CN112775419B

CN112775419B - Rotation type casting machine is used in foundry goods processing

Info

Publication number: CN112775419B
Application number: CN202011546355.2A
Authority: CN
Inventors: 崔华波
Original assignee: Linyi Kaishibi Machinery Co ltd
Current assignee: Linyi Kaishibi Machinery Co ltd
Priority date: 2020-12-24
Filing date: 2020-12-24
Publication date: 2022-04-22
Anticipated expiration: 2040-12-24
Also published as: CN112775419A

Abstract

The invention relates to the technical field of casting processing, and discloses a rotary casting machine for casting processing, which comprises a base, a liquid injection column, a mechanical arm, a box body, a rotary disc, a mold, a clamping component and a buffer component, wherein the top end of the base is fixedly connected with the liquid injection column, the box body is positioned on the left side of the liquid injection column and fixedly connected with the top end of the base, the top end of the inner wall of the box body is movably connected with the rotary disc, the top end of the inner wall of the rotary disc is movably connected with the mold, the inner wall of the rotary disc is movably connected with the buffer component, the left side of the rotary disc is movably connected with the clamping component, a driving motor is arranged in the rotary disc, and the rotary disc is driven to rotate when the driving motor operates; this rotation type casting machine for foundry goods processing is than traditional manual casting, and is accurate and difficult for producing during the pouring and melts the phenomenon that the metal splashes, and the mould can not produce great rocking in the initial stage that rises to let the mould inside melt the metal and can not produce the phenomenon of splashing.

Description

Rotation type casting machine is used in foundry goods processing

Technical Field

The invention relates to the technical field of casting processing, in particular to a rotary casting machine for casting processing.

Background

The pouring is a modern production process for injecting molten metal and other molten liquid into a mold and then casting metal parts, most of the existing pouring modes are that workers clamp a container filled with the molten metal by using tools, then move the container to the mold, pour the container and pour the molten metal stored in the container into the mold, the pouring mode is dangerous to the personal safety of the workers, when the molten metal is poured into the mold, the mold is placed on iron sand, under most conditions, the mold is not in a vertical state, the molten metal is easy to splash and leak, due to the fact that the mass of the metal is large, and due to the weight of the container, the workers cannot pour the molten metal into the mold accurately when pouring the molten metal by using the self-force, the molten metal is wasted greatly, and after the pouring is completed, the rotary casting machine for casting has the advantages that a large amount of metal is remained at the casting opening of the mold, and the metal is easy to adhere to the outside of the mold after being cooled and formed, so that the demolding is difficult, and therefore the rotary casting machine for casting is capable of preventing the mold from shaking and stably clamping.

Disclosure of Invention

In order to realize the purposes of preventing the mold from shaking and stably clamping, the invention provides the following technical scheme: the utility model provides a rotation type casting machine is used in foundry goods processing, includes base, notes liquid post, arm, box, gyration disc, mould, centre gripping subassembly and buffer unit, the base top with annotate liquid post fixed connection, the box is located notes liquid post left side and base top fixed connection, box inner wall top and gyration disc swing joint, gyration disc inner wall top and mould swing joint, gyration disc inner wall and buffer unit swing joint, gyration disc left side and centre gripping subassembly swing joint, the gyration disc embeds there is driving motor, and the driving motor area is turned round the disc when moving and is rotated.

