CN215662441U - Automatic circulation multi-angle transfer printing equipment - Google Patents

Abstract

The utility model discloses automatic-circulation multi-angle transfer printing equipment which comprises a sheath feeding mechanism, a transfer mechanism, a movable carrying mechanism, a multi-position transfer printing machine and a plurality of blow drying devices, wherein the sheath feeding mechanism is used for feeding a plurality of sheaths side by side, the transfer mechanism is arranged below the sheath feeding mechanism and can horizontally slide, the movable carrying mechanism is matched with the transfer mechanism, the multi-position transfer printing machine is arranged above the movable carrying mechanism and is used for printing the surface layers of the sheaths, and the blow drying devices are arranged behind the multi-position transfer printing machine and are used for blowing dry printing positions; the movable carrying mechanism comprises a clamping rack which can be arranged in a lifting mode, clamping plates which are arranged on two sides of the clamping rack and can be opened and closed relatively to slide or parallel synchronous horizontal slide, a plurality of groups of positioning caps arranged on the clamping plate on one side, and rotating caps arranged on the clamping plate on the other side and corresponding to the positioning caps at intervals, a plurality of protective sleeves which are arranged in groups can be positioned on the clamping rack, and the rotating caps and the positioning caps can synchronously rotate, position and transfer the protective sleeves. The automatic sheath conveying device realizes automatic and efficient sheath conveying and improves the transfer printing efficiency.

Description

Automatic circulation multi-angle transfer printing equipment

Technical Field

The utility model belongs to the technical field of printing equipment, and particularly relates to automatic-circulation multi-angle transfer printing equipment.

Background

The sheath structure for the existing injector needs to be printed and marked at the quartering positions of the circumferential surface due to the structural particularity, the sheath is conventionally positioned on a positioning carrier for four times, the positioning is troublesome, circulation of the sheath cannot be formed, and the problem that multiple sleeve transfer is asynchronous and uncoordinated is caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problems and provides automatic circulation multi-angle transfer printing equipment, so that automatic and efficient circulation sheath transportation is realized, and transfer printing efficiency is improved. In order to achieve the purpose, the technical scheme of the utility model is as follows:

the automatic-circulation multi-angle pad printing equipment comprises a sheath feeding mechanism for feeding a plurality of sheaths side by side, a transfer mechanism which is arranged below the sheath feeding mechanism and can horizontally slide, a moving and carrying mechanism matched with the transfer mechanism, a multi-pad printing machine which is arranged above the moving and carrying mechanism and used for printing the sheath surface layer, and a plurality of blow-drying devices which are arranged behind the multi-pad printing machine and used for blowing dry printing positions; the movable carrying mechanism comprises a clamping rack which can be arranged in a lifting mode, clamping plates which are arranged on two sides of the clamping rack and can be opened and closed relatively to slide or parallel synchronous horizontal slide, a plurality of groups of positioning caps arranged on the clamping plate on one side, and rotating caps arranged on the clamping plate on the other side and corresponding to the positioning caps at intervals, a plurality of protective sleeves which are arranged in groups can be positioned on the clamping rack, and the rotating caps and the positioning caps can synchronously rotate, position and transfer the protective sleeves.

Specifically, the sheath comprises a hollow through cylinder, an annular flange arranged on the upper portion of the outer wall of the cylinder, and a plurality of rib positions axially extending and arranged on the connecting flange, the plurality of rib positions are respectively arranged at the circumferential quartering positions of the cylinder, and the plurality of rib positions are positioned between adjacent rib positions on the cylinder and printed with marks.

The sheath feeding mechanism comprises a feeding hopper, a vibration track, a plurality of flow grooves, rotatable screening teeth and a turnover plate, wherein the vibration track is connected with the feeding hopper and is obliquely arranged, the flow grooves are arranged in the vibration track and used for arranging sheaths and vertically hanging and matching the sheaths relative to the flow grooves, the rotatable screening teeth are arranged on two sides of each flow groove and used for rolling, turning and selecting directions, and the turnover plate is arranged at the tail end of each flow groove and used for turning and shifting the sheaths.

