CN113000106B - Carbide leftover bits are retrieved and are ground powder equipment - Google Patents

Abstract

The invention relates to the field of recycling of hard alloy leftover materials, in particular to equipment for recycling and grinding hard alloy leftover materials into powder, which comprises a base, a supporting seat, a grinding frame, a cover frame, a clamping seat and the like; base top one side rigid coupling has the supporting seat, and supporting seat middle part one side rigid coupling has the grinding frame, and grinding frame one side rotary type is connected with the lid frame, and lid frame top one side rigid coupling has the cassette. Through mutually supporting of base and device and lifting means and rotatory grinding component on it, can grind carbide leftover bits into powder, make the staff can carry out recycle to carbide leftover bits, realized can grinding the carbide leftover bits that retrieve into the mesh of powder.

Description

Carbide leftover bits are retrieved and are ground powder equipment

Technical Field

The invention relates to the field of recycling of hard alloy leftover materials, in particular to equipment for recycling and grinding hard alloy leftover materials into powder.

Background

The hard alloy leftover materials generally refer to productive waste metals used in the fields of buildings, water conservancy, railways, oil fields, communication, electric power, national defense and other production, and generally refer to metal materials and metal products losing the original use value.

Carry out recycle to carbide leftover bits, generally need grind it into powder earlier, and because the hardness ratio of carbide leftover bits is higher, so current equipment is difficult to effectively grind into powder, and current equipment operation process is more loaded down with trivial details, uses inconveniently.

Disclosure of Invention

In view of the above, it is necessary to provide a cemented carbide scrap recycling and grinding apparatus capable of grinding cemented carbide scrap into powder, separating acceptable cemented carbide powder from large cemented carbide particles, and cooling parts that generate heat by grinding cemented carbide scrap.

The utility model provides a carbide leftover bits are retrieved and are ground whitewashed equipment, which comprises a base, a supporting seat, grind the frame, the lid frame, the cassette, the piece seat is dialled to the spring, promote the subassembly, rotatory grinding component and powder filtering component, base top one side rigid coupling has the supporting seat, supporting seat middle part one side rigid coupling has the grinding frame, it is connected with the lid frame to grind frame one side rotary type, lid frame top one side rigid coupling has the cassette, it has the piece seat to dial the spring to grind frame top one side rigid coupling, spring group piece seat and cassette block, it locates on the grinding frame to promote the subassembly, rotatory grinding component locates on the grinding frame, powder filtering component locates on the promotion subassembly.

Optionally, the lifting assembly comprises a supporting plate, a motor, a power shaft, a convex disc, a lifting rod, a concave lifting rod, a grinding cone, a hollow column, a rotary clamping rod and a first compression spring, the supporting plate is fixedly connected to one side of the upper portion of the grinding frame, the motor is installed at the top of the supporting plate, the power shaft is fixedly connected to an output shaft of the motor, the convex disc is fixedly connected to the middle of the power shaft, the lifting rod is slidably arranged on the supporting plate, one side of the upper portion of the lifting rod is in contact with the convex disc, the bottom end of the lifting rod is fixedly connected with the concave lifting rod, the concave lifting rod is slidably matched with the grinding frame, the grinding cone is placed at the top of one side of the concave lifting rod, the top of the grinding cone is fixedly connected with the hollow column, four rotary clamping rods are slidably arranged at the top of the hollow column, and the first compression spring is connected between the rotary clamping rods and the top of the hollow column.

Optionally, the rotary grinding assembly comprises a large belt wheel, a hollow rotating shaft, a small belt wheel, a belt and a rotary fluted disc, the large belt wheel is fixedly connected to the upper portion of the power shaft, the hollow rotating shaft is rotatably arranged on the upper portion of the grinding frame, the small belt wheel is fixedly connected to the hollow rotating shaft, the small belt wheel is connected with the large belt wheel through the belt, and the rotary fluted disc is fixedly connected to the bottom end of the hollow rotating shaft.

Optionally, the powder filtering component comprises a fixing block, a screw rod, a filtering groove ring, a rotating frame and a push plate, the fixing block is fixedly connected to the bottom of one side of the concave lifting rod, the screw rod is fixedly connected to the bottom of the fixing block, the filtering groove ring is fixedly connected to the inner side of the grinding frame, the rotating frame is connected to the screw rod in a threaded fit mode, the rotating frame is in sliding fit with the filtering groove ring, the push plate is fixedly connected to the tops of four sides of the rotating frame respectively, and the push plate is in contact with the bottom in a sliding groove of the filtering groove ring.

