CN218577387U - Six processingequipment of square toy piece - Google Patents

Abstract

The utility model discloses a six-side processing device of a cube toy block, wherein an upper processing groove and a lower processing groove which are opened leftwards and are used for the left and right movement of the toy block are formed in the middle of a central support plate; an upper supporting plate is fixed on the upper end surface of the central supporting plate; a lower telescopic groove is formed on the upper end surface of the workbench; a lower pressing die is vertically and movably arranged in the lower telescopic groove; an upper telescopic groove is formed at the left end of the upper supporting plate, and a square groove-shaped feeding groove with an upper opening and a lower opening is formed in the middle of the upper supporting plate; an upper pressing die is vertically and movably arranged in the upper telescopic groove; an outer baffle is formed on the upper end surface of the workbench; the outer baffle consists of a left baffle, a right baffle, a front baffle, a rear baffle, a middle baffle and a central support plate, and gaps for the movement of the toy blocks are arranged between the baffles on the corresponding sides and the four end surfaces of the central support plate; thermoprinting through grooves are formed in four baffles of the outer baffle; a stamping head is arranged in the stamping through groove in a moving manner; the left thermoprinting head is over against the left end opening of the upper and lower processing grooves; utility model advantage: the distance that toy piece processing was removed is short, provides six machining efficiency.

Description

Six processingequipment of square toy piece

Technical Field

The utility model relates to a technical field of the processing of toy piece, concretely relates to six processingequipment of square toy piece.

Background

The general method for thermoprinting the wooden toy in the market is to carbonize the pictures and texts on a thermoprinting plate on the wooden toy by using an electrically heated thermoprinting plate; for a square wood block, four surfaces are thermoprinted, and the other two surfaces are pressed, and the traditional method is that one surface and one surface are manually turned over and placed on a thermoprinting machine for thermoprinting and pressing, so that the mode is low in efficiency and low in thermoprinting quality; the existing equipment can complete the work, but the whole processing flow is too long, so that the position is prone to be inaccurate in the processing process.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a six processingequipment of cube toy piece to the too lengthy technical problem of the whole process flow of current cube toy piece.

The utility model provides an above-mentioned technical problem's technical scheme as follows: a six-face processing device of a cube toy block comprises a workbench and six-face processing devices; a plurality of supporting legs which are uniformly distributed are arranged on the bottom surface of the workbench; the six-face processing device comprises a square plate-shaped central support plate and a translation driving device; an upper and lower processing groove which is opened leftwards and is used for the toy block to move leftwards and rightwards is formed in the middle of the central supporting plate; an upper supporting plate is fixed on the upper end surface of the central supporting plate; a lower telescopic groove is formed on the upper end surface of the workbench; a lower pressing die is vertically and movably arranged in the lower telescopic groove; an upper telescopic groove is formed at the left end of the upper supporting plate, and a square groove-shaped feeding groove with an upper opening and a lower opening is formed in the middle of the upper supporting plate; the feeding groove is positioned on the right side of the lower telescopic groove; an upper pressing die is vertically and movably arranged in the upper telescopic groove; the upper pressing die and the lower pressing die are opposite to the upper processing groove and the lower processing groove; the upper pressing die is positioned on the left side of the lower pressing die; an outer baffle is formed on the upper end surface of the workbench; the outer baffle consists of a left baffle, a right baffle, a front baffle and a rear baffle, and gaps for moving the toy blocks are arranged between the baffles on the corresponding sides and the four end faces of the central support plate; thermoprinting through grooves are formed on four baffles of the outer baffle; a stamping head is arranged in the stamping through groove in a moving manner; the left thermoprinting head is over against the left end opening of the upper and lower processing grooves; a discharge baffle is formed at the rear end of the left end face of the central support plate; a gap for moving the toy blocks is arranged between the discharge baffle and the left part of the baffle at the rear side of the outer baffle; the translation driving device is used for driving the toy blocks to move anticlockwise in a stepping mode along gaps among the upper machining groove, the lower machining groove, the outer baffle and the center supporting plate.

Preferably, the upper end surface of the upper supporting plate is provided with a square frame column-shaped feeding guide sleeve for the vertical movement of the toy block; the lower end opening of the feeding guide sleeve is over against the feeding groove; a right supporting plate is formed at the right end of the upper end surface of the upper supporting plate; a feeding limiting cylinder is fixed on the right end face of the right supporting plate; a feeding limiting pressing block is fixed at the left end of a piston rod of the feeding limiting cylinder; the lower end of the right side wall of the feeding guide sleeve is provided with a limiting perforation for the left and right penetration of the feeding limiting pressing block.

