SUMMERY OF THE UTILITY MODEL
The automatic material taking and placing device solves the problems that material taking and placing are carried out automatically, and automatic cutting is carried out through the automatic cutting device.
In order to solve the problems, the utility model provides automatic cutting equipment for power battery connecting sheets, which comprises a base, wherein a material taking and placing device and an automatic cutting device are arranged at the top of the base, the material taking and placing device is arranged at the upper and lower material ends of the automatic cutting device, the automatic cutting device comprises a material feeding and discharging mechanism and a pressing mechanism, the pressing mechanism is vertically arranged right below the material feeding and discharging mechanism, the pressing mechanism is connected with the material feeding and discharging mechanism in a sliding manner, the material feeding and discharging mechanism comprises a material feeding and discharging module and a lower die fixed on the material feeding and discharging module, the pressing mechanism comprises an upper pressing module and an upper die fixed on the upper pressing module, and the upper die is matched with the lower die.
Preferably, the in-out module comprises a linear slide rail set, a push-pull cylinder and a push-pull plate, the linear slide rail set is connected with the push-pull plate in a sliding mode, the output end of the push-pull cylinder is fixedly connected with the push-pull plate, the lower die is fixedly installed on the push-pull plate, the push-pull cylinder is used for realizing in-out of the push-pull plate, and automatic material in-out is realized.
Preferably, go up die assembly including air cylinder, push down mounting panel, optical axis slide rail set, push down the support, push down the air cylinder install in directly over pushing down the support, push down the mounting panel with optical axis slide rail set sliding connection, push down the air cylinder the output with it is fixed to push down the mounting panel, push down the bottom installation of mounting panel go up the mould, will push down the power transmission through the air cylinder and give and push down the mounting panel and realize going up the moulding-die and closely close with last moulding-die to realize the shaping of material.
Preferably, the upper die comprises an upper pressing die and a cutting knife, the cutting knife is vertically fixed at the bottom of the lower pressing mounting plate, the upper pressing die is connected with the lower pressing mounting plate in a floating mode, the upper pressing die is connected with the cutting knife in a relatively parallel and sliding mode, and excess materials exposed outside the die are cleaned through the cutting knife.
Preferably, get and put the material device including getting and put support, servo electric jar, get and put the assembly, servo electric jar horizontal installation in get the top of putting the support, the output installation of servo electric jar get and put the assembly, can pinpoint the material through servo electric jar.
Preferably, the taking and placing assembly comprises a rotary cylinder, a conversion plate, a material taking cylinder and a material taking unit, the output end of the rotary cylinder is horizontally installed on the conversion plate, the two ends of the conversion plate are symmetrically provided with the material taking cylinder, the output end of the material taking cylinder is installed on the material taking unit, and automatic feeding and discharging can be achieved through the rotary cylinder, the conversion plate and the material taking unit.
Has the beneficial effects that: according to the automatic feeding and discharging device, automatic feeding and discharging can be achieved through the feeding and discharging device, accurate forming of materials and cutting of redundant materials can be achieved through the automatic cutting device, the yield and the product quality are improved, and meanwhile, the labor intensity is reduced.
Detailed Description
In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.
It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the utility model described herein are capable of operation in sequences other than those illustrated or described herein.
In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; may be a mechanical connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.
In the description herein, references to the terms "an embodiment," "one embodiment," and "one implementation," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or implementation is included in at least one embodiment or example implementation of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or implementation. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or implementations.
The embodiments of the present invention will be described in detail with reference to the following specific drawings:
in specific embodiment 1, as shown in fig. 1, an automatic material forming and cutting apparatus includes a base 1, a material taking and placing device and an automatic cutting device are arranged at the top of the base 1, the material taking and placing device is located at a material feeding end and a material discharging end of the automatic cutting device, the automatic cutting device includes a material feeding and discharging mechanism 2 and a pressing mechanism 4, the pressing mechanism 4 is vertically located under the material feeding and discharging mechanism 2, the pressing mechanism 4 is in sliding connection with the material feeding and discharging mechanism 2, the material feeding and discharging mechanism 2 includes a material feeding and discharging module and a lower mold 215 fixed on the material feeding and discharging module, the pressing mechanism includes a pressing module and an upper mold fixed on the upper pressing module, and the upper mold is matched with the lower mold 215.
It should be noted that, the material taking and placing device carries out feeding, and the material is put into the lower die 215 of the material feeding and discharging mechanism 2, and the material feeding and discharging mechanism 2 drives the lower die 215 to enter the pressing mechanism 4, and the upper die and the lower die 215 in the pressing mechanism 4 are matched for press-cutting, and the material feeding and discharging mechanism 2 returns to the original position after press-cutting forming, and the material taking and placing device carries out blanking on the processed material, and the material is automatically fed and discharged through the material taking and placing device, and is automatically cut through the automatic cutting device, so that the labor cost is reduced.
