阅读说明：本技术 一种铸砂回收处理系统 (Foundry sand recycling system ) 是由 张先友 于 2021-07-20 设计创作，主要内容包括：本申请涉及一种铸砂回收处理系统,包括传输带一、提升机一、传输带二、提升机二、振筛机以及筛选装置,筛选装置包括机体、磁铁、转筒,转筒倾斜设置,转筒平行设有两个,两个转筒的侧壁相贴在其顶部形成筛料槽,转筒同轴设有安装腔,磁铁的形状与筛料槽槽壁的形状相适配,磁铁与安装腔靠近筛料槽的内壁相贴,两个转筒由设置在机体上的驱动机构驱动转动,两个转筒的转动方向相反。通过设置筛选装置,使的铸砂与钢料碎块相互分离,使回收铸砂的质量更好；通过设置螺旋推进杆,在筛料槽中对铸砂进行搅拌,便于筛料中的钢料碎块能够与转筒外壁充分接触,使得钢料碎块的筛分率提高；通过设置拨件、弹性件,使得钢料碎块不易将铸砂带出。(The utility model relates to a cast sand recovery processing system, including transmission band one, lifting machine one, transmission band two, lifting machine two, sieving machine and sieving mechanism, the sieving mechanism includes the organism, magnet, the rotary drum slope sets up, the rotary drum parallel is equipped with two, the lateral wall of two rotary drums pastes mutually and forms the sieve silo at its top, the coaxial installation cavity that is equipped with of rotary drum, the shape of magnet and the shape looks adaptation of sieve silo cell wall, magnet pastes mutually with the inner wall that the installation cavity is close to the sieve silo, two rotary drums are rotated by the actuating mechanism drive that sets up on the organism, the rotation opposite direction of two rotary drums. The screening device is arranged, so that the casting sand and the steel material fragments are separated from each other, and the quality of the recovered casting sand is better; by arranging the spiral propelling rod, the casting sand is stirred in the screening trough, so that the steel material fragments in the screening material can be in full contact with the outer wall of the rotary drum, and the screening rate of the steel material fragments is improved; through setting up plectrum, elastic component for the steel material fragment is difficult for taking out the foundry sand.)

1. The utility model provides a foundry sand recovery processing system which characterized in that: including transmission band (1), lifting machine (2), transmission band two (3), lifting machine two (4), sieving machine (5) and sieving mechanism (6), transmission band (1) is used for transmitting the cast sand of smashing to lifting machine (2), the discharge gate of lifting machine (2) is located the feed inlet top of sieving machine (5), transmission band two (3) are located sieving machine (5) below in order to connect and get the cast sand, the discharge end of transmission band two (3) is located the feed inlet top of lifting machine two (4), lifting machine two (4) are arranged in transmitting the cast sand to sieving mechanism (6), sieving mechanism (6) include organism (61), magnet (62), rotary drum (63) slope and set up, rotary drum (63) are rotated with organism (61) and are connected, rotary drum (63) parallel is equipped with two, the side walls of the two rotary drums (63) are attached to the top of the rotary drums to form a screening trough (64), the top of the screening trough (64) is used for receiving casting sand, the bottom of the screening trough (64) is provided with a discharge hole, the discharge hole is close to the bottom end of the sieving trough (64), the magnet (62) is fixedly connected with the machine body (61), the rotary drum (63) is coaxially provided with a mounting cavity (69), the magnet (62) is positioned in the mounting cavity (69), the shape of the magnet (62) is matched with the shape of the wall of the screening trough (64), the magnet (62) is attached to the inner wall of the mounting cavity (69) close to the screening trough (64), the two rotary drums (63) are driven to rotate by a driving mechanism (7) arranged on the machine body (61), the rotating directions of the two rotary drums (63) are opposite, to transfer the steel material fragments from the screening trough (64) to the side of the drum (63) remote from the screening trough (64).

