CN210615913U - Electric automatization control improved generation lathe - Google Patents

Abstract

The utility model discloses an electric automation control improved generation lathe belongs to the automatic control field. An electrical automation control improved machine tool, comprising: a conveying mechanism for conveying feedstock, further comprising: set up in the hammering mechanism that is used for hammering the raw materials at conveying mechanism middle part, set up in the climbing mechanism that is used for taut conveying mechanism of conveying mechanism one end, set up in the shrink mechanism that the conveying mechanism other end is used for loose conveying mechanism, the utility model discloses can make the conveyer belt keep normal operation in the twinkling of an eye of tup hammering stock, avoided the conveyer belt to corrugate or the conveyer belt is struggled absolutely, guaranteed the continuation of conveyer belt transport stock.

Description

Electric automatization control improved generation lathe

Technical Field

The utility model belongs to the technical field of automatic control, especially, relate to an electrical automation control improved generation lathe.

Background

Machine tools are machines for manufacturing machines, also called as machine tools or machine tools, which are conventionally called machine tools for short, and generally divided into metal cutting machine tools, forging machine tools, woodworking machine tools and the like, in modern machine manufacturing, a plurality of methods for processing machine parts are provided, except cutting, casting, forging, welding, stamping, extruding and the like, but all parts with higher precision requirements and thinner surface roughness requirements generally need to be processed finally on the machine tools by cutting. The forged and pressed blank cannot be immediately conveyed away after the blank is hammered, so that the conveying time is prolonged, the working efficiency is reduced, and a machine tool capable of immediately conveying the forged and pressed blank after the blank is forged and pressed is needed.

SUMMERY OF THE UTILITY MODEL

1. Technical problem to be solved

To the problem that hammering and conveying process that exist among the prior art can not go on simultaneously, the utility model aims to provide an electric automatization control improved machine tool solves the problem that hammering and conveying process can not go on simultaneously.

2. Technical scheme

In order to solve the above problems, the utility model adopts the following technical proposal.

An electrical automation control improved machine tool, comprising: a conveying mechanism for conveying feedstock, further comprising: the conveying mechanism comprises a support, a driving rotary drum, a first driven rotary drum, a second driven rotary drum and a third driven rotary drum, wherein the driving rotary drum, the first driven rotary drum, the second driven rotary drum and the third driven rotary drum are movably arranged on the support and can rotate around the axis of the driving rotary drum and the third driven rotary drum, the driving rotary drum is connected with a driving motor, the first driven rotary drum, the second driven rotary drum and the third driven rotary drum are parallel to each other and can rotate around the axis of the driving rotary drum and the third driven rotary drum, the first driven rotary drum is positioned between the driving rotary drum and the third driven rotary drum, the driving rotary drum is close to the driving rotary drum, and the same conveying belt is sleeved outside the driving rotary drum, the first driven rotary drum, the second driven rotary drum and the third driven rotary drum, conveyer belt and climbing mechanism and shrink mechanism swing joint, and climbing mechanism is located between initiative rotary drum and the first driven rotary drum, and shrink mechanism is located between second driven rotary drum and the third driven rotary drum.

Preferably, the hammering mechanism comprises a hammering rotating shaft, set up the backing plate between two band faces about the conveyer belt middle part, backing plate top surface conflict conveyer belt, backing plate one side is provided with the connecting plate, the perpendicular conveyer belt direction of delivery of connecting plate extending direction, the connecting plate top surface is provided with the vertical pole of vertical upwards extension, the movable groove has been seted up to vertical pole top surface, the movable groove is provided with the connecting rod, the perpendicular conveyer belt direction of delivery of connecting rod length direction, the connecting rod is through hammering pivot and movable groove cell wall swing joint, hammer the parallel conveyer belt direction of delivery of pivot axial, the one end that the connecting rod closes on the conveyer belt is provided with the tup that is located the conveyer belt top, the one end side swing joint that the connecting rod deviates from the conveyer belt has the movable slider, the movable slider is through perpendicular pivot and connecting.

