CN210231520U

CN210231520U - Casting production equipment

Info

Publication number: CN210231520U
Application number: CN201921138591.3U
Authority: CN
Inventors: Deyu Huang; 黄德余; Xiaotao Shi; 史小涛
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-07-19
Filing date: 2019-07-19
Publication date: 2020-04-03
Anticipated expiration: 2029-07-19

Abstract

The utility model discloses a foundry goods production facility, include the pouring ladle and be located the frame of pouring ladle downside, the frame is the slope form, the frame includes two track boards that are parallel to each other, two the track board all includes two horizontal plates and two semicircle boards, two through a plurality of fixed plate fixed connection between the track board, and the fixed plate is located the inboard of two track boards, the bottom of frame is equipped with drive gear, drive gear is the biplate gear, drive gear's the external driving motor's in axle center drive end, two be equipped with a plurality of moulds jointly between the inside wall of track board. The automatic production equipment of the scheme can greatly improve the production efficiency, save the use amount of molten iron, reduce the production cost, greatly improve the density and hardness of the casting, effectively enhance the impact resistance and realize the full-automatic rapid production of the casting.

Description

Casting production equipment

Technical Field

The utility model relates to a foundry goods casting technical field especially relates to a metal casting production facility.

Background

The grinding casting is a grinding medium used with a grinding machine, can be divided into steel balls and steel sections according to shapes, is a consumable product for industrial production, is mainly used for grinding materials to enable the materials to be ground more finely so as to reach the use standard, is widely applied to industries such as mines, power plants, cement plants, steel plants, silica sand plants, coal chemical industry and the like, the consumption of the grinding casting is thousands of tons every year all over the world, more than half of the grinding casting is sold by China, China is also a large consumption country of grinding parts, and at present, the production and manufacturing of the grinding parts still adopt the traditional metal mold and sand mold manual pouring production process in the industry.

The casting equipment in the prior art mainly has the following defects: the casting equipment has the defects of complex structure, high maintenance cost, low automation degree, large equipment floor area, low production efficiency, high production cost, poor product quality and the like, so the improvement is needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing casting production equipment.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a casting production device comprises a pouring ladle and a rack positioned on the lower side of the pouring ladle, wherein the rack is inclined, the rack comprises two track plates which are parallel to each other, the two track plates respectively comprise two horizontal plates and two semicircular plates, the two track plates are fixedly connected through a plurality of fixing plates, the fixing plates are positioned on the inner sides of the two track plates, the bottom end of the rack is provided with a driving gear, the driving gear is a double-piece gear, the axis of the driving gear is externally connected with the driving end of a stepping driving motor, a plurality of dies are jointly arranged between the inner side walls of the two track plates, the upper side of the rack close to one side of the bottom end is provided with a dead head placing mechanism, the inner side of the rack is provided with two high-frequency micro-amplitude vibration mechanisms, and the two high-frequency micro-amplitude vibration mechanisms;

the bottom wall of each die is fixedly provided with a connecting plate by bolts, the middle part of each connecting plate is provided with a shaft pin, two ends of each shaft pin are provided with a first bearing, tooth grooves of the driving gear are meshed with two ends of the shaft pin, the side walls of two sides of each die are connected with shaft levers, one end of each shaft lever, which is far away from the die on the same side, is provided with a second bearing, the inner side of each track plate is provided with a first track groove and a second track groove, each shaft pin and each first bearing are connected in the first track groove in a sliding manner, and each shaft lever and each second bearing are connected in the second track groove in a sliding manner;

the top wall of each mould is provided with a flow guide groove, two sides of each mould are symmetrically provided with a plurality of sub-pouring cavities, each sub-pouring cavity is communicated with the flow guide groove, each sub-pouring cavity consists of a sub-riser groove and a sub-cavity which are communicated with each other, the sub-riser grooves are positioned at the upper sides of the sub-cavities, the sub-pouring cavities between two adjacent moulds are butted into a mother pouring cavity together, the sub-riser grooves between two adjacent moulds are butted into a mother riser groove together, and the sub-cavities between two adjacent moulds are butted into a mother cavity together;