2. The foundry sand reclamation processing system of claim 1, wherein: the machine body (61) is fixedly provided with a scraping plate (613) and a material receiving box (614), the end part of the scraping plate (613) is attached to the outer wall of the rotary drum (63), and the material receiving box (614) is positioned below the scraping plate (613) to receive and take steel material fragments.

3. The foundry sand reclamation processing system of claim 1, wherein: the machine body (61) is provided with a spiral pushing rod (611), the spiral pushing rod (611) is driven to rotate by a driving motor (612) arranged on the machine body (61), and the spiral pushing rod (611) is located in the screening trough (64).

4. The foundry sand reclamation processing system of claim 3, wherein: the machine body (61) is provided with a shielding plate (66), and the shielding plate (66) is positioned above the screening trough (64) to shield the notch of the screening trough (64).

5. The foundry sand reclamation processing system of claim 4, wherein: shutter (66) lateral wall is equipped with elastic component (666), the one end of elastic component (666) and shutter (66) fixed connection, the other end are connected with and are used for dialling into stirring (667) of screen trough (64) with the foundry sand, the tip of dialling (667) offsets with the outer wall of rotary drum (63), elastic component (666), dial (667) and be equipped with a plurality ofly along the circumference interval of shutter (66).

6. The foundry sand reclamation processing system of claim 5, wherein: baffle (66) include baffle body (661) and driving chain (662), driving chain (662) cup joint on the circumference lateral wall of baffle body (661), dial piece (667), elastic component (666) and fix on driving chain (662), driving chain (662) is by setting up driving motor (663) drive transmission on baffle body (661).

7. The foundry sand reclamation processing system of claim 6, wherein: the poking piece (667) is a plastic piece.

8. The foundry sand reclamation processing system of claim 1, wherein: the driving mechanism (7) comprises a first gear (71), a second gear (72), a third gear (73) and a slow motor (74), the first gear (71) and an output shaft of the slow motor (74) are coaxially fixed, the second gear (72) and the third gear (73) are respectively coaxially fixed with the two rotary drums (63), the second gear (72) is meshed with the third gear (73), the first gear (71) is meshed with the second gear (72), and the slow motor (74) is fixedly connected with the machine body (61).

Technical Field

The application relates to the field of metal parts, in particular to a casting sand recycling system.

Background

Casting is a relatively early metal hot working process mastered by human beings, and has a history of about 6000 years. Casting is a method in which liquid metal is cast into a casting cavity that conforms to the shape of a part, and after it is cooled and solidified, a part or a blank is obtained.

The sand mold casting is one of casting methods, and a finished part model or a wooden model is put into a cavity of a sand mold, sand is filled around the model, the sand forms a casting mold after the model is taken out after a box is opened, and then molten metal is poured into the cavity of the sand mold for forming. Since the sand mold needs to be destroyed to take out the workpiece when taking out the formed workpiece, the casting sand needs to be recovered after the sand mold is destroyed.

In the prior art, when the sand mould is recycled, a part of steel material fragments generated by pouring can be mixed, and the steel material fragments are cast into the sand mould along with the casting sand, so that the quality of the sand mould can be influenced.

Disclosure of Invention

In order to separate the steel material fragment from the casting sand, the application provides a casting sand recovery processing system.

The application provides a foundry sand recovery processing system adopts following technical scheme:

the utility model provides a foundry sand recovery processing system, includes transmission band one, lifting machine one, transmission band two, lifting machine two, sieving machine and sieving mechanism, transmission band one is used for transmitting the foundry sand of smashing to lifting machine one, the discharge gate of lifting machine one is located sieving machine's feed inlet top, the transmission band is two in sieving machine below in order to connect and get foundry sand, the discharge end of transmission band two is located lifting machine two's feed inlet top, lifting machine two is arranged in transmitting foundry sand to sieving mechanism, sieving mechanism includes organism, magnet, rotary drum, the rotary drum slope sets up, the rotary drum is connected with the organism rotation, the rotary drum parallel is equipped with two, and two the lateral wall of rotary drum pastes at its top and forms the sieve groove mutually, sieve groove top is used for connecting and gets foundry sand, the bottom of sieve groove is equipped with the discharge gate, the discharge gate is close to the bottom of sieve groove, the magnet is fixedly connected with the machine body, the rotary drums are coaxially provided with installation cavities, the magnet is located in the installation cavities, the shape of the magnet is matched with that of the wall of the screening trough, the magnet is attached to the inner wall, close to the screening trough, of the installation cavities, the two rotary drums are driven to rotate by a driving mechanism arranged on the machine body, the rotation directions of the two rotary drums are opposite, and therefore steel material fragments are transmitted to one side, away from the screening trough, of the rotary drum from the screening trough.

