CN214684178U - Casting machine - Google Patents

Abstract

The utility model discloses a casting machine relates to the casting device, can realize the automatic casting of non ferrous metal. The metal mold comprises a machine body, be equipped with the crystallization wheel on the fuselage, crystallization wheel face is equipped with annular channel, be equipped with the steel band of laminating crystallization wheel part wheel face on the crystallization wheel, the steel band with the channel cooperation forms the die cavity, the entrance point of die cavity is equipped with and is used for making the steel band of entrance point is near the extrusion wheel of crystallization wheel and is used for pouring into the ladle of liquid metal to the entrance point injection, the die cavity periphery is equipped with the cooling device who is used for cooling liquid metal, the exit end of die cavity is equipped with the drawing of patterns boots that are used for making the metal after the cooling break away from the channel and is used for accepting the access bridge that breaks away from back metal, still be equipped with take-up pulley and a plurality of leading wheel on the moving path of steel band. The utility model discloses make whole casting process automation, improve work efficiency.

Description

Casting machine

Technical Field

The utility model relates to a casting device, concretely relates to casting machine.

Background

The casting is an important link of non-ferrous metal continuous casting and rolling, the quality of cast non-ferrous metal ingots directly influences the quality of rolling of subsequent products, and the size of a crystallization wheel influences the yield. The cast metal often needs to be rolled, the requirements of the rolling process on the input metal can be different, and at the moment, different casting machines need to be replaced or the casting machines need to be modified, so that the time and labor are wasted. In the pouring process, the cooled nonferrous metal ingot has the problems of hollowness, sugar cores and the like due to uneven cooling.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: a casting machine is designed, and automatic casting of nonferrous metals can be realized.

The utility model provides a casting machine of solving above-mentioned problem.

The utility model discloses a following technical scheme realizes:

a casting machine comprises a machine body, wherein a crystallization wheel is arranged on the machine body, an annular channel is arranged on the wheel surface of the crystallization wheel, a steel belt attached to part of the wheel surface of the crystallization wheel is arranged on the crystallization wheel, the steel belt and the channel are matched to form a mold cavity, an extrusion wheel used for enabling the steel belt of the inlet end to be close to the crystallization wheel and a casting ladle used for injecting liquid metal into the inlet end are arranged at the inlet end of the mold cavity, a cooling device used for cooling the liquid metal is arranged on the periphery of the mold cavity, a demolding shoe used for enabling the cooled metal to be separated from the channel and an approach bridge used for receiving the separated metal are arranged at the outlet end of the mold cavity, and a tensioning wheel and a plurality of guide wheels are further arranged on the moving path of the steel belt.

In the scheme: wherein the mold cavity is a cavity which is enclosed by the channel and the steel strip covered on the channel and is opened at two ends. And when casting is carried out, liquid metal is output from the output end of the casting ladle, and the liquid metal is molten metal after solid metal is melted and has high temperature. The liquid metal enters from the inlet end of the die cavity, wherein the extrusion wheel is used for ensuring the stability of the inlet end of the die cavity by extruding the steel strip at the inlet end to be close to the crystallization wheel, so as to counteract the impact of the falling of the liquid metal and ensure the stability of the casting process. The liquid metal is driven by the crystallization wheel and the steel strip to move in the die cavity, the liquid or gas for cooling is sprayed out of the die cavity by the cooling device through the cooling device, the liquid metal is cooled and is converted into a solidified metal ingot from a liquid state, the metal ingot is driven by the crystallization wheel and the steel strip to move continuously, is output from the outlet end of the die cavity, is guided by the demolding shoe to be separated from the channel of the crystallization wheel and enters the approach bridge for output to a subsequent rolling process. In the operation process, the tensioning wheel is used for tensioning the steel strip to ensure that the steel strip is attached to the crystallization wheel, and the guide wheel is used for guiding the trend of the steel strip. Through the arrangement of the structure, the whole casting process is automated, and the working efficiency is improved.