Preferably, the power member includes a power drum disposed on one side of the connecting rod, the power drum is axially perpendicular to the belt surface of the conveying belt, a curved chute is disposed on the outer circumferential surface of the power drum, the curved chute is a complete loop and extends from low to high and then extends from high to low to form a loop, the movable slider is matched with the curved chute, a power rotating shaft is coaxially disposed through the power drum, one end of the power rotating shaft is coaxially connected with a power motor, the power motor is disposed on the bracket, and the active motor and the power motor are connected with a PLC control system and controlled by the PLC control system.

Preferably, climbing mechanism including set up the jacking connecting rod between initiative rotary drum and the first driven rotary drum, the parallel initiative rotary drum axial of jacking connecting rod extending direction, jacking connecting rod and leg joint, jacking connecting rod both ends are provided with the vertical guide bar that upwards extends, the upper band face of above-mentioned conveyer belt is located between two guide bars, the vertical jacking spout of extending direction has been seted up to two guide bar opposite sides, be provided with the gliding jacking pivot of jacking spout guiding direction that can follow between two jacking spouts, the outside coaxial cover of jacking pivot is equipped with the jacking rotary drum, jacking rotary drum conflict conveyer belt, jacking rotary drum below is provided with the gliding jacking push rod of jacking spout guiding direction that can follow, be provided with a plurality of jacking springs between jacking push rod and the jacking connecting rod.

Preferably, the contraction mechanism comprises two steering drums arranged between a second driven drum and a third driven drum, the two steering drums are movably connected with the support, the two steering drums are parallel to the second driven drum, a contraction connecting rod is arranged between the two steering drums and is parallel to the steering drums, the contraction connecting rod is connected with the support, two ends of the contraction connecting rod are provided with a contraction vertical rod extending vertically and downwardly, the opposite surface of the contraction vertical rod is provided with a contraction chute, the extension direction of the contraction chute is parallel to the length direction of the contraction vertical rod, a contraction rotating shaft capable of sliding along the guide direction of the contraction chute is arranged between the two contraction chutes, the contraction rotating shaft is parallel to the contraction connecting rod, the contraction rotating drums are coaxially sleeved outside the contraction rotating shaft, a contraction push rod capable of sliding along the guide direction of the contraction chute is arranged between the contraction rotating drums and the contraction connecting rod, and a plurality of contraction springs are arranged, the lower belt surface of the conveyor belt extends to a second driven rotary drum through a turning rotary drum, a contraction rotary drum and the other turning rotary drum.

3. Has the advantages that:

1. the utility model discloses place the stock and be close to the one end of initiative rotary drum at the conveyer belt, start through PLC control system control initiative motor and motor power, the initiative motor drives the rotation of initiative rotary drum, the rotation of initiative rotary drum drives the conveyer belt motion and drives first driven rotary drum, second driven rotary drum, third driven rotary drum and rotate, meanwhile, the jacking rotary drum, turn to rotary drum and jacking rotary drum rotate, the motor power rotates and drives the rotation of power pivot, the power pivot drives the rotation of power rotary drum, the activity slider slides along crooked spout and drives the connecting rod and sway from top to bottom at this moment, the connecting rod drives the tup and sways from top to bottom, the tup hits the stock when the stock moves to tup below, in this moment, part conveyer belt below the stock is fixed, the initiative motor still rotates and drives other positions of conveyer belt motion at this moment, the jacking spring promotes the jacking push, the jacking push rod pushes the jacking rotary drum to move upwards, and the jacking rotary drum drives the conveying belt to move upwards, so that the conveying of blanks is prevented from being influenced by wrinkling of the conveying belt.