Optionally, still last the lifting subassembly including the coolant liquid, the coolant liquid lasts the lifting subassembly and locates on the promotion subassembly, the coolant liquid lasts the lifting subassembly including the pendulum rod, the ejector pin, lifting groove pole, chucking pole and compression spring two, lifting pole one side is located to the pendulum rod rotary type, the ejector pin rigid coupling is in lifting pole one side, ejector pin and the contact of pendulum rod one side top, backup pad one side is located to lifting groove pole slidingtype, lifting groove pole and the contact of pendulum rod opposite side, backup pad one side slidingtype is equipped with a pair of chucking pole, chucking pole one end and the contact of lifting groove pole recess, be connected with compression spring two between chucking pole and the backup pad.

Optionally, the cooling device further comprises a cooling liquid conveying assembly, the cooling liquid conveying assembly is arranged on the supporting seat, the cooling liquid conveying assembly comprises a cooling liquid storage cylinder, a lifting disc and a conveying pipe, the cooling liquid storage cylinder is arranged at the top of the supporting seat, the lifting disc is slidably arranged in the cooling liquid storage cylinder, one side of the upper portion of the lifting disc is fixedly connected with the upper portion of a lifting groove rod, one end of the conveying pipe is fixedly connected to the upper portion of the cooling liquid storage cylinder, the conveying pipe penetrates through the hollow rotating shaft, the rotating groove disc and the hollow column, and the other end of the conveying pipe is located in the hollow column.

The beneficial effects of the invention are as follows:

Through mutually supporting of base and device and lifting means and rotatory grinding component on it, can grind carbide leftover bits into powder, make the staff can carry out recycle to carbide leftover bits, realized can grinding the carbide leftover bits that retrieve into the mesh of powder.

Through the powder filtering component, qualified hard alloy powder and larger hard alloy particles can be separated, so that the staff can further grind the larger hard alloy particles, and the trouble that the staff manually separates the qualified hard alloy powder from the larger hard alloy particles is saved.

Last lifting subassembly and coolant liquid conveying component's mutually supporting through the coolant liquid, can cool off because of grinding the spare part that carbide leftover bits and pieces generated heat, prevent that it from influencing life because of generating heat, use the device to grind carbide leftover bits into powder for the staff and provide convenience.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a partially sectional perspective structure diagram of the present invention.

Fig. 4 is a schematic view of a first partially assembled component of the lifting assembly of the present invention.

Fig. 5 is a schematic view of a second partially assembled body of the lifting assembly of the present invention.

Fig. 6 is an enlarged schematic view of the structure of the present invention a.

Fig. 7 is a schematic perspective view of a powder filter assembly according to the present invention.

FIG. 8 is an enlarged schematic view of the present invention B.

FIG. 9 is a schematic cross-sectional perspective view of the coolant delivery assembly of the present invention.

Reference numbers in the drawings: 1: base, 2: supporting seat, 3: grinding frame, 31: cover frame, 32: cartridge, 33: spring plectrum seat, 4: lifting assembly, 41: support plate, 42: motor, 43: power shaft, 44: convex disc, 45: lifting rod, 46: concave lifting rod, 47: abrasive vertebral body, 48: hollow column, 49: rotating clamping rod, 410: compression spring I, 5: rotary abrasive assembly, 51: large pulley, 52: hollow rotating shaft, 53: small pulley, 54: belt, 55: rotating grooved disc, 6: powder filter assembly, 61: fixed block, 62: screw, 63: filter groove ring, 64: rotating frame, 65: push plate, 7: coolant continuous lift assembly, 71: swing link, 72: ejector rod, 73: lifting groove bar, 74: chucking rod, 75: compression spring two, 8: cooling liquid conveying assembly, 81: coolant storage cylinder, 82: lifting disk, 83: a delivery pipe.

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.