Preferably, the clamping assembly comprises a first magnetic block, a baffle, a second magnetic block, a first spring pull rod, a guide rod, a rotary sleeve block, a fixed inner block, a chute, a roller, an arc-shaped clamping block and a cross rod, the first magnetic block is slidably connected with the left side of the inner wall of the box body, the baffle is positioned on the right side of the first magnetic block and fixedly connected with the inner wall of the box body, the second magnetic block is positioned on the right side of the first magnetic block and slidably connected with the inner wall of the rotary disc, the top end of the second magnetic block is fixedly connected with the first spring pull rod, the right side of the first spring pull rod is fixedly connected with the inner wall of the rotary disc, the right side of the second magnetic block is rotatably connected with the guide rod, the right side of the guide rod is rotatably connected with the rotary sleeve block, the back of the rotary sleeve block is rotatably connected with the rotary disc, the chute is arranged on the inner wall of the rotary sleeve block, the inner wall of the chute is slidably connected with the roller, and the right side of the cross rod is fixedly connected with the cross rod, the die comprises a cross rod, a spring push rod, a rotary disc, a clamping assembly and a clamping assembly, wherein the right side of the cross rod is fixedly connected with the arc-shaped clamping block, the left side of the spring push rod is fixedly connected with a fixed inner block, the right side of the spring push rod is fixedly connected with the arc-shaped clamping block, the back of the fixed inner block is fixedly connected with the rotary disc, the clamping assembly clamps a die, and the stability of the motion of the die is kept as much as possible when the die rotates along with the rotary disc.

As optimization, the buffer assembly comprises a circular cavity, a circular baffle plate, a sliding rod, a compression spring, an ejector block, a fixed block, a second spring pull rod, a magnetic column, an ejector head, a torsional spring and an insertion rod, wherein the circular cavity is arranged on the inner wall of the rotary disc, the top end of the circular baffle plate is fixedly connected with the sliding rod, the compression spring is fixedly connected with the right side of the inner wall of the sliding rod, the right side of the compression spring is fixedly connected with the ejector block, the outer wall of the ejector block is slidably connected with the inner wall of the sliding rod, the top end of the second spring pull rod is fixedly connected with the inner wall of the fixed block, the bottom end of the second spring pull rod is fixedly connected with the magnetic column, the outer wall of the magnetic column is slidably connected with the inner wall of the fixed block, the left side of the magnetic column is fixedly connected with the ejector head, the torsional spring is positioned on the right side of the magnetic column and fixedly connected with the inner wall of the rotary disc, the bottom end of the insertion rod is fixedly connected with the insertion rod, and the top end of the fixed block is fixedly connected with the mold, the mechanical arm clamping die drives the fixing block to ascend when ascending.

Preferably, the number of the first spring pull rods is two, the first spring pull rods are symmetrically arranged about the horizontal center line of the second magnetic block, and the second magnetic block always keeps a rightward movement trend before being close to the first magnetic block by the first spring pull rods.

Preferably, the number of the spring push rods and the four auxiliary assemblies thereof is four, the four spring push rods and the four auxiliary assemblies thereof are arranged in an annular array relative to a central point of the fixed inner block, the cross rods are positioned inside the spring push rods and fixedly connected with the arc-shaped clamping blocks, and acting force is simultaneously applied to the die through the four arc-shaped clamping blocks, so that the die is clamped.

Preferably, twelve fixed inner blocks and twelve auxiliary assemblies are arranged in an annular array about the center point of the rotary disk, so that twelve molds can be simultaneously carried on the rotary disk.

Preferably, the number of the second spring pull rods and the auxiliary assemblies thereof is two, the second spring pull rods and the auxiliary assemblies thereof are symmetrically arranged about the vertical center line of the slide rod, and when the die is placed on the rotary disc, the fixed block and the slide rod are connected together through the two ejection heads and the auxiliary assemblies thereof.

Preferably, the two sliding rods and the auxiliary assemblies thereof are symmetrically arranged about the vertical center line of the circular baffle plate, so that the sliding rods drive the circular baffle plate to stably rise.

Preferably, the circular baffle is located in the circular cavity, damping liquid is filled in the circular cavity, the inner wall of the rotary disc is located above the circular baffle and fixedly provided with a heat insulation plate, the inner wall of the heat insulation plate is connected with the sliding rod in a sliding mode, and the sliding rod stably ascends due to the fact that the circular baffle is matched with the damping liquid.

