CN218135192U - Strip milling machine - Google Patents

Abstract

The utility model provides a strip milling machine, includes drive mechanism, processing mechanism and actuating mechanism, actuating mechanism passes through drive mechanism and drives processing mechanism, drive mechanism includes first milling cutter axle and second milling cutter axle, first milling cutter axle with second milling cutter axle by actuating mechanism drives, processing mechanism includes first milling cutter and second milling cutter, first milling cutter is installed the one end of first milling cutter axle, second milling cutter is installed the one end of second milling cutter axle. The strip milling machine can simplify the structure, reduce energy consumption and improve production efficiency.

Description

Strip milling machine

Technical Field

The utility model relates to a metalwork processing field especially relates to a mill strip machine.

Background

The solid state capacitor manufacture factory can weld a plurality of solid state capacitor's positive pole guide pin to an iron bar when producing solid state capacitor, then becomes this group of solid state capacitor, and after the formation, the positive pole guide pin of cutting off solid state capacitor again, leaves an iron bar that remains the welding needle this moment. In order to save the production cost, the iron bar needs to be recycled, so the iron bar with the residual welding needle needs to cut off the welding needle, then the secondary welding is carried out, and the operation is repeated.

The existing strip milling machine is generally provided with two milling cutters and a plurality of guide wheel sets for pushing the iron strips, and each milling cutter and different guide wheel sets are powered by different power devices, so that the structure is complex and redundant, the occupied space is large, and the manufacturing cost and the use energy consumption of the equipment are increased. And current iron bar clamp plate surfacing that mills the strip machine, when the iron bar gets into between two clamp plates, need less position error, otherwise make the iron bar card pause easily or even damage the iron bar, be unfavorable for the circulation of iron bar, produce great influence and influence the reutilization of iron bar and cause the waste to machining efficiency. After the iron bar is cut, a large amount of scrap iron and fine dust remain on the surface of the iron bar, the existing rust removing and dust removing method usually removes the iron rust and the fine dust on the surface of the iron bar through manual sweeping or fixing a brush by using a simple mechanism, the process consumes manpower, the operation speed is slow, and the rust removing and dust removing rate is low.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a mill strip machine can simplify the structure, reduces the energy consumption, improves production efficiency.

The utility model provides a mill strip machine, including drive mechanism, processing agency and actuating mechanism, actuating mechanism passes through drive mechanism and drives processing agency, drive mechanism includes first milling cutter axle and second milling cutter axle, first milling cutter axle with the second milling cutter axle by actuating mechanism drives, processing agency includes first milling cutter and second milling cutter, first milling cutter is installed the one end of first milling cutter axle, second milling cutter is installed the one end of second milling cutter axle.

In an embodiment, the transmission mechanism further includes a third milling cutter shaft, a first rotating shaft, a shifting member and an impurity removing device, the third milling cutter shaft and the first rotating shaft are both driven by the driving mechanism, the first rotating shaft is used for driving the impurity removing device, and the third milling cutter shaft is used for driving the shifting member to be inserted between the two impurity removing devices.

In an embodiment, the impurity removing device comprises a first gear set and a second gear set, the first gear set and the second gear set are arranged in parallel, a first brush for removing rust is arranged on the first gear set, a second brush for removing dust is arranged on the second gear set, the first gear set and the second gear set are driven by the first rotating shaft, and the first brush and the second brush extend out of the impurity removing device to the processing mechanism.

In an embodiment, the displacement member includes a first punch and a second punch, the first punch is used for moving from one end of the two first gear sets to the middle of the two first gear sets under the driving of a third milling cutter shaft, the second punch is used for moving from one end of the two second gear sets to the middle of the two second gear sets under the driving of a third milling cutter shaft, and the first punch and the second punch are fixedly connected.

In an embodiment, the milling device further comprises a third milling cutter, the third milling cutter is connected to one end of the third milling cutter shaft, and the third milling cutter shaft is driven by the driving mechanism.

