RU215076U1 - snow melting device - Google Patents

Abstract

The utility model is intended for the disposal of snow in areas for various purposes, such as parking lots, parking lots, technological dead ends with narrow passages that are not intended for the passage of large-sized harvesting equipment. The technical result achieved by the utility model is to increase the efficiency of the snow-melting device due to the intensification of snow melting without additional consumption of coolant from the heat supply system. The technical result is achieved by the fact that a heat exchange module connected to a large heat exchange circuit is additionally introduced into the snow melting device, which contains a snow receiving bin, a large heat exchange circuit and an irrigation unit, while a small heat exchange circuit is placed inside the heat exchange module, the entrance of which is led into the central cavity the heat exchange module, and the outlet is brought out of the heat exchange module and connected to the irrigation unit. The claimed utility model provides for the recycling of melt water formed as a result of melting the lower layers of snow, its heating by means of a heat exchange module and the use of heated melt water for watering snow in the bunker, which intensifies snow melt, increasing the efficiency of the device. 9 w.p. f-ly, 4 ill.

Description

The snow-melting device is designed for the disposal of snow in areas for various purposes, such as parking lots, parking lots, technological dead ends with narrow passages that are not intended for the passage of large-sized harvesting equipment.

A stationary snow-melting plant based on a CHP plant is known from the prior art [RU 165483, application: 2016108861/13, 03/11/2016, published on 10/20/2016 Bull. No. 29], containing a snow-melting chamber with a surface heat exchanger. The inlet branch pipe of the surface heat exchanger of the stationary snow melting plant is connected via the heating medium to the return network water pipeline between the network pump of the first lift and the flow controller, and the outlet branch pipe of the surface heat exchanger of the stationary snow melting installation is connected via the heating medium to the return network water pipeline between the flow regulator and the lower network heater. At the same time, the snow-melting chamber of the stationary snow-melting plant is made with the possibility of being connected in summer to a storm sewer pipeline for supplying rainwater from the territory of the combined heat and power plant.

The disadvantage of such a snow melting plant is the low intensity of snow melting.

Common features with the claimed utility model are: snow melting chamber, heat exchanger.

The prior art installation for the processing of snow-ice formations [RU 2290471, application 2005127957/11, 08.09.2005, published 27.12.2006 Bull. No. 36], including a loading chamber for receiving snow-ice mass and its processing. At the bottom of the chamber there is a drain pipe for the removal of melt water. The walls of the chamber are double made of a heat-conducting material, and the cavity between them is connected with a source of coolant supply for heating the walls. On the inner side of the walls there are longitudinal fins made of heat-conducting material, turning into fins made on the inner side of the chamber bottom and directed to the drain pipe. A shower manifold and a device for supplying heated liquid in cavitation mode are installed inside the chamber. Before being fed into the chamber, the snow-ice mass enters the grinder.

Common features with the claimed device: a loading chamber for receiving snow mass, a thermal circuit.

The disadvantage of such an installation is the need to heat the water entering the shower manifold using an external heat source, as well as the presence of additional mechanical elements in the form of a chopper, which reduces the overall reliability of the installation.

A snow melter is known from the prior art [RU 114328, application 2011130088/13, 07/19/2011, published 03/20/2012 Bull. No. 8], selected as the closest analogue, containing a rectangular receiving hopper with a bottom, side and rear walls, connected through a grate installed in its lower part, with an overflow well with a cover, a heat carrier source with a submersible pump and a pipeline with a control valve for supplying it into the shower manifold with nozzles directed to the grate of the receiving hopper, and the shower manifold is made of looped pipes placed around the perimeter of the upper part of the receiving hopper, while at the level of the upper part of the receiving hopper of the snow melter, an access platform for supplying snow is equipped, in the lower part of the back wall of the receiving hopper, at the level of the specified grate, there is a hatch for unloading garbage, below which, at the level of the overflow well cover, an additional access platform is equipped for garbage and sludge removal, and the grate is placed between the side and rear walls of the receiving hopper above the bottom, made in the form of a gutter , installed with an inclination to the side overflow well.

Common features: receiving hopper, shower manifold.

The disadvantage of the snow melter is the low intensity of snow melting.