The invention has the beneficial effects that: the first magnetic block attracts the second magnetic block to drive the guide rod to move, the guide rod drives the rotary sleeve block to rotate anticlockwise, the rotary sleeve block drives the arc-shaped clamping block to no longer clamp the mold through the cooperation of the chute and the roller, then the mechanical arm is used for replacing the mold, the mold is stably clamped during movement, the mold is simple and convenient to replace, molten metal stored in the liquid injection column is poured into the mold through the liquid outlet on the left side, the opening and closing of the mold are controlled by the electromagnetic valve, compared with the traditional manual pouring, the rotary pouring machine for casting processing is used for pouring the mold through the liquid injection column, the mechanical arm is used for replacing the mold, the phenomenon that the molten metal splashes is accurately and difficultly generated during pouring, the mold is clamped through the clamping assembly, the clamping is stable, the mechanical arm is convenient to take, and the circular resistance plate moves in damping liquid at the initial stage of upward movement of the mechanical arm clamping the mold, through the deceleration effect of the damping liquid on the circular baffle plate, the die cannot generate large shaking in the initial rising stage, and the phenomenon of splashing cannot be generated when metal is melted in the die.

Drawings

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

FIG. 2 is a schematic top view of a rotating disk according to the present invention;

FIG. 3 is a schematic view of a clamping assembly according to the present invention;

FIG. 4 is an enlarged view of the structure at A in FIG. 3 according to the present invention;

FIG. 5 is a schematic view of a front view of a rotating disk in partial cross-section according to the present invention;

FIG. 6 is an enlarged view of the structure at B in FIG. 5 according to the present invention;

FIG. 7 is an enlarged view of the structure at C in FIG. 5 according to the present invention.

In the figure: 100. a base; 200. injecting a liquid column; 300. a mechanical arm; 400. a box body; 500. a rotating disk; 600. a mold; 700. a clamping assembly; 701. a first magnetic block; 702. a baffle plate; 703. a second magnetic block; 704. a first spring pull rod; 705. a guide bar; 706. a rotary sleeve block; 707. fixing the inner block; 708. a chute; 709. a roller; 710. an arc-shaped clamping block; 711. a cross bar; 712. a spring push rod; 800. a buffer assembly; 801. a circular lumen; 802. a circular baffle plate; 803. a slide bar; 804. a compression spring; 805. a top block; 806. a fixed block; 807. a second spring pull rod; 808. a magnetic column; 809. ejecting the head; 810. a torsion spring; 811. and (4) inserting the rod.

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.

Referring to fig. 1-7, a rotary casting machine for casting processing comprises a base 100, a liquid injection column 200, a mechanical arm 300, a box 400, a rotary disk 500, a mold 600, a clamping assembly 700 and a buffer assembly 800, wherein the top end of the base 100 is fixedly connected with the liquid injection column 200, the box 400 is positioned at the left side of the liquid injection column 200 and is fixedly connected with the top end of the base 100, the top end of the inner wall of the box 400 is movably connected with the rotary disk 500, the top end of the inner wall of the rotary disk 500 is movably connected with the mold 600, the inner wall of the rotary disk 500 is movably connected with the buffer assembly 800, the left side of the rotary disk 500 is movably connected with the clamping assembly 700, a driving motor is arranged in the rotary disk 500, according to fig. 1, the driving motor drives the rotary disk 500 to rotate when the driving motor operates, when the mechanical arm 300 clamps the mold 600 to enable the mold to rise, a great instantaneous acceleration is generated, therefore, molten metal in the mold 600 can shake, most part is offset with the pulling force that this instantaneous acceleration produced to buffering subassembly 800 for mould 600 steadily rises, according to fig. 1, has stored at annotating liquid post 200 inside and has melted the metal, and annotates liquid post 200 left side and be provided with the liquid outlet, and the liquid outlet top is provided with its break-make of solenoid valve control.