In an embodiment, the transmission mechanism further includes a first transmission shaft, the first transmission shaft is driven by the driving mechanism, and the first transmission shaft drives the third milling cutter shaft and the first rotating shaft respectively.

In an embodiment, the transmission mechanism further includes a second transmission shaft, the second transmission shaft is driven by the driving mechanism, the second transmission shaft is provided with a first driving gear for transmitting power, the first milling cutter shaft is provided with a first driven gear for receiving power, and the first driving gear is engaged with the first driven gear.

In an embodiment, the transmission mechanism further includes a third transmission shaft, the third transmission shaft is driven by the second transmission shaft, the third transmission shaft is provided with a second driving gear for receiving power and transmitting power, the second milling cutter shaft is provided with a second driven gear for receiving power, and the second driving gear is meshed with the second driven gear.

In one embodiment, the machining mechanism further comprises a pressing member mechanism for adjusting the running angle of the machined workpiece, the pressing member mechanism comprises a pressing plate and a holder, the pressing plate is hinged to the holder, one surface of the pressing plate, which is used for contacting the machined workpiece, is in an arc shape, and the pressing member mechanism is respectively arranged around the first milling cutter and the second milling cutter.

In an embodiment, the processing mechanism further includes a feeding roller for delivering a processed workpiece, the transmission mechanism further includes the second rotating shaft, the second rotating shaft is driven by the driving mechanism, and the feeding roller is connected to one end of the second rotating shaft.

The utility model provides a mill strip machine drives a plurality of pivots through a actuating mechanism, and a plurality of pivots utilize modes such as belt, chain or gear to make a plurality of cutting, polish, revise and deliver the device and can work the operation for mill the structure of strip machine and simplified, and improve power transmission's flexibility, cancelled a plurality of motors simultaneous workings, reduce the energy consumption, and less milling strip machine's occupation space. This impurity removal device in milling strip machine changes the position of brush through shifting for the brush produces pressure to the ironbar, improves the clearance of ironbar surface impurity. Additionally, the utility model provides an iron bar clamp plate that includes in the strip milling machine has special shape, can reduce the damage of iron bar extravagant and reduce the trouble of course of working.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on these drawings without inventive efforts.

Fig. 1 is a schematic perspective view of a strip milling machine according to a preferred embodiment of the present invention.

Fig. 2 is a perspective view of a transmission mechanism in the bar milling machine shown in fig. 1.

Fig. 3 is a front view of the transmission mechanism of fig. 2.

Fig. 4 is a front view of a processing mechanism in the bar milling machine shown in fig. 1.

Fig. 5 is a perspective view of an impurity removing device in the bar milling machine shown in fig. 1.

FIG. 6 is a plan view of the trash removing apparatus of FIG. 5.

Fig. 7 is a schematic view of the operating state of the transmission mechanism in fig. 2.

Detailed Description

Specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It is obvious that the described embodiments are only some of the embodiments of the present invention, and not all of them. Based on the description of the present invention, all other embodiments obtained by a person skilled in the art without making creative efforts belong to the protection scope of the present invention.

In the description of the present invention, unless otherwise expressly specified or limited, the terms "disposed," "mounted," "connected," and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms can be understood in a specific case to those of ordinary skill in the art.

The terms "upper", "lower", "left", "right", "front", "back", "top", "bottom", "inner", "outer", and the like, refer to an orientation or positional relationship based on that shown in the drawings, or that is conventionally placed during use of the invention, for convenience of description and simplicity of illustration, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the invention.

The terms "first," "second," "third," and the like are used solely to distinguish between similar elements and not to indicate or imply relative importance or a particular order.

The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, including not only those elements listed, but also other elements not expressly listed.