the riser placing mechanism comprises a buckle plate erected on the top walls of two track plates, a plurality of riser storage pipes are installed at the top end of the buckle plate, a plurality of risers are placed inside each riser storage pipe, every two adjacent riser storage pipes are fixed through a mounting plate, the riser storage pipe located on the outermost side is fixed with the inner side wall of the buckle plate through the mounting plate, a stepping motor is installed on the inner side wall, a first driving wheel is installed at the driving end of the stepping motor, a vertical rotating rod is rotatably connected to the outer side wall of each riser storage pipe through a supporting rotating seat, a first rotating plate is installed at the top end of each vertical rotating rod, a second rotating plate is installed at the bottom end of each vertical rotating rod, the top end of each vertical rotating rod penetrates through the first rotating plate and is provided with a first driven wheel, and two adjacent first driven wheels are driven through a connecting belt, the first driving wheel and the first driven wheel are also driven by a connecting belt, the distance between the top wall of the second rotating plate and the bottom wall of the first rotating plate which are positioned on the same side is the same as the height of a riser, and each of the first rotating plate and the second rotating plate comprises a circular plate and two symmetrically-arranged annular plates;

two high frequency vibration mechanism of a little amplitude includes high-speed motor, two high-speed motor installs respectively on the interior roof of two track boards, every the second drive wheel is all installed to high-speed motor's drive end, two the downside of roof all is equipped with a plurality of seconds from driving wheel, every in the track board the second is rotated all from the axle center of driving wheel and is connected with two rotor plates, every the top of rotor plate is all fixed on the interior roof of corresponding track board, every equal symmetry is installed two balancing weights on the lateral wall of second follow driving wheel, is located every of homonymy the second is all through belt transmission from between driving wheel and the second drive wheel.

Preferably, the side wall of the fixing plate, which is located on one side of the top end of the rack, is symmetrically provided with two resistance elastic pieces, each resistance elastic piece is of an inverted-V-shaped structure, one end of each resistance elastic piece is fixed with the fixing plate through a bolt, and the two resistance elastic pieces are in contact with two ends of the shaft pin.

Preferably, the sidewall of the riser storage tube is respectively provided with an arc-shaped notch matched with the first rotating plate and the second rotating plate on the same side, and the first rotating plate and the second rotating plate are in contact with the riser through the corresponding arc-shaped notches.

Preferably, positioning pins are symmetrically arranged on the side wall of one side, close to the same side connecting plate, of each mold, positioning grooves are symmetrically formed in the side wall of the other side, close to the same side connecting plate, of each mold, connecting plates are symmetrically arranged on the side wall of one side, far away from the same side connecting plate, of each mold, connecting grooves are symmetrically formed in the side wall of the other side, far away from the same side connecting plate, of each mold, the positioning pins on one mold side wall are matched with the positioning grooves in the other mold side wall, and the connecting plates on one mold side wall are matched with the connecting grooves in the other mold side wall.

Preferably, the stepping driving motor, the stepping motor and the high-speed motor are externally connected with a PLC controller.

Compared with the prior art, the beneficial effects of the utility model reside in that:

1. a plurality of castings can be made simultaneously to a pair of mould in this scheme, very big improvement production efficiency, promote the utilization ratio of molten iron simultaneously, the molten iron is difficult for splashing outward and produces extravagantly, and then has reduced manufacturing cost.

2. Through setting up installation high frequency micro-amplitude vibrator, can flow into the die cavity when the molten iron, catch up out the bubble in the molten iron to very big improvement the density and the hardness of foundry goods, effectively strengthen the impact resistance and the abrasiveness of foundry goods.

3. The riser placing mechanism can be installed to automatically place risers before molten iron pouring, and therefore full-automatic production of casting equipment is achieved.

4. The casting equipment of this scheme adopts the mould of front and back branch mould form, and the structure of mould and concatenation mode are simple firm, safe and reliable, and manufacturing and cost of maintenance are low.

To sum up, the automated production equipment of this scheme, very big improvement production efficiency practices thrift the use amount of molten iron, reduction in production cost, very big improvement the density and the hardness of foundry goods, effectively strengthen impact resistance and grinding nature, can realize the full automatic rapid production of grinding foundry goods.