Preferably, be equipped with pneumatic slewing mechanism on the fuselage, pneumatic slewing mechanism's output with the pivot of extrusion wheel is passed through the extrusion pole and is connected, the extrusion wheel can under pneumatic slewing mechanism's the drive with the output rotates as the axis and has to crystallization wheel face draws close trend.

In the scheme: the extrusion wheel moves on the machine body through the pneumatic rotating mechanism and is driven by the pneumatic rotating mechanism to have a tendency of closing towards the wheel surface of the crystallization wheel, so that the extrusion wheel is ensured to have a function of enabling the steel strip at the inlet end to abut against the crystallization wheel, and meanwhile, the extrusion wheel capable of moving can vacate a space for replacing the crystallization wheel. Through changing different crystallization wheels, can satisfy the demand of different follow-up rolling processes, have the flexibility, can change the crystallization wheel according to self demand.

Preferably, a rotating shaft of the tensioning wheel is connected with a pneumatic telescopic mechanism, and an output end of the pneumatic telescopic mechanism can drive the tensioning wheel to move and enable the tensioning wheel to have a tendency of being far away from the crystallization wheel.

In the scheme: the output end of the pneumatic telescopic mechanism drives the tensioning wheel to extrude towards the direction far away from the crystallization wheel, so that the whole steel belt is driven to be tightened, the whole steel belt is ensured to be tightly attached to the partial surface comprising the crystallization wheel, the extrusion wheel, the guide wheel and the tensioning wheel in the operation process, and further the stable operation of the whole device is ensured.

Preferably, the cooling device includes interior cold charge, outer cold charge and two side cold charge, interior cold charge sets up the one side of die cavity is kept away from to the tank bottom of crystallization wheel channel, outer cold charge sets up one side that the die cavity was kept away from to the steel band on the crystallization wheel, the side cold charge is located respectively the both sides of die cavity are kept away from to the lateral wall of channel, all be equipped with the nozzle of a plurality of directional die cavities on interior cold charge, outer cold charge and two side cold charge.

In the scheme: the groove bottom is one side of the groove channel close to the axis of the crystallization wheel. The cooling device is including distributing in die cavity internal cooling device all around, outer cold charge and two side cold charge, through the liquid metal of internal cooling device, outer cold charge and two side cold charge carry out the omnidirectional cooling to the die cavity, improve the cooling effect of liquid metal, ensure that the metal ingot quality of crystallization out is more stable, can not produce hollow, sugar core scheduling problem.

Further preferably, the inner cooling device, the outer cooling device and the two side cooling devices are provided with arc-shaped parts matched with the die cavity, and the nozzles are uniformly distributed on the arc-shaped parts.

In this scheme, interior cold charge, outer cold charge and two side cold charges all are equipped with the matching the arc portion of die cavity, the nozzle evenly distributed is in on the arc portion. Through the setting of segmental arc, ensure that the nozzle that sets up respectively on interior cold charge, outer cold charge and two side cold charge with the interval of cavity is unanimous, and liquid distribution is even when guaranteeing to spray the die cavity, and then ensures further promotion cooling effect's stability.

Preferably, the drawing of patterns boots include length-adjustable's connecting rod and with the drawing of patterns portion that connecting rod one end is connected, drawing of patterns portion stretches into the channel, drawing of patterns portion is including the guide of the channel tank bottom that can laminate, the guide include with the binding face of tank bottom laminating and keeping away from the guide face of tank bottom, the binding face with the guide face is crossing and forms the closed angle that is used for the perk metal.

In the scheme: after the metal ingot is cooled by the cooling device, the liquid metal forms a metal ingot still having higher temperature, when the metal ingot is output from the outlet end, the joint part of the bottom surface of the metal ingot and the groove bottom of the groove channel is inserted by the sharp corner on the demoulding part, at the moment, the bottom surface of the metal ingot and the groove bottom are separated from the joint state, and the metal ingot still has certain temperature and stronger ductility, and is driven by the crystallization wheel, the metal ingot is separated from the groove channel and output to the approach bridge along the guide surface, so that the metal casting is completed. In this process, the contained angle needs the laminating at the tank bottom of channel, consequently, sets up length-adjustable's connecting rod, through the position of demoulding portion is adjusted to the connecting rod, ensures to take turns under the crystallization of different diameters, can both accomplish the work that breaks away from that makes metal ingot and channel tank bottom, has more the flexibility.

