CN215468026U - Automatic batch pouring system for phosphorus-copper alloy - Google Patents

Abstract

The utility model discloses an automatic batch pouring system for phosphorus-copper alloy, which relates to the field of automatic batch pouring systems for phosphorus-copper alloy, and comprises a pouring machine, wherein a pouring area, a heating cavity and a fuel cavity are sequentially arranged above and below the pouring machine, a phosphorus-copper alloy plate is arranged in the pouring area, a pouring box fixed on the upper surface of the pouring machine is arranged above the phosphorus-copper alloy plate, a rotating unit is protected in the protecting box, a clamping mechanism and the phosphorus-copper alloy plate can be driven to turn over through a partition plate, fuel can be used for heating in the fuel cavity, phosphorus-copper alloy stored in the heating cavity generates phosphorus-copper alloy liquid, the phosphorus-copper alloy liquid is pumped into a pouring pipeline through a suction unit and then uniformly falls on the surface of the phosphorus-copper alloy plate through a pouring hole for pouring, and the rotating unit drives the phosphorus-copper alloy plate to rotate when the phosphorus-copper alloy plate is fixed by the clamping mechanism, so that uniform pouring is convenient, a phosphor-copper alloy layer can be poured on the surface of the phosphor-copper alloy plate.

Description

Automatic batch pouring system for phosphorus-copper alloy

Technical Field

The utility model relates to the field of automatic batch pouring systems for phosphorus-copper alloys, in particular to an automatic batch pouring system for phosphorus-copper alloys.

Background

The phosphorus-copper alloy is an excellent deoxidizer, plays an important role in the field of colored casting, can effectively remove oxygen particles in molten metal, and effectively improves the quality and yield of castings. The main production process is to electrolyze copper and red phosphorus or white phosphorus, and to synthesize the copper and red phosphorus or white phosphorus at high temperature.

However, when the actual phosphorus-copper alloy is poured on the surface of a workpiece to improve the oxidation resistance of the workpiece, the surface of the workpiece needs to be polished to make the surface of the workpiece smooth or have a frosted surface so as to increase the precision requirement of the workpiece, but phosphorus-copper alloy powder exists in the polishing process, so that pollution and waste are caused. Therefore, it is necessary to develop an automated batch casting system for phosphorus-copper alloys to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an automatic batch pouring system for phosphorus-copper alloy, which solves the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: an automatic batch pouring system for phosphorus-copper alloy comprises a pouring machine, wherein a pouring area, a heating cavity and a fuel cavity are sequentially arranged on the pouring machine from top to bottom, a phosphorus-copper alloy plate is arranged in the pouring area, a pouring box fixed on the upper surface of the pouring machine is arranged above the phosphorus-copper alloy plate, a plurality of groups of pouring holes corresponding to the upper part of the phosphorus-copper alloy plate are arranged on the lower surface of the pouring box, a pouring pipeline is arranged in the pouring machine and communicated with the pouring holes, a suction unit communicated with one side of the bottom of the heating cavity is arranged at the end part of the pouring pipeline, a processing area is arranged on one side of the pouring area, a protection box is arranged in the processing area, a first pushing unit capable of pushing the protection box to move in the processing area is fixedly welded on the inner wall of the processing area, the protection box is arranged on one side of the phosphorus-copper alloy plate, the bottom in processing district is provided with the relief hole that runs through from top to bottom of multiunit, and the below of relief hole is provided with the material collecting tank, the top in return channel intercommunication heating chamber is passed through to the bottom one end in material collecting tank, be provided with the check valve that supplies material one-way entering in the material collecting tank in the return channel heating chamber.

Preferably, the inside of protection box is provided with rotatable rotation unit, be fixed with the fixture of centre gripping phosphorus copper alloy panel on rotation unit's the tip pivot, the bottom surface fixed welding in district of pouring has the baffle of restriction protection box towards the inside removal in district of pouring.

