RU2610491C1 - Installation for snowmelt (versions) - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: group of inventions relates to a device for disposal of snow and ice masses, namely to devices forcing the snow melts, and can be used in municipal services for the utilization of snow-ice mass, resulting in the purification of urban areas, fractionation and removal contained in the snow -ledovoy mass garbage inclusions. Installation for melting the snow comprises a housing, a heat exchange system, meltwater drainage system, garbage disposal system. The housing has two housings rigidly connected with three inclined plates and coaxially arranged with a gap between the tubular member. The first plate is firmly connected with the outer end on a tubular outer and inner surface with a tubular projecting element, over which the shield is attached. The second plate is rigidly connected at its end with an averagely located between the plates tubular member. The inner tubular element has a heat exchange system, which comprises a heating element and a propeller rotatably mounted on the shaft. Wherein the first plate, made with perforations between the housing and a tubular outer member coupled to a receiving device for large garbage, and the lower plate is connected to the receiver for fine dust. As a second embodiment, the heat exchange system may be implemented as a centrifugal bubble device, with one side connected to the air heater and on the other hand - the water supply pipe in a centrifugal bubbling device located at the bottom of the housing, and removing water from the nozzle centrifugal-bubble machine, located in the interior of the tubular element, with installation for melting snow.

EFFECT: invention provides a cost-effective, easily operated installation allowing to separate garbage inclusion contained in the snow and ice mass fractionation, highlighting the large and small debris without interrupting the snow melting process.

2 cl, 2 dwg

Description

The invention relates to devices for the disposal of snow and ice mass, namely, devices for forced snow melting, and can be used in municipal services for the disposal of snow and ice mass obtained by cleaning urban areas (roads, intra-quarter territories, territories of industrial facilities, etc. .), separation into fractions and removal of garbage inclusions contained in the snow-ice mass.

Known is “Snow Melter”, utility model patent No. 96874 (Е01Н 5/10), which consists of a rectangular receiving hopper with a bottom, internal and external heated side walls, a dirt collector, a coolant source that is fed into the lower heated part of the receiving hopper and shower collector, which is made in the form of looped pipes around the perimeter of the upper part of the receiving hopper, with nozzles directed to the snow mass. The snow mass is located in removable containers mounted on the bottom of the hopper. Trash in the snow is trapped in containers and containers can be removed if necessary to remove trash. Through the perforated inner wall of the hopper, melt water enters the sump, settles and goes into the sewer, and small debris is removed as the sludge collects.

The disadvantages of this device include large energy losses associated with the consumption of thermal energy for heating the bunker, heat loss during the irrigation of snow mass, the need for periodic cleaning of the grate of garbage containers and the use of additional mechanisms (sludge suction) to clean the bottom of the well.

Known "Installation for melting snow", patent for utility model No. 109155 (Е01Н 5/10), containing a bath divided into interconnected compartments, one of which is designed to collect snow, the first heat exchange means for heating, designed to heat melt water baths, and a second heat exchange means for heating associated with a heat source, as well as a heated water supply system to the snow collection compartment, which includes a pump installed in the bath and connected by pipelines to the heated water supply manifold s, wherein said first and second means for heating are configured to interact with each other to transfer heat from the second means to the first, and said heat source is a fuel device that heats the second heat exchange means for heating.

The disadvantages of this device include the presence of two heat exchangers, which creates a reduced efficiency, heat loss during irrigation of snow mass, the complexity of waste disposal from the installation, because it is necessary to stop the installation and completely drain the water from the garbage disposal tank. In addition, the presence of two pumps and two heat exchangers leads to an increase in installation costs and a decrease in reliability.

Closest to the technical nature of the claimed device is "Snowmaking installation", patent for utility model No. 121822 (Е01Н 5/10), consisting of a tank with a heat exchanger located below, through which hot water passes, heating systems, melt water drainage systems, irrigation system, cleaning system, which is made in the form of a technological hatch located at the bottom of the tank and mounted on the rear of the hatch, a cleaning device adapted to the shape of the surface being cleaned.

The disadvantages of this installation are energy losses during the irrigation of snow mass, the need to stop the device for cleaning the tank of debris and garbage inclusions, and the fact that the debris is not divided into fractions by size.

An object of the present invention is to provide an economical, easy-to-operate and reliable installation for melting snow and capable of fractioning waste inclusions in a snow-ice mass.