Further preferably, the output end of the approach bridge is arranged on the extending direction of the guide surface, the approach bridge comprises two parallel side plates, and belt wheels for driving the metal to move are uniformly laid between the side plates.

In the scheme: the approach bridge is used for receiving the metal ingots led out from the guide part, the side plates arranged on the approach bridge are used for preventing the metal ingots from deviating from the track in the moving process, and the belt wheels are used for transporting the metal ingots and preventing the metal ingots from being dragged to influence the quality of output products.

Preferably, a dewatering device for removing liquid on the steel strip and a drying device for further drying the liquid are further sequentially arranged on the moving path of the steel strip.

In the scheme: because a cooling device is used, the steel belt can contain liquid in the process of bypassing, so that small-scale burning explosion caused by direct contact of the liquid and liquid metal is avoided, potential safety hazards are caused, and the product quality is influenced.

Preferably, a catch wheel for supporting the steel belt is further arranged on the moving path of the steel belt.

In the scheme: in addition, the steel belt needs to be replaced sometimes when the device is maintained, and the retaining wheels can also support the steel belt stably to a certain extent when the steel belt is replaced, so that the replacement of the steel belt is facilitated.

The utility model discloses have following advantage and beneficial effect:

1. the utility model discloses a crystallization wheel, pinch roller, water the cooperation of package, cooling device, drawing of patterns boots, approach bridge, leading wheel and steel band for whole casting process automation improves work efficiency.

2. The utility model discloses a set up adjustable pinch roller, drawing of patterns boots, can change the crystallization wheel according to self demand to this can satisfy the different demands to the metal casting, has the flexibility.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principles of the invention. In the drawings:

fig. 1 is an overall configuration diagram of an embodiment of the present invention;

reference numbers and corresponding part names in the drawings:

1-machine body, 2-pressing wheel, 3-approach bridge, 4-crystallization wheel, 5-demolding shoe, 6-guide wheel, 7-steel belt, 8-tensioning wheel, 9-retaining wheel, 10-cooling device, 11-casting ladle, 12-dewatering device and 13-drying device.

Detailed Description

To make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the following examples and drawings, and the exemplary embodiments and descriptions thereof of the present invention are only used for explaining the present invention, and are not intended as limitations of the present invention.

Example (b):

as shown in fig. 1, a casting machine comprises a machine body 1, wherein a crystallization wheel 4 is arranged on the machine body 1, an annular channel is arranged on the wheel surface of the crystallization wheel 4, a steel strip 7 attached to a part of the wheel surface of the crystallization wheel 4 is arranged on the crystallization wheel 4, the steel strip 7 is matched with the channel to form a mold cavity, a squeezing wheel for enabling the steel strip 7 at the inlet end to be close to the crystallization wheel 4 and a pouring ladle 11 for injecting liquid metal into the inlet end are arranged at the inlet end of the mold cavity, a cooling device 10 for cooling the liquid metal is arranged on the periphery of the mold cavity, a demolding shoe 5 for enabling the cooled metal to be separated from the channel and a guide bridge 3 for receiving the separated metal are arranged at the outlet end of the mold cavity, and a tensioning wheel 8 and a plurality of guide wheels 6 are further arranged on the moving path of the steel strip 7.

