CN110936176A

CN110936176A - Metal strip embossing device

Info

Publication number: CN110936176A
Application number: CN201911276124.1A
Authority: CN
Inventors: 李伟
Original assignee: Jiaozhou Ougui Metal Products Co Ltd
Current assignee: Jiaxing Jinsen Wood Industry Co ltd
Priority date: 2019-12-12
Filing date: 2019-12-12
Publication date: 2020-03-31
Anticipated expiration: 2039-12-12
Also published as: CN110936176B

Abstract

The invention discloses a metal strip embossing device, which comprises a shell, wherein a working cavity is arranged in the shell, a transmission cavity is communicated with the outside through the left end wall of the working cavity, an embossing mechanism is arranged in the transmission cavity, a cutting mechanism is arranged in the working cavity, a driving cavity is arranged in the rear end wall of the transmission cavity, a driving mechanism is arranged in the driving cavity, a transmission mechanism is arranged at the lower side of the driving mechanism, an adjusting mechanism is arranged at the upper side of the embossing mechanism, and a pressing mechanism is arranged at the upper side of the cutting mechanism. Thereby improving the processing efficiency and reducing the processing cost.

Description

Metal strip embossing device

Technical Field

The invention relates to the technical field of metal non-cutting machining or metal processing, in particular to a metal strip embossing device.

Background

At present, the embossing processing to the metal strip is accomplished through the manual work to the majority, the briquetting machine of current metal strip impressed watermark carries out the impressed watermark usually after by the finish machining, thereby the cost of processing has been improved, and when processing the low metal strip of precision, make the burr that remains on the metal strip surface easily cause the damage to the line of embosser, and then influence the integrality of processing literary composition, and the metal strip need cut according to needs through external cutting device behind the impressed watermark, when the metal strip is in transportation and storage easily, because the external force leads to the metal strip surface to take place crooked unevenness, and easy and the steam oxidation in the air when depositing, thereby reduce the precision of processing and the integrality of impressed watermark.

Disclosure of Invention

The object of the present invention is to provide a metal bar embossing apparatus that overcomes the above-mentioned drawbacks.

The metal strip embossing device comprises a shell, wherein a working cavity is arranged in the shell, a transmission cavity penetrates through the left end wall of the working cavity and is communicated with the outside, an embossing mechanism is arranged in the transmission cavity, a cutting mechanism is arranged in the working cavity, a driving cavity is arranged in the rear end wall of the transmission cavity, a driving mechanism is arranged in the driving cavity, a transmission mechanism is arranged on the lower side of the driving mechanism, an adjusting mechanism is arranged on the upper side of the embossing mechanism, and a pressing mechanism is arranged on the upper side of the cutting mechanism;

the embossing mechanism comprises a metal strip arranged in the transmission cavity, two flattening cavities with openings communicated with the transmission cavity are symmetrically arranged in the upper end wall and the lower end wall of the transmission cavity, the rear end wall of the flattening cavity is rotatably connected with a first driven shaft with the rear end penetrating through the rear end wall of the flattening cavity and the rear end being located in the driving cavity, the front end of the first driven shaft is fixedly provided with a flattening wheel located in the flattening cavity, the first driven shaft is fixedly provided with a first belt wheel located in the driving cavity, a first belt is connected between the two first belt wheels, the upper side of the first driven shaft is fixedly provided with a first bevel gear located in the driving cavity, the metal strip is conveyed into the transmission cavity through the outside, and the embossing mechanism performs flattening, polishing and embossing on the metal strip so as to adjust the required length through a cutting mechanism for cutting.

On the basis of the technical scheme, an inverted U-shaped cavity is communicated with the outside through the lower end wall of the transmission cavity, two first transmission cavities which are symmetrical up and down relative to the transmission cavity and are communicated with the driving cavity through rear end openings are arranged in the lower end wall of the inverted U-shaped cavity, the end wall of the first transmission cavity far away from the transmission cavity is rotatably connected with two second driven shafts which are close to the end wall of the transmission cavity, one end of the first transmission cavity is close to the end wall of the transmission cavity, the upper end of the first transmission cavity is close to the end wall of the transmission cavity, the other end of the first transmission cavity is located in the transmission cavity, the lower end of the first driven shaft close to the transmission cavity is located in the inverted U-shaped cavity, one end of the second driven shaft far away from the transmission cavity is fixedly provided with a second belt wheel located in the first transmission cavity, one end of the second driven shaft close to the transmission cavity, the lower end of the second driven shaft close to the, the transmission cavity upper end wall is internally provided with an embossing cavity which is positioned at the right side of the inverted U-shaped cavity and is communicated with the transmission cavity and the working cavity, the rear end wall of the embossing cavity is rotatably connected with a rotating wheel shaft, the rear end of the rotating wheel shaft penetrates through the rear end wall of the embossing cavity, the rear end of the rotating wheel shaft is positioned in the driving cavity, an embossing rotating wheel with the lower end extending into the transmission cavity is fixedly arranged on the rotating wheel shaft, and the rear end of the rotating wheel shaft is fixedly provided with a second bevel gear positioned in the driving cavity.