Example 1

A hard alloy leftover material recycling and grinding device is shown in figures 1-9 and comprises a base 1, a supporting seat 2, a grinding frame 3, a cover frame 31, a clamping seat 32, a spring piece pulling seat 33, a lifting component 4, a rotary grinding component 5 and a powder filtering component 6, wherein the supporting seat 2 is fixedly connected to one side of the top of the base 1, the supporting seat 2 is used for supporting a cooling liquid storage cylinder 81 and the grinding frame 3, the grinding frame 3 is fixedly connected to one side of the middle of the supporting seat 2, the grinding frame 3 is used for placing hard alloy leftover materials, the cover frame 31 is rotatably connected to one side of the grinding frame 3, the clamping seat 32 is fixedly connected to one side of the top of the cover frame 31, the cover frame 31 is also used for placing hard alloy leftover materials, the spring piece pulling seat 33 is fixedly connected to one side of the top of the grinding frame 3, the spring piece pulling seat 33 is used for clamping the clamping seat 32, the spring piece pulling seat 33 is clamped with the clamping seat 32, the lifting component 4 is arranged on the grinding frame 3, the rotary grinding component 5 is arranged on the grinding frame 3, through base 1 and the device on it and lifting means 4 and rotatory grinding component 5 mutually support, can grind into powder with carbide leftover bits, on lifting means 4 was located to powder filtering component 6, powder filtering component 6 was used for separating qualified carbide powder and great carbide granule.

The lifting assembly 4 comprises a supporting plate 41, a motor 42, a power shaft 43, a convex disc 44, a lifting rod 45, a concave lifting rod 46, a grinding cone 47, a hollow column 48, a rotary clamping rod 49 and a first compression spring 410, wherein the supporting plate 41 is fixedly connected to one side of the upper part of the grinding frame 3 close to the supporting seat 2, the motor 42 is installed at the top of the supporting plate 41, the motor 42 is used for driving the power shaft 43 to rotate, the power shaft 43 is fixedly connected to an output shaft of the motor 42, the power shaft 43 is used for driving the convex disc 44 and a large belt wheel 51 to rotate, the convex disc 44 is fixedly connected to the middle part of the power shaft 43, the convex disc 44 is used for extruding the lifting rod 45 and an upper device thereof to move upwards, the lifting rod 45 is slidably arranged on the supporting plate 41, the lifting rod 45 is used for driving the concave lifting rod 46 to move, the upper part of one side of the lifting rod 45 far away from the supporting seat 2 is in contact with the convex disc 44, the bottom end of the lifting rod 45 is fixedly connected with the concave lifting rod 46, the concave lifting rod 46 is used for driving the grinding cone 47 and the upper device thereof to move, concave lifting rod 46 and grinding frame 3 are in sliding fit, grinding cone 47 is placed at the top of one side of concave lifting rod 46 far away from lifting rod 45, grinding cone 47 is used for grinding hard alloy leftover materials, hollow column 48 is fixedly connected to the top of grinding cone 47, hollow column 48 is used for driving grinding cone 47 to rotate, four rotary clamping rods 49 are arranged at the top of hollow column 48 in a sliding mode, rotary clamping rods 49 drive hollow column 48 to rotate, compression springs 410 are connected between rotary clamping rods 49 and the top of hollow column 48, and compression springs 410 are used for driving rotary clamping rods 49 to reset.

The rotary grinding component 5 comprises a large belt wheel 51, a hollow rotating shaft 52, a small belt wheel 53, a belt 54 and a rotary fluted disc 55, the large belt wheel 51 is fixedly connected to the upper part of the power shaft 43, the large belt wheel 51 is used for driving the belt 54 to rotate, the hollow rotating shaft 52 is rotatably arranged on the upper part of the grinding frame 3, the hollow rotating shaft 52 is used for driving the rotary fluted disc 55 to rotate, the small belt wheel 53 is fixedly connected to the hollow rotating shaft 52, the small belt wheel 53 is used for driving the hollow rotating shaft 52 to rotate, the small belt wheel 53 is connected with the large belt wheel 51 through the belt 54, the belt 54 is used for driving the small belt wheel 53 to rotate, the rotary fluted disc 55 is fixedly connected to the bottom end of the hollow rotating shaft 52, and the rotary fluted disc 55 is used for driving the rotary clamping rod 49 to rotate.

The powder filtering component 6 comprises a fixed block 61, a screw 62, a filtering groove ring 63, a rotating frame 64 and a push plate 65, wherein the fixed block 61 is fixedly connected to the bottom of one side of the concave lifting rod 46 far away from the lifting rod 45, the fixed block 61 is used for driving the screw 62 to move, the screw 62 is fixedly connected to the bottom of the fixed block 61 and is used for enabling the rotating frame 64 to rotate along the upper thread of the screw 62, the filtering groove ring 63 is fixedly connected to the inner side of the grinding frame 3, the filtering groove ring 63 is used for separating qualified hard alloy powder from larger hard alloy particles, the rotating frame 64 is connected to the screw 62 in a thread fit mode, the rotating frame 64 is used for driving the push plate 65 to rotate, the rotating frame 64 is in sliding fit with the filtering groove ring 63, the push plates 65 are fixedly connected to the tops of the four sides of the rotating frame 64, the push plates 65 are used for pushing the hard alloy powder in the filtering groove ring, and the push plates 65 are in contact with the inner bottom of the sliding grooves of the filtering groove ring 63.

