cavity is connected with the channel of the housing for supplying fluid to the trawl core, in its lower part, a spray gun made in the form of a truncated cone coaxial with the central hole of the core and fastened with its upper base to the base of the cylinder of the central core, and attached to the lower base of the truncated cone by means of at least three knitting needles a divider, which is made in the form of an end round plate, the edges of which are bent towards the annular gap, and on the outer side surface of the truncated cone there are screw grooves, and in the dissect le nozzle, which is attached to the lower base of the truncated cone, through at least three knitting needles, and made in the form of an end round plate, the edges of which are bent towards the annular gap, axisymmetric to the Central hole of the Central core, made a throttle hole, characterized in that an external diffuser is coaxially attached to the sleeve rigidly connected with the nozzle body in its lower part, and to the lower base of the truncated cone of the atomizer, rigidly attached to the central core, in its lower part, wherein on the outer side surface of a truncated cone have helical grooves coaxially fixed inner perforated diffuser so that the output cross section of the outer and inner cones lie in one plane.

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