CN215880087U - Cutting device is used in processing of zinc steel guardrail - Google Patents

Abstract

The utility model discloses a cutting device for processing a zinc steel guardrail, which belongs to the technical field of zinc steel guardrail processing and comprises a cutting table, wherein a first n-type fixing frame is fixed at the top end of the cutting table; compared with the prior art, the cutting device for processing the zinc steel guardrail is capable of intermittently conveying zinc steel plates by using the linkage mechanism, and realizing continuous fixed-length cutting operation of the zinc steel plates while reciprocating lifting by matching with the cutting knife in the rotating process, so that the cutting efficiency is greatly improved.

Description

Cutting device is used in processing of zinc steel guardrail

Technical Field

The utility model relates to the technical field of zinc steel guardrail processing, in particular to a cutting device for zinc steel guardrail processing.

Background

The zinc steel guardrail is a balcony guardrail made of zinc alloy materials, and has the advantages of high strength, high hardness, exquisite appearance, bright color and the like, so that the zinc steel guardrail becomes a mainstream product used in residential districts. The traditional balcony guardrail uses iron bars and aluminum alloy materials.

At present, cutting device is as the conventional use tool in the zinc steel guardrail course of working, and it is in the use, in cutting process, needs artifical manual press zinc steel guardrail to cut, can't guarantee artificial security when leading to the cutting, secondly, can't carry out continuity fixed length cutting to the panel of zinc steel guardrail, and cutting efficiency is low when leading to the cutting, and the result of use is not good, and for this reason, we provide a cutting device for processing of zinc steel guardrail.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a cutting device for processing a zinc steel guardrail, which aims to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a cutting device for processing a zinc steel guardrail comprises a cutting table, wherein an n-type first fixing frame is fixed at the top end of the cutting table, two symmetrical sliding rods are fixed between the inner top wall of the n-type first fixing frame and the top end of the cutting table, sliding sleeves are slidably sleeved on the outer sides of the sliding rods, a movable plate with an inverted L-shaped vertical cross section is fixed on the outer sides of the two sliding sleeves, a driving motor is fixedly embedded on the movable plate, and a cutting knife is fixed on an output shaft of the driving motor;

be fixed with the biax motor on the lateral wall of n type mount one, the one end output shaft of biax motor runs through n type mount one to the rigid coupling has the rolling disc, the surperficial edge of rolling disc articulates there is the push-and-pull rod, the other end of push-and-pull rod articulates the top at the fly leaf, the top of cutting bed is seted up flutedly, rotate through the bearing in the recess and be connected with two symmetrical driving rollers, the transmission is connected with the conveyer belt between two driving rollers, install linkage mechanism between the other end output shaft of biax motor and the cutting bed, two symmetrical adjustable auxiliary positioning mechanism are installed on the top of cutting bed.

Preferably, the linkage mechanism comprises a second n-type fixing frame fixed at the top end of the cutting table, an output shaft at the other end of the double-shaft motor penetrates through the second n-type fixing frame and is fixedly connected with a worm, a worm wheel is meshed and connected to the lower portion of the worm, a first transmission shaft is fixedly connected in a mounting shaft hole of the worm wheel, two ends of the first transmission shaft are rotatably connected with a first bearing seat, the first bearing seats are fixed on one side wall of the second n-type fixing frame, and an extending portion at one end of the first transmission shaft is fixedly connected with a first belt pulley.

Preferably, a second transmission shaft is installed below the first transmission shaft, two ends of the second transmission shaft are rotatably connected with second bearing blocks, the second bearing blocks are fixed on one side wall of the second n-type fixing frame, a second belt pulley and a sector gear are fixedly connected to an extending portion at one end of the second transmission shaft, a transmission belt is connected between the first belt pulley and the second belt pulley in a transmission mode, a driven gear is connected to the lower portion of the sector gear in a meshed mode, one end of one transmission roller extends to the outer side of the cutting table and is fixedly connected with a mounting shaft hole of the driven gear.

Preferably, the adjustable auxiliary positioning mechanism comprises an inverted L-shaped movable plate which is slidably connected to the top end of the cutting table, two symmetrical sliding seats are fixed at the bottom end of the inverted L-shaped movable plate, and sliding grooves matched with the sliding seats are formed in the top end of the cutting table.

