CN216716749U - Air cooling device for processing refractory materials - Google Patents

Abstract

The utility model discloses an air cooling device for processing a refractory material, and relates to the technical field of cooling equipment. The equipment is provided with the heat dissipation monomer and the cooling plate, heat is transferred to the heat dissipation monomer by utilizing the solid heat conduction effect of the cooling plate, and then the heat exchange, flow and dissipation effects are realized by carrying out air cooling on the heat dissipation monomer, so that the rapid cooling action is realized; the heat exchanger is divided according to the principle of long distance, low wind pressure and low baffle plate blockage, thereby effectively enhancing the heat exchange effect between the radiating fins and the airflow and realizing the full flow and quick dissipation of heat.

Description

Air cooling device for processing refractory materials

Technical Field

The utility model relates to the technical field of cooling equipment, in particular to an air cooling device for processing a refractory material.

Background

The existing air cooling is used for carrying out heat exchange with the surface of a hot object through a gas medium, and then the heat is taken away by utilizing the fluidity of air flow, so that the rapid cooling of the material is realized.

The heat conduction efficiency of the gas medium is not high, and when the gas medium contacts with the material, the heat exchange between the airflow and the surface of the object has certain hysteresis, so that the cooling forming of the material is easily influenced.

Meanwhile, the airflow flowing power of the existing air cooling equipment is provided by a pump, the speed attenuation of the airflow from the air blowing position of the pump to the tail end of heat exchange hardware is large, the airflow speed differential is large, the gas medium is not fully exchanged with the heat conduction hardware and is discharged out of the equipment, the energy is wasted, and the gas raw material is not fully utilized in the production process of heat dissipation by utilizing the inert gas medium aiming at part of the gas medium.

And this air feed characteristic also leads to heat transfer metal hardware surface temperature inequality easily, and then leads to that the heat exchange effect is not good between material and the heat transfer hardware, influences the cooling operation quality of material.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an air cooling device for processing refractory materials, which aims to solve the problems that the air cooling device in the background technology is low in heat exchange efficiency and the cooling gas medium is not fully utilized.

In order to achieve the purpose, the utility model is realized by the following technical scheme: the utility model provides an air cooling device is used in refractory material processing, includes the cooling plate, the through-hole has been seted up on the surface of cooling plate, the bottom surface equidistance fixedly connected with heat dissipation monomer of cooling plate, the heat dissipation monomer includes the fin, the fin is hollow sheet structure.

The outer side of the top of the radiating fin is fixedly provided with a mounting plate, and four corners of the mounting plate are connected with the bottom surface of the cooling plate through bolts in a locking mode.

The fixed shrouding that is provided with in middle part of fin top surface, the both ends of shrouding are fixed and are provided with the end plate that extends to the fin inboard, one of them side constitute the air intake between end plate bottom and the inboard bottom surface of fin, opposite side end plate bottom meets with the inboard bottom surface of fin, and the air outlet has been seted up at the middle part of this end plate, both sides be provided with the baffle between the end plate, the front and back side of baffle meets with the front and back side of fin inner wall respectively, baffle perpendicular to shrouding, the baffle becomes the slope to arranging to the air outlet by the air intake, by the air intake to the adjacent of air outlet direction interval crescent between the baffle.

The both ends of shrouding are all fixed and are provided with the seal piece, two seal piece surface is run through respectively and is connected with the air-supply line and goes out the tuber pipe, the air-supply line corresponds with the air intake, it corresponds with the air outlet to go out the tuber pipe.

The fin becomes parallel equidistance setting in the cooling plate bottom surface, adjacent two the air-supply line and the play tuber pipe of fin are established ties together through the relay pipe that runs through the through-hole, two end to end the air-supply line and the play tuber pipe of fin are gone up the fixed cover respectively and are connect with air inlet house steward and air-out house steward.

Optionally, the heat dissipation units are alternately arranged from front to back, and the heat dissipation units are made of heat-conducting metal materials.

Optionally, the end of the end plate is perpendicular to the end head of the sealing plate, and cavities for accommodating the air inlet pipe and the air outlet pipe are reserved on the side surface of the end plate and the left side and the right side of the inner wall of the radiating fin.