2. The utility model discloses the shrink rotary drum is pressed to the lower tape surface of conveyer belt and through shrink push rod extrusion shrink spring, and the bellied part of lower tape surface of conveyer belt is pressed flatly, has avoided the lower tape surface to struggle absolutely.

Drawings

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

FIG. 2 is a schematic view of the overall structure of the present invention;

fig. 3 is a schematic structural view of the jacking mechanism of the present invention;

fig. 4 is a schematic structural view of the retracting mechanism of the present invention;

FIG. 5 is a schematic view of the connection structure of the connecting rod and the movable slider of the present invention;

fig. 6 is a schematic structural view of the power member of the present invention.

The reference numbers in the figures illustrate:

10. a conveying mechanism; 110. a driving drum; 120. a first driven drum; 130. a second driven drum; 140. a third driven drum; 150. a conveyor belt; 20. a hammering mechanism; 210. a base plate; 220. a connecting plate; 230. a vertical rod; 240. a movable groove; 250. hammering the rotating shaft; 260. a connecting rod; 270. beating head; 280. a power member; 281. a power motor; 282. a power shaft; 283. bending the chute; 284. a power drum; 290. a movable slide block; 30. a jacking mechanism; 310. a guide rod; 320. jacking a connecting rod; 330. jacking a chute; 340. a jacking spring; 350. jacking the rotary drum; 360. jacking a rotating shaft; 370. jacking a push rod; 40. a retracting mechanism; 410. a steering drum; 420. shrinking the vertical rod; 430. retracting the chute; 440. a retracting connecting rod; 450. a retraction spring; 460. retracting the push rod; 470. contracting the rotating drum; 480. the rotating shaft is retracted.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the mechanism or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

As shown in fig. 1 to 6, an electrical automation control improved machine tool includes: a conveying mechanism 10 for conveying a feedstock, further comprising: the device comprises a hammering mechanism 20 arranged in the middle of a conveying mechanism 10 and used for hammering raw materials, a jacking mechanism 30 arranged at one end of the conveying mechanism 10 and used for tensioning the conveying mechanism 10, and a contraction mechanism 40 arranged at the other end of the conveying mechanism 10 and used for loosening the conveying mechanism 10, wherein the jacking mechanism 30 and the contraction mechanism 40 are movably connected with the conveying mechanism 10.

The conveying mechanism 10 comprises a support, a driving drum 110 movably arranged on the support, a first driven drum 120, a second driven drum 130 and a third driven drum 140, wherein the driving drum 110 is connected with a driving motor, the driving drum 110, the first driven drum 120, the second driven drum 130 and the third driven drum 140 are parallel to each other and can rotate around the axes of the driving drum, the first driven drum 120 and the second driven drum 130 are positioned between the driving drum 110 and the third driven drum 140, the first driven drum 120 is close to the driving drum 110, the first driven drum 120, the second driven drum 130 and the third driven drum 140 are externally sleeved with a same conveying belt 150, and the conveying belt 150 is movably connected with the jacking mechanism 30 and the contraction mechanism 40, with the jacking mechanism 30 located between the driving drum 110 and the first driven drum 120 and the retraction mechanism 40 located between the second driven drum 130 and the third driven drum 140.

The hammering mechanism 20 comprises a hammering rotating shaft 250, a backing plate 210 arranged between the upper and lower two belt surfaces of the middle part of the conveyer belt 150, the top surface of the backing plate 210 is abutted against the conveyer belt 150, one side of the backing plate 210 is provided with a connecting plate 220, the extending direction of the connecting plate 220 is vertical to the conveying direction of the conveyer belt 150, the top surface of the connecting plate 220 is provided with a vertical rod 230 extending upwards vertically, the top surface of the vertical rod 230 is provided with a movable groove 240, a connecting rod 260 is arranged in the movable groove 240, the length direction of the connecting rod 260 is vertical to the conveying direction of the conveyer belt 150, the connecting rod 260 is movably connected with the groove wall of the movable groove 240 through the hammering rotating shaft 250, the hammering rotating shaft 250 is axially parallel to the conveying direction of the conveyer belt 150, one end of the connecting rod 260 close to the conveyer belt 150, the vertical axis is perpendicular to the length direction of the connecting rod 260, and the movable slider 290 is connected with a power member 280.

