CN210551719U

CN210551719U - Last servo blanking mechanism of tubular product cutting production line

Info

Publication number: CN210551719U
Application number: CN201921557987.1U
Authority: CN
Inventors: 蒋习锋; 王明利; 岳念举
Original assignee: Jinan GWeike Science & Technology Co ltd
Current assignee: Jinan Jinweike Laser Technology Co ltd
Priority date: 2019-09-17
Filing date: 2019-09-17
Publication date: 2020-05-19
Anticipated expiration: 2029-09-17

Abstract

The utility model provides a pipe cutting production line end follow-up blanking mechanism, belonging to the technical field of pipe cutting, which comprises an upstream fixing seat and a downstream fixing seat, wherein the upstream end of a transmission shaft is coaxially and fixedly connected with an upstream gear, and the downstream end of the transmission shaft is coaxially and fixedly connected with a downstream gear; the upstream end face of the upstream fixing seat is fixedly connected with a follow-up motor seat, a follow-up motor is fixedly arranged on the follow-up motor seat, a shaft of the follow-up motor outputs a driving gear, and the driving gear is meshed with an upstream gear; the upstream end of the unloading supporting plate extends towards the upstream direction, the bottom surface of the unloading supporting plate of the extension part is provided with an inclined lifting plate hinged support, and an inclined lifting cylinder is hinged on the inclined lifting plate hinged support. The utility model discloses be favorable to making the height of backup pad cooperation tubular product of unloading, on the other hand, the slope is unloaded and is favorable to making the tubular product from cutting production line direct tilting downward independently roll unload convenient and fast, easily control after cutting.

Description

Last servo blanking mechanism of tubular product cutting production line

Technical Field

The utility model belongs to the technical field of the tubular product cutting technique and specifically relates to a last servo-actuated unloading mechanism of tubular product cutting production line.

Background

Generally, the last unloading of line after the cutting of tubular product cutting production line adopts to snatch the promotion, axial to carry, lateral transport mostly, and these three kinds of circumstances all need be equipped with extra power unit at the end of the line outside the main part production line, and the process matching of the automated processing of extra power unit and production line still needs extra correction to match, even match the mistake emergence on the operating mode still sometimes can appear after correcting. How to design and manufacture a device capable of integrating the line end unloading after the pipe cutting into the whole production line equipment for uniform automatic precise operation is an important subject to be solved urgently in the modern pipe cutting industry.

Disclosure of Invention

The technical task of the utility model is to solve the not enough of prior art, provide a last servo-actuated unloading mechanism of tubular product cutting production line.

The technical proposal of the utility model is realized in the following way that the end follow-up blanking mechanism of the pipe cutting production line of the utility model structurally comprises an upstream fixing seat and a downstream fixing seat,

the upstream end surface of the upstream fixed seat is fixedly connected with an upstream fixed sliding block;

an upstream shaft seat is arranged on the seat body of the upstream fixed seat;

the downstream end surface of the downstream fixed seat is fixedly connected with a downstream fixed sliding block;

a downstream shaft seat is arranged on the seat body of the downstream fixed seat;

the inner side plate surface of the upstream follow-up lifting plate is fixedly connected with an upstream guide rail and an upstream rack, the upstream guide rail and the upstream rack are parallel to each other and are vertically arranged, and the upstream guide rail is in sliding fit with the upstream fixed sliding block;

the downstream guide rail and the downstream rack are parallel and vertically arranged, and the downstream guide rail is in sliding fit with the downstream fixed sliding block;

a transmission shaft is connected between the upstream shaft seat and the downstream shaft seat in a penetrating manner, and the transmission shaft is horizontally arranged;

the upstream end of the transmission shaft is coaxially and fixedly connected with an upstream gear, and the downstream end of the transmission shaft is coaxially and fixedly connected with a downstream gear;

the upstream gear is meshed with the upstream rack;

the downstream gear is meshed with the downstream rack;

the upstream end face of the upstream fixing seat is fixedly connected with a follow-up motor seat, a follow-up motor is fixedly arranged on the follow-up motor seat, a shaft of the follow-up motor outputs a driving gear, and the driving gear is meshed with an upstream gear;

the servo motor drives the driving gear to rotate to drive the transmission shaft to rotate, the transmission shaft rotates, and the upstream gear and the downstream gear synchronously rotate at the same time, so that the upstream rack and the downstream rack are synchronously driven to move to drive the upstream follow-up lifting plate and the downstream follow-up lifting plate to move up and down.