Through adopting above-mentioned technical scheme, through setting up the sieving mechanism, in will casting the sand and transmitting the screen pot, the steel charge fragment can be adsorbed on the outer wall of rotary drum by magnet, and later the rotary drum rotates, can transmit the steel charge fragment in the screen pot out of the screen pot to fall out because of the lateral wall of keeping away from the screen pot of gravity from the rotary drum, make steel charge fragment and casting sand separation.

Preferably, the machine body is fixedly provided with a scraping plate and a material receiving box, the end part of the scraping plate is attached to the outer wall of the rotary drum, and the material receiving box is positioned below the scraping plate to receive and take the steel material fragments.

Through adopting above-mentioned technical scheme, scrape the setting of flitch, can all scrape the steel material fragment that attaches to on the rotary drum outer wall and fall to the case that connects, it is comparatively convenient.

Preferably, the machine body is provided with a spiral propelling rod, the spiral propelling rod is driven to rotate by a driving motor arranged on the machine body, and the spiral propelling rod is positioned in the screening trough.

Through adopting above-mentioned technical scheme, the screw propulsion pole can accelerate the transmission of foundry sand in the screen silo, and the screw propulsion pole can stir the foundry sand simultaneously, gets rid of the outer wall of rotary drum with the steel material fragment in the foundry sand on, improves the broken screening efficiency of steel material.

Preferably, the machine body is provided with a shielding plate, and the shielding plate is positioned above the screening trough to shield the notch of the screening trough.

Through adopting above-mentioned technical scheme, the shielding plate makes the casting sand be difficult for being thrown away through the notch of screening trough.

Preferably, the side wall of the shielding plate is provided with an elastic piece, one end of the elastic piece is fixedly connected with the shielding plate, the other end of the elastic piece is connected with a shifting piece used for shifting the casting sand into the screening trough, the end part of the shifting piece is abutted against the outer wall of the rotary drum, and a plurality of elastic pieces and shifting pieces are arranged at intervals along the circumferential direction of the shielding plate.

Through adopting above-mentioned technical scheme, because the steel charge fragment is being carried out by the rotary drum transmission, can bring out partly cast sand sometimes, the setting of elastic component and plectrum can block the cast sand that takes out, will dial it and fall to the screen pot in, and the steel charge fragment can not be stirred by the plectrum because of magnetic force adsorbs, makes the cast sand difficult to be brought out along with the steel charge fragment together.

Preferably, the baffle plate comprises a baffle plate body and a transmission chain, the transmission chain is sleeved on the circumferential side wall of the baffle plate body, the shifting piece and the elastic piece are fixed on the transmission chain, and the transmission chain is driven and transmitted by a transmission motor arranged on the baffle plate body.

Through adopting above-mentioned technical scheme, because there is the lateral wall of steel charge fragment can hinder the falling back of casting sand for the steel charge fragment can't directly fall the screen trough along rotary drum circumference, so setting up of driving chain makes the piece of dialling can exert along the axial power of rotary drum to the casting sand, makes the piece of dialling push away efficiency that the area of dialling out the casting sand further improve.

Preferably, the poking piece is a plastic piece.

Through adopting above-mentioned technical scheme, the material of piece is dialled for it is difficult for receiving the magnetic force effect influence its normal work of magnet to dial the piece, and the working of plastics is lighter, is convenient for promote by the steel material fragment.