The power member 280 comprises a power drum 284 arranged on one side of the connecting rod 260, the power drum 284 is axially vertical to the belt surface of the conveyer belt 150, a curved chute 283 is arranged on the outer circular surface of the power drum 284, the curved chute 283 is a complete loop and extends from low to high and then extends from high to low to form a loop, the movable slider 290 is matched with the curved chute 283, a power rotating shaft 282 is coaxially arranged in the power drum 284 in a penetrating manner, one end of the power rotating shaft 282 is coaxially connected with a power motor 281, the power motor 281 is arranged on the bracket, and the driving motor and the power motor 281 are connected with a PLC control system and controlled by the PLC control system.

Climbing mechanism 30 including setting up the jacking connecting rod 320 between initiative rotary drum 110 and the first driven rotary drum 120, the parallel initiative rotary drum 110 axial of jacking connecting rod 320 extending direction, jacking connecting rod 320 and leg joint, jacking connecting rod 320 both ends are provided with the vertical guide bar 310 that upwards extends, the upper band face of above-mentioned conveyer belt 150 is located between two guide bars 310, the vertical jacking spout 330 of extending direction has been seted up to two guide bar 310 opposite sides, be provided with between two jacking spouts 330 and follow the gliding jacking pivot 360 of jacking spout 330 direction, the outside coaxial cover of jacking pivot 360 is equipped with jacking rotary drum 350, jacking rotary drum 350 contradicts conveyer belt 150, jacking rotary drum 350 below is provided with can follow the gliding jacking push rod 370 of jacking spout 330 direction, be provided with a plurality of jacking springs 340 between jacking push rod 370 and the jacking connecting rod 320.

Further, in order to make the stress uniform, the jacking springs 340 are uniformly arranged along the length direction of the jacking connecting rod 320 at intervals.

Furthermore, the surface of the jacking push rod 370 is smooth, and smooth glass is adopted, so that the jacking push rod 370 is prevented from influencing the rotation of the jacking rotary drum 350.

The contraction mechanism 40 comprises two steering drums 410 arranged between the second driven drum 130 and the third driven drum 140, the two steering drums 410 are movably connected with the support, the two steering drums 410 are parallel to the second driven drum 130, a contraction connecting rod 440 is arranged between the two steering drums 410, the contraction connecting rod 440 is parallel to the steering drums 410, the contraction connecting rod 440 is connected with the support, two ends of the contraction connecting rod 440 are provided with a contraction vertical rod 420 extending vertically and downwardly, a contraction sliding chute 430 is arranged on the opposite surface of the contraction vertical rod 420, the extension direction of the contraction sliding chute 430 is parallel to the length direction of the contraction vertical rod 420, a contraction rotating shaft 480 capable of sliding along the guide direction of the contraction sliding chute 430 is arranged between the two contraction sliding chutes 430, the contraction rotating shaft 480 is parallel to the contraction connecting rod 440, a contraction rotating drum 470 is coaxially sleeved outside the contraction rotating shaft 480, a contraction pushing rod 460 capable of sliding along the guide direction of the contraction sliding chute, a plurality of contracting springs 450 are arranged between the contracting pushing rod 460 and the contracting connecting rod 440, and the lower belt surface of the conveyor belt 150 extends to the second driven drum 130 through one steering drum 410, the contracting drum 470 and the other steering drum 410.

To further enhance, the jacking mechanism 30 is provided with a reversing drum that functions in the same way as the steering drum 410.