The front edge of the outer side plate surface of the upstream follow-up lifting plate is fixedly connected with an upstream air cylinder hinge seat, an upstream air cylinder is hinged on the upstream air cylinder hinge seat, and the upstream air cylinder is vertically arranged;

the front edge of the outer side plate surface of the downstream follow-up lifting plate is fixedly connected with a downstream air cylinder hinged seat, a downstream air cylinder is hinged to the downstream air cylinder hinged seat, and the downstream air cylinder is vertically arranged;

the top end of an upstream push-pull rod of the upstream cylinder, the top end of a downstream push-pull rod of the downstream cylinder, the top end of the rear edge of the upstream follow-up lifting plate and the top end of the rear edge of the downstream follow-up lifting plate are respectively provided with a discharging support plate bottom hinged support;

the hinge rotation direction of the hinge seats at the bottoms of the four discharging supporting plates is consistent with the hinge rotation direction of the hinge seats of the upstream air cylinder and the hinge seats of the downstream air cylinder;

the bottom hinged supports of the four unloading supporting plates are connected with the bottom surface of the unloading supporting plate together;

the upstream end of the discharging supporting plate extends towards the upstream direction, the bottom surface of the discharging supporting plate of the extending part is provided with an inclined lifting plate hinged support, an inclined lifting cylinder is hinged on the inclined lifting plate hinged support, an inclined lifting push pull rod of the inclined lifting cylinder faces towards the upstream direction,

the upstream end of the lifting and inclined push-pull rod is hinged on an optical axis, the two ends of the optical axis are respectively hinged on the short side hinge holes of the two right-angle hinge seats,

the long-side hinge holes of the two right-angle hinge seats are hinged with the downstream frame of the inclined lifting plate together;

a concave platform is arranged at the downstream edge of the inclined lifting plate,

the plate surface at the upstream end of the unloading supporting plate is provided with an inclined ascending plate matching opening;

the inclined lifting plate is matched with the inclined lifting plate matching opening of the discharging supporting plate, and the plate surface of the inclined lifting plate sinks relative to the plate surface of the discharging supporting plate;

the concave platform is matched with the blind end of the lifting inclined plate of the unloading supporting plate and the opening to be matched and fastened.

The plate surface of the upstream follow-up lifting plate is parallel to the upstream end surface of the upstream fixed seat;

the plate surface of the downstream follow-up lifting plate is parallel to the downstream end surface of the downstream fixed seat.

The upstream cylinder and the downstream cylinder are arranged in parallel.

The concave platform is inserted into the bottom surface of the ascending sloping plate matching opening.

The follow-up motor is powered and driven by the power unit.

The upstream cylinder, the downstream cylinder and the inclined cylinder are driven by power supply of the electric power unit.

The discharging support plate is a rectangular discharging support plate, and the length span direction of the rectangle is consistent with the span direction between the upstream fixed seat and the downstream fixed seat.

The inclined lifting plate is a rectangular inclined lifting plate, and the width span of the rectangular inclined lifting plate is smaller than that of the rectangular unloading supporting plate.

The elevation plate is disposed at an upstream end portion of the discharge support plate.

The matching surfaces of the bottom hinged support of the four discharging supporting plates and the hinged supporting plates are arranged on the same plane, the discharging supporting plate is arranged at the position of an upper top point of the four discharging supporting plates, which are overturned along the bottom hinged support of the four discharging supporting plates, and the surface and the horizontal plane of the discharging supporting plate are parallel.

Compared with the prior art, the utility model produced beneficial effect is:

the tail follow-up blanking mechanism of the pipe cutting production line of the utility model synchronously drives the unloading support plate to move up and down by utilizing the upstream follow-up lifting plate and the downstream follow-up lifting plate, and synchronously drives the overturning, tilting and unloading of the unloading support plate by utilizing the upstream cylinder and the downstream cylinder on the upstream follow-up lifting plate and the downstream follow-up lifting plate; the pipe cutting machine is favorable for enabling the discharging support plate to be matched with the height of the pipe, and on the other hand, the inclined discharging is favorable for enabling the pipe to be directly inclined and automatically rolled downwards for discharging after being cut from a cutting production line, and the pipe cutting machine is convenient, quick and easy to control.