Preferably, one side of the inverted-L-shaped movable plate is provided with a first electric push rod fixed at the top end of the cutting table, the telescopic end of the first electric push rod is connected with one side wall of the inverted-L-shaped movable plate, two symmetrical second electric push rods are fixed at the top end of the inverted-L-shaped movable plate, and the telescopic ends of the two second electric push rods penetrate through the inverted-L-shaped movable plate in a sliding manner and are fixedly connected with the same positioning plate.

Preferably, a plurality of guide rollers I arranged at equal intervals are rotatably connected into the cavity at the bottom end of the positioning plate through bearings, and a plurality of guide rollers II arranged at equal intervals are rotatably connected into the cavity on the inner wall of one side of the inverted L-shaped moving plate through bearings.

Compared with the prior art, the utility model has the beneficial effects that:

the cutting device is different from the prior art, and can intermittently convey the zinc steel plates by utilizing the setting of the linkage mechanism in the use process of the cutting device for processing the zinc steel guardrail, and realize the continuous fixed-length cutting operation of the zinc steel plates while matching with the reciprocating lifting of the cutting knife in the rotation process, so that the cutting efficiency is greatly improved.

Drawings

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

FIG. 2 is a right side view of the present invention;

FIG. 3 is a schematic view of the unfolding structure of the driving roller and the conveying belt thereof according to the present invention;

FIG. 4 is a schematic view of the unfolding structure of each component of the adjustable auxiliary positioning mechanism of the present invention.

In the figure: 1. cutting table; 2. an n-type fixing frame I; 21. a slide bar; 22. a sliding sleeve; 23. a movable plate; 24. a drive motor; 25. a cutting knife; 26. a double-shaft motor; 27. rotating the disc; 28. a push-pull rod; 3. a groove; 31. a driving roller; 32. a conveyor belt; 4. a linkage mechanism; 401. an n-type fixing frame II; 402. a worm; 403. a worm gear; 404. a first transmission shaft; 405. a first bearing seat; 406. a first belt pulley; 407. a second transmission shaft; 408. a second bearing seat; 409. a second belt pulley; 410. a transmission belt; 411. a driven gear; 412. a sector gear; 5. an adjustable auxiliary positioning mechanism; 501. an inverted L-shaped moving plate; 502. a sliding seat; 503. an electric push rod I; 504. a second electric push rod; 505. positioning a plate; 506. a first guide roller; 507. and a second guide roller.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a cutting device for processing a zinc steel guardrail comprises a cutting table 1, wherein an n-type fixing frame I2 is fixed at the top end of the cutting table 1, two symmetrical sliding rods 21 are fixed between the inner top wall of the n-type fixing frame I2 and the top end of the cutting table 1, sliding sleeves 22 are respectively slidably sleeved on the outer sides of the sliding rods 21, a same movable plate 23 with an inverted L-shaped vertical section is fixed on the outer sides of the two sliding sleeves 22, a driving motor 24 is fixedly embedded on the movable plate 23, and a cutting knife 25 is fixed on an output shaft of the driving motor 24;

a double-shaft motor 26 is fixed on one side wall of the n-type fixing frame I2, an output shaft at one end of the double-shaft motor 26 penetrates through the n-type fixing frame I2, a rotating disc 27 is fixedly connected, a push-pull rod 28 is hinged at the edge of the surface of the rotating disc 27, the other end of the push-pull rod 28 is hinged at the top end of the movable plate 23, a groove 3 is arranged at the top end of the cutting table 1, two symmetrical transmission rollers 31 are rotatably connected in the groove 3 through a bearing, a conveyer belt 32 is connected between the two transmission rollers 31 in a transmission manner, a linkage mechanism 4 is arranged between the output shaft at the other end of the double-shaft motor 26 and the cutting table 1, two symmetrical adjustable auxiliary positioning mechanisms 5 are arranged at the top end of the cutting table 1, the top end face of the conveyer belt 32 is higher than the top end face of the cutting table 1, in order to ensure the stability of conveying, in the implementation process of the scheme, anti-skid lines can be arranged on the surface of the conveying belt 32, so that the intermittent progressive of the plates is effectively ensured.

