CN215315595U - A die-casting cooling device for tombarthite alloy processing - Google Patents

Abstract

The utility model belongs to the technical field of die-casting cooling, in particular to a die-casting cooling device for processing rare earth alloy, which aims at the problems of more complicated cooling and larger danger of the die-cast rare earth alloy and comprises an installation plate, wherein a supporting rod is fixed on the side wall at the top end of the installation plate, a placing pipe is fixed on the side wall at the top end of the supporting rod, a cooling pipe is arranged on the inner side wall of the placing pipe, and two placing frames which are symmetrically distributed are arranged on the side wall at the top end of the cooling pipe; according to the utility model, the placing disc is driven to rotate by the rotation of the rotating rod, so that the phenomenon that the placing disc shakes during movement can be effectively reduced, the flexible disc is driven to move by the movement of the jacking block, the working efficiency can be effectively improved, the flexible disc drives the jacking rod and the buffer spring to move simultaneously, and the jacking disc is driven to move, so that the working efficiency can be effectively increased, the safety is effectively improved, and the harm to workers is reduced.

Description

A die-casting cooling device for tombarthite alloy processing

Technical Field

The utility model relates to the technical field of die-casting cooling, in particular to a die-casting cooling device for rare earth alloy processing.

Background

The rare earth alloy is formed by combining a rare earth metal or other metals with non-metal elements and can be made into binary or multi-element rare earth alloy products, because the rare earth alloy has unique properties, the rare earth alloy has wide application in various industrial departments, the demand is increased rapidly, in the late stage of the twenty-century fifty years, China completes the technical research on the process for producing the rare earth alloy, in the early stage of the twenty-century sixties, a large-scale rare earth silicon-iron alloy factory is built, ten thousand tons of rare earth alloy products are produced every year, and various rare earth alloy products are produced.

At present, the existing die-casting cooling is basically separated operation, firstly, the die-cast rare earth alloy is taken out by manually holding a pliers, then the die-cast rare earth alloy is placed in a cooling box, workers take the pliers to take out the die-cast rare earth alloy, the workers are injured by carelessness, the danger is high, and the die-cast rare earth alloy is placed in the cooling box, so the operation is complicated.

Therefore, a die-casting cooling device for processing rare earth alloy is needed to solve the problems of complicated cooling and high risk of die-cast rare earth alloy.

SUMMERY OF THE UTILITY MODEL

The die-casting cooling device for processing the rare earth alloy solves the problems that the rare earth alloy after die-casting is cooled more complexly and dangerousness is high.

In order to achieve the purpose, the utility model adopts the following technical scheme: the utility model provides a die-casting cooling device for rare earth alloy processing, includes the mounting panel, the top lateral wall of mounting panel is fixed with the bracing piece, the top lateral wall of bracing piece is fixed with places the pipe, the inside wall of placing the pipe is provided with the cooling tube, the top lateral wall of cooling tube is provided with two racks that are the symmetric distribution, one side lateral wall that the rack is close to each other is provided with a plurality of cooling frames that are the symmetric distribution, the bottom lateral wall of cooling tube is fixed with the actuating lever, the lateral wall of actuating lever rotates and has cup jointed drive belt, drive belt's inside wall rotates and is connected with the rotary rod, the top lateral wall of rotary rod is fixed with ejecting subassembly.

Preferably, the ejection assembly comprises a placing disc fixed on the top side wall of the rotary rod, a plurality of symmetrically distributed ejector blocks are fixed on the top side wall of the placing disc, a telescopic disc is arranged right above the ejector blocks, a plurality of symmetrically distributed ejector grooves are formed in the bottom side wall of the telescopic disc, an ejector rod is arranged on the top side wall of the telescopic disc, a buffer spring is fixed on the top side wall of the telescopic disc, a limiting block is fixed at one end, away from the telescopic disc, of the buffer spring, a pressing block is fixed on the top side wall of the limiting block, a pressing hole is formed in the top side wall of the pressing block, an ejection disc is fixed on the top side wall of the ejector rod, and a driving motor is fixed on the bottom side wall of the rotary rod.

Preferably, one side lateral wall of driving motor is fixed with the fixed block, one side lateral wall of fixed block is fixed with the mounting bracket, the top lateral wall of mounting bracket with the bottom lateral wall of briquetting is fixed.

Preferably, one side lateral wall of rack is provided with a plurality of stable pieces that are the symmetric distribution, a plurality of cooling holes that are the symmetric distribution are seted up to the lateral wall of cooling frame.

Preferably, the outer side wall of the cooling frame is provided with two hanging holes which are symmetrically distributed, and the sizes of the hanging holes are matched with the size of the stabilizing block.