On the basis of the technical scheme, the cutting mechanism comprises a cutting table arranged in the working cavity, the cutting table penetrates through the cutting table and a pressing cavity communicated with the working cavity, the lower end wall of the pressing cavity is located on the same horizontal plane with the lower end wall of the transmission cavity, the upper end wall of the pressing cavity is internally provided with a lower end communicated with the pressing cavity which is used for pressing the pressing cavity, a pressing block is connected with the pressing block in a sliding mode and moves downwards, the upper end face of the moving block is fixedly provided with an upper end which penetrates through the upper end wall of the pressing cavity, the upper end of the pressing block is located on a push rod in the working cavity, and the pressing block upper end face is bilaterally symmetrical and fixedly provided with two first springs.

On the basis of the technical scheme, the driving mechanism comprises a first motor fixed on the upper end wall of the driving cavity, the lower end face of the first motor is in power connection with a first power shaft, a first friction wheel is fixedly arranged at the upper end of the first power shaft, a third belt wheel located at the position of a communication port of the driving cavity is fixedly arranged on the first power shaft, the first driving cavity is connected with a third belt wheel located at the position of the communication port of the driving cavity, the third belt wheel is connected with a second belt through the second belt wheel, the lower end of the first power shaft is fixedly arranged at the lower side, the first driving cavity is connected with a fourth belt wheel located at the position of the communication port of the driving cavity, the third belt wheel is connected with a third belt through the second belt wheel, and the driving mechanism is used for driving power.

On the basis of the technical scheme, the transmission mechanism comprises two third driven shafts which are in bilateral symmetry with the first motor and are rotatably connected to the upper end wall of the driving cavity, a second friction wheel meshed with the first friction wheel is fixedly arranged on the second friction wheel, a third bevel gear meshed with the second bevel gear is fixedly arranged at the lower end of the third driven shaft on the right side, a fourth bevel gear meshed with the first bevel gear is fixedly arranged at the lower end of the third driven shaft on the left side, and power of the driving mechanism is transmitted to other components to work through the transmission mechanism.

On the basis of the technical scheme, the adjusting mechanism comprises a sliding chute with an upward opening arranged on the upper end surface of the shell, a first sliding block is connected in the sliding chute in a sliding manner, a second spring fixed with the left end wall of the sliding chute is fixedly arranged on the left end surface of the first sliding block, a safety cover is fixedly arranged on the upper end surface of the first sliding block, a first sliding cavity is arranged in the right end wall of the sliding chute, a second sliding block is connected in the first sliding cavity in a sliding manner, a cylindrical pin with the upper end penetrating through the upper end wall of the first sliding cavity and the upper end positioned in the safety cover is fixed on the upper end surface of the second sliding block, a third spring fixed with the lower end wall of the first sliding cavity is fixedly arranged on the lower end surface of the second sliding block, a second transmission cavity with a right end opening communicated with the working cavity is arranged in the lower end wall of the first sliding cavity, an adjusting cavity is arranged in the lower end wall of the second, the lower end face of the second motor is in power connection with a second power shaft, a third friction wheel is fixedly arranged on the second power shaft, the upper end wall and the lower end wall of the second transmission cavity are in rotational connection with a first transmission shaft which is bilaterally symmetrical relative to the second motor, the first transmission shaft is in sliding connection with a fourth friction wheel which can be meshed with the third friction wheel, the upper end face of the fourth friction wheel is in sliding connection with a third sliding block, the upper end face of the left third sliding block is fixedly provided with a first pull rope, the upper end of the first pull rope penetrates through the upper end face of the second transmission cavity and is fixed with the lower end face of the second sliding block, the lower end of the first transmission shaft on the left side extends downwards into the adjusting cavity, the lower end face of the first transmission shaft on the left side is fixedly provided with a cam positioned in the adjusting cavity, the adjusting cavity is internally provided with a moving rod, the right end face of the, and a moving block which is in sliding connection with the upper end wall and the lower end wall of the adjusting cavity is fixed on the right end surface of the moving rod, and two fourth springs which are fixed with the right end wall of the adjusting cavity are fixedly arranged on the right end surface of the moving block.