When the device is used, a blank is placed at one end of the conveyer belt 150 close to the driving rotary drum 110, the driving motor and the power motor 281 are controlled to start through the PLC control system, the driving motor drives the driving rotary drum 110 to rotate, the driving rotary drum 110 rotates to drive the conveyer belt 150 to move and drive the first driven rotary drum 120, the second driven rotary drum 130 and the third driven rotary drum 140 to rotate, meanwhile, the jacking rotary drum 350, the steering rotary drum 410 and the jacking rotary drum 350 rotate, the power motor 281 rotates to drive the power rotary shaft 282 to rotate, the power rotary shaft 282 drives the power rotary drum 284 to rotate, at the moment, the movable sliding block 290 slides along the bending chute 283 and drives the connecting rod 260 to swing up and down, the connecting rod 260 drives the hammer head 270 to swing up and down, when the blank moves to the position below the hammer head 270, at the moment, the conveyer belt 150 below the blank is fixed, at the moment, at this moment, the jacking spring 340 pushes the jacking push rod 370 to slide upwards, the jacking push rod 370 pushes the jacking drum 350 to move upwards, the jacking drum 350 drives the conveying belt 150 to move upwards, so that the conveying belt 150 is prevented from wrinkling, meanwhile, the lower belt surface of the conveying belt 150 presses the contraction drum 470 and extrudes the contraction spring 450 through the contraction push rod 460, the convex part of the lower belt surface of the conveying belt 150 is pressed flat, and the lower belt surface is prevented from breaking.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (5)

1. An electrical automation control improved machine tool, comprising: conveying mechanism (10) for conveying raw materials, characterized by further comprising: the material conveying device comprises a hammering mechanism (20) arranged in the middle of a conveying mechanism (10) and used for hammering raw materials, a jacking mechanism (30) arranged at one end of the conveying mechanism (10) and used for tensioning the conveying mechanism (10), and a contraction mechanism (40) arranged at the other end of the conveying mechanism (10) and used for loosening the conveying mechanism (10), wherein the jacking mechanism (30) and the contraction mechanism (40) are movably connected with the conveying mechanism (10), the conveying mechanism (10) comprises a support, a driving rotary drum (110), a first driven rotary drum (120), a second driven rotary drum (130) and a third driven rotary drum (140) which are movably arranged on the support, the driving rotary drum (110) is connected with a driving motor, the driving rotary drum (110), the first driven rotary drum (120), the second driven rotary drum (130) and the third driven rotary drum (140) are parallel to each other and can rotate around the axis of the driving rotary drum (110), and the first driven rotary drum (120) and the second driven rotary drum (130) are positioned (140) Between, first driven rotary drum (120) is close to initiative rotary drum (110), first driven rotary drum (120), the outside cover of second driven rotary drum (130) and third driven rotary drum (140) is equipped with same conveyer belt (150), conveyer belt (150) and climbing mechanism (30) and shrink mechanism (40) swing joint, and climbing mechanism (30) are located between initiative rotary drum (110) and first driven rotary drum (120), shrink mechanism (40) are located between second driven rotary drum (130) and third driven rotary drum (140).

2. An improved machine tool for electrical automation control according to claim 1, wherein: the hammering mechanism (20) comprises a hammering rotating shaft (250) and a base plate (210) arranged between the upper and lower belt surfaces of the middle part of the conveying belt (150), the top surface of the base plate (210) is abutted against the conveying belt (150), one side of the base plate (210) is provided with a connecting plate (220), the extending direction of the connecting plate (220) is vertical to the conveying direction of the conveying belt (150), the top surface of the connecting plate (220) is provided with a vertical rod (230) extending vertically and upwards, the top surface of the vertical rod (230) is provided with a movable groove (240), a connecting rod (260) is arranged in the movable groove (240), the length direction of the connecting rod (260) is vertical to the conveying direction of the conveying belt (150), the connecting rod (260) is movably connected with the groove wall of the movable groove (240) through the hammering rotating shaft (250), the hammering rotating shaft (250) is axially parallel to the conveying direction of the conveying, one end side face, deviating from the conveying belt (150), of the connecting rod (260) is movably connected with a movable sliding block (290), the movable sliding block (290) is movably connected with the connecting rod (260) through a vertical rotating shaft, the vertical rotating shaft is axially perpendicular to the length direction of the connecting rod (260), and the movable sliding block (290) is connected with a power member (280).