Drawings

Fig. 1 is a schematic view of the overall structure of a casting production apparatus according to the present invention;

FIG. 2 is a schematic sectional view A-A of a casting production apparatus according to the present invention;

FIG. 3 is a schematic cross-sectional view B-B of a casting production apparatus according to the present invention;

FIG. 4 is a schematic view of a C-C section of a casting production apparatus according to the present invention;

fig. 5 is a front view of the mold of the present invention;

FIG. 6 is a schematic view of the middle connection plate of the present invention;

FIG. 7 is a side view of a single mold of the present invention;

fig. 8 is a side view of the plurality of molds after being butted according to the present invention;

FIG. 9 is a top view of a single mold of the present invention;

fig. 10 is a top view of the multiple molds of the present invention after being butted;

fig. 11 is a diagram showing the positional relationship between the feeder head placement mechanism and the track plate according to the present invention;

FIG. 12 is a top view of the riser storage tube of FIG. 11;

FIG. 13 is an enlarged left side view of the structure of portion A of FIG. 11;

FIG. 14 is an enlarged top view of the first and second rotation plates of FIG. 13;

FIG. 15 is an enlarged view of the high frequency micro-vibration mechanism of the present invention;

FIG. 16 is a side view of the second driven wheel of the present invention mounted thereon;

fig. 17 is an enlarged view of the middle resistance spring of the present invention.

In the figure: the device comprises a track plate 1, a driving gear 2, a pouring ladle 3, a fixing plate 4, a die 5, a flow guide groove 51, a sub-riser groove 52, a sub-cavity 53, a connecting plate 54, a pin 55, a shaft 56, a first bearing 57, a second bearing 571, a positioning pin 58, a positioning groove 59, a connecting plate 510, a connecting groove 511, a riser placing mechanism 6, a buckle 60, a riser placing pipe 61, a riser 62, a mounting plate 63, a stepping motor 64, a first driving wheel 65, a first driven wheel 651, a first supporting rotating seat 66, a vertical rotating rod 67, a first rotating plate 68, a second rotating plate 69, a high-frequency micro-amplitude vibration mechanism 7, a high-speed motor 71, a second driving wheel 711, a second driven wheel 72, a belt 73, a balancing weight 74, a rotating plate 75 and a resistance elastic sheet 8.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to fig. 1-17, the casting ladle comprises a casting ladle 3 and a frame located on the lower side of the casting ladle 3, the frame is inclined, the frame comprises two track plates 1 which are parallel to each other, each of the two track plates 1 comprises two horizontal plates and two semicircular plates, the two track plates 1 are fixedly connected through a plurality of fixing plates 4, the fixing plates 4 are located on the inner sides of the two track plates 1, a driving gear 2 is arranged at the bottom end of the frame, the driving gear 2 is a double-piece gear, the axis of the driving gear 2 is externally connected with the driving end of a stepping driving motor, a plurality of molds 5 are jointly arranged between the inner side walls of the two track plates 1, a dead head placing mechanism 6 is arranged on the upper side of one side, close to the bottom end, two high-frequency micro-amplitude vibration mechanisms 7 are arranged on the inner side of;

the bottom wall of each mold 5 is fixedly provided with a connecting plate 54 through bolts, the middle part of each connecting plate 54 is provided with a shaft pin 55, two ends of each shaft pin 55 are provided with first bearings 57, tooth grooves of the driving gear 2 are meshed with two ends of the shaft pin 55, side walls on two sides of each mold 5 are connected with shaft rods 56, one end of each shaft rod 56, which is far away from the mold 5 on the same side, is provided with a second bearing 571, the inner side of each track plate 1 is provided with a first track groove and a second track groove, each shaft pin 55 and the first bearings 57 are connected in the first track groove in a sliding manner, and each shaft rod 56 and the second bearings 571 are connected in the second track groove in a sliding manner;

the top wall of each mold 5 is provided with a flow guide groove 51, two sides of each mold 5 are symmetrically provided with a plurality of sub-pouring cavities, each sub-pouring cavity is communicated with the flow guide groove 51, each sub-pouring cavity consists of a sub-riser groove 52 and a sub-cavity 53 which are communicated with each other, the sub-riser grooves 52 are positioned at the upper sides of the sub-cavities 53, the sub-pouring cavities between two adjacent molds 5 are jointly butted to form a mother pouring cavity, the sub-riser grooves 52 between two adjacent molds 5 are jointly butted to form a mother riser groove, and the sub-cavities 53 between two adjacent molds 5 are jointly butted to form a mother cavity;