The inclined lifting plate is arranged at the upstream end of the unloading supporting plate and is independently controlled by an inclined lifting cylinder at the bottom of the unloading supporting plate, so that the inclined lifting plate can be independently operated under the static or overturning state of the unloading supporting plate, and the inclined lifting cylinder lifts the inclined lifting plate to obtain the elevation overturning of the inclined lifting plate. Elevation lifting of the lifting inclined plate can sense the distance between the discharging support plate and the lower edge of the cut pipe, lifting action strokes of the upstream cylinder and the downstream cylinder are calculated and controlled in an auxiliary mode, the discharging support plate is lifted to be attached to the lower edge of the cut pipe, the cut pipe is stabilized, and the discharging support plate is favorable for discharging the cut pipe in an inclined mode.

The utility model discloses a last servo-actuated unloading mechanism of tubular product cutting production line reasonable in design, simple structure, safe and reliable, convenient to use, easy to maintain have fine using value widely.

Drawings

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

FIG. 2 is a left side view structure diagram of the present invention;

FIG. 3 is a schematic structural view of the left-view direction of the turnover unloading state of the unloading support plate of the utility model;

FIG. 4 is a schematic diagram of the right-side view structure of the present invention;

FIG. 5 is a schematic rear view of the present invention;

fig. 6 is a schematic top view of the present invention;

FIG. 7 is a schematic view of the bottom view structure of the present invention;

FIG. 8 is a schematic structural view of the discharging support plate of the present invention;

FIG. 9 is a schematic structural view of the discharging support plate of the present invention;

FIG. 10 is a schematic structural view of a perspective unloading support plate of the present invention;

fig. 11 is a schematic structural view of the hidden discharge support plate of the present invention;

fig. 12 is a schematic perspective view of the present invention.

The reference numerals in the drawings denote:

1. an upstream fixed seat 2 and a downstream fixed seat,

3. an upstream end face, 4, an upstream fixed slide block, 5, an upstream shaft seat,

6. a downstream end face, 7, a downstream fixed sliding block, 8, a downstream shaft seat,

9. an upstream follow-up lifting plate 10, an upstream guide rail 11, an upstream rack,

12. a downstream follow-up lifting plate 13, a downstream guide rail 14, a downstream rack,

15. a transmission shaft is arranged on the transmission shaft,

16. the upstream gear, 17, the downstream gear,

18. a follow-up motor base 19, a follow-up motor 20, a driving gear,

21. an upstream cylinder hinged seat, 22, an upstream cylinder,

23. a downstream cylinder hinged seat, 24, a downstream cylinder,

25. the bottom of the discharging supporting plate is hinged with a base,

26. a discharging support plate is arranged on the bottom of the discharging device,

27. an extension part 28, a lift inclined plate hinged support 29, a lift inclined cylinder 30, a lift inclined push pull rod,

31. an optical axis 32, a right-angle hinged support 33, a short-side hinged hole 34 and a long-side hinged hole,

35. a rising sloping plate 36, a downstream frame 37 and a concave platform,

38. the rising sloping plate is matched with the opening, 39 and the blind end.

Detailed Description

The following detailed description is made on the following blanking mechanism of the pipe cutting production line of the present invention with reference to the accompanying drawings.

As shown in the attached drawings, the structure of the tail follow-up blanking mechanism of the pipe cutting production line of the utility model comprises an upstream fixed seat 1 and a downstream fixed seat 2,

an upstream end face 3 of the upstream fixed seat 1 is fixedly connected with an upstream fixed sliding block 4;

an upstream shaft seat 5 is arranged on the seat body of the upstream fixed seat 1;

the downstream end surface 6 of the downstream fixed seat 2 is fixedly connected with a downstream fixed sliding block 7;

a downstream shaft seat 8 is arranged on the seat body of the downstream fixed seat 2;

an upstream guide rail 10 and an upstream rack 11 are fixedly connected to the inner side plate surface of the upstream follow-up lifting plate 9, the upstream guide rail and the upstream rack are parallel and vertically arranged, and the upstream guide rail 10 is in sliding fit with the upstream fixed sliding block 4;

a downstream guide rail 13 and a downstream rack 14 are fixedly connected to the inner side plate surface of the downstream follow-up lifting plate 12, the downstream guide rail and the downstream rack are parallel and vertically arranged, and the downstream guide rail 13 is in sliding fit with the downstream fixed sliding block 7;

a transmission shaft 15 is connected between the upstream shaft seat 5 and the downstream shaft seat 8 in a penetrating manner, and the transmission shaft 15 is horizontally arranged;

the upstream end of the transmission shaft 15 is coaxially and fixedly connected with an upstream gear 16, and the downstream end of the transmission shaft is coaxially and fixedly connected with a downstream gear 17;

the upstream gear 16 is meshed with the upstream rack 11;

the downstream gear 17 is meshed with the downstream rack 14;

a follow-up motor seat 18 is fixedly connected to the upstream end face of the upstream fixing seat 1, a follow-up motor 19 is fixedly arranged on the follow-up motor seat 18, a driving gear 20 is output by a follow-up motor shaft, and the driving gear 20 is meshed with the upstream gear 16;