In the scheme: when casting, liquid metal, which is molten metal of solid metal and has a high temperature, is output from the output end of the ladle 11. The liquid metal enters from the inlet end of the mould cavity, wherein the squeezing wheel ensures the stability of the inlet end of the mould cavity by squeezing the steel strip 7 at the inlet end against the crystallisation wheel 4, counteracting the impact of the falling liquid metal and ensuring the stability of the casting process. The liquid metal is driven by the crystallization wheel 4 and the steel strip 7 to move in the die cavity, the liquid or gas for cooling is sprayed out of the die cavity by the cooling device 10 through the cooling device 10, the liquid metal is cooled, the liquid metal is converted into a relatively solidified metal ingot from the liquid state, the metal ingot is driven by the crystallization wheel 4 and the steel strip 7 to move continuously, is output from the outlet end of the die cavity, passes through the demolding shoe 5, is guided by the demolding shoe to be separated from the channel of the crystallization wheel 4, enters the approach bridge 3 and is used for outputting to a subsequent rolling process. During operation, the tension wheel 8 is used for tensioning the steel strip 7 to ensure that the steel strip 7 is attached to the crystallization wheel 4, and the guide wheel 6 is used for guiding the steel strip 7. Through the arrangement of the structure, the casting process is automated, and the working efficiency is improved.

Wherein the shape of the channel can form a trapezoidal groove, a square groove or a semi-cylindrical groove according to the requirement of subsequent rolling.

The crystallization wheel 4 is detachably connected with the output end of the rotation driving motor and can rotate coaxially with the output end along with the driving of the rotation driving motor.

For one or more embodiments, a pneumatic rotating mechanism is arranged on the machine body 1, the output end of the pneumatic rotating mechanism is connected with the rotating shaft of the extrusion wheel through an extrusion rod, and the extrusion wheel can rotate under the driving of the pneumatic rotating mechanism by taking the output end as an axis and has a tendency of closing to the surface of the 4 wheels of the crystallization wheel.

In the scheme: the extrusion wheel moves on the machine body 1 through the pneumatic rotating mechanism and is driven by the pneumatic rotating mechanism to have a tendency of closing towards the wheel surface of the crystallization wheel 4, so that the extrusion wheel is ensured to have a function of enabling the steel strip 7 at the inlet end to be close to the crystallization wheel 4, and meanwhile, the extrusion wheel capable of moving can vacate a space for replacing the crystallization wheel 4. Through changing different crystallization wheel 4, can satisfy the demand of different follow-up rolling processes, have the flexibility, can change crystallization wheel 4 according to self demand.

For one or more embodiments, a pneumatic telescoping mechanism is connected to the rotating shaft of the tension wheel 8, and an output end of the pneumatic telescoping mechanism can drive the tension wheel 8 to move and make the tension wheel 8 have a tendency to move away from the crystallization wheel 4.

In the scheme: the output end of the pneumatic telescopic mechanism drives the tensioning wheel 8 to extrude towards the direction far away from the crystallization wheel 4, so that the whole steel belt 7 is driven to be tightened, the whole steel belt 7 is ensured to be tightly attached to the partial surface comprising the crystallization wheel 4, the extrusion wheel, the guide wheel 6 and the tensioning wheel 8 in the operation process, and further the stable operation of the whole device is ensured, and on the basis of the mode, when the crystallization wheels 4 with different diameters are replaced, the steel belt 7 can be ensured to be attached without influencing the operation of the whole device.

For one or more embodiments, the cooling device 10 includes an inner cooling device, an outer cooling device, and two side cooling devices, the inner cooling device is disposed on one side of the groove bottom of the groove of the crystallization wheel 4 away from the mold cavity, the outer cooling device is disposed on one side of the steel strip 7 on the crystallization wheel 4 away from the mold cavity, the side cooling devices are respectively disposed on two sides of the side wall of the groove bottom away from the mold cavity, and a plurality of nozzles pointing to the mold cavity are disposed on the inner cooling device, the outer cooling device, and the two side cooling devices.

In the scheme: the groove bottom is one side of the groove channel close to the axis of the crystallization wheel 4. Cooling device 10 including distribute in die cavity internal cooling device all around, outer cold charge and two side cold charge, through the liquid metal of internal cooling device, outer cold charge and two side cold charge carry out the omnidirectional cooling to the die cavity, improve the cooling effect of liquid metal, ensure that the metal ingot quality of crystallization out is more stable, can not produce hollow, sugar core scheduling problem.