Preferably, the driving mechanism comprises a first gear, a second gear, a third gear and a slow-speed motor, the first gear is coaxially fixed with an output shaft of the slow-speed motor, the second gear and the third gear are respectively coaxially fixed with the two rotary drums, the second gear is meshed with the third gear, the first gear is meshed with the second gear, and the slow-speed motor is fixedly connected with the machine body.

Through adopting above-mentioned technical scheme, personnel can rotate through the drive slow speed motor and drive gear one and rotate to drive gear two and three antiport of gear, only need a driving source alright drive two rotary drums and rotate, it is comparatively convenient.

In summary, the present application includes at least one of the following beneficial technical effects:

the screening device is arranged, so that the casting sand and the steel material fragments are separated from each other, and the quality of the recovered casting sand is better;

by arranging the spiral propelling rod, the casting sand is stirred in the screening trough, so that the steel material fragments in the screening material can be in full contact with the outer wall of the rotary drum, and the screening rate of the steel material fragments is improved;

through setting up plectrum, elastic component for the steel material fragment is difficult for taking out the foundry sand.

Drawings

Fig. 1 is a perspective view of an embodiment of the present application.

Fig. 2 is a schematic structural diagram of a screening apparatus according to an embodiment of the present application.

Fig. 3 is a schematic partial structural view of a screening apparatus according to an embodiment of the present application.

Fig. 4 is a schematic structural diagram of a drive chain according to an embodiment of the present application.

Fig. 5 is an enlarged view of fig. 4 at a.

Description of reference numerals: 1. a first conveying belt; 2. a first hoister; 3. a second conveying belt; 4. a second hoisting machine; 5. a vibrating screen machine; 6. a screening device; 61. a body; 611. a screw propulsion rod; 612. a drive motor; 613. a scraping plate; 614. a material receiving box; 62. a magnet; 63. a rotating drum; 64. a material screening groove; 641. a ring groove; 65. an installation part; 66. a shielding plate; 661. a baffle body; 662. a drive chain; 663. a drive motor; 664. a transmission gear; 665. a driven gear; 666. an elastic member; 667. pulling a piece; 68. A connecting member; 69. a mounting cavity; 7. a drive mechanism; 71. a first gear; 72. a second gear; 73. a third gear; 74. a slow speed motor.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses a foundry sand recovery processing system.

Referring to fig. 1, a cast sand recycling system includes a first transmission belt 1, a first hoister 2, a second transmission belt 3, a second hoister 4, a vibrating screen machine 5 and a screening device 6, wherein the first transmission belt 1, the first hoister 2, the vibrating screen machine 5, the second transmission belt 3, the second hoister 4 and the screening device 6 are sequentially arranged along a transmission direction of cast sand.

The first transmission band 1 is used for transmitting smashed casting sand to a feeding port of the first hoister 2, the first hoister 2 is used for lifting the casting sand to a high position, a discharging port of the first hoister 2 is located above a feeding port of the vibrating screen machine 5, the casting sand falls into the vibrating screen machine 5 after being discharged from the discharging port, the vibrating screen machine 5 is used for screening the casting sand, qualified casting sand particles are screened out, and the oversize casting sand particles are blocked.

The second transmission belt 3 is located below the vibrating screen machine 5 to receive casting sand, the discharge end of the second transmission belt 3 is located above the feed inlet of the second hoister 4, the casting sand can enter the second transmission belt 3 after being screened by the vibrating screen machine 5, the second transmission belt 3 is used for lifting the casting sand to a high position at the feed inlet of the second hoister 4, and the casting sand falls into the screening device 6 from the discharge port of the second hoister 4.