Preferably, the size of the top block is matched with that of the top groove, the cross section of the top block is arc-shaped, and the cross section of the top groove is arc-shaped.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the placing disc is driven to rotate by the rotation of the rotating rod, so that the phenomenon that the placing disc shakes during movement can be effectively reduced, the flexible disc is driven to move by the movement of the jacking block, the working efficiency can be effectively improved, the flexible disc drives the jacking rod and the buffer spring to move simultaneously, and the jacking disc is driven to move, so that the working efficiency can be effectively increased, the safety is effectively improved, and the harm to workers is reduced.

2. According to the utility model, the plurality of cooling frames are sequentially arranged on the stabilizing block, so that a plurality of die-cast rare earth alloys can be cooled simultaneously, the working efficiency can be greatly improved, the driving rod rotates to drive the cooling pipe to rotate, the cooling pipe rotates to drive the placing rack to rotate, and the cooling frames are driven to rotate, so that the working efficiency can be effectively improved, and the safety of workers is effectively protected.

Drawings

FIG. 1 is a schematic structural diagram of a rare earth alloy processing machine according to the present invention;

FIG. 2 is a schematic view of a partial structure of a hanging hole for processing rare earth alloy according to the present invention;

FIG. 3 is a schematic view of a partial structure of an ejection assembly for rare earth alloy processing according to the present invention;

FIG. 4 is a schematic view of a partial structure of a top groove for rare earth alloy processing according to the present invention.

In the figure: 1. mounting a plate; 2. a support bar; 3. placing a tube; 4. a cooling tube; 5. placing a rack; 6. a cooling frame; 7. a drive rod; 8. a drive belt; 9. rotating the rod; 10. ejecting the assembly; 1001. placing the disc; 1002. a top block; 1003. a telescopic disc; 1004. a top groove; 1005. A top rod; 1006. a buffer spring; 1007. a limiting block; 1008. briquetting; 1009. pressing the hole; 1010. ejecting the disc; 1011. a drive motor; 11. a fixed block; 12. a mounting frame; 13. A stabilizing block; 14. a cooling hole; 15. and (7) hanging holes.

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.

Referring to fig. 1-4, a die-casting cooling device for processing rare earth alloy, including mounting panel 1, the top lateral wall of mounting panel 1 is fixed with bracing piece 2, the top lateral wall of bracing piece 2 is fixed with places pipe 3, the inside wall of placing pipe 3 is provided with cooling tube 4, the top lateral wall of cooling tube 4 is provided with two racks 5 that are symmetric distribution, one side lateral wall that rack 5 is close to each other is provided with a plurality of cooling frames 6 that are symmetric distribution, the bottom lateral wall of cooling tube 4 is fixed with actuating lever 7, the lateral wall of actuating lever 7 rotates and has cup jointed driving belt 8, the inside wall of driving belt 8 rotates and is connected with rotary rod 9, the top lateral wall of rotary rod 9 is fixed with ejecting subassembly 10, so can effectually improve work efficiency.

Ejecting subassembly 10 is including fixing the disc 1001 of placing at the top lateral wall of rotary rod 9, the top lateral wall of placing disc 1001 is fixed with a plurality of kicking blocks 1002 that are the symmetric distribution, be provided with flexible disc 1003 directly over kicking blocks 1002, a plurality of top grooves 1004 that are the symmetric distribution are seted up to the bottom lateral wall of flexible disc 1003, the top lateral wall of flexible disc 1003 sets up ejector pin 1005, the top lateral wall of flexible disc 1003 is fixed with buffer spring 1006, buffer spring 1006 keeps away from the one end of flexible disc 1003 and is fixed with spacing piece 1007, the top lateral wall of spacing piece 1007 is fixed with pressure piece 1008, the top lateral wall of briquetting 1008 is seted up and is pressed the hole 1009, the top lateral wall of ejector pin 1005 is fixed with ejecting disc 1010, the bottom lateral wall of rotary rod 9 is fixed with driving motor 1011, work efficiency has been effectually improved like this, and workman's security has still been effectually improved.

A fixed block 11 is fixed on the side wall of one side of the driving motor 1011, an installation frame 12 is fixed on the side wall of one side of the fixed block 11, and the side wall of the top end of the installation frame 12 is fixed with the side wall of the bottom end of the pressing block 1008.

A plurality of stabilizing blocks 13 which are symmetrically distributed are arranged on the side wall of one side of the placing frame 5, and a plurality of cooling holes 14 which are symmetrically distributed are formed in the outer side wall of the cooling frame 6.