The problem solved by the claimed utility model is insufficient intensification of snow melting without additional coolant consumption.

The problem solved by the utility model is the creation of a small-sized snow-melting device for the disposal of snow masses in places that are difficult to access for large-sized harvesting equipment, while ensuring high efficiency.

The technical result achieved by the utility model is to increase the efficiency of the snow-melting device due to the intensification of snow melting without additional consumption of coolant from the heat supply system.

This ensures the disposal of snow masses in places that are difficult to access for large-sized harvesting equipment.

The technical result is achieved by the fact that a heat exchange module connected to a large heat exchange circuit is additionally introduced into the snow melting device, which contains a snow receiving bin, a large heat exchange circuit and an irrigation unit, while a small heat exchange circuit is placed inside the heat exchange module, the entrance of which is led into the central cavity the heat exchange module, and the outlet is brought out of the heat exchange module and connected to the irrigation unit.

It is preferable to make the snow receiving bunker with a coarse filtration tray.

It is preferable to install a filter grate between the capacity of the snow receiving hopper and the central cavity of the heat exchange module.

It is preferable to place a large heat exchange circuit at the bottom of the snow bin.

In the preferred embodiment of the device, it is advisable to place the irrigation unit in the upper part of the snow bin.

It is preferable to make technological slots in the bottom of the snow receiving bunker for draining melt water.

It is optimal to make a heat exchange module with cylindrical inner and outer walls.

It is advisable to make the heat exchange module with a sealed circuit formed between the inner and outer walls of the heat exchange module.

It is preferable to place a small heat exchange circuit in a sealed circuit of the heat exchange module.

It is preferable to make the heat exchange module with a pump installed in the central cavity of the heat exchange module and connected to the inlet of the small heat exchange circuit.

The claimed utility model provides for the recycling of melt water formed as a result of melting the lower layers of snow, its heating by means of a heat exchange module and the use of heated melt water for watering snow in the bunker, which ensures the intensification of snow melt without additional energy consumption, increasing the efficiency of the device.

In FIG. 1 shows a schematic representation of a snow melting device, which presents:

1 - bunker for receiving snow; 2 - large heat exchange circuit; 3 - coarse filtration pan; 4 - filter grate, 5 - heat exchange module, including: 6 - central cavity of the heat exchange module, 7 - pump, 8 - small heat exchange circuit; 9 - irrigation block; 10 - input of a large heat exchange circuit; 11 - output of a large heat exchange circuit.

In FIG. 2 shows an image of the heat exchange module (bottom view) , which shows:

12 - inner wall of the heat exchange module; 13 - outer wall of the heat exchange module; 6 - central cavity of the heat exchange module; 14 - cover of the heat exchange module; 15 - sealed contour of the heat exchange module, formed by the space between the outer 13 and inner 12 walls of the heat exchange module; 8 - small heat exchange circuit; 16 - input of a small heat exchange circuit; 17 - output of a small heat exchange circuit.

In FIG. 3 shows the technological scheme of the snow melting device.

In FIG. 4 shows the technological scheme of the heat exchange module.

The preferred embodiment of the utility model is described below.

The snow-melting device consists of a bin for receiving snow 1, at the bottom of which there is a large heat exchange circuit 2, made with the possibility of connecting an external source of heat carrier through inlet 10 and outlet 11, and in the upper part of the hopper for receiving snow 1 there is an irrigation unit 9. To the large heat exchange circuit 2 the heat exchange module is connected 5by means of fittings. It is also preferable to make a coarse filtration pan 3 at the bottom of the bunker 1 for receiving snow.

The heat exchange module 5 is a body of inner 12 and outer 13 cylindrical walls, a central cavity 6, a cover 14 and a hermetic contour 15 formed in the space between the inner 12 and outer 13 walls, in which a small heat exchange circuit 8 is placed, the entrance 16 of which is led into the central cavity 6, and the outlet 17 is brought out of the outer wall 13 and connected to the irrigation unit 9. In the preferred embodiment, the inlet 16 of the small heat exchange circuit 8 is connected to the pump 7 located in the central cavity 6. It is also preferable to perform in the technological gap between the cover 14 and the rest housing filter grill 4.

