CN111843705B - Toy building blocks triangular prism chamfer equipment of polishing - Google Patents

Abstract

The invention relates to polishing equipment, in particular to toy building block triangular prism chamfer polishing equipment. The invention aims to provide the chamfering and polishing equipment for the triangular prism of the toy building block, which can save labor during operation and ensure the safety of operators during operation. In order to solve the technical problem, the invention provides a toy building block triangular prism chamfer polishing device, which comprises: the supporting frame is connected to one side of the top of the bottom plate, and the cutting frame is connected to the supporting frame; the grinding assembly is arranged between the bottom plate and the supporting frame; and the rotation assembly is arranged between the bottom plate and the cutting frame. According to the invention, the grinding component and the rotation component are matched to operate to grind the triangular prism-shaped building blocks, so that the effect of grinding the triangular prism-shaped building blocks is achieved.

Description

Toy building blocks triangular prism chamfer equipment of polishing

Technical Field

The invention relates to polishing equipment, in particular to toy building block triangular prism chamfer polishing equipment.

Background

The blocks are generally cubic solid wood or plastic toys, generally decorated on each surface with letters or pictures, allowing different arrangements or architectural activities of the blocks in various patterns, developing intelligence for children, making up houses, various animals, etc. Some building blocks are triangular prism-shaped, and triangular prism-shaped building blocks need to be chamfered and polished after the manufacturing is finished, so that the situation that the hand is cut sharply by the chamfer is avoided.

At present, the mode of polishing the triangular prism form building blocks is carried out the chamfer and is polished by the manual work handheld triangular prism form building blocks reciprocating motion in the equipment of polishing usually, and after polishing one side, the angle of readjustment triangular prism form is polished again to accomplish polishing of triangular prism form building blocks, above-mentioned mode needs the manual work to operate repeatedly when the operation and polishes, comparatively consumes the manpower during the operation, and need be cut the hand by the equipment of polishing by manual operation easily when the operation, have certain danger.

Therefore, the need of developing a polishing device for triangular prism chamfer of toy building block, which can save labor during operation and ensure the safety of operators during operation, is urgently needed.

Disclosure of Invention

(1) Technical problem to be solved

In order to overcome the defects that the operation is labor-consuming, the hand is easily cut by polishing equipment through manual operation and the operation is dangerous, the invention provides the polishing equipment for the triangular prism chamfer of the toy building block, which can save labor during operation and ensure the safety of an operator during operation.

(2) Technical scheme

In order to solve the technical problem, the invention provides a toy building block triangular prism chamfer polishing device which comprises a bottom plate, wherein a support frame is connected to one side of the top of the bottom plate, and a cutting frame is connected to the support frame; the polishing assembly is arranged between the bottom plate and the supporting frame; and the rotation assembly is arranged between the bottom plate and the cutting frame.

Preferably, the grinding assembly comprises a motor which is arranged on the other side of the top of the bottom plate, and an output shaft of the motor is connected with a rotating shaft; the three driving gears are uniformly and rotatably connected to the support frame at intervals, and a rack belt is wound among the three driving gears and meshed with the driving gears; the driving rods are arranged in three numbers and are respectively connected to the three driving gears; the driving belt is wound between the rotating shaft and one of the driving rods; the three polishing disks are arranged and respectively connected to the three driving rods; the pressing wheels are arranged in a plurality of ways and are connected to one side of the cutting frame, and the pressing wheels press the toothed belt.

Preferably, the rotation assembly comprises a guide frame connected to the middle of the top of the bottom plate, and the guide frame is connected with a push block in a sliding manner; the connecting cylinder is connected to the pushing block, a guide rod is connected to the connecting cylinder in a sliding mode, and a return spring is connected between the guide rod and the connecting cylinder; the cutting frame is provided with two guide grooves, and the direction rod is in sliding fit with one of the guide grooves; a connecting plate connected to the direction lever; the connecting rod is rotatably connected to the connecting plate and is in sliding fit with the other guide groove; a touch gear connected to the connecting rod; the two touch racks are respectively connected to two sides of the guide groove in sliding fit with the connecting rod, and the touch racks can be meshed with the touch gears; the charging barrel is connected to the connecting rod.