Two hanging holes 15 which are symmetrically distributed are formed in the outer side wall of the cooling frame 6, the size of each hanging hole 15 is matched with that of the stabilizing block 13, the size of the top block 1002 is matched with that of the top groove 1004, the cross section of the top block 1002 is arc-shaped, and the cross section of the top groove 1004 is arc-shaped.

The working principle is as follows: when the rare earth alloy that die-casting has been accomplished needs to be cooled down, at first, driving motor 1011 is started, the output shaft of driving motor 1011 rotates and drives rotary rod 9 to rotate, rotary rod 9 rotates and drives actuating lever 7 to rotate through drive belt 8, because rotary rod 9's rotation drives and places disc 1001 and rotates, drive kicking block 1002 and move, kicking block 1002 moves and drives flexible disc 1003 and move, flexible disc 1003 moves and drives ejector pin 1005 and buffer spring 1006 simultaneous movement, drive ejecting disc 1010 and move, thereby arrange into cooling frame 6 with the rare earth alloy that die-casting has been accomplished in, then place a plurality of cooling frames 6 on stabilizing block 13 in proper order, thereby accomplish placing of cooling frame 6, actuating lever 7 rotates and drives cooling tube 4 and rotates, cooling tube 4 rotates and drives rack 5 to rotate, drive cooling frame 6 and rotate.

The driving motors 1011 can be purchased in the market, and the driving motors 1011 are all provided with power supplies, which belong to the mature technology in the field and are fully disclosed, so that repeated description is omitted in the specification.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (6)

1. A die-casting cooling device for processing rare earth alloy comprises a mounting plate (1), it is characterized in that a supporting rod (2) is fixed on the side wall of the top end of the mounting plate (1), a placing pipe (3) is fixed on the side wall of the top end of the supporting rod (2), a cooling pipe (4) is arranged on the inner side wall of the placing pipe (3), two symmetrically distributed placing racks (5) are arranged on the side wall of the top end of the cooling pipe (4), a plurality of cooling frames (6) which are symmetrically distributed are arranged on the side wall of one side of the placing rack (5) which is close to each other, a driving rod (7) is fixed on the side wall of the bottom end of the cooling pipe (4), a driving belt (8) is rotatably sleeved on the outer side wall of the driving rod (7), the inner side wall of the driving belt (8) is rotationally connected with a rotating rod (9), and an ejection assembly (10) is fixed on the side wall of the top end of the rotating rod (9).

2. The die-casting cooling device for processing the rare earth alloy according to claim 1, wherein the ejection assembly (10) comprises a placement disc (1001) fixed on the top side wall of a rotating rod (9), the top side wall of the placement disc (1001) is fixed with a plurality of symmetrically distributed ejector blocks (1002), a telescopic disc (1003) is arranged right above the ejector blocks (1002), the bottom side wall of the telescopic disc (1003) is provided with a plurality of symmetrically distributed ejector slots (1004), the top side wall of the telescopic disc (1003) is provided with ejector rods (1005), the top side wall of the telescopic disc (1003) is fixed with a buffer spring (1006), one end of the buffer spring (1006) far away from the telescopic disc (1003) is fixed with a limiting block (1007), the top side wall of the limiting block (1007) is fixed with a pressing block (1008), and the top side wall of the pressing block (1008) is provided with a pressing hole (1009), an ejection disc (1010) is fixed on the side wall of the top end of the ejector rod (1005), and a driving motor (1011) is fixed on the side wall of the bottom end of the rotating rod (9).

3. The die-casting cooling device for processing rare earth alloy as claimed in claim 2, wherein a fixing block (11) is fixed on one side wall of the driving motor (1011), a mounting frame (12) is fixed on one side wall of the fixing block (11), and a top end side wall of the mounting frame (12) is fixed with a bottom end side wall of the pressing block (1008).

4. The die-casting cooling device for processing rare earth alloy according to claim 1, wherein a plurality of symmetrically distributed stabilizing blocks (13) are arranged on a side wall of the placing frame (5), and a plurality of symmetrically distributed cooling holes (14) are formed on an outer side wall of the cooling frame (6).

5. The die-casting cooling device for processing rare earth alloy as recited in claim 4, wherein the outer side wall of the cooling frame (6) is provided with two hanging holes (15) which are symmetrically distributed, and the size of the hanging holes (15) is matched with the size of the stabilizing block (13).

6. The die-casting cooling device for rare earth alloy processing as claimed in claim 2, wherein the size of the top block (1002) is matched with the size of the top groove (1004), the cross section of the top block (1002) is arc-shaped, and the cross section of the top groove (1004) is arc-shaped.

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