Further, the linkage mechanism 4 comprises a second n-type fixing frame 401 fixed at the top end of the cutting table 1, an output shaft at the other end of the double-shaft motor 26 penetrates through the second n-type fixing frame 401 and is fixedly connected with a worm 402, a worm wheel 403 is engaged and connected below the worm 402, a first transmission shaft 404 is fixedly connected in a mounting shaft hole of the worm wheel 403, two ends of the first transmission shaft 404 are rotatably connected with a first bearing seat 405, the first bearing seat 405 is fixedly connected on one side wall of the second n-type fixing frame 401, a first belt pulley 406 is fixedly connected to an extending part at one end of the first transmission shaft 404, a second transmission shaft 407 is mounted below the first transmission shaft 404, two ends of the second transmission shaft 407 are rotatably connected with a second bearing seat 408, the second bearing seat 408 is fixedly connected on one side wall of the second n-type fixing frame 401, a second belt pulley and a sector gear 412 are fixedly connected to an extending part at one end of the second transmission shaft 407, and a transmission belt 410 is connected between the first belt pulley 406 and the second belt pulley 409, a driven gear 411 is engaged and connected below the sector gear 412, one end of one of the driving rollers 31 extends to the outer side of the cutting table 1 and is fixedly connected with a mounting shaft hole of the driven gear 411, the worm 402 rotates clockwise, and the worm wheel 403 rotates counterclockwise.

Further, the adjustable auxiliary positioning mechanism 5 includes an inverted L-shaped moving plate 501 slidably connected to the top end of the cutting table 1, two symmetrical sliding seats 502 are fixed at the bottom end of the inverted L-shaped moving plate 501, sliding grooves matched with the sliding seats 502 are formed at the top end of the cutting table 1, a first electric push rod 503 fixed at the top end of the cutting table 1 is arranged at one side of the inverted L-shaped moving plate 501, a telescopic end of the first electric push rod 503 is connected to one side wall of the inverted L-shaped moving plate 501, two symmetrical second electric push rods 504 are fixed at the top end of the inverted L-shaped moving plate 501, telescopic ends of the two second electric push rods 504 slidably penetrate through the inverted L-shaped moving plate 501 and are fixedly connected to a same positioning plate 505, a plurality of equidistantly arranged guide rollers 506 are rotatably connected through bearings in cavities at the bottom end of the positioning plate 505, a plurality of equidistantly arranged guide rollers 507 are rotatably connected through bearings in cavities at one side inner wall of the inverted L-shaped moving plate 501, the arrangement of the first guide roller 506 and the second guide roller 507 enables the clamped or pressed zinc steel plate to move, and the effect of changing rigid clamping into rolling clamping is achieved.

In the scheme, a worker inserts a zinc steel plate to be cut between two inverted-L-shaped moving plates 501, the bottom ends of the zinc steel plate to be cut are movably attached to the top end of a conveyor belt 32, the two inverted-L-shaped moving plates 501 move relatively by simultaneously starting two electric push rods one 503, a plurality of guide rollers two 507 which are rotatably connected with the two inverted-L-shaped moving plates 501 clamp two side walls of the zinc steel plate, then the two positioning plates 505 move downwards simultaneously by simultaneously starting four electric push rods two 504, the top ends of the zinc steel plate are pressed by a plurality of guide rollers one 506 which are rotatably connected with the bottom ends of the two positioning plates 505, and furthermore, by starting a double-shaft motor 26 and a driving motor 24, a rotating disc 27 rotates clockwise and is matched with a push-pull rod 28, the driving motor 24 on the moving plate 23 can reciprocate outside two slide rods 21 through two sliding sleeves 22, however, the worm 402 rotates clockwise, and the transmission carries out anticlockwise rotation in the transmission shaft 404 that worm wheel 403 is connected, because be connected through the transmission of drive belt 410 between belt pulley 406 and the belt pulley 409 two, make sector gear 412 anticlockwise rotation then, and intermittent type's transmission rotates in driven gear 411, then the conveyer belt 32 of transmission connection can carry out intermittent type to the galvanized steel sheet on two driving rollers 31, and when the cooperation rotates cutting knife 25 of in-process and goes on reciprocating lift, realize the continuity fixed length cutting operation of galvanized steel sheet, improve the efficiency of its cutting greatly.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a cutting device is used in processing of zinc steel guardrail, includes cutting bed (1), its characterized in that: an n-type fixing frame I (2) is fixed at the top end of the cutting table (1), two symmetrical sliding rods (21) are fixed between the inner top wall of the n-type fixing frame I (2) and the top end of the cutting table (1), sliding sleeves (22) are slidably sleeved on the outer sides of the sliding rods (21), a same movable plate (23) with an inverted L-shaped vertical section is fixed on the outer sides of the two sliding sleeves (22), a driving motor (24) is fixedly embedded on the movable plate (23), and a cutting knife (25) is fixed on an output shaft of the driving motor (24);