the riser placing mechanism 6 comprises a pinch plate 60 erected on the top wall of the two track plates 1, a plurality of riser storing pipes 61 are installed at the top end of the pinch plate 60, a plurality of risers 62 are placed inside each riser storing pipe 61, two adjacent riser storing pipes 61 are fixed through a mounting plate 63, the riser storing pipe 61 located on the outermost side is fixed with the inner side wall of the pinch plate 60 through the mounting plate 63, a stepping motor 64 is installed on the inner side wall, a first driving wheel 65 is installed at the driving end of the stepping motor 64, a vertical rotating rod 67 is rotatably connected to the outer side wall of each riser storing pipe 61 through a supporting rotating seat 66, a first rotating plate 68 is installed at the top end of each vertical rotating rod 67, a second rotating plate 69 is installed at the bottom end of each vertical rotating rod 67, and a first driven wheel 651 penetrates through the first rotating plate 68 at the top end of each vertical rotating rod 67, the adjacent two first driven wheels 651 are driven by a connecting belt, the first driving wheels 65 and the first driven wheels 651 are also driven by the connecting belt, the distance between the top wall of the second rotating plate 69 and the bottom wall of the first rotating plate 68 on the same side is the same as the height of the riser 62, and each first rotating plate 68 and each second rotating plate 69 comprise a circular plate and two symmetrically-arranged annular plates;

two high frequency slight amplitude vibration mechanism 7 all include high speed motor 71, two high speed motor 71 are installed respectively on the interior roof of two track boards 1, second drive wheel 711 is all installed to every high speed motor 71's drive end, the downside of roof all is equipped with a plurality of seconds and follows driving wheel 72 in two track boards 1, every second is all rotated from the axle center of driving wheel 72 and is connected with two rotor plates 75, the top of every rotor plate 75 is all fixed on the interior roof of corresponding track board 1, equal symmetry is installed two balancing weights 74 on every second driven driving wheel 72's the lateral wall, every second that is located the homonymy is all driven through belt 73 transmission between driving wheel 72 and the second drive wheel 711.

The symmetry is equipped with two resistance shell fragments 8 on the lateral wall of the fixed plate 4 that is located frame top one side, and every resistance shell fragment 8 all is the structure of falling V-arrangement, and every resistance shell fragment 8's one end all is fixed with fixed plate 4 through the bolt, and two resistance shell fragments 8 all contact with the both ends of pivot 55.

The sidewall of the riser storage tube 61 is respectively provided with an arc-shaped notch matched with the first rotating plate 68 and the second rotating plate 69 on the same side, and the first rotating plate 68 and the second rotating plate 69 are in contact with the riser 62 through the corresponding arc-shaped notches.

The side wall of each mould 5 close to one side of the connecting plate 54 on the same side is symmetrically provided with a positioning pin 58, the side wall of each mould 5 close to the other side of the connecting plate 54 on the same side is symmetrically provided with a positioning groove 59, the side wall of each mould 5 far away from one side of the connecting plate 54 on the same side is symmetrically provided with a connecting plate 510, the side wall of each mould 5 far away from the other side of the connecting plate 54 on the same side is symmetrically provided with a connecting groove 511, the positioning pin 58 on the side wall of one mould 5 is matched with the positioning groove 59 on the side wall of the other mould 5, and the connecting plate 510 on the side wall of one mould.

The stepping drive motor, the stepping motor 64 and the high-speed motor 71 are all externally connected with a PLC controller.

The riser 62 is configured in a cylindrical tubular shape with cutouts provided at both ends thereof, and the cutout at the upper end is smaller than the cutout at the lower end thereof.

The utility model discloses in, mould 5 is under drive gear 2's drive, by lower supreme operation (the arrow in fig. 1 shows the direction promptly), drive gear 2 is fixed with step drive motor's drive end, step drive motor receives the control of PLC controller, can realize regular intermittent type nature and rotate, promotes mould 5 from this and moves forward at regular intermittent type nature between two track boards 1, and at the intermittent type moment that mould 5 pauses to move forward, place rising head 62 by rising head placement mechanism 6.

The placement of the risers 62 is as follows: the PLC controller controls the step motor 64 to rotate, the step motor 64 firstly drives the first driving wheel 65 to rotate, then, the first driving wheel 65, the first driven wheel 651 and the connecting belt can simultaneously drive the plurality of vertical rotating rods 67 to rotate, and when the vertical rotating rods 67 rotate, the first rotation plate 68 and the second rotation plate 69 rotate simultaneously, the ring plate of the second rotation plate 69 gradually releases the binding of the lowermost riser 62, while the annular plate of the first rotation plate 68 is gradually tied up against the penultimate riser 62, and finally the riser 62 located at the lowermost side leaves the riser storage tube 61 and enters the female riser slot formed by the two sub-riser slots 52, while the first rotation plate 68 and the second rotation plate 69 continue to rotate, the first rotation plate 68 then gradually releases the restraint of the current riser 62, and the riser 62 then falls and is blocked by the second rotation plate 69, completing one cycle of operation.