A preferred embodiment of the utility model provides a mill strip machine, please refer to fig. 1 to 4, including drive mechanism 10, processing mechanism 20 and actuating mechanism 30, drive mechanism 10 provides power through actuating mechanism 30 for processing mechanism 20 can operate, drive mechanism 10 includes first mill axle 11 and second mill axle 12, first mill axle 11 and second mill axle 12 are driven by actuating mechanism 30, processing mechanism 20 includes first milling cutter 21 and second milling cutter 22, first milling cutter 21 is installed in the one end of first mill axle 11, second milling cutter 22 is installed in the one end of second mill axle 12.

Specifically, the first milling cutter 21 and the second milling cutter 22 are respectively fixed on the first milling cutter shaft 11 and the second milling cutter shaft 12, and when the driving mechanism 30 directly or indirectly provides power for the first milling cutter shaft 11 and the second milling cutter shaft 12, the first milling cutter 21 and the second milling cutter 22 are respectively driven by the first milling cutter shaft 11 and the second milling cutter shaft 12.

The transmission mechanism 10 further comprises a third milling cutter shaft 13, a first rotating shaft 14, a shifting piece 15 and an impurity removing device 16, wherein the third milling cutter shaft 13 and the first rotating shaft 14 are both driven by a driving mechanism 30 in a direct or indirect mode, the third milling cutter shaft 13 pushes the shifting piece 15 to enable the shifting piece 15 to move from one end of each of the two impurity removing devices 16 to the middle of the two impurity removing devices 16, and the first rotating shaft 14 transmits the power of the driving mechanism 30 to the impurity removing devices 16 to enable the impurity removing devices 16 to operate.

The impurity removing device 16 comprises a first gear set 161 and a second gear set 162, the first gear set 161 and the second gear set 162 are arranged in parallel, a first brush 23 for removing rust is arranged on the first gear set 161, a second brush 24 for removing dust is arranged on the second gear set 162, the first gear set 161 and the second gear set 162 are respectively connected to the first rotating shaft 14, and the first brush 23 and the second brush 24 extend out of the impurity removing device 16 to the processing mechanism 20.

Specifically, the first gear set 161 and the second gear set 162 are fixed on the first rotating shaft 14 in parallel, and the first rotating shaft 14 transmits the power of the driving mechanism 30 to the first gear set 161 and the second gear set 162, so as to realize the operation of the first brush 23 on the first gear set 161 and the second brush 24 on the second gear set 162; wherein, the first gear set 161 and the second gear set 162 are provided with driving gears for transmitting power at the connection position with the first rotating shaft 14, the first gear set 161 is provided with at least one driven gear for receiving power, the second gear set 162 is provided with a plurality of driven gears for receiving power and/or transmitting power, the driven gear of the second gear set 162 is always at least one more than the driven gear of the first gear set 161, the second brush 24 is connected to any one driven gear of the second gear set 162 through a connecting rod, the first brush 23 is connected to the driven gear of the first gear set 161 and the driven gear of the second gear set 162 connected with the second brush 24 through a connecting rod, the transmission ratio of the driving gear of the first gear set 161 and/or the second gear set 162 to the driven gear is 50:30

Referring to fig. 5 to 6, in order to remove impurities on both the upper surface and the lower surface of the workpiece, in this embodiment, two impurity removing devices 16 are disposed in parallel, so that both the upper surface and the lower surface of the workpiece can contact the first brush 23 and the second brush 24 fixed on the impurity removing devices 16, the shifting member 15 includes a first punch 151 and a second punch 152, the first punch 151 moves from one end of the two first gear sets 161 to the middle of the two first gear sets 161 under the driving of the third milling cutter shaft 13, the second punch 152 moves from one end of the two second gear sets 162 to the middle of the two second gear sets 162 under the driving of the third milling cutter shaft 13, the first punch 151 is fixed on the second punch 152, and a spring is connected between the outermost driven wheels on the two first gear sets 161, so that the shifting member 15 can exit from between the two impurity removing devices 16 and return to the original position.