Preferably, the reciprocating assembly comprises a support plate which is connected to the middle part of the guide frame, and the middle part of the support plate is rotatably connected with a connecting rod; the two first bevel gears are respectively connected to the bottom of the connecting rod and the rotating shaft and are meshed with each other; the two fixed plates are respectively connected to two sides of the guide frame, and the lower parts of the fixed plates are rotatably connected with rotating rods; two second bevel gears are arranged and are respectively connected to one of the rotating rods and the top of the connecting rod, and the two second bevel gears are meshed with each other; two chain wheels are arranged and are respectively connected to the two rotating rods, and a chain is wound between the two chain wheels; the guide plate is connected to the bottom of the push block, a sliding block is connected to the guide plate in a sliding mode, and the sliding block is connected with the chain.

Preferably, still including pushing out the subassembly, push out the subassembly including the mount, its connect plant the bottom plate top and be close to one side of cutting frame, install electric putter on the mount, electric putter's telescopic link can stretch into in the feed cylinder.

Preferably, the positioning device also comprises a positioning component, wherein the positioning component comprises a connecting strip which is connected to the connecting plate; a first disc connected to the connection bar; and the second disc is connected to the connecting rod, three magnets are uniformly connected to one side, close to the first disc, of the second disc at intervals along the circumferential direction, and the magnets on the first disc and the second disc are attracted.

(3) Advantageous effects

1. According to the invention, the triangular prism-shaped building blocks are polished by the matching operation of the polishing component and the rotation component, so that the polishing effect on the triangular prism-shaped building blocks is achieved.

2. The invention assists the rotation assembly to operate through the reciprocating assembly and the positioning assembly, does not need manual operation to operate the rotation assembly, and effectively saves manpower.

3. The triangular prism-shaped building block polishing machine is simple to operate and capable of effectively saving manpower, and the triangular prism-shaped building block does not need to be manually held for polishing during operation, so that the safety of operators during operation is effectively guaranteed.

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.

Figure 3 is a schematic view of a first partial perspective view of the sanding assembly of the present invention.

Figure 4 is a schematic view of a second partial perspective view of the sanding assembly of the present invention.

Fig. 5 is a schematic partial perspective view of a rotation assembly according to a first embodiment of the present invention.

Fig. 6 is a partially enlarged structural view of the rotation assembly of the present invention.

Fig. 7 is a second partial perspective view of the rotation assembly of the present invention.

Fig. 8 is a perspective view of the shuttle assembly of the present invention.

Fig. 9 is a schematic perspective view of the pushing assembly of the present invention.

Fig. 10 is a perspective view of the positioning assembly of the present invention.

The labels in the figures are: 1-base plate, 2-support frame, 3-cutting frame, 4-grinding component, 41-motor, 42-rotating shaft, 43-driving belt, 44-toothed belt, 45-driving gear, 46-driving rod, 47-grinding disc, 48-pressing wheel, 5-self-rotating component, 51-guide frame, 52-push block, 53-connecting cylinder, 54-guide rod, 55-reset spring, 56-direction rod, 57-connecting plate, 58-connecting rod, 59-touch gear, 510-touch rack, 511-charging barrel, 6-reciprocating component, 61-first bevel gear, 62-connecting rod, 63-support plate, 64-second bevel gear, 65-rotating rod, 66-fixing plate, 67-chain wheel and 68-chain, 69-sliding block, 610-guide plate, 7-pushing-out component, 71-fixing frame, 72-electric push rod, 8-positioning component, 81-connecting bar, 82-first disk, 83-magnet, 84-second disk and 9-triangular prism-shaped building block.

Detailed Description

The invention is further described below with reference to the figures and examples.

First embodiment

The utility model provides a toy building blocks triangular prism chamfer equipment of polishing, as shown in fig. 1-7, including bottom plate 1, support frame 2 and cutting frame 3, 1 top right side of bottom plate is connected with support frame 2, is connected with cutting frame 3 on the support frame 2, still including polishing subassembly 4 and rotation subassembly 5, is equipped with polishing subassembly 4 between bottom plate 1 and the support frame 2, is equipped with rotation subassembly 5 between bottom plate 1 and the cutting frame 3.

Polishing assembly 4 is including motor 41, pivot 42, the drive belt 43, rack belt 44, drive gear 45, drive rod 46, polish set 47 and pinch roller 48, 1 top left side forward-mounted of bottom plate has motor 41, be connected with pivot 42 on motor 41's the output shaft, even interval rotary type is connected with three drive gear 45 on the support frame 2, it has rack belt 44 to wind between the three drive gear 45, drive gear 45 and rack belt 44 meshing, be connected with drive rod 46 on the drive gear 45, it has drive belt 43 to wind through the belt pulley between pivot 42 and the front side drive rod 46, be connected with on the drive rod 46 and polish set 47, 3 right sides on the cutting frame are connected with two pinch rollers 48, pinch roller 48 pushes down rack belt 44.