Optionally, the inner space of the cooling fin is divided into a high-pressure air duct, a medium-pressure air duct and a low-pressure air duct by the partition plate, the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct are sequentially arranged from the air inlet to the air outlet, the gaps of the partition plates in the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct are gradually increased, and the distance between the bottom ends of the partition plates in the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct and the front bottom surface of the inner side of the cooling fin is gradually reduced.

Optionally, the sealing blocks correspond to the through holes one by one, and the sealing blocks penetrate through the upper side and the lower side of the through holes.

Optionally, the bottom ports of the air inlet pipe and the air outlet pipe are both arranged above the air inlet and the air outlet.

The utility model has the technical effects and advantages that:

1. this equipment utilizes the solid-state heat conduction effect of cooling plate to give heat dissipation monomer with heat transfer through setting up heat dissipation monomer and cooling plate, realizes fast cooling action through carrying out forced air cooling to heat dissipation monomer again and realizing thermal exchange, flow and the effect of scattering and disappearing, its cooling efficiency height.

2. The equipment is enabled to carry out the air flow entering the radiating fins from the air inlet pipe according to the 'short distance, strong air pressure and strong baffle retardation' through the oblique arrangement of the baffles and the arrangement of the gaps between the baffles from narrow to wide; the distance is far, the wind pressure is low, and the baffle block is low, so that the heat exchange effect between the radiating fins and the airflow is effectively enhanced, and the heat can flow sufficiently and be dissipated rapidly.

Drawings

FIG. 1 is a front view of the structure of the present invention;

FIG. 2 is a front view of a structural heat dissipating unit of the present invention;

fig. 3 is a cross-sectional view of the heat dissipating unit of the present invention.

In the figure: 1. a cooling plate; 2. a through hole; 3. a heat dissipation monomer; 301. a heat sink; 302. mounting a plate; 303. closing the plate; 304. an end plate; 305. an air inlet; 306. an air outlet; 307. a partition plate; 308. sealing blocks; 309. an air inlet pipe; 310. an air outlet pipe; 4. a relay pipe; 5. an air inlet main pipe; 6. an air outlet main pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the utility model.

In the present invention, unless otherwise expressly specified or limited, the terms "disposed," "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected or detachably connected; may be a mechanical connection; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The utility model provides an air cooling device for processing refractory materials, which comprises a cooling plate 1, wherein through holes 2 are formed in the surface of the cooling plate 1, heat dissipation monomers 3 are fixedly connected to the bottom surface of the cooling plate 1 at equal intervals, the heat dissipation monomers 3 are alternately arranged from front to back in a forward and reverse direction, the heat dissipation monomers 3 are made of heat-conducting metal materials, the heat dissipation monomers 3 comprise heat dissipation fins 301, and the heat dissipation fins 301 are of hollow sheet structures. Through setting up heat dissipation monomer 3 and cooling plate 1, utilize the solid-state heat conduction effect of cooling plate 1 to give heat dissipation monomer 3 with heat transfer, realize thermal exchange, flow and the effect of scattering and disappearing through carrying out the forced air cooling to heat dissipation monomer 3 again, realize quick cooling action, its cooling efficiency is high.

The outer side of the top of the heat sink 301 is fixedly provided with a mounting plate 302, and four corners of the mounting plate 302 are fixedly connected with the bottom surface of the cooling plate 1 through bolts.

