CN223361074U - A magnesium alloy melting and stirring equipment - Google Patents

Abstract

The utility model relates to the field of magnesium alloy smelting, and provides magnesium alloy smelting stirring equipment, which comprises a base and a smelting furnace; the plurality of positioning rods are movably embedded on one side of the base, and one side of each positioning rod is fixedly provided with a furnace cover, at this time, pouring smelting raw materials into the smelting furnace, enabling the plurality of positioning rods to slide in the plurality of through holes respectively, inserting the plurality of positioning rods into the plurality of through holes, covering the furnace cover on the smelting furnace, the external power switch of the driving motor is turned on, the output shaft of the driving motor drives the rotating rod to rotate, the plurality of scraping plates rotate to scrape the inside of the smelting furnace, and the adhesion is formed on the furnace wall when the magnesium alloy is prevented from smelting, so that the adhesion is formed on the furnace wall when the magnesium alloy is prevented from smelting and stirring, the available metal quantity is improved, and the yield is further improved.

Description

Magnesium alloy smelting stirring equipment

Technical Field

The application relates to the field of magnesium alloy smelting, in particular to magnesium alloy smelting stirring equipment.

Background

The smelting of magnesium alloy is a process of heating magnesium and its alloy materials to a molten state, heating raw materials in a smelting furnace, stirring them, pouring the melt into a mould, and cooling and solidifying to form the required shape and structure.

When smelting magnesium and magnesium alloy raw materials, some existing smelting stirring equipment possibly forms accumulation on the furnace wall of a smelting furnace if the fluidity of the melt is insufficient, so that some raw materials adhere to the furnace wall, the adhered melt can reduce the available metal amount and influence the yield, and after the smelting of the magnesium alloy is finished, some equipment needs to pour the smelting furnace manually, the melt in the furnace is poured out, workers directly contact the high-temperature melt, and scalding or other accidents possibly occur.

Disclosure of utility model

According to the magnesium alloy smelting stirring equipment, when the magnesium alloy is smelted and stirred, accumulation formed on the furnace wall due to adhesion of the magnesium alloy can be prevented, the available metal quantity is increased, the yield is further increased, a smelting furnace is not needed to be manually poured after the magnesium alloy is smelted, the risk that workers directly contact with high-temperature melt is reduced, and scalding or other accidents are prevented.

In order to achieve the purpose, the application adopts the following technical scheme that the magnesium alloy smelting stirring equipment comprises:

A base and a smelting furnace;

The positioning rods are movably embedded in one side of the base, and one side of each positioning rod is fixedly provided with a furnace cover;

The rotary rod is arranged on one side of the furnace cover through a bearing, a plurality of fixing rings are fixedly sleeved on the outer surface of the rotary rod, and the rotary rod can rotate due to the bearing;

The plurality of first telescopic rods are fixedly arranged on the outer surface of the rotating rod, the inner walls of the plurality of first telescopic rods are movably embedded with the second telescopic rods, the plurality of stirring blades are driven to rotate when the plurality of fixed rings rotate, and the rotating stirring blades stir raw materials;

The plurality of scrapers are respectively and fixedly arranged at one ends of the second telescopic rods, the plurality of scrapers are clung to the inner wall of the smelting furnace, and the plurality of scrapers which rotate scrape the interior of the smelting furnace, so that the magnesium alloy is prevented from being adhered to the furnace wall to form accumulation during smelting.

As a further improvement scheme of the application, a plurality of stirring blades are fixedly arranged on the outer surfaces of the plurality of fixing rings, springs are fixedly arranged on one sides of the plurality of second telescopic rods, one sides of the plurality of springs are respectively fixedly arranged on the inner walls of one sides of the plurality of first telescopic rods, and the plurality of springs generate reverse acting force when being extruded.

As a further improvement scheme of the application, two mounting rods are fixedly arranged on one side of the furnace cover, a driving motor is arranged at the opposite end of each mounting rod, an output shaft of each driving motor is fixedly arranged on one side of a rotating rod, the two mounting rods have supporting effect on the driving motor, an external power switch of the driving motor is turned on, and the output shaft of the driving motor drives the rotating rod to rotate.

As a further improvement scheme of the application, two handles are fixedly arranged on one side of the furnace cover, a plurality of through holes are formed on one side of the base, the through holes are respectively matched with a plurality of positioning rods, and the positioning rods can slide in the through holes.

As a further improvement scheme of the application, two brackets are fixedly arranged on one side of the base, connecting rods are arranged on the opposite sides of the two brackets through bearings, the opposite sides of the two connecting rods are respectively and fixedly arranged on the two sides of the smelting furnace, and the two connecting rods can rotate on the opposite sides of the two brackets due to the bearings.