The rotation assembly 5 comprises a guide frame 51, a push block 52, a connecting cylinder 53, a guide rod 54, a reset spring 55, a direction rod 56, a connecting plate 57, a connecting rod 58, a touch gear 59, a touch rack 510 and a charging barrel 511, the guide frame 51 is connected in the middle of the top of the bottom plate 1, the push block 52 is slidably connected on the guide frame 51, the connecting cylinder 53 is connected on the push block 52, the guide rod 54 is slidably connected in the connecting cylinder 53, the reset spring 55 is connected between the guide rod 54 and the connecting cylinder 53, the direction rod 56 is connected at the bottom of the guide rod 54, the connecting plate 57 is connected on the direction rod 56, the connecting rod 58 is rotatably connected on the connecting plate 57, the touch gear 59 is connected on the connecting rod 58, the charging barrel 511 is connected on the connecting rod 58, two guide grooves are arranged on the left side of the cutting frame 3 and are arranged up and down, the front and back sides of the upper wall in the lower guide groove are both connected with the touch rack 510, the touch rack 510 can be meshed with the touch gear 59, the direction bar 56 is slidably engaged with the upper guide channel and the connecting bar 58 is slidably engaged with the lower guide channel.

When the triangular prism-shaped building blocks 9 need to be polished, the equipment can be used, firstly, a user can pack the triangular prism-shaped building blocks 9 into the charging barrel 511, then the user starts the motor 41 to drive the rotating shaft 42 to rotate, the rotating shaft 42 rotates to drive the front driving rod 46 to rotate through the driving belt 43, the front driving rod 46 rotates to drive all the driving rods 46 to rotate together through the driving gear 45 and the rack belt 44, the pinch roller 48 can enable the rack belt 44 to be always meshed with the driving gear 45, the driving rod 46 rotates to drive the polishing disc 47 to rotate, then the user pulls the push block 52 to move backwards along the guide frame 51, the guide frame 51 drives all the devices on the guide frame to move backwards together when moving backwards, so as to drive the triangular prism-shaped building blocks 9 to move backwards, when the triangular prism-shaped building blocks 9 move backwards to be in contact with the polishing disc 47 at the foremost side, the triangular prism-shaped building blocks 9 continue to move backwards to be polished through the polishing disc 47 at the foremost side, after polishing, the guide frame 51 is pushed continuously to drive all the devices on the guide frame to move backwards together, when the direction rod 56 and the connecting rod 58 move upwards along the inclined surface of the guide groove, the direction rod 56 moves upwards to drive the guide rod 54 to move upwards, the return spring 55 is compressed, the direction rod 56 and the connecting rod 58 move continuously to drive all the devices on the guide frame to move together, when the direction rod 56 and the connecting rod 58 move to the plane above the guide groove, the touch gear 59 also moves to be meshed with the touch rack 510, at the moment, the touch gear 59 moves continuously to rotate through the touch rack 510, the touch gear 59 rotates to drive the connecting rod 58 to rotate, the connecting rod 58 rotates to drive the charging barrel 511 to rotate, the charging barrel 511 rotates to drive the triangular prism-shaped building block 9 inside the charging barrel 511 to rotate together, when the touch gear 59 is disengaged from the touch rack 510, the triangular prism-shaped building block 9 rotates by exactly one hundred twenty degrees to enable the non-polished surface to be aligned with the next polishing disc 47, at this time, the pushing block 52 is continuously pulled to drive the direction rod 56 and the connecting rod 58 to move downwards along the guide groove for resetting, the resetting spring 55 plays a role in assisting resetting, after the triangular prism-shaped building block 9 moves to be in contact with the next polishing disc 47, the triangular prism-shaped building block 9 continues to move, the other side of the triangular prism-shaped building block 9 can be polished by the next polishing disc 47, then the pushing block 52 is continuously pushed to move backwards, the angle progress of the triangular prism-shaped building block 9 can be adjusted to be polished by touching the rack 510 again, after all three corners of the triangular prism-shaped building block 9 which need to be polished are polished, the pushing block 52 also moves backwards to the limit, at this time, the pushing block 52 can be pulled to move forwards to drive all devices thereon to move forwards together to polish the triangular prism-shaped building block 9 again, when the pushing block 52 moves forwards to the limit, the polished triangular prism-shaped building block 9 can be taken out, and in this way, the triangular prism-shaped building blocks 9 can be polished.