In this embodiment, the rotation unit is protected in the inside of protection box, accessible baffle drives fixture and the upset of phosphorus copper alloy panel, and can use fuel to heat in the fuel chamber, make the phosphorus copper alloy of storage in the heating chamber generate phosphorus copper alloy liquid, phosphorus copper alloy liquid is through absorbing the unit suction and pouring the pipeline and evenly fall on the surface of phosphorus copper alloy panel by pouring the hole and pour, rotation unit drives phosphorus copper alloy panel rotatory when fixture fixed phosphorus copper alloy panel, be convenient for evenly pour, can pour the phosphorus copper alloy layer on the surface of phosphorus copper alloy panel, in the device, rotation unit can use devices such as motor, fixture can use devices such as ordinary splint.

Preferably, the bottom of the pouring area is provided with a plurality of groups of backflow holes communicated with the heating cavity.

It should be noted that, when the phosphorus-copper alloy liquid is poured on the phosphorus-copper alloy plate, the excess phosphorus-copper alloy liquid falls into the pouring area and then flows into the heating cavity again through the backflow hole for recycling, which is relatively economical, and the suction unit can use a suction pump and other devices.

Preferably, a feeding hopper for adding the phosphorus-copper alloy into the heating cavity is arranged on the side surface of the pouring machine.

Furthermore, the charging hopper is convenient for adding the phosphorus-copper alloy into the heating cavity in real time.

Preferably, a fan for blowing air into the processing area is arranged on one side, located on the protection box, of the upper surface of the pouring machine.

Specifically, after the phosphorus copper alloy plate surface is poured through phosphorus copper alloy liquid and is accomplished, drive phosphorus copper alloy plate through first promotion unit and remove to the processing district in, blow phosphorus copper alloy plate surface through the fan, air-dry the phosphorus copper alloy liquid on phosphorus copper alloy plate surface fast, machining efficiency is high, and first promotion unit can use devices such as electric putter.

Preferably, the last fixed surface of pouring machine is provided with first base plate, the fixed welding in upper end bottom of first base plate has the second to promote the unit, the fixed welding of lower extreme that the second promoted the unit has the second base plate, the fixed welding in surface intermediate position of second base plate has the intermediate lamella, the equal fixed welding in upper and lower both ends of intermediate lamella has the third to promote the unit, the fixed welding of tip that the third promoted the unit has slewing mechanism, fixed cover is equipped with the emery wheel of polishing that can laminate on phosphor-copper alloy plate surface in the pivot of slewing mechanism tip.

In this embodiment, when phosphorus copper alloy panel moved to the processing district in, the second promotes the unit and promotes the whole decline of second base plate, promote the unit through the third flexible and adjust the distance between two sets of grinding wheels from top to bottom, make two sets of grinding wheels laminate respectively at the upper and lower surface of phosphorus copper alloy panel, and slewing mechanism drives the grinding wheel and rotates, the effect of polishing phosphorus copper alloy panel surface has been realized, and the powder etc. after polishing gets into the collecting tank through the relief hole, the powder accessible return channel that gets into in the collecting tank gets into heating chamber cyclic utilization once more, in the device, the second promotes the unit, the third promotes devices such as the unit all can use the cylinder, slewing mechanism can use devices such as motor.

Preferably, the bottom of collecting trough and heating chamber all is provided with the inclined plane, and the inclined plane on the collecting trough inclines towards return channel below, the inclined plane on the heating chamber inclines towards the below of sucking the unit.

It should be noted that the inclined surface facilitates the descent of the material.

