CN216403005U - Automatic interval feeding machine - Google Patents

Abstract

The utility model provides an automatic interval feeding machine which comprises a rack, a feeding mechanism, a workpiece jacking mechanism, a pushing identification mechanism and a positioning and fixing mechanism, wherein the workpiece jacking mechanism is positioned below the tail end of the feeding mechanism, the pushing identification mechanism is positioned above the feeding mechanism, the positioning and fixing mechanism and the pushing identification mechanism are arranged oppositely, the feeding mechanism is used for conveying the workpiece to the position above the workpiece jacking mechanism forwards, the workpiece jacking mechanism is used for jacking the workpiece to the position of the pushing identification mechanism, the pushing identification mechanism is used for pushing the workpiece to the position of the positioning and fixing mechanism and identifying whether the workpiece is a thin workpiece or a thick workpiece, and the positioning and fixing mechanism is used for positioning the workpiece; according to the automatic interval feeding machine, the feeding mechanism, the workpiece jacking mechanism, the pushing identification mechanism and the positioning fixing mechanism are arranged, so that automatic feeding of workpieces with different thicknesses can be realized, and the purposes of reducing the number of types of workpieces to be changed, improving the production efficiency and reducing the working strength of operators are achieved.

Description

Automatic interval feeding machine

Technical Field

The utility model relates to the technical field of feeding machinery, in particular to an automatic interval feeding machine.

Background

The 108E tile cover broken blank comprises 2 products, the difference of the thickness of the 2 products is only different and is 3mm, the other sizes are the same, the type of the product needs to be changed frequently according to the requirements of field production technology, the existing feeding structure needs to be changed frequently when the workpiece is produced, the production efficiency is low, and the working strength of operators is high.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the prior art, the utility model provides an automatic interval feeding machine which can realize automatic feeding of workpieces with different thicknesses.

The utility model provides an automatic interval feeding machine which comprises a rack, a feeding mechanism, a workpiece jacking mechanism, a pushing identification mechanism and a positioning and fixing mechanism, wherein the workpiece jacking mechanism is positioned below the tail end of the feeding mechanism, the pushing identification mechanism is positioned above the feeding mechanism, and the positioning and fixing mechanism and the pushing identification mechanism are arranged oppositely;

the feeding mechanism is used for conveying the workpiece to the upper part of the workpiece jacking mechanism; the workpiece jacking mechanism is used for jacking the workpiece to the pushing identification mechanism; the pushing identification mechanism is used for pushing the workpiece to the positioning fixing mechanism and identifying whether the workpiece is a thin workpiece or a thick workpiece; the positioning and fixing mechanism is used for positioning the workpiece.

In order to further realize the utility model, the feeding mechanism comprises a feeding lifting mechanism, a feeding forward-backward moving mechanism, a material supporting strip and a material supporting plate, wherein the feeding forward-backward moving mechanism is arranged on the feeding lifting mechanism and is used for driving the feeding forward-backward moving mechanism to move up and down, the material supporting strip is arranged on the feeding forward-backward moving mechanism and is used for driving the material supporting strip to move back and forth, the material supporting plate is provided with a material strip gap, and the material supporting strip is arranged in the material strip gap.

In order to further realize the feeding and lifting mechanism, the feeding and lifting mechanism comprises a lifting installation base, a lifting installation bearing, a lifting driving shaft, a lifting driven shaft, a lifting chain wheel chain and a lifting driving motor, wherein the lifting installation base is arranged on the frame, the lifting installation bearing is arranged on the top surface of the lifting installation base, the lifting driving shaft and the lifting driven shaft can be rotatably arranged on the lifting installation bearing, the lifting driving shaft and the lifting driven shaft are arranged in parallel, chain wheels are arranged at the same ends of the lifting driving shaft and the lifting driven shaft, the lifting chain wheel chain is wound around the chain wheels arranged on the lifting driving shaft and the lifting driven shaft and is tensioned, the lifting driving motor is connected with the end part of the lifting driving shaft and is used for driving the lifting driving shaft to rotate, and cams are arranged on the lifting driving shaft and the lifting driven shaft.