The hard alloy leftover materials are put into the grinding frame 3 from the top, then the motor 42 is controlled manually to drive the power shaft 43 and the device on the power shaft to rotate, the convex disc 44 firstly pushes the lifting rod 45 and the device on the lifting rod to move upwards along with the rotation of the power shaft 43, the lifting rod 45 drives the grinding cone 47 and the device on the grinding cone 47 to move upwards through the concave lifting rod 46 when moving, meanwhile, the large belt wheel 51 drives the small belt wheel 53 to rotate through the belt 54 when rotating along with the power shaft 43, and further drives the hollow rotating shaft 52 and the rotating grooved disc 55 to rotate, when the grinding cone 47 and the device on the grinding cone 47 move upwards until the rotating clamping rod 49 contacts with the rotating grooved disc 55, the rotating grooved disc 55 pushes the rotating clamping rod 49 to move downwards, when the rotating grooved disc 55 rotates until the groove at the bottom contacts with the rotating clamping rod 49, the rotating grooved disc 55 drives the hollow column 48 and the device on the hollow column through the rotating clamping rod 49, and then the rotating clamping rod 49 returns under the action of the compression spring 410, and the rotating grooved disc 55 is clamped, so under the matching of the grinding frame 3 and the cover frame 31, the grinding cone 47 rotates and rises and simultaneously grinds the hard alloy leftover materials, the ground hard alloy powder slides into the filtering grooved ring 63 along the grinding cone 47, then when the convex disc 44 rotates to the original position along with the power shaft 43 for one circle, the lifting rod 45 moves downwards along the convex disc 44 to reset and drives the concave lifting rod 46 and the device thereon to reset, and the lifting rod 45 continuously moves up and down repeatedly along the convex disc 44, so that the grinding cone 47 can continuously grind the hard alloy leftover materials.

When the fixed block 61 drives the screw 62 to ascend along with the concave lifting rod 46, the screw 62 can drive the rotating frame 64 to rotate along the upper thread thereof and drive the push plate 65 to rotate together, a loading frame is placed below the filter tank ring 63, the push plate 65 can drive the hard alloy powder in the filter tank ring when rotating, and then the qualified hard alloy powder can fall into the loading frame from the small circular hole of the filter tank ring 63, while the larger hard alloy particles can continue to stay in the filter tank ring 63, when the fixed block 61 drives the screw 62 to reset along with the concave lifting rod 46, the screw 62 can drive the rotating frame 64 to reversely rotate along the upper thread thereof to reset and drive the push plate 65 to reset, then after the initial grinding is completed, the motor 42 is manually controlled to be closed, then the spring shifting seat 33 is shifted to not clamp the clamping seat 32, then the cover frame 31 is opened to take out the hard alloy particles in the filter tank ring 63, then the cover frame 31 is closed, the spring striking plate seat 33 is poked to clamp the clamping seat 32 again, and then the motor 42 can be manually controlled again to start to repeat the operation to further grind the hard alloy particles.

Example 2

On the basis of embodiment 1, as shown in fig. 8, the coolant continuous lifting assembly 7 is further included, the coolant continuous lifting assembly 7 is disposed on the lifting assembly 4, the coolant continuous lifting assembly 7 includes a swing rod 71, an ejector rod 72, a lifting groove rod 73, a clamping rod 74 and a second compression spring 75, the swing rod 71 is rotatably disposed on one side of the lifting rod 45, the swing rod 71 can drive the lifting groove rod 73 to move upward, the ejector rod 72 is fixedly connected to one side of the lifting rod 45, the ejector rod 72 is used for abutting against the swing rod 71 to prevent the swing rod 71 from rotating randomly, the ejector rod 72 is in contact with the top of one side of the swing rod 71, the lifting groove rod 73 is slidably disposed on one side of the support plate 41 close to the support seat 2, the lifting groove rod 73 is used for squeezing the two clamping rods 74 to move in a direction away from each other and squeezing the swing rod 71 with the lifting rod 45 as a center, the lifting groove rod 73 is in contact with one side of the swing rod 71 far away from the ejector rod 72, a pair of the clamping rods 74 is slidably disposed on one side of the support plate 41 close to the support seat 2, the clamping rod 74 is used for clamping the lifting groove rod 73 to prevent the lifting groove rod 73 and the upper lifting disc 82 thereof from moving randomly, one end of the clamping rod 74 is in contact with the groove of the lifting groove rod 73, a second compression spring 75 is connected between the clamping rod 74 and the supporting plate 41, and the second compression spring 75 is used for driving the clamping rod 74 to reset.