As a further improvement scheme of the application, one side of one bracket is fixedly provided with an L-shaped plate, one side of the L-shaped plate is provided with a hydraulic rod, and the L-shaped plate supports the hydraulic rod.

As a further improvement scheme of the application, the output end of the hydraulic rod is fixedly provided with a transmission plate, one side of the transmission plate is fixedly provided with a rack, and the output end of the hydraulic rod is controlled to move forwards to drive the transmission plate to move, so that the rack drives the gear to rotate anticlockwise.

As a further improvement scheme of the application, one side of the rack is provided with the gear in a meshed manner, the inner wall of the gear is fixedly sleeved on the outer surface of one of the connecting rods, and the gear is driven to rotate anticlockwise when the rack moves forwards, so that the smelting furnace is tilted forwards, smelted materials in the smelting furnace are poured out, the smelting furnace is not manually tilted, the risk that a worker directly contacts with high-temperature melt is reduced, and scalding or other accidents are prevented.

Compared with the prior art, the application has the advantages and positive effects that,

1. According to the application, when the magnesium alloy is smelted and stirred by using equipment, the furnace cover is taken out from the upper surface of the smelting furnace through the two handles, smelting raw materials are poured into the smelting furnace, the plurality of positioning rods can slide in the through holes respectively, the plurality of positioning rods are inserted into the through holes respectively, the furnace cover is covered on the smelting furnace, the plurality of second telescopic rods can slide in the first telescopic rods respectively, the plurality of springs can generate reverse acting force when being extruded, the second telescopic rods are extruded, the plurality of scrapers are further clung to the inner wall of the smelting furnace, raw materials are heated in the smelting furnace during smelting, an external power switch of a driving motor is turned on, and the two mounting rods have supporting effect on the driving motor, so that the driving motor is arranged on the upper surface of the furnace cover, and then an output shaft of the driving motor drives a rotating rod to rotate, thereby enabling the first telescopic rods and the fixed rings to rotate, the first telescopic rods drive the scrapers to rotate when rotating, the fixed rings drive the stirring blades to rotate, the stirring blades to stir the magnesium alloy when being extruded, the stirring blades to stir the magnesium alloy evenly, and the magnesium alloy can be further adhered to the inner wall of the smelting furnace, and the magnesium alloy can be prevented from accumulating when the magnesium alloy is formed, and the metal is further smelted, and the magnesium alloy is more evenly adhered to the smelting furnace wall is prevented from being formed.

2. According to the application, after magnesium alloy smelting is finished, the die is placed, the furnace cover is taken down from the upper surface of the smelting furnace through the two handles, the two connecting rods can rotate on one side opposite to the two brackets because of the bearings, at the moment, the output end of the hydraulic rod is controlled to move forwards, the L-shaped plate supports the hydraulic rod, the output end of the hydraulic rod further drives the transmission plate to move, so that the rack drives the gear to rotate anticlockwise, the smelting furnace is enabled to topple forwards, and the smelted materials in the smelting furnace are poured out, so that after magnesium alloy smelting is finished, the smelting furnace is not needed to be manually toppled, the risk that a worker directly contacts with high-temperature melt is reduced, and scalding or other accidents are prevented.

Drawings

Fig. 1 is a schematic side view perspective structure of a magnesium alloy smelting stirring device according to the present application.

Fig. 2 is a schematic bottom perspective view of a magnesium alloy smelting stirring apparatus according to the present application.

Fig. 3 is a schematic diagram of a perspective structure of a furnace cover pulled out of a magnesium alloy smelting stirring device.

Fig. 4 is a schematic diagram of a perspective structure of a furnace cover in a magnesium alloy smelting stirring device.

Fig. 5 is an enlarged view of fig. 4 at a in accordance with the present application.

The legend is 1, a base, 2, a smelting furnace, 201, a locating rod, 202, a furnace cover, 203, a rotating rod, 204, a fixed ring, 205, stirring blades, 206, a first telescopic rod, 207, a second telescopic rod, 208, a scraper, 209, a mounting rod, 210, a driving motor, 211, a handle, 212, a through hole, 213, a spring, 3, a bracket, 301, a connecting rod, 302, an L-shaped plate, 303, a hydraulic rod, 304, a transmission plate, 305, a rack, 306 and a gear.

Detailed Description

In order that the above objects, features and advantages of the application will be more clearly understood, a further description of the application will be rendered by reference to the appended drawings and examples. It should be noted that, without conflict, the embodiments of the present application and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced otherwise than as described herein, and therefore the present application is not limited to the specific embodiments of the disclosure that follow.