It should be noted that the cooling liquid sprayed from the nozzles arranged on the inner cooling device, the outer cooling device and the two side cooling devices can not be directly sprayed to the inlet end or the outlet end of the die cavity but can be sprayed to the crystallizing wheel 4 and the steel strip 7 which form the die cavity, and the wheel surface of the crystallizing wheel 4 and the steel strip 7 are indirectly cooled, so that the cooling liquid is prevented from contacting with the liquid metal to cause small-scale explosion, potential safety hazards and influence on the product quality

Wherein the crystallization wheel 4 can be provided with an annular groove for placing an inner cooling device on the end surface.

Further, for one or more embodiments, the inner cooling device, the outer cooling device, and both side cooling devices are provided with an arc portion matching the mold cavity, and the nozzles are uniformly distributed on the arc portion.

In this scheme, interior cold charge, outer cold charge and two side cold charges all are equipped with the matching the arc portion of die cavity, the nozzle evenly distributed is in on the arc portion. Through the setting of segmental arc, ensure that the nozzle that sets up respectively on interior cold charge, outer cold charge and two side cold charge with the interval of cavity is unanimous, and liquid distribution is even when guaranteeing to spray the die cavity, and then ensures further promotion cooling effect's stability.

The circle centers of the overall arcs of the arc parts of the inner cooling device and the outer cooling device are superposed with the circle center of the crystallization wheel 4, and the shadows of the arc parts of the two side cooling devices projected on the end surface of the crystallization wheel 4 cover the shadows of the channel projected on the end surface of the crystallization wheel 4.

To one or more embodiments, the stripper shoe 5 includes length-adjustable connecting rod and with the demoulding portion that connecting rod one end is connected, the demoulding portion stretches into the channel, the demoulding portion is including the guide that can laminate the channel tank bottom, the guide include with the binding face of tank bottom laminating and keeping away from the guide face of tank bottom, the binding face with the guide face is crossing and is formed the closed angle that is used for the perk metal.

In the scheme: after being cooled by the cooling device 10, the liquid metal forms a metal ingot with a still higher temperature, when the metal ingot is output from the outlet end, the joint part of the bottom surface of the metal ingot and the groove bottom of the groove channel is inserted by the sharp corner on the demoulding part, at the moment, the bottom surface of the metal ingot and the groove bottom are separated from the joint state, because the metal ingot still has a certain temperature and has stronger ductility, under the drive of the crystallization wheel 4, the metal ingot is separated from the groove channel and output to the approach bridge 3 along the guide surface, and therefore the casting of the metal is completed. In this process, the contained angle needs the laminating at the tank bottom of channel, consequently, sets up length-adjustable's connecting rod, through the position of demoulding portion is adjusted to the connecting rod, ensures to make the work of breaking away from of ingot and channel tank bottom can both be accomplished under the crystallization wheel 4 of different diameters, has more the flexibility.

Further, for one or more embodiments, the output end of the access bridge 3 is disposed in the extending direction of the guide surface, the access bridge 3 includes two parallel side plates, and belt wheels for driving the metal to move are uniformly laid between the side plates.

In the scheme: the approach bridge 3 is used for receiving the metal ingots led out from the guide part, side plates arranged on the approach bridge are used for preventing the metal ingots from deviating from the track in the moving process, and the belt wheel is used for transporting the metal ingots and preventing the metal ingots from being dragged to influence the quality of output products.

For one or more embodiments, a dewatering device 12 for removing liquid on the steel belt 7 and a drying device 13 for further drying the liquid are further sequentially arranged on the moving path of the steel belt 7.

In the scheme: due to the use of the cooling device 10, the steel strip 7 is provided with liquid during the process of bypassing, so as to avoid direct contact between the liquid and the liquid metal, cause small-scale burning explosion, cause potential safety hazard and influence on product quality, therefore, a dewatering device 12 and a drying device 13 are arranged on the moving path of the steel strip 7, and are used for removing moisture on the steel strip 7 and drying, thereby protecting safety and ensuring product quality.

For one or more embodiments, a catch wheel 9 for supporting the steel belt 7 is further provided on the moving path of the steel belt 7.