The problem is solved in that in a snow melting installation comprising a housing, a heat exchange system, a melt water drainage system, a garbage disposal system, the housing has two inclined plates rigidly connected to the housing and three pipe-shaped elements coaxially mounted with gaps between them, the first plate rigidly connected at the end with the outer tube-shaped element and on the outer surface with a protruding inner tube-shaped element, over which a protective screen is fixed with a gap, the second plate is rigidly o is connected at the end with the middle, located between the plates, tube-shaped element, in the inner tube-shaped element there is a heat exchange system comprising a heating element and a propeller mounted for rotation on the shaft, while the first plate made with perforation between the body and the outer tube-like element connected to a receiver for large debris, the bottom plate is connected to a receiver for small debris.

Also, the stated problem can be solved by the fact that in a snow melting installation comprising a housing, a heat exchange system, a melt water drainage system, a waste disposal system, two inclined plates rigidly connected to the housing and three pipe-like elements coaxially mounted with gaps between each other are located, moreover, the first plate is rigidly connected at the end with the outer tube-like element and on the outer surface with a protruding inner tube-shaped element, over which a protective screen is fixed with a gap, the second end face is connected to the middle, located between the plates, tube-shaped element, while the first plate, made with perforation between the body and the outer tube-shaped element, is connected to a receiving device for large debris, the lower plate is connected to a receiving device for small debris, and a heat exchange system made in the form of a centrifugal bubbler apparatus, on the one hand connected to an air heater, and on the other hand, a water supply pipe to the centrifugal bubbler apparatus located at the bottom of the housing, and a nozzle for removing water from a centrifugal bubbler apparatus located in the inner tube-shaped element, with a snow melting unit.

In FIG. 1 shows a snow melting apparatus with a heat exchange system comprising a heater and a propeller.

In FIG. 2 shows a snow melting unit using a centrifugal bubbler for a heat exchange system.

The snow melting installation consists of a housing 1, inside of which there is an inclined plate 2, an inclined plate 3, and three coaxially mounted tube-shaped elements: outer 4, middle 5, internal 6. The inclined plate 2 is rigidly connected to the housing 1 around the perimeter and with the end face of the outer tube-shaped element 4, and the plate between the housing 1 and the outer tube-shaped element 4 is perforated with a hole size, for example 1-2 mm, for passing small debris (sand). The inclined plate 3 around the perimeter is rigidly connected to the housing 1 and to the end of the middle tube-shaped element 5.

The plate 2 is connected to a container 7 for collecting large debris located in the housing 1, in which large debris slides along the inclined plate 2 and settles on the bottom of the container 7. When filling the container 7 with garbage, it is lifted and the garbage is removed.

The inclined plate 3 is connected to the container 8 for small debris through the pipe 9 with a shut-off valve. To drain the melt water, the housing 1 at the bottom level is connected to a pipe 10, which is divided into two nozzles: a nozzle 11 used to drain the melt water during operation, located at the installation height and branched above the junction of the inclined plate 2 with the housing 1, and the nozzle 12, used to completely drain the water from the system. Above the housing 1 for delaying bulky debris, a grate 13 is installed, which can be lifted to remove debris from the grate. The protective screen 14 is installed above the inner tube-shaped element 6 and prevents it from falling into the snow-ice mass, which would disrupt the circulation of water.

According to the first embodiment, the heat exchange system is as follows. In the inner tube-shaped element 6, there is a propeller 15 mounted on a shaft 16, which is driven by a motor 17. Above the propeller 15 is a heater 18, made in the form of looped serpentine-shaped pipes through which hot water flows, heated by an electric or gas source ( not shown in the drawing).

According to the second option, when performing a heat exchange system using a centrifugal bubbler apparatus 19, a nozzle 20 is mounted in the bottom of the housing 1, through which melt cold water is taken and passed through a centrifugal bubbler apparatus 19. Heat exchange between the heated by means of a heater is carried out inside the centrifugal bubbler apparatus 19 21 by air and melt water, then through the pipe 22 hot water is supplied to the inner tube-shaped element 6.

Installation for melting snow works as follows.

In the embodiment, when the heat exchange system contains a heater and a propeller, before starting the melting of the snow-ice mass, the housing 1 must be filled with water to the overflow level in the nozzle 11. Then, the engine 17 is turned on, which rotates the propeller 15, the water flow generated by the propeller 15 moves upward along the inner tube-like element 6, in which the water is heated from the heater 18, hits the screen 14 mounted on top, bends around it and enters the upper part of the melting zone, into which the snow-ice mass is also fed, passed through the lattice 13. Then, under the influence of turbulence, the water mixes with the snow and, transmitting to it the thermal energy received from the heater, melts the snow. Then the water passes through the perforated part of the inclined lattice 2, goes around the labyrinth formed by the tube-shaped elements 4, 5, 6 and then enters the lower part of the housing 1. Then the flow of cold water again rises through the inner tube-shaped element 6, is heated by the heater 18 and the cycle repeated.