Referring to fig. 2 and 3, the screening device 6 includes a machine body 61, a magnet 62 and two drums 63, one end of each drum 63 near the second elevator 4 tilts and tilts upward, the upper end of each drum 63 is rotatably connected with the machine body 61, two drums 63 are arranged in parallel along the horizontal direction, the side walls of the two drums 63 are attached to the tops of the two drums 63 to form a screening trough 64, the screening trough 64 is a depression between the two drums 63, a driving mechanism 7 is arranged at the bottom of the machine body 61, the driving mechanism 7 includes a first gear 71, a second gear 72, a third gear 73 and a slow motor 74, the slow motor 74 is fixedly connected with the machine body 61, the first gear 71 is fixedly sleeved on an output shaft of the slow motor 74, and the axial direction of the output shaft of the slow motor 74 is parallel to the axial direction of the drum 63. The bottom end of the rotary drum 63 is fixed with a mounting part 65, each rotary drum 63 is correspondingly provided with one mounting part 65, the diameter of each mounting part 65 is smaller than that of the rotary drum 63, and the second gear 72 and the third gear 73 are respectively and coaxially fixed on the two mounting parts 65. The second gear 72 is meshed with the third gear 73, the first gear 71 is meshed with the second gear 72, and a person can drive the drum 63 to rotate slowly through the slow motor 74.

The installation cavity 69 has been seted up to the rotary drum 63 is coaxial, and magnet 62 is the strip, and the upper end and the organism 61 fixed connection of magnet 62, magnet 62 are located the installation cavity 69 and paste mutually with the inner wall that installation cavity 69 is close to sieve silo 64, and the material of rotary drum 63 can adopt aluminum alloy or copper alloy, and the surface that magnet 62 pasted mutually with installation cavity 69 inner wall is the cambered surface, and its cross-section radian is 90 degrees. The shape of the magnet 62 attached to the inner wall of the mounting cavity 69 is matched with the shape of the wall of the sieve channel 64, so that the wall of the sieve channel 64 has magnetic force.

When the rotating drum 63 rotates, the steel material fragments are adsorbed on the outer wall of the rotating drum 63 under the influence of the magnetic force of the magnet 62, and are brought to the other side of the rotating drum 63 under the rotation of the rotating drum 63, and the magnet 62 is not attached to the inner wall of the installation cavity 69 close to the side, so that the steel material fragments lose the magnetic force after the rotating drum 63 brings the steel material fragments to the side, and the steel material fragments fall from the side surface under the action of gravity. The body 61 is fixedly connected with a scraping plate 613, and the scraping plate 613 is attached to the side wall of the rotating drum 63 so as to hang down the steel material fragments transferred to the scraping plate 613 by the rotating drum 63. In addition, a receiving box 614 is fixedly connected to the machine body 61, the receiving box 614 is detachably fixed to the machine body 61 through a bolt connection, and the receiving box 614 is located right below the scraping plate 613, so that steel material fragments can fall into the receiving box 614 to be stored after being scraped by the scraping plate 613.

Organism 61 is equipped with connects the material mouth, connects the material mouth to sieve silo 64 top so that sieve silo 64 connects and gets the foundry sand, and the bottom of sieve silo 64 is equipped with the discharge gate, and the discharge gate runs through sieving mechanism 6 along vertical direction, and the discharge gate is formed by the annular 641 of setting on rotary drum 63.

The machine body 61 is provided with a spiral pushing rod 611 and a driving motor 612, the driving motor 612 is fixedly installed on the machine body 61, the spiral pushing rod 611 is coaxially fixed with an output shaft of the driving motor 612, the length direction of the spiral pushing rod 611 is along the length direction of the screening trough 64, the spiral pushing rod 611 is located in the screening trough 64 so as to stir the casting sand in the screening trough 64, and steel material fragments in the casting sand are thrown to the wall of the screening trough 64, so that the steel material fragments are easily adsorbed and attached to the wall of the screening trough 64 by magnetic force.

Fixed mounting has shielding plate 66 on the organism 61, shielding plate 66's length direction is along the length direction of sieve silo 64, shielding plate 66 is through connecting piece 68 and organism 61 fixed connection fixed on organism 61, shielding plate 66 is located sieve silo 64 top, shielding plate 66's diapire and the outer wall of rotary drum 63 have the punishment in advance interval of certain length, punishment in advance interval can allow the steel material fragment to pass through, shielding plate 66 shelters from the notch of sieve silo 64, when making spiral push rod 611 rotate, the foundry sand can not be thrown away from the notch of sieve silo 64 by spiral push rod 611.