Second embodiment

On the basis of the first embodiment, as shown in fig. 8, the reciprocating assembly 6 is further included, the reciprocating assembly 6 includes a first bevel gear 61, a connecting rod 62, a supporting plate 63, a second bevel gear 64, a rotating rod 65, a fixing plate 66, a chain wheel 67, a chain 68, a sliding block 69 and a guide plate 610, the supporting plate 63 is connected to the middle portion of the front side of the guide frame 51, the connecting rod 62 is rotatably connected to the middle portion of the supporting plate 63, the first bevel gear 61 is connected to the bottom portion of the connecting rod 62 and the rotating shaft 42, the two first bevel gears 61 are engaged with each other, the fixing plate 66 is connected to the upper portions of the front and rear sides of the guide frame 51, the rotating rod 65 is rotatably connected to the lower portion of the fixing plate 66, the second bevel gear 64 is connected to the left end of the rotating rod 65 at the front side and the top portion of the connecting rod 62, the two second bevel gears 64 are engaged with each other, the chain wheel 67 is connected to the rotating rod 65, the chain wheel 68 is wound between the two chain wheels 67, the guide plate 610 is connected to the bottom portion of the push block 52, the guide plate 610 is slidably connected with a slide block 69, and the slide block 69 is rotatably connected with the chain 68.

When the rotating shaft 42 rotates, the connecting rod 62 is driven to rotate through the first bevel gear 61, the connecting rod 62 rotates to drive the front rotating rod 65 to rotate through the second bevel gear 64, the front rotating rod 65 rotates to drive the chain 68 to rotate through the chain wheel 67, the chain 68 rotates to drive the sliding block 69 to rotate, the sliding block 69 rotates to drive the guide plate 610 to reciprocate back and forth, the guide plate 610 reciprocates back and forth to drive the push block 52 to reciprocate back and forth, and therefore the push block 52 does not need to be pulled manually to reciprocate back and forth to polish the triangular prism-shaped building blocks 9, and manpower is effectively saved.

Third embodiment

On the basis of the second embodiment, as shown in fig. 9, the device further includes a pushing-out assembly 7, the pushing-out assembly 7 includes a fixing frame 71 and an electric push rod 72, the fixing frame 71 is connected to the front side of the top of the bottom plate 1, the electric push rod 72 is mounted on the fixing frame 71, and a telescopic rod of the electric push rod 72 can extend into the material barrel 511.

After polishing three prismatic building blocks 9 and finishing, can start electric putter 72 telescopic link extension, electric putter 72 telescopic link extension earlier stretch into in the feed cylinder 511 with the contact of three prismatic building blocks 9, electric putter 72 telescopic link continues the extension afterwards and releases three prismatic building blocks 9 in the feed cylinder 511, so, just do not need the manual work to take out three prismatic building blocks 9, the effectual manpower of having saved.

As shown in fig. 10, the positioning assembly 8 is further included, the positioning assembly 8 includes a connecting bar 81, a first disk 82, a magnet 83 and a second disk 84, the connecting bar 81 is connected to the left side of the connecting plate 57, the first disk 82 is connected to the left end of the connecting bar 81, the second disk 84 is connected to the left end of the connecting bar 58 through the first disk 82, three magnets 83 are uniformly connected to the mutually adjacent sides of the second disk 84 and the first disk 82 at intervals along the circumferential direction, and the magnets 83 on the first disk 82 and the second disk 84 attract each other.

The connecting rod 58 drives the second disk 84 to rotate when rotating through the touch gear 59 and the touch rack 510, the second disk 84 rotates to enable the magnet 83 on the second disk to be no longer attracted with the magnet 83 on the first disk 82, and after the connecting rod 58 rotates, the magnet 83 on the second disk 84 is attracted with the magnet 83 on the first disk 82 again, so that the connecting rod 58 is assisted in positioning when rotating.