Referring to fig. 1-7, the clamping assembly 700 comprises a first magnetic block 701, a baffle plate 702, a second magnetic block 703, a first spring rod 704, a guide rod 705, a rotary sleeve block 706, a fixed inner block 707, a chute 708, a roller 709, an arc-shaped clamping block 710 and a cross bar 711, wherein the first magnetic block 701 is slidably connected with the left side of the inner wall of the box 400, the baffle plate 702 is positioned at the right side of the first magnetic block 701 and fixedly connected with the inner wall of the box 400, the second magnetic block 703 is positioned at the right side of the first magnetic block 701 and slidably connected with the inner wall of the rotary disk 500, the top end of the second magnetic block 703 is fixedly connected with the first spring rod 704, the right side of the first spring rod 704 is fixedly connected with the inner wall of the rotary disk 500, the right side of the second magnetic block 703 is rotatably connected with the guide rod 705, the right side of the guide rod 705 is rotatably connected with the rotary sleeve block 706, the back of the rotary sleeve block 706 is rotatably connected with the rotary disk 500, the chute 708 is opened at the inner wall of the rotary sleeve block 706 and slidably connected with the roller 709, the right side of the roller 709 is fixedly connected with a cross rod 711, the right side of the cross rod 711 is fixedly connected with an arc-shaped clamping block 710, the left side of a spring push rod 712 is fixedly connected with an inner fixed block 707, the right side of the spring push rod 712 is fixedly connected with the arc-shaped clamping block 710, the back side of the inner fixed block 707 is fixedly connected with a rotary disc 500, according to fig. 4, the spring push rod 712 drives the arc-shaped clamping block 710 to exert an acting force on the mold 600 so as to clamp the mold 600, according to fig. 2, when the rotary disc 500 drives the clamping assembly 700 to move right below the mechanical arm 300 during operation, according to fig. 3, the first magnetic block 701 and the second magnetic block 703 are mutually attracted, so that the second magnetic block 703 overcomes the pulling force of the first spring pull rod 704 to be in contact with the first magnetic block 701, and the guide rod 705 drives the rotary sleeve block 706 to rotate so that the clamping force of the arc-shaped clamping block 710 on the mold 600 disappears.

Referring to fig. 1-7, the buffering assembly 800 comprises a circular cavity 801, a circular baffle 802, a sliding rod 803, a compression spring 804, a top block 805, a fixed block 806, a second spring pull rod 807, a magnetic column 808, a top 809, a torsion spring 810 and an insertion rod 811, the circular cavity 801 is arranged on the inner wall of the rotary disk 500, the top end of the circular baffle 802 is fixedly connected with the sliding rod 803, the compression spring 804 is fixedly connected with the right side of the inner wall of the sliding rod 803, the right side of the compression spring 804 is fixedly connected with the top block 805, the outer wall of the top block 805 is slidably connected with the inner wall of the sliding rod 803, the top end of the second spring pull rod 807 is fixedly connected with the inner wall of the fixed block 806, the bottom end of the second spring pull rod 807 is fixedly connected with the magnetic column 808, the outer wall of the magnetic column 808 is slidably connected with the inner wall of the fixed block 806, the left side of the magnetic column 808 is fixedly connected with the top 809, the torsion spring 810 is located on the right side of the magnetic column 808 and fixedly connected with the inner wall of the rotary disk 500, the bottom end of the torsion spring 810 is fixedly connected with the insertion rod 811, the top end of the fixed block 806 is fixedly connected with the mold 600, according to fig. 1, the mechanical arm 300 clamps the mold 600 and brings the fixed block 806 to ascend, according to fig. 7, the insertion rod 811 keeps a clockwise rotation movement trend all the time due to the action of the torsion spring 810, according to fig. 7, the sliding rod 803 is specifically a magnetic rod and attracts the magnetic column 808, when the fixed block 806 brings the sliding rod 803 to move upwards, and when the contact point of the magnetic column 808 and the sliding rod 803 moves to the insertion rod 811, the insertion rod 811 separates the magnetic column 808 from the sliding rod 803.