When the swing rod 71 ascends along with the lifting rod 45, the top rod 72 abuts against the swing rod 71 to prevent the swing rod 71 from rotating randomly, so that the swing rod 71 can drive the lifting groove rod 73 and the upper lifting disc 82 thereof to move upwards, the two clamping rods 74 can be squeezed to move towards the directions away from each other when the lifting groove rod 73 moves, when the lifting groove rod 73 does not move any more, the clamping rods 74 can reset under the action of the second compression springs 75 and contact with the groove of the lifting groove rod 73 again to clamp the lifting groove rod 73 to prevent the lifting groove rod 73 and the upper lifting disc 82 thereof from moving randomly, when the swing rod 71 resets along with the descending of the lifting rod 45, the lifting groove rod 73 can squeeze the swing rod 71 to swing by taking the lifting rod 45 as the center, after the lifting rod 45 resets, the swing rod 71 can reset to contact with the next tooth of the lifting groove rod 73 under the action of gravity, and when the lifting groove rod 73 needs to reset, the swing rod 71 needs to be separated from the lifting groove rod 73 manually, the lifting groove rod 73 is manually pressed again to be reset.

Example 3

Based on embodiment 2, as shown in fig. 9, the polishing apparatus further includes a coolant conveying assembly 8, the coolant conveying assembly 8 is disposed on the supporting base 2, and the coolant continuous lifting assembly 7 and the coolant conveying assembly 8 are matched with each other, so as to cool the components and parts that generate heat due to the grinding of the cemented carbide scrap, and prevent the components and parts from affecting the service life due to the generation of heat, the coolant conveying assembly 8 includes a coolant storage cylinder 81, a lifting disc 82 and a conveying pipe 83, the coolant storage cylinder 81 is mounted on the top of the supporting base 2, the coolant storage cylinder 81 is used for containing coolant, the lifting disc 82 is slidably disposed in the coolant storage cylinder 81, the lifting disc 82 is used for extruding the coolant in the coolant storage cylinder 81 into the conveying pipe 83, one side of the upper portion of the lifting disc 82 is fixedly connected to the upper portion of the lifting slot rod 73, one end of the conveying pipe 83 is fixedly connected to the upper portion of the coolant storage cylinder 81, the conveying pipe 83 is used for enabling the coolant to flow to the top of the grinding cone 47, the delivery pipe 83 passes through the hollow rotating shaft 52, the rotating grooved disk 55 and the hollow column 48, and one end of the delivery pipe 83 remote from the coolant storage cylinder 81 is located in the hollow column 48.

When the lifting disc 82 ascends along with the lifting grooved rod 73, the cooling liquid in the cooling liquid storage cylinder 81 can be extruded into the conveying pipe 83, and further the cooling liquid can flow to the top of the grinding cone 47 along the conveying pipe 83, so that the cooling liquid can flow to the side face of the grinding cone 47 and the inner sides of the grinding frame 3 and the cover frame 31 along the sliding groove at the top of the grinding cone 47, the grinding frame 3 and the cover frame 31 which generate heat due to grinding of the hard alloy leftover materials are cooled, and then when the lifting disc 82 is reset along with the lifting grooved rod 73, the cooling liquid in the cooling liquid storage cylinder 81 can be supplemented.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (3)

1. The utility model provides a carbide leftover bits are retrieved and are ground whitewashed equipment which characterized by: the grinding device comprises a base (1), a supporting seat (2), a grinding frame (3), a cover frame (31), a clamping seat (32), a spring shifting sheet seat (33), a lifting component (4), a rotary grinding component (5) and a powder filtering component (6), wherein the supporting seat (2) is fixedly connected to one side of the top of the base (1), the grinding frame (3) is fixedly connected to one side of the middle of the supporting seat (2), the cover frame (31) is rotatably connected to one side of the grinding frame (3), the clamping seat (32) is fixedly connected to one side of the top of the cover frame (31), the spring shifting sheet seat (33) is fixedly connected to one side of the top of the grinding frame (3), the spring shifting sheet seat (33) is clamped with the clamping seat (32), the lifting component (4) is arranged on the grinding frame (3), the rotary grinding component (5) is arranged on the grinding frame (3), and the powder filtering component (6) is arranged on the lifting component (4);