The above examples are merely representative of preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that various changes, modifications and substitutions may be made by those skilled in the art without departing from the spirit of the invention, and all are intended to be included within the scope of the invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (4)

1. The utility model provides a toy building blocks triangular prism chamfer equipment of polishing which characterized in that, including: the cutting machine comprises a base plate (1), a support frame (2) is connected to one side of the top of the base plate (1), and a cutting frame (3) is connected to the support frame (2); the grinding assembly (4) is arranged between the bottom plate (1) and the support frame (2); a rotation assembly (5) arranged between the bottom plate (1) and the cutting frame (3);

the grinding component (4) comprises: the motor (41) is arranged on the other side of the top of the bottom plate (1), and an output shaft of the motor (41) is connected with a rotating shaft (42); the three driving gears (45) are arranged in three ways, the three driving gears (45) are uniformly and rotatably connected to the support frame (2) at intervals, a rack belt (44) is wound among the three driving gears (45), and the driving gears (45) are meshed with the rack belt (44); three driving rods (46) are arranged, and the three driving rods (46) are respectively connected to the three driving gears (45); a transmission belt (43) wound between the rotating shaft (42) and one of the transmission rods (46); the three polishing disks (47) are arranged, and the three polishing disks (47) are respectively connected to the three driving rods (46); the pressing wheels (48) are arranged in a plurality of ways, the pressing wheels (48) are all connected to one side of the cutting frame (3), and the pressing wheels (48) press the toothed belt (44);

the rotation assembly (5) comprises: the guide frame (51) is connected to the middle of the top of the bottom plate (1), and the guide frame (51) is connected with a push block (52) in a sliding mode; the connecting cylinder (53) is connected to the push block (52), a guide rod (54) is connected to the connecting cylinder (53) in a sliding mode, and a return spring (55) is connected between the guide rod (54) and the connecting cylinder (53); the direction rod (56) is connected to the bottom of the guide rod (54), two guide grooves are formed in the cutting frame (3), and the direction rod (56) is in sliding fit with one of the guide grooves; a connecting plate (57) connected to the steering rod (56); the connecting rod (58) is rotatably connected to the connecting plate (57), and the connecting rod (58) is in sliding fit with the other guide groove; a touch gear (59) connected to the connecting rod (58); the two touch racks (510) are arranged, the two touch racks (510) are respectively connected to two sides of the guide groove in sliding fit with the connecting rod (58), and the touch racks (510) are meshed with the touch gear (59); a cartridge (511) connected to the connecting rod (58).

2. A toy building block triangular prism chamfer angle sanding device according to claim 1, further comprising a reciprocating assembly (6), the reciprocating assembly (6) comprising: a support plate (63) connected to the middle part of the guide frame (51), wherein the middle part of the support plate (63) is rotatably connected with a connecting rod (62); the two first bevel gears (61) are arranged, the two first bevel gears (61) are respectively connected to the bottom of the connecting rod (62) and the rotating shaft (42), and the two first bevel gears (61) are meshed with each other; the two fixing plates (66) are arranged, the two fixing plates (66) are respectively connected to two sides of the guide frame (51), and the lower part of each fixing plate (66) is rotatably connected with a rotating rod (65); two second bevel gears (64) are arranged, the two second bevel gears (64) are respectively connected to the top of one rotating rod (65) and the top of the connecting rod (62), and the two second bevel gears (64) are meshed with each other; two chain wheels (67) are arranged, the two chain wheels (67) are respectively connected to the two rotating rods (65), and a chain (68) is wound between the two chain wheels (67); and the guide plate (610) is connected to the bottom of the push block (52), a sliding block (69) is connected on the guide plate (610) in a sliding mode, and the sliding block (69) is connected with the chain (68).

3. The toy building block triangular prism chamfer angle grinding device according to claim 2, further comprising a push-out component (7), wherein the push-out component (7) comprises: the fixing frame (71) is connected with one side, close to the cutting frame (3), of the top of the planting bottom plate (1), an electric push rod (72) is installed on the fixing frame (71), and a telescopic rod of the electric push rod (72) can extend into the charging barrel (511).

4. A toy building block triangular prism chamfer angle grinding device according to claim 3, further comprising a positioning assembly (8), the positioning assembly (8) comprising: a connecting bar (81) connected to the connecting plate (57); a first disc (82) connected to the connecting strip (81); and the second disc (84) is connected to the connecting rod (58), three magnets (83) are uniformly connected to one side, close to the first disc (82), of the second disc (84) along the circumferential direction at intervals, and the magnets (83) on the first disc (82) and the second disc (84) attract each other.

Images