Referring to fig. 3 and 4, the shielding plate 66 includes a shielding plate body 661 and a transmission chain 662, the transmission chain 662 is sleeved on a circumferential side wall of the shielding plate body 661, a transmission motor 663 is fixedly installed on the top of the shielding plate body 661, the transmission motor 663 adopts a slow-speed motor, a transmission gear 664 is fixed on an output shaft of the transmission motor 663, the transmission chain 662 is meshed with the transmission gear 664, a driven gear 665 is further rotatably connected on the circumferential side wall of the shielding plate body 661, an axial direction of the driven gear 665 is parallel to an axial direction of the transmission gear 664, and a person can drive the transmission motor 663 to run, so that the transmission chain 662 is circularly driven along the circumferential direction of the shielding plate body 661.

Referring to fig. 4 and 5, the lateral wall of transmission chain 662 is equipped with elastic component 666, elastic component 666 adopts the torsional spring, elastic component 666's one end and shielding plate 66 fixed connection, another end fixedly connected with dials the piece 667, shielding plate 66's width is less than the width of the widest department of screening trough 64, the lower extreme orientation of dialling the piece 667 is kept away from the direction slope of baffle body 661, it is square plate-shaped to dial the piece 667, dial the piece 667 and adopt the working of plastics, the concrete material adopts PVC, the lower tip of dialling the piece 667 offsets with the outer wall of rotary drum 63, accurately say and offset with the cell wall of screening trough 64. A plurality of elastic pieces 666 and a plurality of shifting pieces 667 are arranged at intervals along the circumferential direction of the shielding plate 66, and the side walls of the adjacent shifting pieces 667 are close to each other to prevent casting sand from leaking out of a gap between the two adjacent shifting pieces 667.

Because rotary drum 63 is when screening the steel material fragment, behind a large amount of steel material fragments attached to the cell wall of screen trough 64 by magnetic force, can bring partial casting sand out of screen trough 64, cause the casting sand loss, so for making the difficult steel material fragment that adsorbs on screen trough 64 lateral wall of casting sand bring out, utilize the atress difference of steel material fragment and casting sand: the fragments of the steel material are tightly attached to the wall of the screening trough 64 under the action of magnetic force, the casting sand is only brought out of the screening trough 64 with extremely small friction force, and once the casting sand is extremely easy to roll under the action of external force, the casting sand falls back into the screening trough 64, so that the elastic force of the elastic piece 666 is set as follows: the adsorbed steel material fragments cannot be pushed to move, and the stirring piece 667 can easily stir the unadsorbed casting sand into the screening trough 64. In addition, the fact that the bottom of the casting sand is supported by some steel material fragments and the casting sand taken out by the shifting piece 667 is pushed to the screening trough 64 to be blocked is considered, the transmission chain 662 is arranged, so that the shifting piece can push and shift the casting sand in the axial direction of the rotary drum 63, the casting sand is pushed down from the supporting surface formed by the steel material fragments, and the casting sand can be smoothly pushed back to the screening trough 64.

In another embodiment, the elastic member 666 can be an elastic rubber block instead of the torsion spring.

The implementation principle of a foundry sand recovery processing system of the embodiment of the application is as follows: after the unprocessed casting sand is transmitted to the screening trough 64, the steel material fragments in the unprocessed casting sand are adsorbed by the magnetic force emitted by the magnet 62, are attached to the trough wall of the screening trough 64 and are rotated by the rotary drum 63 to be taken out of the screening trough 64, the casting sand taken out in the process is stirred back to the screening trough 64 by the stirring member 667, and the steel material fragments fall to the material receiving box from the other side of the rotary drum 63 after passing through the material passing interval so as to be separated from the casting sand.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.