In embodiment 2, as shown in fig. 2 and 3, a linear slide rail set 211 is horizontally disposed in the middle of the top of the base 1, a push-pull plate 212 is disposed at a movable end of the linear slide rail set 211, the push-pull plate 212 is slidably connected to the base 1, a push-pull cylinder is horizontally disposed in the middle of the back of the push-pull plate 212, a lower mold 215 is disposed in the middle of the upper surface of the push-pull plate 212, an optical axis slide rail set 413 is disposed right above the linear slide rail set 211, the optical axis slide rail set 413 is perpendicular to the base 1, a lower press mounting plate 414 is horizontally disposed at the movable end of the optical axis slide rail set 413, an upper press mold 420 and a cut-off knife 415 are vertically disposed at the bottom of the lower press mounting plate 414, the upper press mold 420 is slidably connected to the cut-off knife 415, the upper press mold 420 and the cut-off knife 415 are both located right above the lower mold 215, a lower press bracket 411 is disposed right above the optical axis slide rail set 413, the top of push-down support 411 sets up down air cylinder 412 perpendicularly, the expansion end of push-down air cylinder 412 with push down mounting panel 414 connects, the place ahead and the rear at the top of base 1 correspond respectively and are provided with front stop 217 and backstop 218, the inside of base 1 is provided with waste storage box 111, waste storage box 111 with base 1 sliding connection, the centre of push-and-pull plate 212 is provided with waste material entry 213, waste material entry 213 is in directly over waste storage box 111, the place ahead of base 1 is provided with emergency stop switch 112.
It should be noted that, by driving the extension and retraction of the push-pull cylinder, the push-pull plate 212 drives the lower mold 215 to make reciprocating linear motion in the material taking and placing device and the pressing mechanism 4, thereby realizing automatic material feeding and discharging, by driving the extension and retraction of the push-pull cylinder 412, the pressing down and lifting of the press-down mounting plate 414 are realized, the material is formed by pressing down the upper press mold 420 on the mounting plate 414 and the lower mold 215 on the push-pull plate 212, the excess material is cut by the combined action of the cutter 415 and the lower mold 215, the waste material falls into the waste material storage box 111 automatically through the waste material inlet 213 at the top of the base 1, specifically, the push-pull cylinder is driven to extend out to drive the push-pull plate 212 to enter the right below of the upper mold, the press-down cylinder 412 is driven to press down the press-down mounting plate 414, the upper press mold 420 is driven to press down, while the cutter 415 synchronously presses down to cut the excess material, after the cutting is completed, the pressing cylinder 412 is lifted to the original position, and the push-pull cylinder retracts to drive the lower die 215 to bring back the formed material.
In embodiment 3, as shown in fig. 4 and 5, a first bolt hole and a second bolt hole are symmetrically arranged at two ends of the upper die, a first mounting hole and a second mounting hole are symmetrically arranged at two ends of the mounting plate, the first mounting hole is symmetrical to the first bolt hole, the second mounting hole is symmetrical to the second bolt hole, a first adjustable bolt is arranged on the first bolt hole, a first spring 418 is arranged on the first adjustable bolt, a second adjustable bolt is arranged on the second bolt hole, a second spring 419 is arranged on the second adjustable bolt, the first adjustable bolt penetrates through the first mounting hole and the first spring and is connected with the left end of the upper die 420, the second adjustable bolt penetrates through the second mounting hole and the second spring and is connected with the right end of the upper die 420, and the upper die 420 is slidably connected with the cutting knife 415, the bilateral symmetry of the rear end of push-and-pull plate 212 is provided with first position sleeve 219 and second position sleeve 220, the both sides of push-and-pull plate 212 set up optical axis slide rail group 413, optical axis slide rail group 413 install perpendicularly in the top of base 1, the top of the middle perpendicular to base in the left of optical axis slide rail group 413 is provided with first altitude mixture control piece 216, the top of the middle perpendicular to base on the right side of optical axis slide rail group 413 is provided with second altitude mixture control piece 214, the rear symmetry that pushes down mounting panel 414 is provided with first locating pin 416 and second locating pin 417, first locating pin 416 with first position sleeve 219 cooperatees, second locating pin 417 with second position sleeve 220 cooperatees.
It should be noted that, through the combined action of the first adjustable bolt and the second adjustable bolt, the first height adjusting block 216 and the second height adjusting block 214, the distance of the upper die 420 can be finely adjusted, the shape of a protrusion or a groove on a material to be molded is changed, the first positioning pin 416 is inserted into the first positioning sleeve 219 for positioning, and the second positioning pin 417 is inserted into the second positioning sleeve 220 for positioning, so that the upper die 420 and the lower die 215 can be quickly positioned in the pressing process, the matching precision of the lower die 420 and the lower die 215 is increased, and the product quality is improved.
In specific embodiment 4, as shown in fig. 6, a taking and placing support 311 is vertically arranged at the front end of the base 1, the taking and placing support 311 is horizontally provided with a servo electric cylinder 312, an output end of the servo electric cylinder 312 is vertically provided with a rotary air cylinder 313, an output end of the rotary air cylinder 313 is horizontally provided with a conversion plate 314, two ends of the conversion plate 314 are symmetrically provided with material taking air cylinders 315 with the same structure, an output end of the material taking air cylinder 315 is provided with a material taking buffer member 316, and a material taking suction nozzle 317 is arranged at the lowest end of the material taking buffer member 316.
It should be noted that the servo electric cylinder 312 is driven to make the rotary cylinder 313 reciprocate linearly in the transverse position, the rotary cylinder 313 is driven to make the conversion plate 314 rotate by 180 degrees, the material taking cylinder 315 is driven to make the material taking buffer 316 move up and down perpendicular to the material, and the material taking and placing are realized through the material taking suction nozzle 317, so that the purpose of automatic feeding and discharging is realized.
Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. Various changes and modifications may be made by those skilled in the art without departing from the spirit and scope of the disclosure, and these changes and modifications are intended to fall within the scope of the utility model.