Example 1 as shown in fig. 1 to 5, the present application provides a magnesium alloy melting and stirring apparatus comprising:

a base 1 and a smelting furnace 2;

The positioning rods 201 are movably embedded in one side of the base 1, and a furnace cover 202 is fixedly arranged on one side of each positioning rod 201;

The rotating rod 203 is arranged on one side of the furnace cover 202 through a bearing, a plurality of fixing rings 204 are fixedly sleeved on the outer surface of the rotating rod 203, and the rotating rod 203 can rotate due to the bearing;

The plurality of first telescopic rods 206 are fixedly arranged on the outer surface of the rotating rod 203, the second telescopic rods 207 are movably embedded in the inner walls of the plurality of first telescopic rods 206, the plurality of stirring blades 205 are driven to rotate when the plurality of fixed rings 204 rotate, and the plurality of stirring blades 205 stir raw materials;

The plurality of scrapers 208 are respectively and fixedly arranged at one ends of the plurality of second telescopic rods 207, the plurality of scrapers 208 are tightly attached to the inner wall of the smelting furnace 2, and the plurality of scrapers 208 which rotate scrape the interior of the smelting furnace 2, so that the magnesium alloy is prevented from being adhered to the furnace wall to form accumulation when being smelted.

As shown in fig. 1 to 5, the outer surfaces of the fixing rings 204 are fixedly provided with a plurality of stirring blades 205, one sides of the second telescopic rods 207 are fixedly provided with springs 213, one sides of the springs 213 are fixedly arranged at the inner walls of one sides of the first telescopic rods 206 respectively, and the springs 213 generate reverse acting force when being extruded.

As shown in fig. 1 to 5, two mounting rods 209 are fixedly arranged on one side of the furnace cover 202, a driving motor 210 is mounted on the opposite end of each of the two mounting rods 209, an output shaft of the driving motor 210 is fixedly arranged on one side of the rotating rod 203, the two mounting rods 209 have supporting effects on the driving motor 210, an external power switch of the driving motor 210 is turned on, and the output shaft of the driving motor 210 drives the rotating rod 203 to rotate.

As shown in fig. 1 to 5, two handles 211 are fixedly arranged on one side of the furnace cover 202, a plurality of through holes 212 are formed on one side of the base 1, the through holes 212 are respectively matched with the positioning rods 201, and the positioning rods 201 can slide in the through holes 212.

As shown in fig. 1 to 5, two brackets 3 are fixedly arranged on one side of the base 1, connecting rods 301 are arranged on opposite sides of the two brackets 3 through bearings, opposite sides of the two connecting rods 301 are fixedly arranged on two sides of the smelting furnace 2 respectively, and the two connecting rods 301 can rotate on opposite sides of the two brackets 3 due to the bearings.

As shown in fig. 1 to 5, one side of one of the brackets 3 is fixedly provided with an L-shaped plate 302, and one side of the L-shaped plate 302 is provided with a hydraulic rod 303, and the L-shaped plate 302 supports the hydraulic rod 303.

As shown in fig. 1 to 5, the output end of the hydraulic rod 303 is fixedly provided with a transmission plate 304, one side of the transmission plate 304 is fixedly provided with a rack 305, and the output end of the hydraulic rod 303 is controlled to move forward to drive the transmission plate 304 to move, so that the rack 305 drives a gear 306 to rotate anticlockwise.

As shown in fig. 1 to 5, a gear 306 is meshed with one side of the rack 305, the inner wall of the gear 306 is fixedly sleeved on the outer surface of one of the connecting rods 301, and the rack 305 drives the gear 306 to rotate anticlockwise when moving forwards, so that the smelting furnace 2 is poured forwards, the smelted material in the smelting furnace 2 is poured out, the smelting furnace 2 is not manually poured, the risk that a worker directly contacts with high-temperature melt is reduced, and scalding or other accidents are prevented.