The utility model has the technical effects and advantages that:

1. the utility model relates to an automatic batch pouring system for phosphorus-copper alloy, which comprises a pouring machine, wherein a pouring area, a heating cavity and a fuel cavity are sequentially arranged on the pouring machine from top to bottom, a phosphorus-copper alloy plate is arranged in the pouring area, a pouring box fixed on the upper surface of the pouring machine is arranged above the phosphorus-copper alloy plate, a plurality of groups of pouring holes corresponding to the upper part of the phosphorus-copper alloy plate are arranged on the lower surface of the pouring box, a pouring pipeline is arranged in the pouring machine and communicated with the pouring holes, a rotating unit is protected in a protective box, a clamping mechanism and the phosphorus-copper alloy plate can be driven to turn over through a partition plate, the fuel cavity can be heated by fuel, the phosphorus-copper alloy stored in the heating cavity generates phosphorus-copper alloy liquid, the phosphorus-copper alloy liquid is pumped into the pouring pipeline through a suction unit and then uniformly falls on the surface of the phosphorus-copper alloy plate through the pouring holes for pouring, when the clamping mechanism fixes the phosphorus-copper alloy plate, the rotating unit drives the phosphorus-copper alloy plate to rotate, so that uniform pouring is facilitated, and a phosphorus-copper alloy layer can be poured on the surface of the phosphorus-copper alloy plate;

2. according to the automatic batch pouring system for the phosphorus-copper alloy, when the phosphorus-copper alloy liquid is poured on a phosphorus-copper alloy plate, redundant phosphorus-copper alloy liquid falls into a pouring area and then flows into a heating cavity again through the backflow hole for recycling;

3. according to the automatic batch pouring system for the phosphorus-copper alloy, after the surface of a phosphorus-copper alloy plate is poured by the phosphorus-copper alloy liquid, the phosphorus-copper alloy plate is driven to move into a processing area through the first pushing unit, the surface of the phosphorus-copper alloy plate is blown by the fan, the phosphorus-copper alloy liquid on the surface of the phosphorus-copper alloy plate is quickly dried, and the processing efficiency is high.

Drawings

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

FIG. 2 is an enlarged view of the structure at A in FIG. 1 according to the present invention.

FIG. 3 is an enlarged view of the structure at B in FIG. 1 according to the present invention.

In the figure: 1. a pouring machine; 2. a suction unit; 3. a hopper; 4. pouring a pipeline; 5. a return orifice; 6. pouring a box; 7. pouring holes; 8. a fan; 9. a phosphorus-copper alloy plate; 10. pouring a region; 11. a protection box; 12. a first pushing unit; 13. a processing zone; 14. a discharge hole; 15. a material collecting groove; 16. a heating cavity; 17. a fuel chamber; 18. a rotating unit; 19. a partition plate; 20. a return channel; 21. a one-way valve; 22. a first substrate; 23. a second pushing unit; 24. a second substrate; 25. grinding the wheel; 26. a middle plate; 27. a third pushing unit; 28. a rotation mechanism.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The utility model provides an automatic batch pouring system for phosphorus-copper alloy, which comprises a pouring machine 1, wherein a pouring area 10, a heating cavity 16 and a fuel cavity 17 are sequentially arranged above and below the pouring machine 1, a phosphorus-copper alloy plate 9 is arranged in the pouring area 10, a pouring box 6 fixed on the upper surface of the pouring machine 1 is arranged above the phosphorus-copper alloy plate 9, a plurality of groups of pouring holes 7 corresponding to the upper part of the phosphorus-copper alloy plate 9 are arranged on the lower surface of the pouring box 6, a pouring pipeline 4 is arranged in the pouring machine 1, the pouring pipeline 4 is communicated with the pouring holes 7, an end part of the pouring pipeline 4 is provided with a suction unit 2 communicated with one side of the bottom of the heating cavity 16, a processing area 13 is arranged on one side of the pouring area 10, a protection box 11 is arranged in the processing area 13, a first pushing unit 12 capable of pushing the protection box 11 to move in the processing area 13 is fixedly welded on the inner wall of the processing area 13, the protection box 11 sets up in one side of phosphorus copper alloy panel 9, and the bottom of processing district 13 is provided with the relief hole 14 that runs through from top to bottom of multiunit, and the below of relief hole 14 is provided with material collecting tank 15, and material collecting tank 15's bottom one end is passed through return channel 20 and is communicated the top of heating chamber 16, is provided with the check valve 21 that supplies material one-way entering in material collecting tank 15 in the return channel 20 in the heating chamber 16.

