CN218283720U - Silicon-barium alloy cooling crystallization device - Google Patents

Abstract

The utility model discloses a silicon barium alloy cooling crystallization device, including being used for the crystallizer for silicon barium alloy cooling crystallization, crystallizer central authorities one side is provided with leads the cigarette striker plate, leads the dust removal gas collecting channel that the dust that is provided with on the cigarette striker plate and is used for producing when reinforced for the crystallizer got rid of, and dust removal gas collecting channel inboard is provided with heat-resisting subassembly. Lead cigarette striker plate top and carry the adsorbed flue gas to remove dust the station through the adsorption tube and handle, this practicality sets up the dust removal gas collecting channel who is used for collecting the smoke and dust at the central lateral part of crystallizer, has avoided the alloy to pour the flue gas pollution problem that the crystallization produced like this, has protected the surrounding environment, sets up heat-resisting subassembly and slag charge in the inboard of dust removal gas collecting channel simultaneously, prevents outer spattering when the barium-silicon alloy is pour, and material saving security improves greatly.

Description

Silicon-barium alloy cooling crystallization device

Technical Field

The utility model relates to an alloy cooling field, concretely relates to silicon barium alloy cooling crystallization device.

Background

The silicon-barium alloy is used as an inoculant for casting and a deoxidizing agent for steelmaking, the silicon-barium alloy is produced by mainly adopting ferrosilicon and barium-containing raw materials in an ore-smelting furnace to be smelted, the smelted silicon-barium alloy enters a ladle from an outlet at the bottom of the ore-smelting furnace, a travelling crane hoists the ladle carrying alloy molten steel to a crystallizer to turn over and flow in, the silicon-barium alloy molten steel entering the crystallizer is stood and cooled, and an alloy block is hoisted to a finished product area to be crushed and stored by the travelling crane after being cooled.

SUMMERY OF THE UTILITY MODEL

In order to solve the existing problems, the utility model provides a silicon-barium alloy cooling crystallization device.

The utility model discloses a realize through following technical scheme:

the utility model provides a silicon barium alloy cooling crystallization device, is including being used for giving the crystallizer of silicon barium alloy cooling crystallization, and crystallizer central authorities one side is provided with leads the cigarette striker plate, leads and is provided with the dust removal gas collecting channel that the dust that produces when feeding for the crystallizer got rid of on the cigarette striker plate, and dust removal gas collecting channel inboard is provided with heat-resisting subassembly.

Further optionally, the top of the smoke guide baffle plate conveys the adsorbed smoke to a dust removal station through an adsorption pipe for treatment.

Further optionally, the heat-resistant component comprises a frame fixed on the inner side of the dust-removing and gas-collecting hood, and an asbestos heat-resistant layer is arranged on the inner side of the frame.

Further optionally, the refractory assembly extends downwardly to an upper portion of the smoke deflector.

Further optionally, a silicon-barium slag material for preventing the materials from splashing outside is arranged on the upper part of the crystallizer close to the side of the smoke guide baffle plate.

Further alternatively, the inner side of the mould is provided with a cooling cushion, which may be provided in concrete.

Further optionally, the bottom of the crystallizer is supported and fixed by support columns, and two sides of the bottom of the crystallizer are arranged obliquely downwards.

Compared with the prior art, the beneficial effects of the utility model are that: this practicality is through setting up the dust removal gas collecting channel that is used for collecting the smoke and dust at the central authorities lateral part of crystallizer, has avoided the alloy to pour the flue gas pollution problem that the crystallization produced like this, has protected the surrounding environment, sets up heat-resisting subassembly and slag charge in the inboard of dust removal gas collecting channel simultaneously, prevents that the silicon barium alloy from splashing outward when pouring, and material saving security improves greatly.

Drawings

Fig. 1 is a perspective view of the structure of the present invention;

FIG. 2 is a front view of the crystallizer of FIG. 1;

in the figure: the device comprises a crystallizer 1, a cooling cushion layer 101, a support column 2, a smoke guide baffle plate 3, a dust removal gas collecting hood 4, an adsorption tube 5, a frame 6, an asbestos heat-resistant plate 7 and slag 8.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings:

as shown in fig. 1, a silicon-barium alloy cooling crystallization device comprises a crystallizer 1 for cooling crystallization of silicon-barium alloy, a smoke guide baffle plate 3 is arranged at one side of the center of the crystallizer 1, a dust removal gas collecting hood 4 for removing dust generated during feeding of the crystallizer 1 is arranged on the smoke guide baffle plate 3, a heat-resistant component is arranged at the inner side of the dust removal gas collecting hood 4, and the heat-resistant component can prolong the service life of the dust removal gas collecting hood.