Specifically, when the shifting member 15 moves from one end of the two impurity removing devices 16 to the middle thereof, due to the first punch 151 pressing the first gear set 161, the two first brushes 23 on the two first gear sets 161 are close to the middle, the closer the first punch 151 is to the middle of the two first gear sets 161, the closer the two first brushes 23 are, so that the greater the pressure on the workpiece between the two first brushes 23, the easier the rust on the surface of the workpiece is to be removed; meanwhile, due to the extrusion of the second punch 152 on the second gear set 162, the two second brushes 24 on the two second gear sets 162 are close to each other in the middle, and the closer the second punch 152 is to the middle of the two second gear sets 162, the closer the two second brushes 24 are to the middle, so that the larger the pressure received by the workpiece between the two second brushes 24 is, the easier the west dust on the surface of the workpiece is to be removed.

Referring to fig. 2, the present invention further includes a correction mechanism 40, the correction mechanism 40 is mainly used for restoring the shape of the processed workpiece to a state capable of being used again, the correction mechanism 40 includes a third milling cutter 41, the third milling cutter 41 is disposed to ensure the milling clearance of the processed workpiece and avoid the processed workpiece having a guide pin residue after passing through the first milling cutter 21 and the second milling cutter 22, the third milling cutter 41 is connected to one end of the third milling cutter shaft 13, and the third milling cutter shaft 13 is driven by the driving mechanism 30.

The transmission mechanism 10 further includes a first transmission shaft 17, the first transmission shaft 17 is driven by the driving mechanism 30, and the third milling cutter shaft 13 and the first rotation shaft 14 can indirectly obtain the power of the driving mechanism 30 from the first transmission shaft 17, or directly obtain the power from the driving mechanism 30 through a belt, a chain or a gear.

The transmission mechanism 10 further includes a second transmission shaft 18, the second transmission shaft 18 is driven by the driving mechanism 30, the second transmission shaft 18 is provided with a first driving gear 181 for transmitting power, the first milling cutter shaft 11 is provided with a first driven gear 111 for receiving power, the first driving gear 181 is in meshing transmission with the first driven gear 111, and the transmission ratio of the first driven gear 111 to the first driving gear 181 is 25:81.

the transmission mechanism 10 further includes a third transmission shaft 19, the third transmission shaft 19 is driven by the second transmission shaft 18, the third transmission shaft 19 is provided with a second driving gear 191 for receiving power and transmitting power, the second milling cutter shaft 12 is provided with a second driven gear 121 for receiving power, the second driving gear 191 is meshed with the second driven gear 121 for transmission, and the transmission ratio of the second driving gear 191 to the second driven gear 121 is 25:81.

the processing mechanism 20 further comprises a pressing mechanism 25, the pressing mechanism 25 comprises a pressing plate 251 and a holder 252, the pressing plate 251 is hinged to the holder 252, one surface of the pressing plate 251, which contacts the workpiece, is arc-shaped, the opening of the arc is towards the workpiece, and the pressing mechanism 25 is respectively arranged around the first milling cutter 21 and the second milling cutter 22.

Specifically, the pan feeding department of clamp plate 251 is equipped with the breach, increases the gap of two clamp plates 251, makes things convenient for the work piece to get into the cutting area smoothly to middle part and the afterbody at clamp plate 251 are the arc, and the afterbody position is slightly less than the position of pan feeding mouth, increases clamp plate 251's flexibility, reduces the work piece and is blocked in clamp plate 251 department.

The processing mechanism 20 further includes a feeding roller 26, the transmission mechanism 10 further includes a second rotating shaft 101, the second rotating shaft 101 is driven by the driving mechanism 30, and the feeding roller 26 is connected to one end of the second rotating shaft 101.

The above embodiments are only specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The utility model provides a mill strip machine, its characterized in that includes drive mechanism (10), processing mechanism (20) and actuating mechanism (30), actuating mechanism (30) pass through drive mechanism (10) and drive processing mechanism (20), drive mechanism (10) are including first milling cutter axle (11) and second milling cutter axle (12), first milling cutter axle (11) with second milling cutter axle (12) by actuating mechanism (30) drive, processing mechanism (20) are including first milling cutter (21) and second milling cutter (22), install first milling cutter (21) the one end of first milling cutter axle (11), install second milling cutter (22) the one end of second milling cutter axle (12).