A rotatable rotating unit 18 is arranged inside the protection box 11, a clamping mechanism for clamping the phosphorus-copper alloy plate 9 is fixed on a rotating shaft at the end part of the rotating unit 18, and a partition plate 19 for limiting the protection box 11 to move towards the inside of the pouring area 10 is fixedly welded on the bottom surface of the pouring area 10.

In this embodiment, the rotating unit 18 is protected inside the protection box 11, the partition plate 19 can drive the clamping mechanism and the phosphorus-copper alloy plate 9 to turn over, and the fuel cavity 17 can be heated by using fuel, so that phosphorus-copper alloy stored in the heating cavity 16 generates phosphorus-copper alloy liquid, the phosphorus-copper alloy liquid is pumped into the pouring pipeline 4 through the suction unit 2 and then uniformly falls on the surface of the phosphorus-copper alloy plate 9 through the pouring hole 7 for pouring, when the clamping mechanism fixes the phosphorus-copper alloy plate 9, the rotating unit 18 drives the phosphorus-copper alloy plate 9 to rotate, so that uniform pouring is facilitated, a phosphorus-copper alloy layer can be poured on the surface of the phosphorus-copper alloy plate 9, in the device, the rotating unit 18 can use a motor and other devices, and the clamping mechanism can use a common clamping plate and other devices.

The bottom of the pouring area 10 is provided with a plurality of groups of backflow holes 5 communicated with the heating cavity 16.

It should be noted that, when the phosphorus-copper alloy liquid is poured on the phosphorus-copper alloy plate 9, the excess phosphorus-copper alloy liquid falls into the pouring area 10 and then flows into the heating cavity 16 again through the backflow hole 5 for recycling, which is relatively economical, and the suction unit 2 can use a suction pump or other devices.

The side surface of the casting machine 1 is provided with a feeding hopper 3 for adding phosphor-copper alloy into the heating cavity 16.

Further, the hopper 3 is used for facilitating the real-time addition of the phosphorus-copper alloy into the heating cavity 16.

And a fan 8 for blowing air into the processing area 13 is arranged on one side of the upper surface of the pouring machine 1, which is positioned on the protection box 11.

Specifically, after the surface of the phosphorus-copper alloy plate 9 is poured through the phosphorus-copper alloy liquid, the first pushing unit 12 drives the phosphorus-copper alloy plate 9 to move to the processing area 13, the surface of the phosphorus-copper alloy plate 9 is blown through the fan 8, the phosphorus-copper alloy liquid on the surface of the phosphorus-copper alloy plate 9 is quickly air-dried, the processing efficiency is high, and the first pushing unit 12 can use devices such as an electric push rod.

The fixed surface of the upper surface of pouring machine 1 is provided with first base plate 22, the fixed welding in upper end bottom of first base plate 22 has second promotion unit 23, the fixed welding in lower extreme of second promotion unit 23 has second base plate 24, the fixed welding in surface intermediate position of second base plate 24 has intermediate plate 26, the equal fixed welding in upper and lower both ends of intermediate plate 26 has third promotion unit 27, the fixed welding in tip of third promotion unit 27 has slewing mechanism 28, fixed cover is equipped with the wheel 25 of polishing that can laminate on phosphorus copper alloy panel 9 surface in the pivot of slewing mechanism 28 tip.

In this embodiment, when the phosphorus-copper alloy plate 9 moves into the processing area 13, the second pushing unit 23 pushes the second substrate 24 to descend as a whole, and the third pushing unit 27 stretches and contracts to adjust the distance between the upper and lower two groups of polishing wheels 25, so that the two groups of polishing wheels 25 are respectively attached to the upper and lower surfaces of the phosphorus-copper alloy plate 9, and the rotating mechanism 28 drives the polishing wheels 25 to rotate, thereby polishing the surface of the phosphorus-copper alloy plate 9, and the polished powder and the like enter the material collecting groove 15 through the discharge hole 14, and the powder entering the material collecting groove 15 can enter the heating cavity 16 again through the backflow channel 20 for recycling.