And then the mold 5 continues to move forwards to receive molten iron flowing from the pouring ladle 3, the molten iron enters a female mold cavity formed by the two sub-mold cavities 53 through the diversion trench 51 and the riser 62 and is cooled and formed in the female mold cavity, and in the process of pouring and cooling the molten iron, bubbles in the molten iron in the female mold cavity can be rapidly extruded under the action of the high-frequency micro-amplitude vibration device 7, so that the density and the hardness of the casting are greatly improved.

The operation principle of the high-frequency micro-amplitude vibration device 7 is as follows: drive second drive wheel 711 through installing high-speed motor 71 on track board 1 diapire and rotate, second drive wheel 711 and second are followed between driving wheel 72 and the second is followed all through the belt 73 transmission between driving wheel 72 and the second, and then drive every second and follow driving wheel 72 and rotate, because every second is followed and all is installed the balancing weight 74 on the lateral wall of driving wheel 72, consequently second follows driving wheel 72 when rotating, can cause the second to follow the slight shake of driving wheel 72, the effect of shake passes through rotating plate 75 and transmits to track board 1, and finally transmit to the female die cavity in the mould 5, and then can discharge the bubble in the molten iron in the female die cavity.

Mould 5 continues to move up, when the semicircle board department in 1 top of two track boards, two front and back moulds 5 can part naturally, the foundry goods is not hard up this moment, the mould 5 that is located relative upside is short-term unsettled under the effect of resistance shell fragment 8 this moment, and the mould 5 that is located relative downside then continues to move and slides to the downside of semicircle board and finally slides to the horizontal plate department of downside, when the mould 5 that is located relative upside is short-term when hanging under the effect of resistance shell fragment 8, the foundry goods drops naturally under self action of gravity, resistance shell fragment 8 is crossed equally to the mould 5 that is located relative upside afterwards, then quick landing to the horizontal plate department of downside, the normal course of whole foundry goods accomplishes single circulation this moment, then continue the next process.

The utility model discloses in, when two adjacent moulds 5 butt joints amalgamation, can form female die cavity between two sub-type chambeies 53, female die cavity's shape can be spherical, cylindrical, and concrete shape can be confirmed according to actual conditions.

Furthermore, on the basis of the structure, for small-sized castings, if riser feeding is not needed in the production process, a riser channel and a riser placing device are eliminated, a cavity channel is used for replacing the riser channel, molten iron directly enters the cavity through the cavity channel, and other settings are unchanged.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims

1. The casting production equipment comprises a pouring ladle (3) and a rack positioned on the lower side of the pouring ladle (3), and is characterized in that the rack is inclined, the rack comprises two mutually parallel track plates (1), the two track plates (1) comprise two horizontal plates and two semicircular plates, the two track plates (1) are fixedly connected through a plurality of fixing plates (4), the fixing plates (4) are positioned on the inner sides of the two track plates (1), the bottom end of the rack is provided with a driving gear (2), the driving gear (2) is a double-piece gear, the driving end of an axis of the driving gear (2) is externally connected with a stepping driving motor, a plurality of molds (5) are jointly arranged between the inner side walls of the two track plates (1), the upper side of the rack close to one side of the bottom end is provided with a riser placing mechanism (6), the inner side of the rack is provided with two high-frequency micro-amplitude vibration mechanisms (7), the two high-frequency micro-amplitude vibration mechanisms (7) are both positioned at the lower side of the pouring point of the pouring ladle (3);

the bottom wall of each mold (5) is fixedly provided with a connecting plate (54) through bolts, the middle of each connecting plate (54) is provided with a shaft pin (55), two ends of each shaft pin (55) are provided with first bearings (57), tooth sockets of the driving gear (2) are meshed with two ends of each shaft pin (55), side walls of two sides of each mold (5) are connected with shaft rods (56), one end, far away from the mold (5) on the same side, of each shaft rod (56) is provided with a second bearing (571), the inner side of each track plate (1) is provided with a first track groove and a second track groove, each shaft pin (55) and each first bearing (57) are connected in the first track groove in a sliding mode, and each shaft rod (56) and each second bearing (571) are connected in the second track groove in a sliding mode;