The front edge of the outer side plate surface of the upstream follow-up lifting plate 9 is fixedly connected with an upstream cylinder hinged seat 21, an upstream cylinder 22 is hinged on the upstream cylinder hinged seat, and the upstream cylinder is vertically arranged;

the front edge of the outer side plate surface of the downstream follow-up lifting plate 10 is fixedly connected with a downstream air cylinder hinged seat 23, a downstream air cylinder 24 is hinged on the downstream air cylinder hinged seat, and the downstream air cylinder is vertically arranged;

the top end of an upstream push-pull rod of the upstream cylinder 22, the top end of a downstream push-pull rod of the downstream cylinder 24, the top end of the rear edge of the upstream follow-up lifting plate 9 and the top end of the rear edge of the downstream follow-up lifting plate 12 are respectively provided with a discharging support plate bottom hinged support 25;

the bottom hinged supports of the four discharging supporting plates are connected with the bottom surface of the discharging supporting plate 26;

the upstream cylinder 22 and the downstream cylinder 24 synchronously lift or pull down the side edge of the discharge supporting plate 26, the other side edge of the discharge supporting plate 26 is rotatably hinged with the top ends of the upstream follow-up lifting plate 9 and the downstream follow-up lifting plate 12 through a discharge supporting plate bottom hinged seat 25 where the discharge supporting plate is located, the lifted or pulled-down discharge supporting plate 26 forms a laterally-overturning inclined discharge state, and the discharge supporting plate 26 returns to the horizontal position after being discharged.

The upstream end of the discharge supporting plate extends towards the upstream direction, the bottom surface of the discharge supporting plate of the extension part 27 is provided with a lift plate hinged support 28, the lift plate hinged support 28 is hinged with a lift inclined cylinder 29, a lift inclined push pull rod 30 of the lift inclined cylinder 29 faces towards the upstream direction,

the upstream end of the lifting and pushing pull rod 30 is vertically hinged on an optical axis 31, the two ends of the optical axis 31 are respectively hinged on short side hinge holes 33 of two right-angle hinge seats 32,

the long-side hinge holes 34 of the two right-angle hinge bases are hinged with the downstream frame 36 of the inclined lifting plate 35 together;

a concave platform 37 is arranged at the downstream side of the inclined elevation plate,

the plate surface at the upstream end of the discharging supporting plate is provided with an ascending sloping plate matching opening 38;

the concave platform is matched and fastened with the blind end 39 of the ascending sloping plate matching opening of the discharging supporting plate.

The upstream cylinder and the downstream cylinder are arranged in parallel.

The follow-up motor is powered and driven by the power unit.

Claims

1. The pipe cutting production line end follow-up blanking mechanism is characterized by comprising an upstream fixed seat and a downstream fixed seat,

an upstream shaft seat is arranged on the seat body of the upstream fixed seat;

the upstream gear is meshed with the upstream rack;

the downstream gear is meshed with the downstream rack;

2. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that:

3. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that:

the upstream cylinder and the downstream cylinder are arranged in parallel.

4. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that: the concave platform is inserted into the bottom surface of the ascending sloping plate matching opening.

5. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that: the follow-up motor is powered and driven by the power unit.

6. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that:

7. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that: the discharging support plate is a rectangular discharging support plate, and the length span direction of the rectangle is consistent with the span direction between the upstream fixed seat and the downstream fixed seat.

8. The pipe cutting production line end follow-up blanking mechanism of claim 7, wherein: the inclined lifting plate is a rectangular inclined lifting plate, and the width span of the rectangular inclined lifting plate is smaller than that of the rectangular unloading supporting plate.

9. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that: the elevation plate is disposed at an upstream end portion of the discharge support plate.

10. The pipe cutting production line end follow-up blanking mechanism of claim 1, characterized in that: the matching surfaces of the bottom hinged support of the four discharging supporting plates and the hinged supporting plates are arranged on the same plane, the discharging supporting plate is arranged at the position of an upper top point of the four discharging supporting plates, which are overturned along the bottom hinged support of the four discharging supporting plates, and the surface and the horizontal plane of the discharging supporting plate are parallel.