On the basis of the technical scheme, the pressing mechanism comprises a second sliding cavity arranged in the right end wall of the working cavity, an electromagnet is fixed on the right end wall of the second sliding cavity, an electromagnetic block is connected in the second sliding cavity in a sliding manner, a square block with the left end penetrating through the left end wall of the second sliding cavity and the left end positioned in the working cavity is fixed on the left end surface of the electromagnetic block, the square block and the pressing cavity are positioned on the same horizontal plane, a fifth spring fixed with the right end wall of the second sliding cavity is fixedly arranged on the right end surface of the electromagnetic block, the right end surface of the electromagnetic block is fixed with two slide rails with the front end wall and the rear end wall of the working cavity, the right end wall of the electromagnetic block penetrates through the right end wall of the second sliding cavity and is positioned in the second transmission cavity and fixed with the upper end surface of the third slide block on the right side, and racks are connected in the slide rails in a sliding, the cutting table is characterized in that teeth are arranged on the left end face of the rack, a fixing plate is fixed on the right end face of the rack, a chute with an opening facing the fixing plate is arranged in the fixing plate, the lower end of the chute penetrates through the right end of the upper side of the cutting table and is located in the chute above the outlet of the right end of the compression cavity, a second transmission shaft is rotatably connected to the rear end wall of the second transmission cavity, a first transmission bevel gear meshed with the teeth of the left end face of the rack is fixedly arranged on the second transmission shaft, a third transmission shaft is rotatably connected to the lower end wall of the second transmission cavity, a second transmission bevel gear meshed with the first transmission bevel gear is fixedly arranged at the upper end of the third transmission shaft, and a fifth friction wheel meshed with the fourth friction wheel is.

The invention has the beneficial effects that: the embossing device can flatten metal strips with lower precision during embossing and polish burrs left on the surfaces of the metal strips, so that embossing depths of the metal strips caused by unevenness can be reduced during embossing, damage to embossing of the pressing wheel is avoided, the service cycle of embossing is prolonged, the lengths of the metal strips after different embossing can be cut through the adjusting mechanism, and the processing efficiency and the processing cost are improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a metal bar embossing apparatus according to the present invention;

FIG. 2 is a cross-sectional view of the rear side of FIG. 1 in accordance with the present invention;

FIG. 3 is an enlarged view taken at A in FIG. 1 according to the present invention;

FIG. 4 is a schematic view of the invention taken along the direction B-B in FIG. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 4, the metal strip embossing apparatus according to the embodiment of the present invention includes a housing 10, a working chamber 11 is disposed in the housing 10, a transmission chamber 29 is communicated with the outside through a left end wall of the working chamber 11, an embossing mechanism 90 is disposed in the transmission chamber 29, a cutting mechanism 91 is disposed in the working chamber 11, a driving chamber 56 is disposed in a rear end wall of the transmission chamber 29, a driving mechanism 92 is disposed in the driving chamber 56, a transmission mechanism 93 is disposed on a lower side of the driving mechanism 92, an adjusting mechanism 94 is disposed on an upper side of the embossing mechanism 90, a pressing mechanism 95 is disposed on an upper side of the cutting mechanism 91, the embossing mechanism 90 includes a metal strip 39 disposed in the transmission chamber 29, two flat chambers 38 having openings communicating with the transmission chamber 29 are symmetrically disposed in the upper and lower end walls of the transmission chamber 29, a first driven shaft 36 having a rear end penetrating through a rear end wall of the flat chamber 38 and a rear end located in the driving chamber 56 is rotatably connected to the rear end wall of the flat, the front end of the first driven shaft 36 is fixedly provided with a flattening wheel 37 positioned in the flattening cavity 38, the first driven shaft 36 is fixedly provided with a first belt wheel 60 positioned in the driving cavity 56, a first belt 59 is connected between the two first belt wheels 60, the rear end of the upper side of the first driven shaft 36 is also fixedly provided with a first bevel gear 58 positioned in the driving cavity 56, a metal strip is conveyed into the transmission cavity 29 through the outside, and the embossing mechanism 90 flattens, polishes and embosses the metal strip, so that the required length is adjusted by the cutting mechanism 91 to cut the metal strip.