the top wall of each mold (5) is provided with a flow guide groove (51), two sides of each mold (5) are symmetrically provided with a plurality of sub-pouring cavities, each sub-pouring cavity is communicated with the flow guide groove (51), each sub-pouring cavity consists of a sub-riser groove (52) and a sub-mold cavity (53) which are communicated with each other, the sub-riser grooves (52) are positioned on the upper sides of the sub-mold cavities (53), the sub-pouring cavities between two adjacent molds (5) are butted into a mother pouring cavity together, the sub-riser grooves (52) between two adjacent molds (5) are butted into a mother riser groove together, and the sub-mold cavities (53) between two adjacent molds (5) are butted into a mother mold cavity together;

the riser placing mechanism (6) comprises a buckle plate (60) erected and installed on the top wall of two track plates (1), a plurality of riser storage pipes (61) are installed on the top end of the buckle plate (60), each riser storage pipe (61) is internally provided with a plurality of risers (62), every two risers are fixed between the riser storage pipes (61) through a mounting plate (63), the riser storage pipes (61) located on the outermost side are fixed with the inner side wall of the buckle plate (60) through the mounting plate (63), the inner side wall is provided with a stepping motor (64), a driving wheel (65) is installed at the driving end of the stepping motor (64), each riser storage pipe (61) is rotatably connected with a vertical rotating rod (67) through a supporting rotating seat (66) on the outer side wall, and each first rotating plate (68) is installed on the top end of the vertical rotating rod (67), the bottom end of each vertical rotating rod (67) is provided with a second rotating plate (69), the top end of each vertical rotating rod (67) penetrates through the first rotating plate (68) and is provided with a first driven wheel (651), two adjacent first driven wheels (651) are in transmission through a connecting belt, the first driving wheel (65) and the first driven wheel (651) are also in transmission through the connecting belt, the distance between the top wall of the second rotating plate (69) and the bottom wall of the first rotating plate (68) on the same side is the same as the height of a riser (62), and each first rotating plate (68) and each second rotating plate (69) comprise a circular plate and two symmetrically-arranged annular plates;

two high frequency slight amplitude vibration mechanism (7) all include high speed motor (71), two high speed motor (71) is installed respectively on the interior roof of two track boards (1), every second drive wheel (711), two are all installed to the drive end of high speed motor (71) the downside of roof all is equipped with a plurality of seconds and follows driving wheel (72), every the second all rotates from the axle center of driving wheel (72) and is connected with two rotor plates (75), every the top of rotor plate (75) is all fixed on the interior roof of corresponding track board (1), every equal symmetry is installed two balancing weights (74) on the lateral wall of second follow driving wheel (72), is located every of homonymy the second all passes through belt (73) transmission between follow driving wheel (72) and the second drive wheel (711).

2. The casting production equipment according to claim 1, wherein two resistance elastic pieces (8) are symmetrically arranged on the side wall of the fixing plate (4) on one side of the top end of the rack, each resistance elastic piece (8) is of an inverted V-shaped structure, one end of each resistance elastic piece (8) is fixed to the fixing plate (4) through a bolt, and the two resistance elastic pieces (8) are in contact with two ends of a shaft pin (55).

3. Casting production equipment according to claim 1, characterized in that the side walls of the riser storage tube (61) are respectively provided with an arc-shaped notch matching with the first rotating plate (68) and the second rotating plate (69) on the same side, and the first rotating plate (68) and the second rotating plate (69) are in contact with the riser (62) through the corresponding arc-shaped notches.

4. Casting production equipment according to claim 1, characterized in that the side wall of each mold (5) close to one side of the same side connecting plate (54) is symmetrically provided with a positioning pin (58), the side wall of each mold (5) close to the other side of the same side connecting plate (54) is symmetrically provided with a positioning groove (59), the side wall of each mold (5) far away from one side of the same side connecting plate (54) is symmetrically provided with a connecting plate (510), the side wall of each mold (5) far away from the other side of the same side connecting plate (54) is symmetrically provided with a connecting groove (511), the positioning pin (58) on the side wall of one mould (5) is matched with the positioning groove (59) on the side wall of the other mould (5), the connector plates (510) on the side walls of one mould (5) are matched with the connector grooves (511) on the side walls of the other mould (5).

5. Casting production equipment according to claim 1, wherein the stepping drive motor, the stepping motor (64) and the high-speed motor (71) are externally connected with a PLC controller.