Drawings
Fig. 1 is a perspective view of an aligner for upright unit bodies in accordance with a preferred embodiment of the present invention.
FIG. 2 is a partially exploded view of the alignment machine of the vertical unit of the preferred embodiment.
Fig. 3 is a side view of the frame of the preferred embodiment described above.
FIG. 4 is a side view of the alignment mechanism of the preferred embodiment described above.
Fig. 5 is an enlarged view of a portion of the components of fig. 4.
Fig. 6 is an enlarged view of a portion of the components of fig. 4.
FIG. 7 is a top view of the alignment mechanism of the preferred embodiment described above.
Fig. 8 is an enlarged view of a portion of the components of fig. 7.
FIG. 9A is a schematic view of the operation of the alignment mechanism of the preferred embodiment.
FIG. 9B is a schematic diagram of the operation of the alignment mechanism of the preferred embodiment.
Fig. 10 is a perspective view of an alignment system of the vertical unit body according to a preferred embodiment of the present invention.
FIG. 11 is a schematic diagram of the alignment system operation of the vertical unit cell of the preferred embodiment.
FIG. 12 is a schematic diagram of the alignment system operation of the vertical unit cell of the preferred embodiment.
FIG. 13 is a schematic diagram of the alignment system operation of the vertical unit cell of the preferred embodiment.
Detailed Description
In order to more clearly illustrate the present invention, preferred embodiments are described in detail below with reference to the accompanying drawings. Referring to fig. 1 to 8, there is shown an aligning machine 1 for upright unit bodies according to a preferred embodiment of the present invention, for pushing a plurality of upright unit bodies together, in which the upright unit body in this embodiment is exemplified by a carton B, and includes a controller 10, a frame 20 and an aligning mechanism 30.
The rack 20 includes two upright rails extending in the Z-axis direction and disposed on the rack 20 at an interval, in this embodiment, the upright rails of the rack 20 include two upright brackets 22 and two Z-axis slide rails 23 disposed on the two upright brackets 22, the alignment mechanism 30 is slidably coupled on the Z-axis slide rails 23, the alignment mechanism 30 includes a Z-axis moving unit, an X-axis moving unit, and a Y-axis moving unit, wherein the Z-axis moving unit includes a first belt 302, a first belt pulley 303, a Z-axis driving motor 304, and a connecting rod 305, the first belt pulleys 303 are disposed at the upper and lower ends of the two upright brackets 22 in a group manner, each first belt 302 is wound around a group of first belt pulleys 303, and the two first belt pulleys 303 disposed near the upper side of the rack 20 are connected to one Z-axis driving motor 304 through the connecting rod 305, the Z-axis driving motor 304 is electrically connected to the controller 10 and the aligning mechanism 30 is fixed to the first belt 302, so that the Z-axis driving motor 304 is controlled by the controller 10 and drives the aligning mechanism 30 to move on the Z-axis slide rail 23 through the first belt pulley 303 and the first belt 302, in other embodiments, the number of the vertical rails may also be one, which can also achieve the effect of limiting the aligning mechanism to move in the Z-axis direction. In addition, in practice, the vertical rail may be a slide rail or other member capable of limiting the movement of the alignment mechanism in the Z-axis direction. It should be noted that the frame 20 further includes a chain 24, a pulley 25 and a counterweight mechanism 26, the pulley 25 is disposed on the frame 20, one end of the chain 24 is connected to the counterweight mechanism 26 after passing around the pulley 25, and the other end is connected to the alignment mechanism 30, so as to reduce the load of the Z-axis driving motor 304 and increase the moving speed of the alignment mechanism 30 in the Z-axis direction.
The Z-axis moving unit includes two sliding bases 301 respectively fixed to the two first belts 302, the X-axis moving unit includes a truss 311, a rack 312, two moving bases 313 and a first moving frame 314, the truss 311 is fixed to the two sliding bases 301, the rack 312 is fixed to the upper end of the truss 311, the truss 311 is provided with a sliding rail 315 parallel to the X-axis direction, the two moving bases 313 are slidably connected to the sliding rail 315 of the truss 311, one end of each first moving frame 314 is connected to a corresponding moving base 313, the X-axis moving unit further includes two first driving units 316, such as motors, and two gears 317, the two driving units are respectively fixed to one moving base 313, the two gears 317 are engaged with the rack 312, each gear 317 is driven by one corresponding first driving unit 316 to rotate, the two first driving units 316 are electrically connected to the controller 10, thus, the plurality of first driving units 316 are controlled by the controller 10 to drive each gear 317 to rotate on the rack 312 to respectively drive one first moving frame 314 to move in the X-axis direction and to move toward or away from each other in a horizontal plane; in other embodiments, the two first moving frames 314 are controlled by the controller 10 to move toward the first distance d1 and the second distance d2 in the X-axis direction, wherein the first distance d1 is equal to the second distance d2, and the two first driving units 316 can be controlled by the controller 10 to respectively drive the two moving bases 313 to move toward the second distance d2 in the X-axis direction, wherein the first distance d1 is greater than or less than the second distance d 2.