The bottom of collecting trough 15 and heating chamber 16 all is provided with the inclined plane, and the inclined plane on collecting trough 15 inclines towards return channel 20 below, and the inclined plane on the heating chamber 16 inclines towards the below of drawing unit 2.

It should be noted that the inclined surface facilitates the descent of the material.

The working principle is as follows: the rotating unit 18 is protected inside the protective box 11, the clamping mechanism and the phosphorus-copper alloy plate 9 can be driven to turn over through the partition plate 19, fuel can be used in the fuel cavity 17 for heating, phosphorus-copper alloy stored in the heating cavity 16 generates phosphorus-copper alloy liquid, the phosphorus-copper alloy liquid is sucked into the pouring pipeline 4 through the suction unit 2 and then evenly falls on the surface of the phosphorus-copper alloy plate 9 through the pouring hole 7 for pouring, the rotating unit 18 drives the phosphorus-copper alloy plate 9 to rotate when the clamping mechanism fixes the phosphorus-copper alloy plate 9, uniform pouring is facilitated, and a phosphorus-copper alloy layer can be poured on the surface of the phosphorus-copper alloy plate 9.

Finally, it should be noted that: 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 (7)

1. The utility model provides an automatic batch casting system for phosphorus copper alloy, includes casting machine (1), its characterized in that: the utility model discloses a building device, including pouring machine (1), pouring machine A promotion unit (12), protection box (11) set up in one side of phosphorus copper alloy panel (9), the bottom of processing district (13) is provided with relief hole (14) that run through from top to bottom of multiunit, and the below of relief hole (14) is provided with material collecting tank (15), the top that backflow channel (20) intercommunication heating chamber (16) was passed through to material collecting tank's (15) bottom one end, be provided with in backflow channel (20) and supply material collecting tank (15) one-way check valve (21) that get into in heating chamber (16).

2. The automated batch casting system for phosphor-copper alloys according to claim 1, wherein: the inside of protection box (11) is provided with rotatable rotation unit (18), be fixed with the fixture of centre gripping phosphorus copper alloy panel (9) in the tip pivot of rotation unit (18), the bottom surface fixed welding of pouring district (10) has baffle (19) of restriction protection box (11) towards pouring district (10) inside removal.

3. The automated batch casting system for phosphor-copper alloys according to claim 1, wherein: and a plurality of groups of backflow holes (5) communicated with the heating cavity (16) are formed in the bottom of the pouring area (10).

4. The automated batch casting system for phosphor-copper alloys according to claim 1, wherein: and a feeding hopper (3) for adding phosphorus-copper alloy into the heating cavity (16) is arranged on the side surface of the pouring machine (1).

5. The automated batch casting system for phosphor-copper alloys according to claim 1, wherein: and a fan (8) blowing air into the processing area (13) is arranged on one side, located on the protection box (11), of the upper surface of the pouring machine (1).

6. The automated batch casting system for phosphor-copper alloys according to claim 1, wherein: the fixed surface of the upper surface of pouring machine (1) is provided with first base plate (22), the fixed welding in upper end bottom of first base plate (22) has second promotion unit (23), the fixed welding in lower extreme of second promotion unit (23) has second base plate (24), the fixed welding in surface intermediate position of second base plate (24) has intermediate plate (26), the equal fixed welding in upper and lower both ends of intermediate plate (26) has third promotion unit (27), the fixed welding in tip of third promotion unit (27) has slewing mechanism (28), fixed cover is equipped with in the pivot of slewing mechanism (28) tip and laminates grinding wheel (25) on phosphor-copper alloy panel (9) surface.

7. The automated batch casting system for phosphor-copper alloys according to claim 1, wherein: the bottom of collecting trough (15) and heating chamber (16) all is provided with the inclined plane, and the inclined plane on collecting trough (15) inclines towards return channel (20) below, the inclined plane on heating chamber (16) inclines towards the below of drawing unit (2).

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