In addition, in an embodiment, an inverted U-shaped cavity 35 is communicated with the outside through the lower end wall of the transmission cavity 29, two first transmission cavities 33 which are symmetrical up and down and have rear end openings communicated with the driving cavity 56 are arranged in the lower end wall of the inverted U-shaped cavity 35, the end wall of the first transmission cavity 33 far away from the transmission cavity 29 is rotatably connected with two second driven shafts 32 which are close to the transmission cavity 29, one ends of the two second driven shafts penetrate through the end wall of the first transmission cavity 33 close to the transmission cavity 29, the upper side of the two first driven shafts are close to the transmission cavity 29, one ends of the two second driven shafts 32 far away from the transmission cavity 29 are located in the transmission cavity 29, one ends of the two second driven shafts 32 far away from the transmission cavity 29 are fixedly provided with second belt wheels 34 located in the first transmission cavity 33, and one ends of the upper side of the two second driven shafts 32 close to the transmission cavity 29 are fixedly provided with second driven shafts 32 which are located in the transmission cavity 29, and one ends of the second driven Two grinding wheels 30 positioned in the inverted U-shaped cavity 35 are fixedly arranged at the end, an embossing cavity 26 positioned at the right side of the inverted U-shaped cavity 35 and communicating the transmission cavity 29 with the working cavity 11 is arranged in the upper end wall of the transmission cavity 29, a rotating wheel shaft 28 with the rear end penetrating through the rear end wall of the embossing cavity 26 and the rear end positioned in the driving cavity 56 is rotatably connected to the rear end wall of the embossing cavity 26, an embossing rotating wheel 27 with the lower end extending into the transmission cavity 29 is fixedly arranged on the rotating wheel shaft 28, and a second bevel gear 49 positioned in the driving cavity 56 is fixedly arranged at the rear end of the rotating wheel shaft 28.

In addition, in an embodiment, the cutting mechanism 91 includes a cutting table 21 disposed in the working chamber 11, a pressing chamber 25 is communicated with the working chamber 11 through the cutting table 21, the lower end wall of the pressing chamber 25 and the lower end wall of the transmission chamber 29 are located on the same horizontal plane, a lower pressing chamber 22 communicated with the pressing chamber 25 is disposed in the upper end wall of the pressing chamber 25, a pressing block 23 and a downward moving block 84 are slidably connected in the downward pressing chamber 22, a push rod 15 is fixedly disposed on the upper end face of the downward moving block 84, the upper end of the push rod penetrates through the upper end wall of the downward pressing chamber 22, the upper end of the push rod 15 is located in the working chamber 11, and two first springs 24 are fixedly disposed on the upper end face of the pressing block 23 in a bilateral symmetry manner and are fixed to the lower end face.

In addition, in one embodiment, the driving mechanism 92 includes a first motor 55 fixed on the upper end wall of the driving cavity 56, a first power shaft 54 is dynamically connected to the lower end surface of the first motor 55, a first friction wheel 53 is fixedly arranged on the upper end of the first power shaft 54, a third pulley 62 positioned at a communication port between the upper side first transmission cavity 33 and the driving cavity 56 is fixedly arranged on the first power shaft 54, a second belt 63 is connected between the third pulley 62 and the upper side second pulley 34, a fourth pulley 61 positioned at a communication port between the lower side first transmission cavity 33 and the driving cavity 56 is fixedly arranged on the lower end of the first power shaft 54, a third belt 31 is connected between the third pulley 62 and the lower side second pulley 34, and the driving mechanism 92 is used for driving power.

In addition, in one embodiment, the transmission mechanism 93 includes two third driven shafts 51 which are bilaterally symmetrical to the first motor 55 and are rotatably connected to the upper end wall of the driving cavity 56, a second friction wheel 52 engaged with the first friction wheel 53 is fixedly arranged on the second friction wheel 52, a third bevel gear 50 engaged with the second bevel gear 49 is fixedly arranged at the lower end of the right third driven shaft 51, a fourth bevel gear 57 engaged with the first bevel gear 58 is fixedly arranged at the lower end of the left third driven shaft 51, and the power of the driving mechanism 92 is transmitted to other components through the transmission mechanism 93 to work.