Specifically, the turnover plate is rotatably abutted to the tail end of the vibration track, a plurality of receiving grooves corresponding to the flow grooves are formed in the turnover plate, and the back of the turnover plate is connected with a rotating shaft for driving the turnover plate to rotate.

Specifically, the transfer mechanism comprises a support rack which can horizontally slide and is arranged in a lifting and moving manner.

Specifically, the bottom of splint sets up along the first slide rail of horizontal arrangement, the bottom of first slide rail is equipped with the base plate, and the bottom of base plate sets up along the second slide rail of longitudinal arrangement.

Compared with the prior art, the automatic circulation multi-angle transfer printing equipment has the beneficial effects that:

the screening teeth and the turnover plate are arranged in the sheath feeding mechanism, so that the sheath has the characteristics of automatic orientation and positioning arrangement, the sheath can be accurately butted to the supporting rack of the transfer mechanism, and synchronous and accurate feeding of a group of multi-batch sheaths is realized; clamping racks are matched and clamped by clamping plates on two sides in the moving and carrying mechanism, so that multiple groups of sheaths can be rotationally controlled and carried, effective printing operation can be carried out on multiple transfer printing stations, automatic circulation is free from obstruction, and effective circulation is accurately realized in positioning; the sheath is through the stoving operation back of weather ware, guarantees that the effect of printing does not decolorize easily, and then the flow operation of integration is accomplished in the unloading, and whole equipment has high efficiency, accurate advantage.

Drawings

FIG. 1 is a schematic diagram of an overall top view configuration of an embodiment of the present invention;

FIG. 2 is a schematic view of a jacket feeding mechanism in the present embodiment;

FIG. 3 is a schematic view of the structure of the screening teeth in this embodiment;

FIG. 4 is a schematic diagram of a flip-flop structure in the present embodiment;

FIG. 5 is a schematic view of the mobile carrying mechanism in the present embodiment;

FIG. 6 is a schematic view of a transfer mechanism in the present embodiment;

FIG. 7 is a partial enlarged view of the clamping rack of the present embodiment;

FIG. 8 is a schematic view of the sheath structure of the present embodiment;

the figures in the drawings represent:

the device comprises a jacket 1, a cylinder 11, a flange 12, a rib position 13, a jacket feeding mechanism 2, a feeding hopper 21, a vibration track 22, a flow groove 23, a screening tooth 24, a turnover plate 25, a tooth groove 26, a bearing groove 27, a rotating shaft 28, a guide rail 29, a transfer mechanism 3, a support rack 31, a movable window 32, a slide rail 33, a movable carrying mechanism 4, a clamping rack 41, a clamping plate 42, a positioning cap 43, a rotating cap 44, a guide sleeve guide post assembly 45, a first slide rail 46, a base plate 47, a second slide rail 48, a multi-position pad printing machine 5, a pad printing station 51, a dryer 6 and a funnel groove 61.

Detailed Description

The technical solutions in the embodiments of the present invention are described clearly and completely below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments.

Example (b):

referring to fig. 1 to 8, the present embodiment is an automatic circulation multi-angle transfer printing apparatus, which includes a sheath feeding mechanism 2 for feeding a plurality of sheaths 1 side by side, a transfer mechanism 3 disposed below the sheath feeding mechanism 2 and capable of sliding horizontally, a moving and carrying mechanism 4 engaged with the transfer mechanism 3, a multi-pad printing machine 5 disposed above the moving and carrying mechanism 4 and used for printing the surface layer of the sheath 1, and a plurality of blow dryers 6 disposed behind the multi-pad printing machine 5 and used for blowing dry the printing position.

The sheath 1 includes the barrel 11 that the cavity link up, locate the annular flange 12 of barrel 11 outer wall upper portion, and connect a plurality of muscle positions 13 that flange 12 arranged along axial extension, and a plurality of muscle positions 13 are arranged in the circumference quartering position of barrel 11 respectively in this embodiment, are located and print the mark between the adjacent muscle position 13 on the barrel 11.