Preferably, a lower hydraulic cylinder is fixed on the lower end surface of the workbench; the lower pressing die is fixed at the upper end of a piston rod of the lower hydraulic cylinder.

Preferably, the left end of the upper end surface of the upper support plate is formed with a U-shaped left support with a downward opening; an upper hydraulic cylinder is fixed on the upper end surface of the left bracket; the upper pressing die is fixed at the lower end of a piston rod of the upper hydraulic cylinder.

Preferably, four vertical supporting plates are formed on the upper end surface of the workbench; a hot stamping cylinder is fixed on the vertical supporting plate; the inside end at the thermoprint cylinder of corresponding side is fixed to the thermoprint printer head.

Preferably, the pushing through grooves are formed at the lower end of the baffle plate on the left side of the outer baffle plate, the right end of the baffle plate on the front side and the rear end of the baffle plate on the right side respectively; the pushing through groove on the left side is over against the gap between the baffle on the front side and the front end face of the central support plate; the pushing through groove on the front side is opposite to a gap between the baffle on the right side and the right end face of the central support plate; the pushing through groove at the rear side is over against the gap between the baffle at the rear side and the rear end face of the central support plate; the translation driving device comprises three front driving seats respectively movably arranged in the pushing through groove, a rear driving seat movably arranged at the rear end of the left end surface of the central supporting plate in a front-and-back mode and a pushing plate arranged in the upper and lower processing grooves in a left-and-right mode; the rear driving seat is L-shaped.

Preferably, a driving support plate is formed on the upper end surface of the workbench; a front driving cylinder is fixed on the driving support plate; the front driving seat is fixed on a piston rod of the front driving cylinder at the corresponding side; a rear driving cylinder is fixed at the right end of the front end face of the discharge baffle; the rear driving seat is fixed at the front end of a piston rod of the rear driving cylinder; a pushing cylinder is fixed on the right side wall of the upper and lower processing tanks; the ejector plate is fixed at the left end of the piston rod of the pushing cylinder.

Preferably, the upper side of four gaps between the four baffles of the outer baffle and the central support plate is respectively provided with an upper baffle; a pair of connecting screw rods are formed on the upper end surface of the upper baffle; a side connecting plate is sleeved on the connecting screw rod; the upper end of the connecting screw rod is in threaded connection with a connecting nut; the other end of the side connecting plate is connected to the central supporting plate through a bolt; the upper baffle plates are upwarped along the arcs at the two ends of the length direction of the gap.

The beneficial effects of the utility model reside in that: the distance that toy piece processing was removed is short, provides six machining efficiency.

Drawings

Fig. 1 is a schematic top view of the present invention;

fig. 2 isbase:Sub>A schematic structural view ofbase:Sub>A sectionbase:Sub>A-base:Sub>A in fig. 1 according to the present invention;

in the figure, 10, a table; 11. supporting legs; 12. a vertical support plate; 13. a drive support plate; 20. Six-face processing device; 21. a center support plate; 210. processing a groove up and down; 211. an upper support plate; 2110. A feed chute; 2111. an upper telescopic groove; 212. a left bracket; 213. a feeding guide sleeve; 2130. limiting and perforating; 214. a right support plate; 22. an outer baffle; 220. pushing the through groove; 23. a discharge baffle; 24. Feeding limit pressing blocks; 241. a feeding limit cylinder; 25. pushing out the plate; 251. a push cylinder; 26. A lower pressing die; 261. a lower hydraulic cylinder; 27. pressing the die; 271. an upper hydraulic cylinder; 28. a printing head is stamped; 281. A hot stamping cylinder; 29. a front drive seat; 291. a front drive cylinder; 292. a rear drive seat; 293. a rear drive cylinder; 30. an upper baffle plate; 31. connecting a screw rod; 32. connecting a nut; 33. side connection board.

