CN210463195U - Convection type nano phase change latent heat energy-gathering radiator - Google Patents

Abstract

The utility model belongs to the technical field of heating equipment, especially, relate to a to STREAMING nanometer phase transition latent heat energy-gathering radiator, be equipped with the cooling group between bottom plate, the last air grid, the cooling group transversely sets up side by side, the cooling group includes the cooling tube, the positive fin of the positive fixedly connected with of cooling tube, cooling tube back fixedly connected with back fin, the cooling tube top is fixed in last air grid, and the bottom mounting is on the fixed plate, the bottom is equipped with the heating rod in the cooling tube, the top is equipped with discharge valve in the cooling tube, be equipped with the nanometer medium in the cooling tube, the heating rod bottom is connected with independent switch.

Description

Convection type nano phase change latent heat energy-gathering radiator

Technical Field

The utility model belongs to the technical field of heating equipment, especially, relate to a convection type nanometer phase transition latent heat gathers can radiator.

Background

Heating is a social service for solving the basic life requirement of winter heating of residents in northern China.

The heating medium used in a heating installation is usually air, steam or hot water.

The specific heat of air is small and the density is also small. When it is used as heat medium, the volume flow rate of air is large, and it has rather thick pipeline, so that its cost and energy consumption are large. The air in the room is directly used as heating medium, and it is unnecessary to install heating radiator, and it can ventilate at the same time. Such heating media are typically used in situations where the heat source is located in close proximity to the heated room.

When the steam is condensed, more than two thousand and thousand of heat energy can be released per kilogram. The circulation of the heating medium almost depends on the pressure of the heating medium without additional electric energy or mechanical energy, so the heating medium is an ideal heating medium. The disadvantage is that the steam trap on the pipe needs to be maintained frequently and is still difficult to avoid air leakage; in order to reduce the impact of steam and water in the pipeline, the horizontal pipeline must be arranged to be inclined downwards along the steam flow direction and cannot fluctuate with the terrain, so that the manufacturing cost is increased. The heat transmission distance using steam as heat medium is not longer than 5 km.

The specific heat and density of hot water are both much greater than that of air. The heat supply pipe has a small size because the heat quantity per kilogram is less than that of the steam, but the heat quantity per cubic meter is more than that of the steam. Although the circulation water pump of the hot water consumes electric energy, the heat loss in the conveying process is less than that of steam; in addition, the supply temperature of the hot water is easily adjusted. Therefore, it is common to use hot water as a heating medium for heating, in addition to houses that are used intermittently.

However, coal-fired heating is one of the main reasons for severe haze weather, causes severe damage to the nature and also has severe influence on human health, and all levels of governments have taken measures to support coal-to-electricity heating in order to eliminate severe haze weather.

Disclosure of Invention

The utility model provides a to STREAMING nanometer phase transition latent heat and gather ability radiator to solve the response government call that proposes in the above-mentioned background art, solve the problem of burning coal polluted environment.

The utility model provides a technical problem adopt following technical scheme to realize:

a convection type nanometer phase change latent heat energy-gathering radiator comprises a first fixing column and a second fixing column, wherein a display screen is arranged on the front side of the second fixing column, a first fixing seat is arranged at the bottom of the first fixing column, a second fixing seat is arranged at the bottom of the second fixing column, an upper ventilating grate and a lower ventilating grate are fixedly installed between the first fixing column and the second fixing column, the lower ventilating grate is located below the upper ventilating grate, a lower fixing plate is arranged above the lower ventilating grate, one end of the lower fixing plate is connected with the first fixing column, the other end of the lower fixing plate is connected with the second fixing column, an upper fixing plate is arranged above the upper ventilating grate, one end of the upper fixing plate is connected with the first fixing column, and the other end of the upper fixing plate is connected with;

be equipped with heat dissipation group between bottom plate, the last air grid, heat dissipation group transversely sets up side by side, heat dissipation group includes the cooling tube, the positive fixedly connected with front fin of cooling tube, cooling tube back fixedly connected with back fin, the cooling tube top is fixed in last air grid, and the bottom mounting is on the fixed plate, the bottom is equipped with the heating rod in the cooling tube, the top is equipped with discharge valve in the cooling tube, be equipped with the nanometer medium in the cooling tube, the heating rod bottom is connected with independent switch.

The radiating pipe is made of steel, copper or aluminum.

The number of the heat dissipation groups is 1-50.

The first fixing column and the second fixing column are equal in height.

The utility model has the advantages that:

the utility model provides a pair of to STREAMING nanometer phase transition latent heat energy-gathering radiator is exactly in order to respond to the question of the calling out solution winter common people heating of government, and the policy of response coal change electricity has solved the problem of burning coal contaminated air from the root. The product has the following specific advantages:

1, the energy-saving effect is good, the power of the single column is between 10W and 500W, but the heat generated is higher than that of the whole electric heater.

2 the surface temperature of the radiating fins is uniform and consistent, the heat efficiency is high, and the phenomenon that the temperature difference exists between every two columns of the integral electric heater is avoided.

3, the convection effect is very good, and the wind resistance phenomenon does not exist.

4 easy maintenance, have a post discovery problem, can change at any time, do not need whole radiator to return the factory maintenance to scrap, very big degree the reduction after sale cost.