3. An improved machine tool for electrical automation control according to claim 2, wherein: the power member (280) comprises a power rotary drum (284) arranged on one side of a connecting rod (260), the axial direction of the power rotary drum (284) is perpendicular to the belt surface of the conveying belt (150), a curved chute (283) is arranged on the outer circular surface of the power rotary drum (284), the curved chute (283) is a complete loop, the loop is formed by extending from low to high and then from high to low, a movable sliding block (290) is matched with the curved chute (283), a power rotary shaft (282) coaxially penetrates through the power rotary drum (284), one end of the power rotary shaft (282) is coaxially connected with a power motor (281), the power motor (281) is arranged on a support, and the driving motor and the power motor (281) are connected with a PLC control system and controlled by the PLC control system.

4. An improved machine tool for electrical automation control according to claim 1, wherein: the jacking mechanism (30) comprises a jacking connecting rod (320) arranged between the driving rotary drum (110) and the first driven rotary drum (120), the extending direction of the jacking connecting rod (320) is parallel to the axial direction of the driving rotary drum (110), the jacking connecting rod (320) is connected with the support, two ends of the jacking connecting rod (320) are provided with guide rods (310) extending vertically upwards, the upper belt surface of the conveying belt (150) is positioned between the two guide rods (310), the opposite sides of the two guide rods (310) are provided with jacking sliding chutes (330) extending vertically, a jacking rotating shaft (360) capable of sliding along the guiding direction of the jacking sliding chutes (330) is arranged between the two jacking sliding chutes (330), the jacking rotary drum (350) is coaxially sleeved outside the jacking rotating shaft (360), the jacking rotary drum (350) is abutted against the conveying belt (150), a jacking push rod (370) capable of sliding along the guiding direction of the jacking sliding chutes (330) is arranged, a plurality of jacking springs (340) are arranged between the jacking push rod (370) and the jacking connecting rod (320).

5. An improved machine tool for electrical automation control according to claim 1, wherein: the contraction mechanism (40) comprises two steering rotary drums (410) arranged between a second driven rotary drum (130) and a third driven rotary drum (140), the two steering rotary drums (410) are movably connected with a support, the two steering rotary drums (410) are parallel to the second driven rotary drum (130), a contraction connecting rod (440) is arranged between the two steering rotary drums (410), the contraction connecting rod (440) is parallel to the steering rotary drums (410), the contraction connecting rod (440) is connected with the support, two ends of the contraction connecting rod (440) are provided with vertical and downward extending contraction vertical rods (420), the opposite surfaces of the contraction vertical rods (420) are provided with contraction sliding chutes (430), the extension direction of the contraction sliding chutes (430) is parallel to the length direction of the contraction vertical rods (420), a contraction rotating shaft (480) capable of sliding along the guide direction of the contraction sliding chutes (430) is arranged between the two contraction sliding chutes (430), and the contraction rotating shaft (480) is parallel to the contraction connecting rod, the shrink rotating shaft (480) is coaxially sleeved with a shrink rotating cylinder (470), a shrink pushing rod (460) capable of sliding along the guide direction of the shrink chute (430) is arranged between the shrink rotating cylinder (470) and the shrink connecting rod (440), a plurality of shrink springs (450) are arranged between the shrink pushing rod (460) and the shrink connecting rod (440), and the lower belt surface of the conveying belt (150) extends to the second driven rotating cylinder (130) through one steering rotating cylinder (410), the shrink rotating cylinder (470) and the other steering rotating cylinder (410).

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