Snow melting device works as follows. The snow mass is loaded into the capacity of the bin for receiving snow 1. The coolant entering the large heat exchange circuit 2 from an external source connected through the input 10 and output 11, for example, hot water from the heat supply system of the CHP, heats the large heat exchange circuit 2, which causes snow to melt, while the melt water through the coarse filtration pan 3 and the grate filter 4 enters the central cavity 6 of the heat exchange module 5 through the technological gap (not shown in the drawings). Then, using pump 7, melt water is supplied to the small heat exchange circuit 8 through the inlet of the small heat exchange circuit 16, where it is heated by the coolant coming from the large heat exchange circuit 2 to the sealed circuit 15 of the heat exchange module 5 connected to the large heat exchange circuit 2. Heated melt water from the output 17 of the small heat exchange circuit 8 enters the irrigation unit 9, which supplies heated melt water to the capacity of the snow receiving hopper 1, intensifying the melting of the snow mass. Accumulating in the capacity of the bunker for receiving snow 1 melt water is removed through technological slots made in the bottom of the bunker (not shown in the drawings).

The constructive implementation of the proposed device in the preferred embodiment can be carried out using materials and technologies known in the prior art.

The snow receiving bunker can be made in the form of a metal container of arbitrary shape.

A large heat exchange circuit can be made in the form of a coil of metal pipes.

The irrigation block can be made of metal pipes of small diameter with holes.

The heat exchange module can be made of two cylindrical coils of pipes of different diameters inserted into each other, while the central cavity is formed by the cavity of the pipe of smaller diameter, and the sealed circuit is formed by the space between the pipes, and its tightness is achieved by rubber seals between the cover and the flange.

The technological gap between the cover and the body of the heat exchange module can be provided by connecting the cover to the body with studs with a gap (not shown in the drawings).

A small heat exchange circuit can be made in the form of a small-diameter copper pipe coil.

A drainage pump can be used as a pump.

The connection of a small thermal circuit to the pump can be carried out by means of fittings.

Connection of a small thermal circuit to the irrigation unit can be carried out by means of fittings.

The connection of an external source of heat carrier can also be carried out by means of fittings.

Any external source of hot water can be used as an external source of heat carrier, for example, the heat supply system of a CHP.

The claimed utility model can be widely used for the disposal of snow in areas for various purposes, such as parking lots, parking lots, technological dead ends with narrow passages, not intended for the passage of large harvesting equipment, providing high efficiency of the snow melting device, due to the intensification of snow melting without additional energy consumption.

Claims (10)

1. A snow-melting device containing a snow receiving hopper, a large heat exchange circuit and an irrigation unit, characterized in that it contains a heat exchange module connected to a large heat exchange circuit, while a small heat exchange circuit is placed inside the heat exchange module, the entrance of which is led into the central cavity of the module heat exchange, and the outlet is brought out of the heat exchange module and connected to the irrigation unit. 2. Snow-melting device according to claim. 1, characterized in that the bunker for receiving snow is made with a coarse filtration tray. 3. Snow-melting device according to claim 1, characterized in that a filter grate is installed between the capacity of the hopper for receiving snow and the central cavity of the heat exchange module. 4. Snow melting device according to claim 1, characterized in that a large heat exchange circuit is located at the bottom of the snow receiving bin. 5. Snow-melting device according to claim 1, characterized in that the irrigation unit is located in the upper part of the snow receiving bin. 6. Snow-melting device according to claim 1, characterized in that technological slots are made in the bottom of the snow receiving bin for draining melt water. 7. Snow melting device according to claim 1, characterized in that the heat exchange module is made with cylindrical inner and outer walls. 8. Snow melting device according to claim. 1, characterized in that the heat exchange module is made with a sealed circuit formed between the inner and outer walls of the heat exchange module. 9. Snow-melting device according to claim 1, characterized in that the small heat exchange circuit is located in the sealed circuit of the heat exchange module. 10. Snow-melting device according to claim 1, characterized in that the heat exchange module is made with a pump installed in the central cavity of the heat exchange module and connected to the inlet of a small heat exchange circuit.

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