A sealing plate 303 is fixedly arranged in the middle of the top surface of the heat sink 301, end plates 304 extending towards the inner side of the heat sink 301 are fixedly arranged at two ends of the sealing plate 303, the end plates 304 are perpendicular to the ends of the sealing plate 303, cavities for accommodating the air inlet pipe 309 and the air outlet pipe 310 are reserved on the side surface of the end plates 304 and the left and right sides of the inner wall of the heat sink 301, an air inlet 305 is formed between the bottom of the end plate 304 on one side and the bottom of the inner side of the heat sink 301, an air outlet 306 is formed in the middle of the end plate 304, partition plates 307 are arranged between the end plates 304 on two sides, the front and back sides of the partition plates 307 are respectively connected with the front and back sides of the inner wall of the heat sink 301, the partition plates 307 are perpendicular to the sealing plate 303, the partition plates 307 are obliquely arranged from the air inlet 305 to the air outlet 306, the space between the adjacent partition plates 307 in the direction from the air inlet 305 to the air outlet 306 is gradually increased, and the space inside of the air duct 301 is divided into high-pressure air duct by the partition plates 307, The high-pressure air duct, the medium-pressure air duct and the low-pressure air duct are sequentially arranged from the air inlet 305 to the air outlet 306, the gaps of the partition plates 307 in the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct are gradually increased, and the distance between the bottom ends of the partition plates 307 in the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct and the front bottom surface of the inner side of the radiating fin 301 is gradually reduced. The high-pressure air duct is closest to the position of the air inlet 305, the flow velocity of air flowing through the air duct is reduced to the maximum, and then the medium-pressure air duct and the low-pressure air duct are arranged, so that air flowing in from the air inlet 305 is divided into multiple strands of heat exchange air flow with small differential speed, the air flow can be fully contacted with the inner surface of the cooling fin 301 for heat exchange, the heat exchange efficiency of a gas medium is improved, meanwhile, the temperatures of the cooling fin 301 and the positions of the surface of the cooling plate 1 are balanced, the heat dissipation effect of the material at each position of the contact surface of the cooling plate 1 is the same, and the forming effect of the material is guaranteed. Through the inclined arrangement of the partition plates 307 and the arrangement of the gaps of the partition plates 307 from narrow to wide, the air flow entering the radiating fins 301 through the air inlet pipe 309 of the air conditioner can be controlled according to the' close distance, wind pressure and strong blocking of the partition plates 307. The principle of long distance, low wind pressure and low blocking of the partition 307 is adopted for division, so that the heat exchange effect between the radiating fins 301 and the airflow is effectively enhanced, and the heat can flow fully and be dissipated quickly.

The two ends of the sealing plate 303 are fixedly provided with sealing blocks 308, the sealing blocks 308 are in one-to-one correspondence with the through holes 2, the sealing blocks 308 penetrate through the upper side and the lower side of the through holes 2, the sealing blocks 308 are locked and sealed with the front side and the rear side of the inner wall of the radiating fin 301 through bolts, the inside of the radiating fin 301 can be cleaned by detaching the sealing blocks 308, the surfaces of the two sealing blocks 308 are respectively connected with an air inlet pipe 309 and an air outlet pipe 310 in a penetrating manner, the air inlet pipe 309 corresponds to the air inlet 305, the air outlet pipe 310 corresponds to the air outlet 306, and the bottom ports of the air inlet pipe 309 and the air outlet pipe 310 are arranged at the positions above the air inlet 305 and the air outlet 306.

The radiating fins 301 are arranged on the bottom surface of the cooling plate 1 in parallel at equal intervals, the air inlet pipe 309 and the air outlet pipe 310 of two adjacent radiating fins 301 are connected in series through the relay pipe 4 penetrating through the through hole 2, and the air inlet header pipe 5 and the air outlet header pipe 6 are fixedly sleeved on the air inlet pipe 309 and the air outlet pipe 310 of the two radiating fins 301 at the head and the tail respectively.

This practical theory of operation: this air cooling device is used in refractory material processing contacts material and cooling plate 1 when using for the material is to the quick heat-conduction of cooling plate 1 and fin 301, material rapid cooling.

The air pump blows cold air flow from the air inlet manifold 5 to the inner side of the heat dissipation fin 301, the cold air flow enters the inner side of the heat dissipation fin 301 and then flows towards the air outlet 306 through the air inlet 305, the partition 307 blows the cold air flow from the side direction of the flowing direction of the cold air flow, the effect that the air flow close to the air inlet 305 is blocked and delayed by the partition 307 is stronger, and the speed reduction degree of the divided air flow is larger. The more far away from the air inlet 305, the slower the blocking effect of the partition 307, the smaller the speed reduction degree of the divided air flow, so that the air flow inside the radiating fin 301 is divided and distributed uniformly, the air flow speed difference of each part is small, the cold air flow and the radiating fin 301 perform sufficient heat exchange, the full utilization of the cold air flow gas medium is realized, the waste is reduced, the cooling efficiency of the equipment is improved, and the influence of the uneven surface temperature of the cooling plate 1 on the material cooling operation is reduced.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the utility model.