The sheath feeding mechanism 2 comprises a feeding hopper 21, a vibration track 22 connected with the feeding hopper 21 and obliquely arranged, a plurality of flow grooves 23 arranged in the vibration track 22 and used for arranging sheaths and vertically hanging and matching the sheaths relative to the flow grooves, rotatable screening teeth 24 arranged on two sides of the flow grooves 23 and used for rolling, turning and selecting directions, and a turning plate 25 arranged at the tail end of the flow grooves 23 and used for turning and shifting the sheaths 1. The side of screening tooth 24 is equipped with and is pegged graft complex tooth's socket 26 with barrel 11 outer wall, and when sheath 1 reverse arrangement in flow groove 23, screening tooth 24 pushes down the higher extreme of sheath 1 and rotatory entering flow groove 23 in, and flange 12 is erect all the time in flow groove 23 outside to carry out the screening of unified direction to sheath 1, sheath 1 from the below of screening tooth 24 along with flow groove 23 changes. The end of the screening teeth 24 is connected to a first motor that drives it in rotation.

The turnover plate 25 is rotatably abutted against the tail end of the vibration track 22, a plurality of receiving grooves 27 corresponding to the flow grooves 23 are formed in the turnover plate 25, the back of the turnover plate 25 is connected with a rotating shaft 28 for driving the turnover plate to rotate, and the end part of the rotating shaft 28 is connected with a second motor. The second motor is mounted on a telescopically slidably arranged guide rail 29. The jacket 1 is transferred into the receiving groove 27 by the turning plate 25, and the turning plate 25 is turned upside down by a rotation angle, thereby transferring the jacket 1 to the transfer mechanism 3.

The transfer mechanism 3 comprises a support rack 31 which can horizontally slide and is arranged in a lifting and moving mode, a moving window 32 is arranged on the workbench, the support rack 31 is installed in the moving window 32, a sliding rail is arranged at the bottom of the moving window 32, the support rack 31 moves along the sliding rail 33, and a first air cylinder which drives the support rack 31 to lift is connected to the bottom of the support rack 31. The supporting rack 31 can be used for positioning a plurality of sheaths 1 arranged in groups, the flange 12 of each sheath 1 is positioned on the outer side of the supporting rack 31, and the sheaths 1 in the turnover plate 25 directly fall into the supporting rack 31 for positioning after being turned over.

The movable carrying mechanism 4 includes a clamping rack 41 capable of being lifted, clamping plates 42 which are arranged on two sides of the clamping rack 41 and can be opened and closed to slide relatively or horizontally and synchronously, a plurality of groups of positioning caps 43 arranged on the clamping plates 42 on one side, rotating caps 44 arranged on the clamping plates 42 on the other side and corresponding to the positioning caps 43 at intervals, and guide sleeve guide rod assemblies 45 connected between the clamping plates 42 on two sides. A plurality of sheaths 1 arranged in a group can be positioned on the clamping rack 41, with the flange 12 of the sheaths 1 being located outside the clamping rack 41. The two ends of the sheath 1 are clamped and positioned between the rotating cap 44 and the positioning cap 43, and the rotating cap 44 and the positioning cap 43 can synchronously rotate to position and transfer the sheath 1.

The bottom of the clamping plate 42 is arranged along a first sliding rail 46 arranged transversely, the bottom of the first sliding rail 46 is provided with a base plate 47, the bottom of the base plate 47 is arranged along a second sliding rail 48 arranged longitudinally, and the clamping plate 42 can move transversely or longitudinally. The clamping rack 41 jacks up the sheath 1 to convey the sheath to a position between the clamping plates 42 on the two sides, the positioning caps 43 and the rotating caps 44 are matched to clamp the sheath 1, the clamping rack 41 descends to avoid, the multi-position pad printing machine 5 comprises four pad printing stations 51 in the embodiment, the clamping plates 42 on the two sides drive a group of sheaths 1 to perform printing processing one by one on the pad printing stations 51, the rotating caps 44 and the positioning caps 43 in each pad printing station 51 synchronously rotate the sheaths 1 to perform 90-degree transposition, and printing marks at circumferential quartering positions of the sheaths 1 are realized.

A plurality of blow dryers 6 are arranged above the clamping plates 42 at the two sides for drying the positions of the printed marks. A funnel groove 61 for blanking the sheath 1 is arranged at the rear part of the blow dryer 6, and the clamping plates 42 at the two sides transversely transfer the sheath 1 dried on the clamping rack 41 into the funnel groove 61 for blanking.