In addition, in one embodiment, the adjusting mechanism 94 includes a sliding groove 43 with an upward opening formed on the upper end surface of the housing 10, a first sliding block 41 is slidably connected in the sliding groove 43, a second spring 42 fixed to the left end wall of the sliding groove 43 is fixedly arranged on the left end surface of the first sliding block 41, a safety cover 44 is fixedly arranged on the upper end surface of the first sliding block 41, a first sliding cavity 48 is arranged in the right end wall of the sliding groove 43, a second sliding block 47 is slidably connected in the first sliding cavity 48, a cylindrical pin 46 with an upper end penetrating through the upper end wall of the first sliding cavity 48 and an upper end located in the safety cover 44 is fixedly arranged on the upper end surface of the second sliding block 47, a third spring 45 fixed to the lower end wall of the first sliding cavity 48 is fixedly arranged on the lower end surface of the second sliding cavity 47, a second transmission cavity 68 with a right end opening communicated with the working cavity 11 is arranged in the lower end wall of the first sliding cavity 48, an adjusting cavity 40 is arranged in the lower end, the upper end wall of the second transmission cavity 68 is fixed with a second motor 71, the lower end surface of the second motor 71 is in power connection with a second power shaft 70, a third friction wheel 69 is fixedly arranged on the second power shaft 70, the upper end wall and the lower end wall of the second transmission cavity 68 are rotationally connected with a first transmission shaft 64 which is symmetrical left and right relative to the second motor 71, the first transmission shaft 64 is in sliding connection with a fourth friction wheel 65 which can be meshed with the third friction wheel 69, the upper end surface of the fourth friction wheel 65 is in sliding connection with a third sliding block 66, the left side of the upper end surface of the third sliding block 66 is fixed with a first pull rope 67, the upper end surface of the second transmission cavity 68 is fixed with the lower end surface of the second sliding block 47, the lower end of the left side of the first transmission shaft 64 extends downwards into the adjustment cavity 40, the lower end surface of the left side of the first transmission shaft 64 is fixed with a cam 82 which is positioned in the adjustment cavity 40, it runs through to be equipped with the right-hand member in the regulation chamber 40 right-hand member wall and right-hand member are located in the working chamber 11 with the fixed carriage release lever 79 of cutting bed 21 left end face, carriage release lever 79 right end face be fixed with regulation chamber 40 upper and lower end wall sliding connection's motion piece 81, motion piece 81 right end face set firmly with two fourth springs 80 that regulation chamber 40 right end wall is fixed.

In addition, in one embodiment, the pressing mechanism 95 includes a second sliding cavity 16 disposed in the right end wall of the working cavity 11, the right end wall of the second sliding cavity 16 is fixed with an electromagnet 85, the second sliding cavity 16 is connected with an electromagnetic block 19 in a sliding manner, the left end surface of the electromagnetic block 19 is fixed with a square block 20 whose left end penetrates through the left end wall of the second sliding cavity 16 and whose left end is located in the working cavity 11, the square block 20 and the pressing cavity 25 are located on the same horizontal plane, the right end surface of the electromagnetic block 19 is fixed with a fifth spring 18 fixed with the right end wall of the second sliding cavity 16, the right end surface of the electromagnetic block 19 is fixed with two sliding rails 78 whose right ends penetrate through the right end wall of the second sliding cavity 16 and are located in the second transmission cavity 68 and fixed with the upper end surface of the third sliding block 66 on the right side, the front and rear end walls of the working cavity 11 are fixed with two sliding rails 78 located at the connection port of the second transmission cavity 68 and the working, a rack 77 is connected in the slide rail 78 in a sliding way, the left end face of the rack 77 is provided with teeth, the right end face of the rack 77 is fixed with a fixed plate 12, a sliding chute 13 with an opening facing is arranged in the fixed plate 12, the sliding chute 13 is connected in a sliding way, the lower end of the sliding chute 13 penetrates through the right end of the upper side of the cutting table 21 and is positioned above the outlet of the right end of the pressing cavity 25, a second transmission shaft 75 is rotatably connected to the rear end wall of the second transmission cavity 68, a first transmission bevel gear 76 engaged with the left end face of the rack 77 is fixedly arranged on the second transmission shaft 75, the lower end wall of the second transmission cavity 68 is rotatably connected with a third transmission shaft 74, the upper end of the third transmission shaft 74 is fixedly provided with a second transmission bevel gear 73 engaged with the first transmission bevel gear 76, a fifth friction wheel 72 capable of meshing with the fourth friction wheel 65 on the right side is fixedly arranged on the third transmission shaft 74.