Detailed Description

As shown in fig. 1 and 2, a six-side processing device for a cube toy block comprises a workbench 10 and a six-side processing device 20; the bottom surface of the workbench 10 is provided with a plurality of supporting legs 11 which are uniformly distributed; the hexahedral machining device 20 includes a central support plate 21 in a square plate shape and a translation drive device; an upper and lower processing groove 210 which is opened to the left and used for the left and right movement of the toy block is formed in the middle of the central supporting plate 21; an upper supporting plate 211 is fixed on the upper end surface of the central supporting plate 21; a lower telescopic groove 100 is formed on the upper end surface of the workbench 10; a lower pressing die 26 is vertically and movably arranged in the lower telescopic groove 100; an upper telescopic groove 2111 is formed at the left end of the upper supporting plate 211, and a feeding groove 2110 in the shape of a square groove with an upper opening and a lower opening is formed in the middle; the feed chute 2110 is located on the right side of the lower telescopic chute 100; an upper pressing die 27 is vertically and movably arranged in the upper telescopic groove 2111; the upper and lower press dies 27 and 26 face the upper and lower processing grooves 210; the upper die 27 is located on the left side of the lower die 26; an outer baffle 22 is formed on the upper end surface of the workbench 10; the outer baffle 22 consists of four baffles, namely a left baffle, a right baffle, a front baffle and a rear baffle, and gaps for moving the toy blocks are arranged between the baffles on the corresponding sides and the four end faces of the central support plate 21; thermoprinting through grooves are formed on four baffles of the outer baffle; a stamping head 28 is arranged in the stamping through groove; the left hot stamping head 28 is opposite to the left end opening of the upper and lower processing grooves 210; a discharge baffle plate 23 is formed at the rear end of the left end face of the central support plate 21; a gap for moving the toy blocks is arranged between the discharge baffle 23 and the left part of the baffle at the rear side of the outer baffle 22; the translation driving device is used for driving the toy blocks to move along the gaps among the upper and lower processing grooves 210, the outer baffle plates 22 and the center support plate 21 in a step-wise manner anticlockwise.

As shown in fig. 1 and 2, a square-frame columnar feeding guide sleeve 213 for the vertical movement of the toy blocks is formed on the upper end surface of the upper support plate 211; the lower end opening of the feeding guide sleeve 213 is opposite to the feeding groove 2110; a right supporting plate 214 is formed at the right end of the upper end surface of the upper supporting plate 211; a feeding limiting cylinder 241 is fixed on the right end surface of the right supporting plate 214; a feeding limiting pressing block 24 is fixed at the left end of the piston rod of the feeding limiting cylinder 241; the lower end of the right side wall of the feeding guide sleeve 213 is formed with a limiting perforation 2130 for the left and right penetration of the feeding limiting pressing block 24.

As shown in fig. 1 and 2, a lower hydraulic cylinder 261 is fixed to a lower end surface of the table 10; the lower die 26 is fixed to the upper end of the piston rod of the lower hydraulic cylinder 261.

As shown in fig. 1 and 2, a left bracket 212 with a downward opening is formed at the left end of the upper end surface of the upper support plate 211; an upper hydraulic cylinder 271 is fixed on the upper end surface of the left bracket 212; the upper die 27 is fixed to the lower end of the piston rod of the upper hydraulic cylinder 271.

As shown in fig. 1 and 2, four vertical support plates 12 are formed on the upper end surface of the worktable 10; a hot stamping cylinder 281 is fixed on the vertical support plate 12; the stamping head 28 is fixed at the inner end of the stamping cylinder 281 at the corresponding side.

As shown in fig. 1 and 2, the pushing groove 220 is formed at the lower end of the left baffle plate, the right end of the front baffle plate, and the rear end of the right baffle plate of the outer baffle plate 22; the left pushing through groove 220 is over against the gap between the front baffle plate and the front end face of the central support plate 21; the pushing through groove 220 at the front side is over against the gap between the baffle at the right side and the right end face of the central support plate 21; the pushing through groove 220 on the rear side is over against the gap between the baffle on the rear side and the rear end face of the central support plate 21; the translation driving device comprises three front driving seats 29 respectively movably arranged in the pushing through groove 220, a rear driving seat 292 which is movably arranged at the rear end of the left end surface of the central supporting plate 21 in a front-and-back mode, and a pushing plate 25 which is arranged in the vertical processing groove 210 in a left-and-right mode; the rear drive seat 292 is L-shaped.