As shown in fig. 1, the top of the smoke guide baffle 3 conveys the adsorbed smoke to a dust removal station for treatment through an adsorption pipe 5.

As shown in fig. 1, the heat-resistant assembly comprises a frame 6 fixed inside the dust-removing and gas-collecting hood 4, the frame 6 functions to fix a heat-resistant asbestos layer 7, and the heat-resistant asbestos layer 7 is arranged inside the frame 6.

As shown in fig. 1, the heat-resistant assembly extending downward to the upper portion of the smoke deflector 3 can protect the smoke deflector 3.

As shown in fig. 1, a barium silicon slag 8 for preventing the materials from splashing is arranged on the upper part of the crystallizer 1 close to the side of the smoke guide striker plate 3, and the barium silicon slag 8 mainly plays a role in blocking the radiation of the alloy liquid and effectively protecting the smoke guide striker plate 3 from splashing.

As shown in fig. 1, a cooling mat 101 is provided inside the mold 1, and the cooling mat 101 may be provided using concrete, so that the heat resistance of the mold 1 is greatly improved.

As shown in fig. 2, the bottom of the crystallizer 1 is supported and fixed by the supporting columns 2, and both sides of the crystallizer are arranged obliquely downwards, so that the crystallizer can flow more quickly during casting.

The implementation principle of the silicon-barium alloy cooling crystallization device in the embodiment of the application is as follows: when the silicon-barium alloy is cast and cooled, the travelling crane hoists the ladle filled with the silicon-barium alloy liquid to the center of the crystallizer 1, the travelling crane is slowly operated to turn over the ladle for casting, the alloy liquid in the ladle flows to two sides along the center of the crystallizer 1 until the whole crystallizer 1 is filled, then the crystallizer 1 is stood for cooling, and the cooled alloy is hoisted to a finished product area for storage;

flue gas generated by liquid in a ladle in the center of the crystallizer 1 through turning and pouring can enter the dust-removing gas-collecting hood 4 at the upper part, and the dust is absorbed and conveyed to a dust-removing station for treatment by negative pressure generated in the dust-removing gas-collecting hood 4 through the absorption tube 5, so that the problem of flue gas pollution generated by alloy pouring and crystallization is avoided, and the surrounding environment is protected;

meanwhile, the silicon-barium alloy liquid entering the crystallizer 1 is blocked by the silicon-barium slag 8 and the smoke guide baffle plate 3 at the rear end, so that the silicon-barium alloy is prevented from splashing during pouring, and the material saving safety is greatly improved;

the heat-resistant component arranged on the inner side of the dust-removing gas-collecting hood 4 can reduce the heat radiation of the silicon-barium alloy to the dust-removing gas-collecting hood when pouring to prevent the heat radiation from deforming, and can also reduce the air flow scouring of the flue gas to the dust-removing gas-collecting hood 4, thereby prolonging the service life of the dust-removing gas-collecting hood 4.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. A silicon-barium alloy cooling crystallization device comprises a crystallizer (1) used for cooling crystallization of silicon-barium alloy, and is characterized in that: the crystallizer is characterized in that a smoke guide baffle plate (3) is arranged on one side of the center of the crystallizer (1), a dust removal gas collecting hood (4) used for removing dust generated during feeding of the crystallizer (1) is arranged on the smoke guide baffle plate (3), and a heat-resisting assembly is arranged on the inner side of the dust removal gas collecting hood (4).

2. The silicon-barium alloy cooling crystallization device according to claim 1, characterized in that: the top of the smoke guide baffle plate (3) conveys the adsorbed smoke to a dust removal station through an adsorption pipe (5) for treatment.

3. The silicon-barium alloy cooling crystallization device according to claim 1, characterized in that: the heat-resistant component comprises a frame (6) fixed on the inner side of the dust-removing gas-collecting hood (4), and an asbestos heat-resistant layer (7) is arranged on the inner side of the frame (6).

4. The silicon-barium alloy cooling crystallization device according to claim 3, characterized in that: the heat-resisting component extends downwards to the upper part of the smoke guide baffle plate (3).

5. The silicon-barium alloy cooling crystallization device according to claim 1, characterized in that: and a silicon-barium slag (8) for preventing the materials from splashing is arranged on the upper part of the crystallizer (1) close to the side of the smoke guide baffle plate (3).

6. The silicon-barium alloy cooling crystallization device according to claim 5, characterized in that: the inner side of the crystallizer (1) is provided with a cooling cushion layer (101), and the cooling cushion layer (101) can be arranged by adopting concrete.

7. The silicon-barium alloy cooling crystallization device according to claim 6, characterized in that: the bottom of the crystallizer (1) is supported and fixed through support columns (2), and two sides of the crystallizer are obliquely and downwards arranged.

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