5, how many single columns can be combined according to actual needs without any limitation.

6 single-column switch control, can select the quantity of opening according to actual need to the energy can be saved.

And 7, the fan is additionally arranged, so that forced convection of air in the outer shell can be realized, and heat discharge is facilitated.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the present invention;

fig. 2 is a schematic structural diagram of a second embodiment of the present invention;

in the figure: 1-first fixed column, 2-second fixed column, 3-first fixed seat, 4-second fixed seat, 5-display screen, 6-lower ventilation grid, 7-upper ventilation grid, 8-lower fixed plate, 9-upper fixed plate, 10-radiating group, 11-radiating pipe, 12-heating rod, 13-exhaust valve, 14-nano medium, 15-front radiating fin, 16-back radiating fin, 17-outer shell and 18-axial flow fan.

Detailed Description

The first embodiment is as follows:

a convection type nanometer phase change latent heat energy-gathering radiator comprises a first fixing column 1 and a second fixing column 2, wherein a display screen 5 is arranged on the front face of the second fixing column 2, a first fixing seat 3 is arranged at the bottom of the first fixing column 1, a second fixing seat 4 is arranged at the bottom of the second fixing column 2, an upper ventilating grate 7 and a lower ventilating grate 6 are fixedly arranged between the first fixing column 1 and the second fixing column 2, the lower ventilating grate 6 is positioned below the upper ventilating grate 7, a lower fixing plate 8 is arranged above the lower ventilating grate 6, one end of the lower fixing plate 8 is connected with the first fixing column 1, the other end of the lower fixing plate is connected with the second fixing column 2, an upper fixing plate 9 is arranged above the upper ventilating grate 7, one end of the upper fixing plate 9 is connected with the first fixing column 1, and the;

bottom plate 8, be equipped with heat dissipation group 10 between the last air grid 7, heat dissipation group 10 transversely sets up side by side, heat dissipation group 10 includes cooling tube 11, 11 front fixedly connected with front fins 15 of cooling tube, 11 back fixedly connected with back fins 16 of cooling tube, 11 tops of cooling tube are fixed in last air grid 7, the bottom mounting is on fixed plate 8, the bottom is equipped with heating rod 12 in cooling tube 11, the top is equipped with discharge valve 13 in cooling tube 11, be equipped with nanometer medium 14 in the cooling tube 13, heating rod 12 bottom is connected with independent switch.

The nano medium is prepared from purified water, absolute ethyl alcohol, ethylene glycol, propylene glycol, glycerol, calcium chloride, boric acid, manganese dioxide, sodium benzoate, benzotriazole, sodium tripolyphosphate, sodium molybdate, borax, potassium permanganate, acetone, europium bromide, antimony tribromide, copper sulfate, potassium sulfate, chromic anhydride and potassium dichromate.

The material of the heat pipe 10 is steel, copper or aluminum.

The number of the heat dissipation groups 10 is 1-50.

The first fixing column 1 and the second fixing column 2 are equal in height.

Example two:

an outer shell 17 and an axial flow fan 18 are added on the basis of the first embodiment, the heat dissipation assembly 10 is located in the outer shell 17 and is bent into a polygon, and the axial flow fan 18 is located at the bottom of the outer shell 17 and below the heat dissipation assembly 10.

The above detailed description of the embodiments of the present invention is only the preferred embodiments of the present invention, and the embodiments of the present invention should not be considered as limiting the scope of the present invention, and all the equivalent changes and improvements made in the application scope of the present invention should still belong to the scope of the present invention.

Claims (4)

1. A convection type nanometer phase change latent heat energy-gathering radiator is characterized in that:

the display screen is arranged on the front side of the second fixed column, a first fixed seat is arranged at the bottom of the first fixed column, a second fixed seat is arranged at the bottom of the second fixed column, an upper ventilating grid and a lower ventilating grid are fixedly arranged between the first fixed column and the second fixed column, the lower ventilating grid is positioned below the upper ventilating grid, a lower fixed plate is arranged above the lower ventilating grid, one end of the lower fixed plate is connected with the first fixed column, the other end of the lower fixed plate is connected with the second fixed column, an upper fixed plate is arranged above the upper ventilating grid, one end of the upper fixed plate is connected with the first fixed column, and the other end of the upper fixed plate is connected with the second fixed column;

be equipped with heat dissipation group between bottom plate, the last air grid, heat dissipation group transversely sets up side by side, heat dissipation group includes the cooling tube, the positive fixedly connected with front fin of cooling tube, cooling tube back fixedly connected with back fin, the cooling tube top is fixed in last air grid, and the bottom mounting is on the fixed plate, the bottom is equipped with the heating rod in the cooling tube, the top is equipped with discharge valve in the cooling tube, be equipped with the nanometer medium in the cooling tube, the heating rod bottom is connected with independent switch.

2. A convective nano phase change latent heat energy concentrating heat sink according to claim 1, wherein: the radiating pipe is made of steel, copper or aluminum.

3. A convective nano phase change latent heat energy concentrating heat sink according to claim 2, wherein: the number of the heat dissipation groups is 1-50.

4. A convective nano phase change latent heat energy concentrating heat sink according to claim 3, wherein: the first fixing column and the second fixing column are equal in height.

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