Claims (6)

1. The utility model provides an air cooling device is used in refractory material processing, includes cooling plate (1), through-hole (2) have been seted up on the surface of cooling plate (1), the bottom surface equidistance fixedly connected with heat dissipation monomer (3) of cooling plate (1), its characterized in that: the heat dissipation unit (3) comprises a heat dissipation fin (301), and the heat dissipation fin (301) is of a hollow sheet structure;

the outer side of the top of the radiating fin (301) is fixedly provided with a mounting plate (302), and four corners of the mounting plate (302) are fixedly connected with the bottom surface of the cooling plate (1) through bolts;

the middle part of the top surface of the radiating fin (301) is fixedly provided with a sealing plate (303), two ends of the sealing plate (303) are fixedly provided with end plates (304) extending towards the inner side of the radiating fin (301), wherein an air inlet (305) is formed between the bottom of the end plate (304) at one side and the bottom surface of the inner side of the radiating fin (301), the bottom of the end plate (304) at the other side is connected with the bottom surface of the inner side of the radiating fin (301), an air outlet (306) is arranged in the middle of the end plate (304), a clapboard (307) is arranged between the end plates (304) at the two sides, the front and rear sides of the partition plate (307) are respectively connected with the front and rear sides of the inner wall of the radiating fin (301), the partition plates (307) are perpendicular to the seal plate (303), the partition plates (307) are arranged from the air inlet (305) to the air outlet (306) in an inclined direction, and the distance between every two adjacent partition plates (307) in the direction from the air inlet (305) to the air outlet (306) is gradually increased;

sealing blocks (308) are fixedly arranged at two ends of the sealing plate (303), the surfaces of the two sealing blocks (308) are respectively connected with an air inlet pipe (309) and an air outlet pipe (310) in a penetrating manner, the air inlet pipe (309) corresponds to the air inlet (305), and the air outlet pipe (310) corresponds to the air outlet (306);

fin (301) become parallel equidistance setting in chill plate (1) bottom surface, adjacent two air-supply line (309) and play tuber pipe (310) of fin (301) are established ties together through relay pipe (4) that run through-hole (2), end to end two air-supply line (309) and play tuber pipe (310) of fin (301) are gone up and are fixed respectively to have cup jointed air inlet house steward (5) and air-out house steward (6).

2. The air cooling device for processing refractory material according to claim 1, wherein: the heat dissipation single bodies (3) are alternately arranged from front to back in a forward and reverse mode, and the heat dissipation single bodies (3) are made of heat conduction metal materials.

3. The air cooling device for processing refractory material according to claim 1, wherein: the end plate (304) is perpendicular to the end of the sealing plate (303), and cavities for accommodating the air inlet pipe (309) and the air outlet pipe (310) are reserved on the side surface of the end plate (304) and the left side and the right side of the inner wall of the radiating fin (301).

4. The air cooling device for processing refractory material according to claim 1, wherein: the space inside the radiating fins (301) is divided into a high-pressure air duct, a medium-pressure air duct and a low-pressure air duct by the partition plates (307), the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct are sequentially arranged from the air inlet (305) to the air outlet (306), gaps among the partition plates (307) in the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct are gradually increased, and distances between the bottom ends of the partition plates (307) in the high-pressure air duct, the medium-pressure air duct and the low-pressure air duct and the front bottom surface of the inner side of the radiating fins (301) are gradually reduced.

5. The air cooling device for processing refractory material according to claim 1, wherein: the sealing blocks (308) correspond to the through holes (2) one by one, and the sealing blocks (308) penetrate through the upper side and the lower side of the through holes (2).

6. The air cooling device for processing refractory material according to claim 1, wherein: the bottom ports of the air inlet pipe (309) and the air outlet pipe (310) are arranged above the air inlet (305) and the air outlet (306).

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