During the melting of the snow mass in the water in the housing 1, large debris rolls down the inclined perforated plate 2 into the container 7, and small debris (sand) passing through the perforated part of the plate 2 hits the inclined plate 3 and flows through the pipe 9 into the container 8 for small garbage. The container 7 is removed using a crane to remove debris, this must be done when the main part of the next portion is melted, so that in the absence of the container large debris gets into the cavity, which, due to its severity, settles in the initial melting period. The container 8 in order to prevent leakage of water during operation is hermetically connected to the pipeline 9, but when it becomes necessary to empty it, the valve of the pipeline 9 is closed, the container 8 is opened and emptied.

Melt water through a pipe 10 and a pipe 11 can merge into the city sewerage. If necessary (in the case of troubleshooting, or at the end of work), water is discharged from the housing through the opening of the nozzle 12. If the perforated grate 2 is clogged, the “propeller” 15 must be turned back, and the water flow directed in the opposite direction will clear the perforated part plates 2.

In an embodiment of a heat exchange system using a centrifugal bubbler apparatus 19, the housing 1 is also initially filled with water, then the water through the nozzle 20 enters the centrifugal bubbler apparatus 19, is heated by supplying hot air from the heater 21, and hot water is supplied through the pipe 22 under pressure is fed into the inner tube-shaped element 6. Then hot water rises, hits the screen 14, bends around it and enters the upper part of the melting zone, which also receives the snow-ice mass, passed passing through the lattice 13. Then, under the action of turbulence, water mixes with snow, transferring thermal energy to it, and the snow mass melts. Then the water passes through the perforated part of the inclined lattice 2, goes around the labyrinth formed by the tube-shaped elements 4, 5, 6 and enters the lower part of the housing 1. Then, the cold water is again taken into the centrifugal bubbler apparatus 19, heated in it and supplied through the nozzle 22 under pressure into the inner tube-shaped element 6 and the cycle repeats again. Large debris rolls down the inclined perforated plate 2 into the container 7, and small debris (sand), passing through the perforated part of the plate 2, hits the inclined plate 3 and flows through the pipe 9 into the container 8 for small debris. The container 7 is removed by a crane to remove garbage, this must be done when the main part of the next portion is melted so that in the absence of the container large debris does not enter the cavity, which, due to its severity, settles in the initial melting period. The container 8 in order to prevent leakage of water during operation is hermetically connected to the pipeline 9, but when it becomes necessary to empty it, the valve on the pipeline 9 is closed, the container 8 is opened and emptied. Drain melt water is also produced through a pipe 10 and a pipe 11, for example, in the city sewer.

Thus, the proposed installation for melting snow is economical, easy to operate and allows you to separate the garbage inclusions contained in the snow-ice mass into fractions, emitting large debris and fine (sand), without interrupting the process of melting snow. The allocated sand can be reused in municipal services.

Claims (2)

1. Installation for melting snow, comprising a housing, a heat exchange system, a drainage system of melt water, a waste disposal system, characterized in that there are two inclined plates rigidly connected to the housing and three pipe-shaped elements coaxially mounted with gaps between them, the first plate rigidly connected at the end with the outer tube-shaped element and on the outer surface with a protruding inner tube-shaped element over which a protective screen is fixed with a gap, the second plate is rigidly connected at an ortsu with a middle pipe-shaped element located between the plates, in the internal pipe-shaped element there is a heat exchange system comprising a heating element and a propeller mounted rotatably on the shaft, while the first plate made with perforation between the body and the external pipe-shaped element is connected to receiver for large debris, the bottom plate is connected to a receiver for small debris. 2. Installation for melting snow, comprising a housing, a heat exchange system, a drainage system of melt water, a waste disposal system, characterized in that there are two inclined plates rigidly connected to the housing and three pipe-like elements coaxially mounted with gaps between them, the first plate rigidly connected at the end with the outer tube-shaped element and on the outer surface with a protruding inner tube-shaped element over which a protective screen is fixed with a gap, the second plate is connected at the end to the middle located between the plates, the tube-shaped element, the first plate made with perforation between the housing and the outer tube-shaped element connected to the receiving device for large debris, the lower plate is connected to the receiving device for small debris, and the heat exchange system is made in the form of a centrifugal a bubbler apparatus, on the one hand connected to an air heater, and on the other hand, a water supply pipe to the centrifugal bubbler device located at the bottom of the housing, and a pipe removal of water from a centrifugal bubbler apparatus located in the inner tube-shaped element, with installation for melting snow.

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