As shown in fig. 1 and 2, a driving support plate 13 is formed on the upper end surface of the table 10; a front driving cylinder 291 is fixed on the driving support plate 13; the front drive seat 29 is fixed on the piston rod of the front drive cylinder 291 on the corresponding side; a rear driving cylinder 293 is fixed at the right end of the front end face of the discharging baffle plate 23; the rear driving seat 292 is fixed at the front end of a piston rod of the rear driving cylinder 293; a pushing cylinder 251 is fixed on the right side wall of the upper and lower processing tank 210; the ejector plate 25 is fixed to the left end of the piston rod of the ejector cylinder 251.

As shown in fig. 1 and 2, upper baffles 30 are respectively arranged on the upper sides of four gaps between the four baffles of the outer baffle 22 and the central support plate 21; a pair of connecting screws 31 are formed on the upper end surface of the upper baffle 30; the connecting screw rod 31 is sleeved with a side connecting plate 33; the upper end of the connecting screw rod 31 is screwed with a connecting nut 32; the other end of the side connecting plate 33 is connected to the center support plate 21 by a bolt; the upper baffle 30 is raised along the arcs of both ends of the gap in the length direction.

Six processingequipment's of square toy piece theory of operation:

during machining, the vertically placed cube toy blocks are filled in the feeding guide sleeve 213, so that the cube toy at the lowest end enters the upper and lower machining grooves 210, the cube toy on the upper portion is limited by the feeding limiting pressing block 24, then the push plate 25 moves leftwards and returns to the original position, the cube toy is located on the lower pressing die 26, then the lower pressing die 26 rises to press the lower end face of the cube toy, then the push plate 25 moves leftwards and positions, under the abutting action of the subsequent cube toy, the cube toy is located right below the upper pressing die 27, then the upper pressing die 27 descends to press the lower end face of the cube toy, then under the pushing action of the push plate 25, the cube toy enters the front side of the rear driving seat 292, then the left stamping head 28 moves rightwards to stamp the left end face of the cube toy, then under the action of the rear driving seat 292 and the three front driving seats 29, the string of cube toy blocks connected in front and rear moves forwards in a stepping mode along the gap between the outer baffle 22 and the central supporting plate 21, and the rest stamping heads 28 move respectively to the front end face, the right end face of the cube toy and the outer baffle 23 of the cube and the baffle 23;

the distance that toy piece processing was removed is short like this, provides six machining efficiency.

The above description is only for the preferred embodiment of the present invention, and for those skilled in the art, there are variations on the detailed description and the application scope according to the idea of the present invention, and the content of the description should not be construed as a limitation to the present invention.

Claims (8)

1. The utility model provides a six processingequipment of square toy piece which characterized in that: comprises a workbench (10) and a six-surface processing device (20); a plurality of supporting legs (11) which are uniformly distributed are arranged on the bottom surface of the workbench (10); the six-face processing device (20) comprises a central support plate (21) in a square plate shape and a translation driving device; an upper and lower processing groove (210) which is opened leftwards and is used for the toy block to move leftwards and rightwards is formed in the middle of the central supporting plate (21); an upper supporting plate (211) is fixed on the upper end surface of the central supporting plate (21); a lower telescopic groove (100) is formed on the upper end surface of the workbench (10); a lower pressing die (26) is vertically and movably arranged in the lower telescopic groove (100); an upper telescopic groove (2111) is formed at the left end of the upper supporting plate (211), and a square groove-shaped feeding groove (2110) with an upper opening and a lower opening is formed in the middle part; the feeding groove (2110) is positioned on the right side of the lower telescopic groove (100); an upper pressing die (27) is vertically and movably arranged in the upper telescopic groove (2111); the upper pressing die (27) and the lower pressing die (26) are opposite to the upper and lower processing grooves (210); the upper pressing die (27) is positioned at the left side of the lower pressing die (26); an outer baffle (22) is formed on the upper end surface of the workbench (10); the outer baffle (22) consists of four baffles, namely a left baffle, a right baffle, a front baffle and a rear baffle, and gaps for moving the toy blocks are arranged between the baffles on the corresponding sides and the four end surfaces of the central support plate (21); thermoprinting through grooves are formed on four baffles of the outer baffle; a stamping head (28) is arranged in the stamping through groove; the left hot printing head (28) is over against the left end opening of the upper and lower processing grooves (210); a discharge baffle plate (23) is formed at the rear end of the left end face of the central support plate (21); a gap for moving the toy block is arranged between the discharge baffle (23) and the left part of the baffle at the rear side of the outer baffle (22); the translation driving device is used for driving the toy blocks to move anticlockwise in a stepping mode along gaps among the upper machining groove (210), the lower machining groove (210), the outer baffle (22) and the central supporting plate (21).