2. The strip milling machine as set forth in claim 1, characterized in that the transmission mechanism (10) further comprises a third milling cutter shaft (13), a first spindle (14), a displacement member (15) and a cleaning device (16), the third milling cutter shaft (13) and the first spindle (14) being driven by the drive mechanism (30), the first spindle (14) being used for driving the cleaning device (16), the third milling cutter shaft (13) being used for driving the displacement member (15) to be inserted in between the two cleaning devices (16).

3. The bar milling machine according to claim 2, characterized in that the cleaning device (16) comprises a first gear set (161) and a second gear set (162), the first gear set (161) and the second gear set (162) are arranged in parallel, a first brush (23) for removing rust is arranged on the first gear set (161), a second brush (24) for removing dust is arranged on the second gear set (162), the first gear set (161) and the second gear set (162) are driven by the first rotating shaft (14), and the first brush (23) and the second brush (24) extend from the cleaning device (16) to the processing mechanism (20).

4. The bar milling machine according to claim 3, characterized in that the displacement element (15) comprises a first punch (151) and a second punch (152), the first punch (151) being adapted to be moved by one end of the two first gear sets (161) towards the middle of the two first gear sets (161) under the drive of the third milling cutter shaft (13), the second punch (152) being adapted to be moved by one end of the two second gear sets (162) towards the middle of the two second gear sets (162) under the drive of the third milling cutter shaft (13), the first punch (151) and the second punch (152) being fixedly connected.

5. The strip milling machine as claimed in claim 2, further comprising a third milling cutter (41), the third milling cutter (41) being connected to one end of the third milling cutter shaft (13), the third milling cutter shaft (13) being carried by the drive mechanism (30).

6. The strip milling machine as claimed in claim 2, characterized in that the transmission mechanism (10) further comprises a first transmission shaft (17), the first transmission shaft (17) being carried by the drive mechanism (30), the first transmission shaft (17) carrying the third milling cutter shaft (13) and the first rotary shaft (14), respectively.

7. The strip milling machine as set forth in claim 1, characterized in that the transmission mechanism (10) further comprises a second transmission shaft (18), the second transmission shaft (18) being carried by the drive mechanism (30), the second transmission shaft (18) being provided with a first driving gear (181) for transmitting power, the first milling cutter shaft (11) being provided with a first driven gear (111) for receiving power, the first driving gear (181) meshing with the first driven gear (111).

8. The strip milling machine as claimed in claim 7, characterized in that the drive mechanism (10) further comprises a third drive shaft (19), the third drive shaft (19) being carried by the second drive shaft (18), the third drive shaft (19) being provided with a second drive gear (191) for receiving power and transmitting power, the second milling cutter shaft (12) being provided with a second driven gear (121) for receiving power, the second drive gear (191) meshing with the second driven gear (121).

9. The strip milling machine as claimed in claim 1, wherein the processing mechanism (20) further comprises a pressing member mechanism (25) for adjusting a running angle of a processed workpiece, the pressing member mechanism (25) comprises a pressing plate (251) and a holder (252), the pressing plate (251) is hinged with the holder (252), a face of the pressing plate (251) for contacting a processed workpiece is arc-shaped, and the pressing member mechanism (25) is respectively arranged around the first milling cutter (21) and the second milling cutter (22).

10. The strip milling machine according to claim 1, characterized in that the machining mechanism (20) further comprises a feeding roller (26) for delivering a workpiece to be machined, the transmission mechanism (10) further comprises a second rotating shaft (101), the second rotating shaft (101) is driven by the driving mechanism (30), and the feeding roller (26) is connected to one end of the second rotating shaft (101).

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