be fixed with biax motor (26) on the lateral wall of n type mount (2), the one end output shaft of biax motor (26) runs through n type mount (2), and the rigid coupling has rolling disc (27), the surface edge of rolling disc (27) articulates there is push-and-pull rod (28), the other end of push-and-pull rod (28) articulates the top at fly leaf (23), recess (3) are seted up on the top of cutting bed (1), it is connected with two symmetrical driving roller (31) to rotate through the bearing in recess (3), the transmission is connected with conveyer belt (32) between two driving roller (31), install linkage mechanism (4) between the other end output shaft of biax motor (26) and cutting bed (1), two symmetrical adjustable auxiliary positioning mechanism (5) are installed on the top of cutting bed (1).

2. The cutting device for processing the zinc-steel guardrail according to claim 1, wherein the cutting device comprises: the linkage mechanism (4) comprises a second n-type fixing frame (401) fixed at the top end of the cutting table (1), an output shaft at the other end of the double-shaft motor (26) penetrates through the second n-type fixing frame (401), a worm (402) is fixedly connected with the lower portion of the worm (402) in a meshed mode, a first transmission shaft (404) is fixedly connected in a mounting hole of the worm (403), two ends of the first transmission shaft (404) are rotatably connected with a first bearing seat (405), the first bearing seat (405) is fixedly arranged on one side wall of the second n-type fixing frame (401), and a first belt pulley (406) is fixedly connected to an extending portion at one end of the first transmission shaft (404).

3. The cutting device for processing the zinc-steel guardrail as claimed in claim 2, wherein: the transmission shaft II (407) is installed below the transmission shaft I (404), two ends of the transmission shaft II (407) are rotatably connected with a bearing seat II (408), the bearing seat II (408) is fixed on one side wall of the n-type fixed frame II (401), one end extending part of the transmission shaft II (407) is fixedly connected with a belt pulley II (409) and a sector gear (412), a transmission belt (410) is connected between the belt pulley I (406) and the belt pulley II (409), the lower part of the sector gear (412) is meshed with a driven gear (411), one end of one transmission roller (31) extends to the outer side of the cutting table (1) and is fixedly connected with a mounting shaft hole of the driven gear (411).

4. The cutting device for processing the zinc-steel guardrail according to claim 1, wherein the cutting device comprises: the adjustable auxiliary positioning mechanism (5) comprises an inverted L-shaped moving plate (501) which is connected to the top end of the cutting table (1) in a sliding mode, two symmetrical sliding seats (502) are fixed to the bottom end of the inverted L-shaped moving plate (501), and sliding grooves matched with the sliding seats (502) are formed in the top end of the cutting table (1).

5. The cutting device for processing the zinc-steel guardrail as claimed in claim 4, wherein: one side of the inverted L-shaped moving plate (501) is provided with a first electric push rod (503) fixed at the top end of the cutting table (1), the telescopic end of the first electric push rod (503) is connected with one side wall of the inverted L-shaped moving plate (501), the top end of the inverted L-shaped moving plate (501) is fixed with a second symmetrical electric push rod (504), and the telescopic ends of the second electric push rods (504) are all slidably penetrated through the inverted L-shaped moving plate (501) and fixedly connected with the same positioning plate (505).

6. The cutting device for processing the zinc-steel guardrail as claimed in claim 5, wherein: all be connected with the deflector roll one (506) that a plurality of equidistance set up through the bearing rotation in the bottom cavity of locating plate (505), all be connected with the deflector roll two (507) that a plurality of equidistance set up through the bearing rotation in the cavity of falling L type movable plate (501) one side inner wall.

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