The Y-axis moving unit includes four second moving frames 321, each first moving frame 314 is provided with a first sliding rail 315 parallel to the Y-axis, the plurality of second moving frames 321 are slidably combined to the first sliding rail 315 in a group of two and respectively disposed at two ends of one first moving frame 314, each second moving frame 321 has a clamping arm 323 extending along the X-axis direction, so that a space for accommodating a plurality of cartons is formed by the clamping arm 323 of each second moving frame 321 and the two first moving frames 314; the Y-axis moving unit further includes two second driving units 324, two second belts 325 and four second pulleys 326, the two second driving units 324 are respectively disposed on a corresponding first moving frame 314, each second driving unit 324 is a motor and electrically connected to the controller 10, the plurality of second pulleys 326 are respectively disposed at two ends of a corresponding first moving frame 314 in a group of two, each second belt 325 bypasses a group of second pulleys 326 and is divided into an upper section 325a and a lower section 325b, one of the group of second pulleys 326 is connected to one second driving unit 324, each second driving unit 324 drives the upper section 325a and the lower section 325b of each second belt 325 to move in opposite directions, wherein a second moving frame 321 is fixedly connected to the upper section 325a and the lower section 325b of each second belt 325 through a fixing member 327, the controller 10 controls the plurality of second driving units 324 to drive the second belt pulleys 326 and the second belt 325 to respectively drive the second moving frames 321 of each group to move toward or away from each other on the horizontal plane.
The number of the second moving frames 321 is four, and in other embodiments, the number of the second moving frames may also be two, for example, one end of each of the two second moving frames is connected to one of the first moving frames, and each of the second moving frames has a clamping arm extending along the X-axis direction, and a space is defined by the two second moving frames and the two first moving frames for accommodating a plurality of cartons, and the two second moving frames are driven by one driving unit to move toward or away from each other on the horizontal plane.
In summary, the plurality of first moving frames 314 and the plurality of second moving frames 321 surround the plurality of cartons B together, and the plurality of cartons B are pushed to close each other by controlling the plurality of first moving frames 314 and the plurality of second moving frames 321 (as shown in fig. 9A and 9B) to move towards each other, so as to eliminate the gaps between the plurality of cartons B, thereby making the arrangement structure of the plurality of cartons B more stable for convenient transportation and transportation; in addition, each of the first movable frames 314 and each of the second movable frames 321 are driven by an independent driving unit, so that a user can control each of the first movable frames 314 and each of the second movable frames 321 to move towards different distances through the controller 10 according to different carton sizes or placement positions, preferably, the controller 10 controls the plurality of first movable frames 314 and the plurality of second movable frames 321 to simultaneously move towards or away from each other on the same horizontal plane, thereby not only increasing the working efficiency, but also avoiding the problem that the cartons topple towards a certain direction due to different action times of the first movable frames 314 and the second movable frames 321 moving towards each other; furthermore, the aligning mechanism 30 of the present invention is controlled by the controller 10 to move in the Z-axis direction, so that, after the aligning mechanism 30 is controlled to move to an appropriate height in the Z-axis direction according to the stacking height of the cartons B, the aligning mechanism 30 is controlled to push the plurality of cartons B in the X-axis and Y-axis directions to close each other.
Referring to fig. 10 to 13, an aligning system 2 of vertical units according to the present invention comprises a conveyor 40, a clamping device 50 and the aligning machine 1 of the vertical units according to the preferred embodiment, wherein the conveyor 40 is connected to the frame 20 for conveying a pallet S to a workstation W, the clamping device 50 is used for placing a plurality of vertical units on the pallet S, the vertical units are cartons B, the aligning machine 1 of the vertical units surrounds the vertical units through the two first movable frames 314 and the second movable frames 321, and the two first movable frames 314 and the second movable frames 321 are controlled to move toward each other to push the cartons B toward each other, so that the clamping device 50 horizontally arranges the cartons B above the pallet S to form a layer La to be aligned, and the controller 10, according to product information of the cartons B, such as length, the controller 10, Width or height, etc., and after controlling the aligning mechanism 30 to move to the periphery of the layer La to be aligned in the Z-axis direction, the controller 10 controls the aligning mechanism 30 to clamp the cartons of the layer La to be aligned to form an aligned layer Lb after they are close to each other, the clamping device 50 horizontally arranges a plurality of cartons on the aligned layer to form another layer to be aligned, and repeats the above operations for a plurality of times, and after the desired height is reached, the controller 10 controls the aligning mechanism 30 to move to the top of the plurality of cartons to facilitate the conveyor belt 40 to convey the aligned cartons to the next station, so that automatic alignment and stacking of the upright units can be completed, and the problem that the stacking structure of the upright units is unstable and is prone to toppling or shifting during the conveying process can be solved.
The above description is only a preferred embodiment of the present invention, and all equivalent changes and modifications to the present invention as described and claimed should be included in the scope of the present invention.
Description of the reference numerals
[ invention ]
1 alignment machine of vertical unit bodies
10 controller
20 frame
22 upright bracket 23Z-axis slide rail 24 chain
25-pulley 26-counterweight mechanism
30 arraying mechanism
301 a slide base 302, a first belt 303, a first pulley
304Z-axis drive motor 305 linkage
311 truss 312 rack
313 moving seat 314 first moving rack 315 slide rail
316 first drive unit 317 gear 321 second mobile frame
322 first slide 323 gripper arm 324 second drive unit
325 second belt 326 second pulley 325a upper section
325b lower section 327 securing element
40 conveying belt
50 clamping device
B paper box
S pallet
W workstation
La to-be-aligned layer Lb aligned layer
d1 first distance d2 second distance
2 alignment machine of vertical unit bodies