Sequence of mechanical actions of the whole device:

in an initial state, the upper end of the push rod 15 is located in the sliding groove 13 and is in contact with the upper end wall of the sliding groove 13, the electromagnetic block 19, the first spring 24, the second spring 42, the third spring 45 and the sixth spring 83 are in a relaxed state, the left end face of the rack 77 is provided with teeth, the rack 77 is located on the uppermost side of the sliding rail 78, the right end face of the cam 82 is in contact with the left end face of the moving block 81, the moving block 81 is in a compressed state, and the electromagnet 85 is electrically connected with the first motor 55.

When a metal strip needing embossing is processed, the device is started, the first motor 55 and the second motor 71 are further started, the metal strip is conveyed into the transmission cavity 29 from left to right through the outside, the first motor 55 drives the first friction wheel 53, the third belt wheel 62 and the fourth belt wheel 61 to rotate through the first power shaft 54, the third belt wheel 62 drives the second belt wheel 34 on the upper side to rotate through the second belt 63, the fourth belt wheel 61 drives the second belt wheel 34 on the lower side to rotate through the third belt 31, the second driven shaft 32 on the upper and lower symmetry of the transmission cavity 29 drives the polishing wheel 30 to rotate, so that the surface of the metal strip entering the transmission cavity 29 can be polished, the first friction wheel 53 rotates, the second friction wheel 52 on the left and right symmetry drives the third driven shaft 51 to rotate, and the third driven shaft 51 on the right side drives the first bevel gear 58 to rotate through the fourth bevel gear 57, the first bevel gear 58 drives the first belt wheel 60 on the upper side and the flattening wheel 37 on the upper side to rotate through the first driven shaft 36 on the upper side, the first belt wheel 60 on the upper side drives the first belt wheel 60 on the lower side to rotate through the first belt 59, the first driven shaft 36 on the lower side drives the flattening wheel 37 on the lower side to rotate, so that the metal strip entering the transmission cavity 29 can be flattened and conveyed into the transmission cavity 29 to be polished through the polishing wheel 30, the third driven shaft 51 on the left side drives the second bevel gear 49 to rotate through the third bevel gear 50, and the embossing rotating wheel 27 is driven to rotate through the rotating wheel shaft 28, so that the polished metal strip can be embossed;

when the metal strips with different cutting lengths and embossed patterns need to be adjusted, the safety cover 44 is manually pushed, the first sliding block 41 is further enabled to leftwards compress the second spring 42, the cylindrical pin 46 is further manually pressed, the second sliding block 47 is further enabled to downwards compress the third spring 45, the first pull rope 67 is further enabled to be loosened, the left fourth friction wheel 65 drives the left third sliding block 66 to downwards move to be meshed with the third friction wheel 69, the second motor 71 drives the third friction wheel 69 to rotate through the second power shaft 70, the fourth friction wheel 65 drives the cam 82 to rotate through the first transmission shaft 64, the moving block 81 is further driven by the acting force of the fourth spring 80 to move the moving rod 79 leftwards and rightwards, the cutting knife 14 and the push rod 15 are further driven to move leftwards and rightwards in the sliding groove 13, the adjustment is further carried out according to the required cutting length, the cylindrical pin 46 is loosened after the adjustment is carried out, the second slider 47 is further driven by the third spring 45 to make the left third slider 66 drive the left fourth friction wheel 65 to move upwards through the first pull rope 67, so that the left fourth friction wheel 65 is disengaged from the third friction wheel 69, the cam 82 stops rotating, and the cutting length is adjusted to be required for cutting;

