CN218787742U - Carbon neutralization closed circulation temperature adjusting device - Google Patents

Abstract

The utility model discloses a carbon neutralization closed circulation attemperator in heat treatment technical field, include: a water source unit, the water source unit comprising: a water tank; the first water pump is arranged on the water discharging end of the water tank; the cold and hot air system is arranged at the drainage end of the water source unit; the air cooling mechanism is arranged at the drainage end of the cold and hot air system; the circulating water tank is arranged at the water discharging end of the air cooling mechanism and is connected with the water inlet end of the water source unit through a pipeline; the pump set is arranged at the water discharging end of the circulating water tank; the furnace body, the furnace body pass through the pipeline with the pump package is connected, the utility model discloses realize that the circulation of changes in temperature equipment utilization furnace body heat and cooling water improves the consumption reduction energy-conservation who replaces indoor heating equipment and burning raw materials, realizes the reuse of the energy.

Description

Carbon neutralization closed circulation temperature adjusting device

Technical Field

The utility model relates to a heat treatment technical field specifically is a carbon neutralization closed circulation attemperator.

Background

Heat treatment refers to a hot metal working process in which a material is heated, held and cooled in the solid state to achieve a desired texture and properties.

In the heat treatment industry, various vacuum furnaces are utilized to carry out heat treatment on metals and non-metals, in the heat treatment process, the periphery of a furnace body needs an equivalent heat maintenance system, meanwhile, the sealing part of the furnace body needs to be cooled by water, a diffusion vacuum pump and the pipeline system part need to be cooled, the heat exchange is carried out on the furnace body mostly in the existing water cooling mode, the temperature of the furnace body is reduced, the water after heat exchange directly enters a circulating cooling mode and is conveyed to a production line again to cool the furnace body, and when heat is wasted after heat exchange in midway, the cooling of the water with higher temperature needs to consume great energy.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a carbon neutralization closed circulation attemperator to solve the current many that propose among the above-mentioned background art and carry out the heat exchange through water-cooled mode to the furnace body, reduce the temperature of furnace body, and the water after the heat exchange directly gets into and cools down to the furnace body on carrying the production line once more after the circulation cooling, when producing the useless waste of heat after the heat exchange midway, cool down the problem that needs consume very big energy consumption to the higher water of temperature.

In order to achieve the above object, the utility model provides a following technical scheme: a carbon-neutral closed-cycle attemperating device, comprising:

a water source unit;

the cold and hot air system is arranged at the drainage end of the water source unit;

the air cooling mechanism is arranged at the drainage end of the cold and hot air system;

the circulating water tank is arranged at the water discharging end of the air cooling mechanism and is connected with the water inlet end of the water source unit through a pipeline;

the pump set is arranged at the water discharging end of the circulating water tank;

the furnace body is connected with the pump set through a pipeline.

Preferably, the water source unit includes:

a water tank;

a first water pump mounted on a drain end of the water tank;

and the second water pump is arranged on the water inlet end of the water tank.

Preferably, the air cooling mechanism includes:

mounting the frame;

a fan assembly mounted on top of the mounting frame;

the spraying mechanism is arranged on the mounting frame and corresponds to the fan assembly at the lower end of the fan assembly;

the coil pipe is coiled on the inner side of the mounting frame, and the lower end of the coil pipe on the spraying mechanism corresponds to a jet port on the spraying mechanism;

and the third water pump is arranged on the water inlet of the coil pipe and is connected with the cold and hot air system and the water discharge end of the pump group through a pipeline.

Preferably, the pump unit includes:

the main pump is connected with a water outlet of the circulating water tank, one end, far away from the circulating water tank, of the main pump is provided with a cooling pipeline, the cooling pipeline is wound on the outer side wall of the furnace body, and the water outlet end of the cooling pipeline is connected with the third water pump;

the auxiliary pump is connected to the main pump in parallel, the auxiliary pump is connected with a water outlet of the circulating water tank, one end, far away from the furnace body, of the cooling pipeline is arranged in the working chamber, and one end, far away from the circulating water tank, of the auxiliary pump is connected with the cooling pipeline.

Preferably, the water inlet end of the cold and hot air system is higher than the water outlet end.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses realize that the circulation of changes in temperature equipment utilization furnace body heat and cooling water improves the consumption reduction energy-conservation who replaces indoor heating equipment and burning raw materials, realize the reuse of the energy, the water that will enter into the circulating water tank inner chamber through the main pump is pumped in the cooling tube, carry out the heat exchange through cooling tube and furnace body, reduce the temperature on the surface of furnace body, the water through the heat exchange passes through the cooling tube and enters into the during operation, get warm to the studio, realize that the changes in temperature equipment utilizes the circulation of furnace body heat and cooling water to improve the consumption reduction energy-conservation who replaces indoor heating equipment and burning raw materials, realize the reuse of the energy.