Referring to fig. 3-7, two first spring rods 704 are symmetrically disposed about the horizontal center line of the second magnetic block 703, and according to fig. 3, the second magnetic block 703 always keeps a rightward movement trend before the second magnetic block 703 approaches the first magnetic block 701 by the first spring rods 704, and the second magnetic block 703 always keeps a clockwise movement trend by the acting force applied to the guide rod 705.

Referring to fig. 3-7, four spring push rods 712 and their accessories are arranged in a circular array with respect to the center point of the fixed inner block 707, a cross bar 711 is located inside the spring push rods 712 and is fixedly connected with the arc-shaped clamping blocks 710, according to fig. 3, the mold 600 is clamped by applying force to the mold 600 through the four arc-shaped clamping blocks 710 simultaneously, according to fig. 3, when the first magnetic block 701 and the second magnetic block 703 are close to each other, the second magnetic block 703 moves leftwards and drives the guide bar 705 to move, so that the rotating sleeve block 706 rotates anticlockwise, and the arc-shaped clamping blocks 710 no longer clamp the mold 600.

Referring to fig. 2-7, twelve fixed inner blocks 707 and their associated components are arranged in a circular array about a center point of the rotatable disk 500, and twelve molds 600 may be simultaneously carried on the rotatable disk 500 according to fig. 2.

Referring to fig. 5-7, there are two second spring rods 807 and their accessories, and they are symmetrically arranged about the vertical center line of the sliding rod 803, when the mold 600 is placed on the rotary disk 500, the fixed block 806 and the sliding rod 803 are connected together by two heads 809 and their accessories, according to fig. 7, after the magnetic column 808 and the sliding rod 803 are no longer in contact, the second spring rods 807 operate to drive the magnetic column 808 upward, so that the magnetic column 808 drives the heads 809, and the heads 809 press the top blocks 805 to move toward the vertical center line of the sliding rod 803 against the elastic force of the compression springs 804, so that the fixed block 806 and the sliding rod 803 are separated.

Referring to fig. 5-7, two slide rods 803 and their attachments are symmetrically disposed about the vertical center line of the circular baffle 802. according to fig. 5, damping fluid surrounds the circular baffle 802 inside the circular cavity 801, so that the slide rods 803 stably lift the circular baffle 802.

Referring to fig. 5-7, the circular baffle 802 is located in the circular cavity 801, and the damping fluid is filled in the circular cavity 801, the thermal insulation board is fixedly installed on the inner wall of the rotary disk 500 above the circular baffle 802, the inner wall of the thermal insulation board is connected with the sliding rod 803 in a sliding manner, according to fig. 5, the circular baffle 802, the damping fluid and the sliding rod 803 are used in cooperation, so that the mechanical arm 300 can stably move at the initial stage of the lifting of the clamping mold 600 without generating large shaking.