In the scheme: in addition, because some long parts of the steel belt 7 may be suspended in the device, and the influence of gravity on the suspended steel belt 7 may interfere with the tensioning function of the tensioning wheel 8, the supporting and blocking wheel 9 is arranged on the part of the steel belt 7 for supporting the part of the steel belt 7, so that the overall tensioning degree of the steel belt 7 is improved, and the stable operation of the device is ensured, in addition, because the steel belt 7 needs to be replaced sometimes when the device is maintained, the supporting and blocking wheel 9 can also support the steel belt 7 stably to a certain extent when the steel belt 7 is replaced, so that the replacement of the steel belt 7 is facilitated.

The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above description is only the embodiments of the present invention, and is not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (9)

1. The casting machine is characterized by comprising a machine body (1), wherein a crystallization wheel (4) is arranged on the machine body (1), the wheel surface of the crystallization wheel (4) is provided with an annular channel, the crystallization wheel (4) is provided with a steel belt (7) attached to part of the wheel surface of the crystallization wheel (4), said steel strip (7) cooperating with said channel to form a mould cavity, the inlet end of said mould cavity being provided with an extrusion wheel for bringing said steel strip (7) at said inlet end into abutment with the crystallisation wheel (4) and a ladle (11) for injecting liquid metal into the inlet end, the periphery of the mould cavity is provided with a cooling device (10) for cooling liquid metal, the outlet end of the mould cavity is provided with a stripper shoe (5) for stripping the cooled metal from the channel and an approach bridge (3) for receiving the stripped metal, and a tension wheel (8) and a plurality of guide wheels (6) are also arranged on the moving path of the steel belt (7).

2. The casting machine according to claim 1, characterized in that a pneumatic rotating mechanism is arranged on the machine body (1), an output end of the pneumatic rotating mechanism is connected with a rotating shaft of the extrusion wheel through an extrusion rod, and the extrusion wheel can rotate by taking the output end as an axis under the driving of the pneumatic rotating mechanism and has a tendency of closing to the wheel surface of the crystallization wheel (4).

3. A casting machine according to claim 1, characterized in that a pneumatic telescopic mechanism is connected to the rotating shaft of the tension wheel (8), and the output end of the pneumatic telescopic mechanism can drive the tension wheel (8) to move and make the tension wheel (8) have a tendency to move away from the crystallization wheel (4).

4. A casting machine according to claim 1, characterized in that the cooling device (10) comprises an inner cooling device, an outer cooling device and two side cooling devices, the inner cooling device is arranged at one side of the bottom of the channel of the crystallization wheel (4) far away from the mold cavity, the outer cooling device is arranged at one side of the steel strip (7) on the crystallization wheel (4) far away from the mold cavity, the side cooling devices are respectively arranged at two sides of the side wall of the channel far away from the mold cavity, and a plurality of nozzles pointing to the mold cavity are arranged on the inner cooling device, the outer cooling device and the two side cooling devices.

5. A casting machine according to claim 4, characterized in that the inner cooling device, the outer cooling device and both side cooling devices are provided with an arc-shaped portion matching the mold cavity, the nozzles being evenly distributed over the arc-shaped portion.

6. A casting machine according to claim 1, characterized in that the stripper shoe (5) comprises a length-adjustable connecting rod and a stripper part connected with one end of the connecting rod, which stripper part extends into the channel, which stripper part comprises a guide that can abut the bottom of the channel, which guide comprises an abutment surface that abuts the bottom of the channel and a guide surface that is remote from the bottom of the channel, which abutment surface intersects the guide surface and forms a sharp angle for tilting the metal.

7. A casting machine according to claim 6, characterized in that the output end of the approach bridge (3) is arranged in the extension direction of the guide surface, the approach bridge (3) comprising two parallel side plates between which belt pulleys for moving the metal are evenly laid.

8. A casting machine according to claim 1, characterized in that the moving path of the steel strip (7) is further provided with a dewatering device (12) for removing liquid from the steel strip (7) and a drying device (13) for further drying the liquid.

9. A casting machine according to claim 1, characterized in that the movement path of the steel strip (7) is also provided with a catch wheel (9) for supporting the steel strip (7).

Images