after the metal strip 39 is rolled, polished and embossed, the metal strip 39 is continuously conveyed through the cutting table 21 with the adjusted cutting length to pass through the pressing cavity 25 to be abutted against the square block 20, then the metal strip 39 pushes the square block 20 to compress the fifth spring 18 through the electromagnetic block 19, further the second pull rope 17 is loosened, the electromagnetic block 19 is contacted with the electromagnet 85, thereby the first motor 55 stops working, the second pull rope 17 is loosened to enable the third slide block 66 on the right side to drive the fourth friction wheel 65 on the right side to move downwards to be meshed with the third friction wheel 69 and the fifth friction wheel 72, further the second motor 71 drives the third friction wheel 69 to rotate through the third friction wheel 69, further drives the fifth friction wheel 72 to rotate through the fourth friction wheel 65 on the right side, further the fifth friction wheel 72 drives the second transmission bevel gear 73 to rotate through the third transmission shaft 74, further the first transmission bevel gear 76 rotates along with the second transmission shaft 75, and the first transmission bevel gear 76 is meshed with the rack 77, so that the rack 77 drives the fixed plate 12 to move downwards and stretch the sixth spring 83, the fixed plate 12 further pushes the push rod 15 and the cutting knife 14 downwards, the push rod 15 further pushes the downward moving block 84 to move downwards, the press block 23 is further pushed by the first spring 24 to press the metal strip in the pressing cavity 25 downwards, the fixed plate 12 pushes the push rod 15 to continue to move downwards, and the required length of the metal strip after embossing is cut.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A metal strip embossing device comprises a shell and is characterized in that a working cavity is arranged in the shell, a transmission cavity is communicated with the outside through the left end wall of the working cavity, an embossing mechanism is arranged in the transmission cavity, a cutting mechanism is arranged in the working cavity, a driving cavity is arranged in the rear end wall of the transmission cavity, a driving mechanism is arranged in the driving cavity, a transmission mechanism is arranged on the lower side of the driving mechanism, an adjusting mechanism is arranged on the upper side of the embossing mechanism, and a pressing mechanism is arranged on the upper side of the cutting mechanism;

2. The metal bar embossing apparatus as set forth in claim 1, wherein: an inverted U-shaped cavity is communicated with the outside through the lower end wall of the transmission cavity, two first transmission cavities which are symmetrical up and down relative to the transmission cavity and are communicated with the driving cavity through a rear end opening are arranged in the lower end wall of the inverted U-shaped cavity, one end of each first transmission cavity, which is far away from the transmission cavity, is rotatably connected with two second driven shafts, one end of each second driven shaft, which is close to the transmission cavity, penetrates through the end wall of the corresponding first transmission cavity, one end of each first driven shaft, which is close to the transmission cavity, is located in the corresponding transmission cavity, one end of each second driven shaft, which is close to the transmission cavity, is located in the corresponding inverted U-shaped cavity, one end of each second driven shaft, which is far away from the transmission cavity, is fixedly provided with a second belt wheel located in the corresponding first transmission cavity, one end of each second driven shaft, which is close to the corresponding transmission cavity, is fixedly provided with two grinding, the transmission cavity upper end wall is internally provided with an embossing cavity which is positioned at the right side of the inverted U-shaped cavity and is communicated with the transmission cavity and the working cavity, the rear end wall of the embossing cavity is rotatably connected with a rotating wheel shaft, the rear end of the rotating wheel shaft penetrates through the rear end wall of the embossing cavity, the rear end of the rotating wheel shaft is positioned in the driving cavity, an embossing rotating wheel with the lower end extending into the transmission cavity is fixedly arranged on the rotating wheel shaft, and the rear end of the rotating wheel shaft is fixedly provided with a second bevel gear positioned in the driving cavity.

3. The metal bar embossing apparatus as set forth in claim 1, wherein: cutting mechanism includes the cutting bed that is equipped with in the working chamber runs through the cutting bed with the working chamber intercommunication has the chamber that compresses tightly, compress tightly the chamber lower extreme wall with the transmission chamber lower extreme wall is in on the same horizontal plane, it is equipped with the lower extreme intercommunication to compress tightly the chamber down to press intracavity sliding connection have the briquetting and move down the piece, it has set firmly the upper end to move down the piece up end and runs through it is located to press down chamber upper extreme wall and upper end the push rod in the working chamber, briquetting up end bilateral symmetry set firmly with move down two first springs that the piece down end face is fixed.

4. The metal bar embossing apparatus as set forth in claim 1, wherein: actuating mechanism includes the fixed first motor of drive chamber upper end wall, terminal surface power is connected with first power shaft under the first motor, first power shaft upper end has set firmly first friction pulley, the epaxial upside that has set firmly of first power first drive chamber with the third band pulley of drive chamber intercommunication mouth department, third band pulley and upside the second band pulley is connected with the second belt, first power shaft lower extreme has set firmly and is located the downside first drive chamber with the fourth band pulley of drive chamber intercommunication mouth department, third band pulley and downside the second band pulley is connected with the third belt, actuating mechanism is used for the drive of power.