In use, referring to fig. 1-7, when the rotating disc 500 is driven to rotate by the built-in motor of the rotating disc 500, the rotating disc 500 drives the clamping assembly 700 to rotate, when twelve rotating blocks 706 and their accessories move to the position under the liquid injection column 200, the rotating blocks 706 and their accessories stay still, then the liquid injection column 200 pours the liquid injection column, at this time, another rotating block 706 and its accessories, which are symmetrical relative to the vertical center line of the box 400, stay under the mechanical arm 300, at this time, the first magnetic block 701 and the second magnetic block 703 attract each other, so that the second magnetic block 703 moves to the left against the pulling force of the first spring pull rod 704, the second magnetic block drives the guide rod 705 to move, the rotating block 706 rotates counterclockwise, the roller 709 moves in the chute 708, the roller 709 drives the cross rod 711 to move to the left, the cross rod 711 drives the arc-shaped clamping block 710 to move to the left against the pushing force of the spring push rod 712, the acting force of the arc-shaped clamping block 710 on the mold 600 disappears, the mold 600 is not clamped any more, then the mechanical arm 300 clamps the cast mold 600 and changes the mold 600 into an empty mold 600, the liquid injection column 200 is cast at this time, the rotary disc 500 continues to rotate clockwise to drive the clamping assembly 700 to move, the second magnetic block 703 moves transversely relative to the first magnetic block 701, the first magnetic block 701 and the second magnetic block 703 are separated through the baffle 702, the first spring pull rod 704 drives the second magnetic block 703 to move rightwards, the spring push rod 712 drives the arc-shaped clamping block 710 to clamp the mold 600 again, the mechanical arm 300 changes the mold 600, when the mechanical arm 300 clamps the mold 600 and moves upwards, the mold 600 drives the fixed block 806 to move upwards, the fixed block 806 drives the slide rod 803 to move upwards, when the contact part of the magnetic column 808 and the slide rod 803 moves to the bottom end of the insert rod 811, the insert rod 811 separates the magnetic column 808 and the slide rod 803 through the action of the torsion spring 810, at this time, the second spring pull rod 807 drives the magnetic column 808 to move upwards, the magnetic column 808 drives the ejector 809 to move, the ejector 809 presses the ejector 805 to move towards the vertical center line of the slide rod 803 against the thrust of the compression spring 804, so that the fixed block 806 is separated from the slide rod 803, at the initial stage of the movement of the mold 600 with the slide rod 803 driven by the fixed block 806, the slide rod 803 drives the circular baffle plate 802 to move, the circular baffle plate 802 moves in the damping fluid, the kinetic energy of the movement of the circular baffle plate 802 and the mold 600 is attenuated through the deceleration effect of the damping fluid on the circular baffle plate 802, so that the shaking phenomenon is reduced, and then when the mechanical arm 300 places the empty mold 600 on the rotary disk 500, the fixed block 806 is inserted with the slide rod 803 again, and drives the circular baffle plate 802 to move to the bottom end of the circular cavity 801.

To sum up, the first magnetic block 701 attracts the second magnetic block 703 to drive the guide rod 705 to move, the guide rod 705 drives the rotary sleeve block 706 to rotate counterclockwise, the rotary sleeve block 706 drives the arc-shaped clamping block 710 to no longer clamp the mold 600 through the matching use of the chute 708 and the roller 709, then the robot 300 replaces the rotary sleeve block, so that the mold 600 is stably clamped during the movement, the mold 600 is replaced simply and conveniently, the molten metal stored in the liquid injection column 200 is poured into the mold 600 through the liquid outlet at the left side, and the on-off of the molten metal is controlled by the solenoid valve, compared with the traditional manual pouring machine, the rotary pouring machine for casting is characterized in that the liquid injection column 200 is used for pouring the mold 600, the robot 300 is used for replacing the mold 600, so that the phenomenon of molten metal splashing is accurately and difficultly generated during the pouring, and the mold 600 is clamped by the clamping assembly 700, the clamping is stable and convenient for the robot 300 to take, at the initial stage when the mechanical arm 300 clamps the mold 600 to move upwards, the circular baffle 802 moves in the damping fluid, and the damping fluid decelerates the circular baffle 802, so that the mold 600 does not shake greatly at the initial stage of rising, and the molten metal in the mold 600 does not splash.

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 able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims

1. The utility model provides a rotation type casting machine is used in foundry goods processing, includes base (100), annotates liquid post (200), arm (300), box (400), gyration disc (500), mould (600), centre gripping subassembly (700) and buffering subassembly (800), its characterized in that: the top end of the base (100) is fixedly connected with the liquid injection column (200), the box body (400) is positioned on the left side of the liquid injection column (200) and is fixedly connected with the top end of the base (100), the top end of the inner wall of the box body (400) is movably connected with the rotary disc (500), the top end of the inner wall of the rotary disc (500) is movably connected with the mold (600), the inner wall of the rotary disc (500) is movably connected with the buffer assembly (800), and the left side of the rotary disc (500) is movably connected with the clamping assembly (700);