When using this embodiment, sheath 1 arranges the upset location to transfer mechanism 3 from sheath feed mechanism 2, and 3 lateral shifting of transfer mechanism transports sheath 1 to removing handling mechanism 4, but both sides splint 42 cooperation centre gripping and rotatory sheath 1 in removing handling mechanism 4, send into each bat printing station 51 printing mark after rotatory certain angle, and the unloading is dried through the weather ware 6, realizes the multi-angle printing operation of sheath 1.

In the embodiment, the screening teeth 24 and the turnover plate 25 are arranged in the sheath feeding mechanism 2, so that the sheath 1 has the characteristics of automatic orientation and positioning arrangement, the sheath 1 can be accurately butted to the supporting rack 31 of the transfer mechanism 3, and synchronous and accurate feeding of a group of multi-batch sheaths is realized; the clamping plates 42 on the two sides in the moving and carrying mechanism 4 are matched with the clamping racks 41 to realize the rotatable control of carrying a plurality of groups of sheaths 1, so that effective printing operation is carried out at a plurality of pad printing stations 51, the automatic circulation is free from obstruction, and the positioning is accurate to realize effective circulation; sheath 1 is through the stoving operation back of weatherer 6, guarantees that the effect of printing is decolorized easily, and then the flow operation of integration is accomplished in the unloading, and whole equipment has high efficiency, accurate advantage.

What has been described above are merely some embodiments of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the inventive concept thereof, and these changes and modifications can be made without departing from the spirit and scope of the utility model.

Claims (6)

1. Automatic multi-angle bat printing equipment of circulation, its characterized in that: the device comprises a sheath feeding mechanism for feeding a plurality of sheaths side by side, a transfer mechanism which is arranged below the sheath feeding mechanism and can horizontally slide, a mobile carrying mechanism matched with the transfer mechanism, a multi-pad printer which is arranged above the mobile carrying mechanism and is used for printing the sheath surface layer, and a plurality of blow-drying devices which are arranged behind the multi-pad printer and are used for blowing dry the printing positions; the movable carrying mechanism comprises a clamping rack which can be arranged in a lifting mode, clamping plates which are arranged on two sides of the clamping rack and can be opened and closed relatively to slide or parallel synchronous horizontal slide, a plurality of groups of positioning caps arranged on the clamping plate on one side, and rotating caps arranged on the clamping plate on the other side and corresponding to the positioning caps at intervals, a plurality of protective sleeves which are arranged in groups can be positioned on the clamping rack, and the rotating caps and the positioning caps can synchronously rotate, position and transfer the protective sleeves.

2. The automated stream multi-angle transfer printing apparatus of claim 1, wherein: the protective sleeve comprises a hollow through cylinder body, an annular flange arranged on the upper portion of the outer wall of the cylinder body and a plurality of rib positions which are arranged along the axial extension direction of the connecting flange, the plurality of rib positions are respectively arranged at the circumferential quartering positions of the cylinder body, and a printing mark is arranged between the adjacent rib positions on the cylinder body.

3. The automated stream multi-angle transfer printing apparatus of claim 1, wherein: the sheath feed mechanism includes the feed fill, connect the vibration track of the slope setting of feed fill, locate in the vibration track be used for arranging the sheath rather than relative perpendicular articulate a plurality of flowing grooves of complex, locate the rotatable screening tooth that is used for rolling stirring selection direction of flowing groove both sides, locate the terminal returning face plate that is used for the upset and shifts the sheath of flowing groove.

4. The automated stream multi-angle transfer printing apparatus of claim 3, wherein: the turnover plate is rotatably abutted to the tail end of the vibration track, a plurality of receiving grooves corresponding to the flow grooves are formed in the turnover plate, and the back of the turnover plate is connected with a rotating shaft for driving the turnover plate to rotate.

5. The automated stream multi-angle transfer printing apparatus of claim 1, wherein: the transfer mechanism comprises a supporting rack which can horizontally slide and is arranged in a lifting and moving mode.

6. The automated stream multi-angle transfer printing apparatus of claim 1, wherein: the bottom of splint sets up along transversely arranged's first slide rail, the bottom of first slide rail is equipped with the base plate, and the bottom of base plate sets up along longitudinally arranged's second slide rail.

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