The lifting assembly (4) comprises a supporting plate (41), a motor (42), a power shaft (43), a convex disc (44), a lifting rod (45), a concave lifting rod (46), a grinding cone body (47), a hollow column (48), a rotary clamping rod (49) and a compression spring I (410), wherein the supporting plate (41) is fixedly connected to one side of the upper part of the grinding frame (3), the motor (42) is installed at the top of the supporting plate (41), the power shaft (43) is fixedly connected to an output shaft of the motor (42), the convex disc (44) is fixedly connected to the middle part of the power shaft (43), the lifting rod (45) is slidably arranged on the supporting plate (41), one side of the upper part of the lifting rod (45) is in contact with the convex disc (44), the concave lifting rod (46) is fixedly connected to the bottom end of the lifting rod (45), the concave lifting rod (46) is in sliding fit with the grinding frame (3), the grinding cone body (47) is placed at the top of one side of the concave lifting rod (46), and the hollow column (48) is fixedly connected to the top of the grinding cone body (47), four rotary clamping rods (49) are arranged at the top of the hollow column (48) in a sliding mode, and a first compression spring (410) is connected between the rotary clamping rods (49) and the top of the hollow column (48);

the rotary grinding assembly (5) comprises a large belt wheel (51), a hollow rotating shaft (52), a small belt wheel (53), a belt (54) and a rotary fluted disc (55), the large belt wheel (51) is fixedly connected to the upper part of the power shaft (43), the hollow rotating shaft (52) is rotatably arranged on the upper part of the grinding frame (3), the small belt wheel (53) is fixedly connected to the hollow rotating shaft (52), the small belt wheel (53) is connected with the large belt wheel (51) through the belt (54), and the rotary fluted disc (55) is fixedly connected to the bottom end of the hollow rotating shaft (52);

Powder filtering component (6) is including fixed block (61), screw rod (62), filter tank ring (63), rotating turret (64) and push pedal (65), fixed block (61) rigid coupling is in spill one side bottom of lifting rod (46), fixed block (61) bottom rigid coupling has screw rod (62), filter tank ring (63) rigid coupling is inboard in grinding frame (3), be connected with rotating turret (64) through screw-thread fit's mode on screw rod (62), rotating turret (64) and filter tank ring (63) sliding type cooperation, four side tops of rotating turret (64) rigid coupling respectively has push pedal (65), bottom contact in push pedal (65) and the spout of filter tank ring (63).

2. The hard alloy leftover material recycling and grinding device as claimed in claim 1, wherein the device is characterized in that: still last lifting subassembly (7) including the coolant liquid, the coolant liquid lasts lifting subassembly (7) and locates on lifting means (4), the coolant liquid lasts lifting subassembly (7) including pendulum rod (71), ejector pin (72), lifting groove pole (73), chucking pole (74) and compression spring two (75), lifting pole (45) one side is located to pendulum rod (71) rotary type, ejector pin (72) rigid coupling in lifting pole (45) one side, ejector pin (72) and the contact of pendulum rod (71) one side top, backup pad (41) one side is located to lifting groove pole (73) slidingtype, lifting groove pole (73) and the contact of pendulum rod (71) opposite side, backup pad (41) one side slidingtype is equipped with a pair of chucking pole (74), chucking pole (74) one end and lifting groove pole (73) groove contact, be connected with compression spring two (75) between chucking pole (74) and backup pad (41).

3. The hard alloy leftover material recycling and grinding device as claimed in claim 2, wherein the device is characterized in that: still including coolant liquid conveying assembly (8), on supporting seat (2) was located in coolant liquid conveying assembly (8), coolant liquid conveying assembly (8) are including coolant liquid storage cylinder (81), lifting dish (82) and conveyer pipe (83), install in supporting seat (2) top coolant liquid storage cylinder (81), in coolant liquid storage cylinder (81) was located to lifting dish (82) slidingtype, lifting dish (82) upper portion one side and lifting channel bar (73) upper portion rigid coupling, conveyer pipe (83) one end rigid coupling in coolant liquid storage cylinder (81) upper portion, hollow pivot (52) are passed in conveyer pipe (83), rotate channel disc (55) and hollow post (48), conveyer pipe (83) other end is located hollow post (48).

Images