the buffer assembly (800) consists of a circular cavity (801), a circular baffle plate (802), a sliding rod (803), a compression spring (804), a top block (805), a fixed block (806), a second spring pull rod (807), a magnetic column (808), a top head (809), a torsion spring (810) and an insertion rod (811), wherein the circular cavity (801) is arranged on the inner wall of the rotary disc (500), the top end of the circular baffle plate (802) is fixedly connected with the sliding rod (803), the compression spring (804) is fixedly connected with the right side of the inner wall of the sliding rod (803), the right side of the compression spring (804) is fixedly connected with the top block (805), the outer wall of the top block (805) is slidably connected with the inner wall of the sliding rod (803), the top end of the second spring pull rod (807) is fixedly connected with the inner wall of the fixed block (806), the bottom end of the second spring pull rod (807) is fixedly connected with the magnetic column (808), and the outer wall of the magnetic column (808) is slidably connected with the inner wall of the fixed block (806), the left side of the magnetic column (808) is fixedly connected with the top (809), the torsion spring (810) is positioned on the right side of the magnetic column (808) and is fixedly connected with the inner wall of the rotary disc (500), and the bottom end of the torsion spring (810) is fixedly connected with the inserted link (811);

the number of the second spring pull rods (807) and the auxiliary components thereof is two, and the second spring pull rods and the auxiliary components are symmetrically arranged about the vertical center line of the sliding rod (803);

the number of the sliding rods (803) and the auxiliary components thereof is two, and the sliding rods and the auxiliary components are symmetrically arranged about the vertical center line of the circular baffle plate (802);

circular resistance board (802) are located circular chamber (801), and circular chamber (801) are inside to be filled with damping fluid, gyration disc (500) inner wall is located circular resistance board (802) top fixed mounting has the heat insulating board, heat insulating board inner wall and slide bar (803) sliding connection.

2. The rotary casting machine for machining castings according to claim 1, wherein: the clamping assembly (700) is composed of a first magnetic block (701), a baffle plate (702), a second magnetic block (703), a first spring pull rod (704), a guide rod (705), a rotary sleeve block (706), a fixed inner block (707), a chute (708), a roller (709), an arc-shaped clamping block (710) and a cross rod (711), wherein the first magnetic block (701) is in sliding connection with the left side of the inner wall of the box body (400), the baffle plate (702) is positioned at the right side of the first magnetic block (701) and is fixedly connected with the inner wall of the box body (400), the second magnetic block (703) is positioned at the right side of the first magnetic block (701) and is in sliding connection with the inner wall of the rotary disc (500), the top end of the second magnetic block (703) is fixedly connected with the first spring pull rod (704), the right side of the first spring pull rod (704) is fixedly connected with the inner wall of the rotary disc (500), and the right side of the second magnetic block (703) is rotatably connected with the guide rod (705), guide arm (705) right side and gyration cover block (706) rotate to be connected, gyration cover block (706) back rotates with gyration disc (500) to be connected, chute (708) are seted up at gyration cover block (706) inner wall, chute (708) inner wall and gyro wheel (709) sliding connection, gyro wheel (709) right side and horizontal pole (711) fixed connection, horizontal pole (711) right side and arc clamp splice (710) fixed connection, spring push rod (712) left side and fixed interior piece (707) fixed connection, spring push rod (712) right side and arc clamp splice (710) fixed connection, fixed interior piece (707) back and gyration disc (500) fixed connection.

3. The rotary casting machine for machining castings according to claim 2, wherein: the number of the first spring pull rods (704) is two, and the first spring pull rods are symmetrically arranged about the horizontal center line of the second magnetic block (703).

4. The rotary casting machine for machining castings according to claim 2, wherein: the four spring push rods (712) and the auxiliary components thereof are arranged in a circular array relative to the central point of the fixed inner block (707).

5. The rotary casting machine for machining castings according to claim 2, wherein: twelve of the fixed inner blocks (707) and their appurtenant components are arranged in an annular array about a center point of the rotatable disk (500).