Drawings

FIG. 1 is a schematic view of the present invention;

FIG. 2 is a schematic view of the water source unit of the present invention;

FIG. 3 is a schematic view of the structure of the air-cooling mechanism of the present invention;

fig. 4 is a schematic diagram of the pump unit of the present invention.

In the figure: 100 water source units, 110 water tanks, 120 first water pumps, 130 second water pumps, 200 cold and hot air systems, 300 air cooling mechanisms, 310 mounting frames, 320 fan assemblies, 330 spraying mechanisms, 340 coil pipes, 350 third water pumps, 400 circulating water tanks, 500 pump groups, 510 main pumps, 520 auxiliary pumps and 600 furnace bodies.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a carbon neutralization closed circulation attemperator realizes that changes in temperature equipment utilizes the circulation of furnace body heat and cooling water to improve the consumption reduction energy-conservation who replaces indoor heating equipment and burning raw materials, realizes the reuse of the energy, include: the device comprises a water source unit 100, a cold and hot air system 200, an air cooling mechanism 300, a circulating water tank 400, a pump set 500 and a furnace body 600;

referring to fig. 1-2, a water supply assembly 100 includes:

the water is placed in the inner cavity of the water tank 110, a liquid level sensor is installed in the inner cavity of the water tank 110, and the water level height of the inner cavity of the water tank 110 is monitored through the liquid level sensor;

the first water pump 120 is installed on the water discharge end of the water tank 110, and the water in the inner cavity of the water tank 110 is pumped out by the first water pump 120;

the second water pump 130 is installed at the water inlet end of the water tank 110, the second water pump 130 is electrically connected with the liquid level sensor through the controller, the liquid level height is monitored through the liquid level sensor, when the water level height is reduced to be below a threshold value, the liquid level sensor sends information to the controller, the second water pump 130 is started through the controller, and water is replenished to the inner cavity of the water tank 110 through the second water pump 130;

referring to fig. 1-2 again, the cold and hot air system 200 is installed at the water discharge end of the first water pump 120, and the water inlet end of the cold and hot air system 200 is higher than the water outlet end to form a fall, so that water is not accumulated in the pipe, and the cold and hot air system has better freezing resistance and a shunting design heat dissipation effect, and the first water pump 120 pumps water in the inner cavity of the water tank 110 to the cold and hot air system 200, and the cold and hot air system 200 exchanges heat with water to reduce the temperature of the water;

referring to fig. 1 and 3, the air cooling mechanism 300 is installed at the water discharging end of the hot and cold air system 200, and the air cooling mechanism 300 includes:

a mounting frame 310;

the fan assembly 320 is arranged on the top of the mounting frame 310, the fan assembly 320 is composed of a fan and a refrigerating sheet, the refrigerating sheet is arranged on an air outlet of the fan, air around the air outlet of the fan is cooled through the refrigerating sheet, and the cooled air is driven by the fan to flow;

the spraying mechanism 330 is installed on the installation frame 310, and the spraying mechanism 330 corresponds to the fan assembly 320 at the lower end of the fan assembly 320;

the coil pipe 340 is coiled on the inner side of the mounting frame 310, and the lower end of the coil pipe 340 on the spraying mechanism 330 corresponds to the spray opening on the spraying mechanism 330;

the third water pump 350 is installed on the water inlet of the coil 340, the third water pump 350 is connected with the cold and hot air system 200 and the water discharge end of the pump group 500 through a pipeline, the cooled water is pumped into the inner cavity of the coil 340 through the third water pump 350, cold air is blown to the surface of the coil 340 through the fan, the water entering the inner cavity of the coil 340 is further cooled, when the weather is hot, the spraying mechanism 330 is started, the water is sprayed onto the coil 340 through the spraying mechanism 330, the water in the inner cavity of the coil 340 is cooled through the combination of the fan assembly 320 and the spraying mechanism 330, when the temperature is low, the fan assembly is only used for cooling, and when the weather temperature is high, the fan assembly and the spraying mechanism are used in a matched mode for cooling;

referring to fig. 1 and fig. 3 again, the circulation water tank 400 is installed at the water discharge end of the coil 340, the circulation water tank 400 is connected with the water inlet end of the second water pump 130 through a pipeline, the cooled water enters the inner cavity of the circulation water tank 400, the cooled water is conveyed to a production line through the circulation water tank 400 to cool equipment on the production line, and meanwhile, when the water level of the inner cavity of the water tank 110 is low, the water pump in the inner cavity of the circulation water tank 400 is taken into the inner cavity of the water tank 110 through the second water pump 130 to supplement water;

referring to fig. 1 and 4, a pump unit 500 is installed at a discharge end of the circulation tank 400, the pump unit 500 including:

the main pump 510 is connected with a water outlet of the circulating water tank 400, a cooling pipeline is installed at one end of the main pump, which is far away from the circulating water tank, and is wound on the outer side wall of the furnace body, one end of the cooling pipeline, which is far away from the furnace body 600, is arranged in the working chamber, the water discharging end of the cooling pipeline is connected with the third water pump 350, water entering the inner cavity of the circulating water tank 400 is pumped into the cooling pipeline through the main pump 510, heat exchange is carried out between the cooling pipeline and the furnace body 600, the temperature of the surface of the furnace body 600 is reduced, water after heat exchange enters the working chamber through the cooling pipeline, the working chamber is warmed, the heating and cooling equipment utilizes the circulation of furnace body heat and cooling water to improve and replace indoor heating equipment and consumption reduction and energy conservation of combustion raw materials, the energy recycling is realized, the inner cavity of the coil 340 is pumped by the third water pump 350 to be cooled and enters the inner cavity of the circulating water tank 400 again, a closed tower water circulating system is not in contact with the external environment, the cleanliness of a pure water system for using water for the furnace body is solved, and the furnace body is kept from scaling;

the auxiliary pump 520 is connected to the main pump 510 in parallel, the auxiliary pump 520 is connected with a water outlet of the circulating water tank 400, one end of the auxiliary pump 520, which is far away from the circulating water tank 400, is connected with a cooling pipeline, the auxiliary pump 520 is in an inoperative state at ordinary times, and when the main pump 510 is damaged or during maintenance, the auxiliary pump 520 replaces the main pump 510 to work, so that the normal work of a production line is guaranteed;

referring to fig. 1 and 4 again, the outer wall of the furnace body 600 is wound around a cooling pipe, and the temperature of the surface of the furnace body 600 is reduced by heat exchange between water in the cooling pipe and the surface of the furnace body 600.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of such combinations is not exhaustive in the present specification only for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (5)

1. The utility model provides a carbon neutralization closed cycle attemperator which characterized in that: the method comprises the following steps:

a water source unit (100);

the cold and hot air system (200), the cold and hot air system (200) is installed at the water discharging end of the water source unit (100);

the air cooling mechanism (300), the said air cooling mechanism (300) is installed in the drainage end of the said cold and hot air system (200);

the circulating water tank (400), the circulating water tank (400) is installed at the water discharging end of the air cooling mechanism (300), and the circulating water tank (400) is connected with the water inlet end of the water source unit (100) through a pipeline;

a pump group (500), the pump group (500) being installed at a water discharge end of the circulation water tank (400);

the furnace body (600), furnace body (600) is connected with pump package (500) through the pipeline.

2. A carbon neutral closed cycle attemperating apparatus as defined in claim 1 wherein: the water source unit (100) comprises:

a water tank (110);

a first water pump (120), the first water pump (120) being mounted on a discharge end of the water tank (110);

a second water pump (130), the second water pump (130) being mounted on a water inlet end of the water tank (110).

3. A carbon neutral closed cycle attemperating apparatus as defined in claim 2 wherein: the air cooling mechanism (300) includes:

a mounting frame (310);

a fan assembly (320), the fan assembly (320) mounted on top of the mounting frame (310);

the spraying mechanism (330), the spraying mechanism (330) is installed on the installation frame (310), and the spraying mechanism (330) corresponds to the fan assembly (320) at the lower end of the fan assembly (320);

a coil pipe (340), wherein the coil pipe (340) is coiled on the inner side of the mounting frame (310), and the coil pipe (340) corresponds to a jet flow opening on the spraying mechanism (330) at the lower end of the spraying mechanism (330);

and the third water pump (350), the third water pump (350) is installed on the water inlet of the coil pipe (340), and the third water pump (350) is connected with the cold and hot air system (200) and the water discharging end of the pump group (500) through pipelines.

4. A carbon neutral closed cycle attemperating apparatus as defined in claim 3 wherein: the pump group (500) comprises:

the main pump (510) is connected with a water outlet of the circulating water tank (400), a cooling pipeline is installed at one end, far away from the circulating water tank (400), of the main pump (510), the cooling pipeline is wound on the outer side wall of the furnace body (600), one end, far away from the furnace body (600), of the cooling pipeline is arranged in a working chamber, and the water outlet end of the cooling pipeline is connected with the third water pump (350);

the auxiliary pump (520), the auxiliary pump (520) is parallelly connected on the main pump (510), the auxiliary pump (520) with the outlet of circulating water tank (400) is connected, keep away from on the auxiliary pump (520) circulating water tank (400) one end with the cooling pipeline is connected.

5. The carbon neutral closed cycle attemperator of claim 4, wherein: the water inlet end of the cold and hot air system (200) is higher than the water outlet end.

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