Working principle: when the magnesium alloy is smelted and stirred by using equipment, the furnace cover 202 is taken out from the upper surface of the smelting furnace 2 through the two handles 211, smelting raw materials are poured into the smelting furnace 2, the plurality of positioning rods 201 can slide in the plurality of through holes 212 respectively, the plurality of positioning rods 201 are inserted into the plurality of through holes 212 respectively, the furnace cover 202 covers the upper surface of the smelting furnace 2, the plurality of second telescopic rods 207 can slide in the plurality of first telescopic rods 206 respectively, the plurality of springs 213 generate reverse acting force when being extruded, the plurality of second telescopic rods 207 are extruded, the plurality of scrapers 208 are further clung to the inner wall of the smelting furnace 2, raw materials are heated in the smelting furnace 2 during smelting, an external power switch of the driving motor 210 is turned on, the two mounting rods 209 have supporting effects on the driving motor 210, the driving motor 210 is arranged on the upper surface of the furnace cover 202, the output shaft of the driving motor 210 drives the rotating rod 203 to rotate, so that the plurality of first telescopic rods 206 and the plurality of fixed rings 204 rotate, the plurality of scraping plates 208 are driven to rotate when the plurality of first telescopic rods 206 rotate, the plurality of fixed rings 204 drive the plurality of stirring blades 205 to rotate when the plurality of fixed rings 204 rotate, the plurality of stirring blades 205 stir raw materials to improve the uniformity and the fluidity of melt, the plurality of scraping plates 208 scrape the inside of the smelting furnace 2 to prevent the magnesium alloy from being adhered to the furnace wall to form accumulation when smelting, thereby preventing the magnesium alloy from being adhered to the furnace wall to form accumulation when smelting and stirring the magnesium alloy, improving the usable metal amount, further improving the yield, putting the die after the magnesium alloy smelting is finished, taking the furnace cover 202 from the smelting furnace 2 through the two handles 211, the two connecting rods 301 can rotate on one side opposite to the two brackets 3 due to the bearings, at the moment, the output end of the hydraulic rod 303 is controlled to move forwards, the L-shaped plate 302 supports the hydraulic rod 303, the output end of the hydraulic rod 303 further drives the transmission plate 304 to move, so that the rack 305 drives the gear 306 to rotate anticlockwise, the smelting furnace 2 is enabled to topple forwards, the smelted materials in the smelting furnace 2 are poured out, after the magnesium alloy is smelted, the smelting furnace 2 is not required to be toppled manually, the risk that workers directly contact with high-temperature melt is reduced, and scalding or other accidents are prevented.

The present utility model is not limited to the above embodiments, and any equivalent embodiments that can be changed or modified to equivalent variations by using the technical content disclosed in the above arts can be applied to other fields, but any simple modification, equivalent variations and modification to the above embodiments according to the technical substance of the present utility model will still fall within the scope of the technical solution of the present utility model, unless departing from the technical content of the present utility model.

Claims (8)

1. A magnesium alloy melting and stirring apparatus, comprising:

A base (1) and a smelting furnace (2);

A plurality of positioning rods (201) are movably embedded in one side of the base (1), and a furnace cover (202) is fixedly arranged on one side of each positioning rod (201);

The rotating rod (203) is arranged on one side of the furnace cover (202) through a bearing, and a plurality of fixing rings (204) are fixedly sleeved on the outer surface of the rotating rod (203);

The first telescopic rods (206) are fixedly arranged on the outer surface of the rotating rod (203), and the second telescopic rods (207) are movably embedded in the inner walls of the first telescopic rods (206);

and a plurality of scrapers (208) fixedly arranged at one ends of the second telescopic rods (207).

2. The magnesium alloy melting and stirring device according to claim 1, wherein a plurality of stirring blades (205) are fixedly arranged on the outer surfaces of the fixing rings (204), springs (213) are fixedly arranged on one sides of the second telescopic rods (207), and one sides of the springs (213) are fixedly arranged on the inner walls of one sides of the first telescopic rods (206).

3. The magnesium alloy smelting stirring device according to claim 1, wherein two mounting rods (209) are fixedly arranged on one side of the furnace cover (202), a driving motor (210) is arranged at the opposite ends of the two mounting rods (209), and an output shaft of the driving motor (210) is fixedly arranged on one side of the rotating rod (203).

4. The magnesium alloy smelting stirring device according to claim 3, wherein two handles (211) are fixedly arranged on one side of the furnace cover (202), a plurality of through holes (212) are formed on one side of the base (1), and the through holes (212) are matched with the positioning rods (201) respectively.

5. The magnesium alloy smelting stirring device according to claim 1, wherein two supports (3) are fixedly arranged on one side of the base (1), connecting rods (301) are arranged on opposite sides of the two supports (3) through bearings, and opposite sides of the two connecting rods (301) are fixedly arranged on two sides of the smelting furnace (2) respectively.

6. The magnesium alloy smelting stirring device according to claim 5, wherein one side of one bracket (3) is fixedly provided with an L-shaped plate (302), and one side of the L-shaped plate (302) is provided with a hydraulic rod (303).

7. The magnesium alloy smelting stirring device according to claim 6, wherein the output end of the hydraulic rod (303) is fixedly provided with a transmission plate (304), and one side of the transmission plate (304) is fixedly provided with a rack (305).

8. The magnesium alloy smelting stirring device according to claim 7, wherein a gear (306) is arranged on one side of the rack (305) in a meshed manner, and the inner wall of the gear (306) is fixedly sleeved on the outer surface of one of the connecting rods (301).