2. A six-sided machining apparatus for a cube toy block according to claim 1, wherein: a square frame column-shaped feeding guide sleeve (213) for the vertical movement of the toy blocks is formed on the upper end surface of the upper supporting plate (211); the lower end opening of the feeding guide sleeve (213) is over against the feeding groove (2110); a right supporting plate (214) is formed at the right end of the upper end surface of the upper supporting plate (211); a feeding limiting cylinder (241) is fixed on the right end surface of the right supporting plate (214); a feeding limiting pressing block (24) is fixed at the left end of a piston rod of the feeding limiting cylinder (241); the lower end of the right side wall of the feeding guide sleeve (213) is provided with a limiting perforation (2130) for the left and right penetration of the feeding limiting pressing block (24).

3. A six-sided tooling for a cube toy building block according to claim 1 further characterised in that: a lower hydraulic cylinder (261) is fixed on the lower end surface of the workbench (10); the lower pressing die (26) is fixed at the upper end of the piston rod of the lower hydraulic cylinder (261).

4. A six-sided machining apparatus for a cube toy block according to claim 1, wherein: a left bracket (212) with a downward opening and shaped like a U is formed at the left end of the upper end surface of the upper supporting plate (211); an upper hydraulic cylinder (271) is fixed on the upper end surface of the left bracket (212); the upper pressing die (27) is fixed at the lower end of the piston rod of the upper hydraulic cylinder (271).

5. A six-sided machining apparatus for a cube toy block according to claim 1, wherein: four vertical supporting plates (12) are formed on the upper end surface of the workbench (10); a hot stamping cylinder (281) is fixed on the vertical supporting plate (12); the hot stamping head (28) is fixed at the inner side end of the hot stamping air cylinder (281) on the corresponding side.

6. A six-sided machining apparatus for a cube toy block according to claim 1, wherein: the lower end of the baffle on the left side of the outer baffle (22), the right end of the baffle on the front side and the rear end of the baffle on the right side are respectively provided with a pushing through groove (220); the left pushing through groove (220) is opposite to a gap between the baffle on the front side and the front end face of the central support plate (21); the pushing through groove (220) on the front side is opposite to a gap between the baffle on the right side and the right end face of the central support plate (21); the pushing through groove (220) on the rear side is over against the gap between the baffle on the rear side and the rear end face of the central support plate (21); the translation driving device comprises three front driving seats (29) which are respectively movably arranged in the pushing through groove (220), a rear driving seat (292) which is movably arranged at the rear end of the left end surface of the central supporting plate (21) in a front-and-back mode, and a pushing plate (25) which is arranged in the upper and lower processing grooves (210) in a left-and-right mode; the rear driving seat (292) is L-shaped.

7. A six-sided machining apparatus for a cube toy block according to claim 6, wherein: a driving support plate (13) is formed on the upper end surface of the workbench (10); a front driving cylinder (291) is fixed on the driving support plate (13); the front driving seat (29) is fixed on a piston rod of a front driving cylinder (291) on the corresponding side; a rear driving cylinder (293) is fixed at the right end of the front end face of the discharge baffle plate (23); the rear driving seat (292) is fixed at the front end of a piston rod of the rear driving cylinder (293); a pushing cylinder (251) is fixed on the right side wall of the upper and lower processing groove (210); the push-out plate (25) is fixed at the left end of the piston rod of the push cylinder (251).

8. A six-sided machining apparatus for a cube toy block according to claim 1, wherein: upper baffles (30) are respectively arranged at the upper sides of four gaps between the four baffles of the outer baffle (22) and the central support plate (21); a pair of connecting screws (31) are formed on the upper end surface of the upper baffle plate (30); a side connecting plate (33) is sleeved on the connecting screw rod (31); the upper end of the connecting screw rod (31) is connected with a connecting nut (32) in a threaded manner; the other end of the side connecting plate (33) is connected to the central supporting plate (21) through a bolt; the upper baffle (30) is upwarped along the circular arcs at the two ends of the length direction of the gap.

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