5. The metal bar embossing apparatus as set forth in claim 1, wherein: the transmission mechanism comprises two third driven shafts which are in bilateral symmetry with the first motor and are rotatably connected with the upper end wall of the driving cavity, a second friction wheel meshed with the first friction wheel is fixedly arranged on the second friction wheel, a third bevel gear meshed with the second bevel gear is fixedly arranged at the lower end of the third driven shaft on the right side, a fourth bevel gear meshed with the first bevel gear is fixedly arranged at the lower end of the third driven shaft on the left side, and power of the driving mechanism is transmitted to other components to work through the transmission mechanism.

6. The metal bar embossing apparatus as set forth in claim 1, wherein: the adjusting mechanism comprises a sliding chute with an upward opening arranged on the upper end surface of the shell, a first sliding block is connected in the sliding chute in a sliding manner, a second spring fixed with the left end wall of the sliding chute is fixedly arranged on the left end surface of the first sliding block, a safety cover is fixedly arranged on the upper end surface of the first sliding block, a first sliding cavity is arranged in the right end wall of the sliding chute, a second sliding block is connected in the first sliding cavity in a sliding manner, a cylindrical pin with the upper end penetrating through the upper end wall of the first sliding cavity and the upper end positioned in the safety cover is fixed on the upper end surface of the second sliding block, a third spring fixed with the lower end wall of the first sliding cavity is fixedly arranged on the lower end surface of the second sliding block, a second transmission cavity with a right end opening communicated with the working cavity is arranged in the lower end wall of the first sliding cavity, an adjusting cavity is arranged in the lower end wall of the second transmission cavity, a second motor is fixed on the upper end wall of, a third friction wheel is fixedly arranged on the second power shaft, the upper end wall and the lower end wall of the second transmission cavity are rotationally connected with a first transmission shaft which is bilaterally symmetrical relative to the second motor, the first transmission shaft is slidably connected with a fourth friction wheel which can be meshed with the third friction wheel, the upper end surface of the fourth friction wheel is slidably connected with a third sliding block, the upper end surface of the left third sliding block is fixedly provided with a first pull rope, the upper end of the first pull rope penetrates through the upper end surface of the second transmission cavity and is fixed with the lower end surface of the second sliding block, the lower end of the left first transmission shaft extends downwards into the adjusting cavity, the lower end surface of the left first transmission shaft is fixedly provided with a cam positioned in the adjusting cavity, the adjusting cavity is internally provided with a moving rod, the right end of the moving rod penetrates through the right end wall of the adjusting cavity and is positioned in the working cavity and is fixed with the left end surface of the cutting table, and the, and two fourth springs fixed with the right end wall of the adjusting cavity are fixedly arranged on the right end face of the moving block.

7. The metal bar embossing apparatus as set forth in claim 6, wherein: the pressing mechanism comprises a second sliding cavity arranged in the right end wall of the working cavity, an electromagnet is fixed on the right end wall of the second sliding cavity, an electromagnetic block is connected in the second sliding cavity in a sliding manner, the left end face of the electromagnetic block is fixed with a square block, the left end of the square block penetrates through the left end wall of the second sliding cavity, the left end of the square block is located in the working cavity, the square block and the pressing cavity are located on the same horizontal plane, a fifth spring fixed with the right end wall of the second sliding cavity is fixedly arranged on the right end face of the electromagnetic block, the right end face of the electromagnetic block is fixed with a right end penetrating through the right end wall of the second sliding cavity and located in the second transmission cavity, the right end face of the electromagnetic block is fixed with the upper end face of a third sliding block, two sliding rails located at the communication port of the second transmission cavity and the working cavity are fixed on the front end wall and the rear end wall, the cutting table is characterized in that a fixed plate is fixed on the right end face of the rack, a sliding groove with an opening facing is formed in the fixed plate, the lower end of the sliding groove is connected with the right end of the upper side of the cutting table in a penetrating mode and is located above an outlet of the right end of the compression cavity, the rear end wall of the second transmission cavity is rotatably connected with a second transmission shaft, a first transmission bevel gear meshed with the left end face of the rack is fixedly arranged on the second transmission shaft, a third transmission shaft is rotatably connected with the lower end wall of the second transmission cavity, a second transmission bevel gear meshed with the first transmission bevel gear is fixedly arranged at the upper end of the third transmission shaft, and a fifth friction wheel meshed with the fourth friction wheel is fixedly arranged on the third transmission shaft.