In order to further realize the utility model, one end of the lifting driven shaft is provided with a lifting sensing mechanism, the lifting sensing mechanism comprises a sensing disc, a groove-shaped photoelectric sensor, a first proximity switch and a second proximity switch, the sensing disc is arranged at the end part of the lifting driven shaft, the circle center of the sensing disc is positioned on the axis of the lifting driven shaft, the outer side surface of the sensing disc is provided with a proximity feeler lever, the edge of the sensing disc is provided with a sensing groove, the groove-shaped photoelectric sensor is positioned below the sensing disc, the first proximity switch and the second proximity switch are fixed at one side of the sensing disc through a proximity switch fixing frame, the proximity feeler lever of the sensing disc can touch the first proximity switch and the second proximity switch in the rotating process, and the first proximity switch is positioned below the second proximity switch.

In order to further realize the feeding device, the feeding front-and-back moving mechanism comprises a moving fixing seat, a moving sliding block, a moving driving air cylinder and a supporting strip connecting plate, wherein the moving fixing seat is arranged on the rack, a moving sliding seat is arranged on the side surface of the moving fixing seat, the moving sliding block can be arranged on the moving sliding seat in a vertically moving mode, the telescopic end of the moving driving air cylinder is connected with the moving sliding block, the other end of the moving driving air cylinder is connected with the supporting strip connecting plate, and the supporting strip connecting plate is connected with the supporting strip.

In order to further realize the feeding mechanism, a material strip sliding block is arranged at the bottom of the material supporting strip, a material strip sliding seat is slidably arranged at the bottom of the material strip sliding block, a cam fixture block sliding rail is arranged at the bottom of the material strip sliding seat and is abutted to a cam, the feeding mechanism further comprises a return mechanism, the return mechanism is used for pushing the cam fixture block sliding rail to return, the return mechanism comprises a return cylinder and a return connecting plate, the telescopic end of the return cylinder is fixedly connected with the return connecting plate, the other end of the return cylinder is fixedly connected with a supporting strip transverse plate, and the return connecting plate is connected with the cam fixture block sliding rail.

In order to further realize the utility model, the workpiece jacking mechanism comprises a jacking fixed plate, a jacking cylinder and a jacking structure, wherein the jacking fixed plate is arranged on the rack, the jacking cylinder is fixedly arranged on the bottom surface of the jacking fixed plate, the telescopic end of the jacking cylinder is connected with the jacking structure and is used for driving the jacking structure to move up and down, the jacking structure comprises a jacking plate, jacking rods and jacking blocks, the jacking rods are arranged on the top surface of the jacking plate, the number of the jacking rods is matched with the number of the material supporting strips, and the jacking blocks are arranged at the tail ends of the jacking rods.

In order to further realize the utility model, the push-out identification mechanism comprises a push-out fixing plate, a push-out air cylinder, a push-out mounting plate, a push-out spring pin, an identification air cylinder, an identification mounting plate and a microswitch, wherein the push-out fixing plate is fixedly arranged on the top surface of the material supporting plate, the push-out air cylinder is arranged on the top surface of the push-out fixing plate, the telescopic end of the push-out air cylinder is fixedly connected with the push-out mounting plate and used for driving the push-out mounting plate to move forwards and backwards, the push-out mounting plate is slidably connected with the push-out fixing plate, the push-out spring pin is arranged at the front end of the push-out mounting plate, the identification air cylinder is arranged on the top surface of the push-out mounting plate, the telescopic end of the identification air cylinder is fixedly connected with the identification mounting plate and used for driving the identification mounting plate to move forwards and backwards, and the microswitch is arranged on the identification mounting plate.

In order to further realize the utility model, the pushing-out recognition mechanism further comprises a workpiece direction recognition sensor and a second material sensor, wherein the workpiece direction recognition sensor and the second material sensor are both arranged on the recognition mounting plate.

In order to further realize the utility model, the positioning and fixing mechanism comprises a positioning and fixing plate, a jacking guide block, a push-out in-place stop block, an adjusting and positioning screw and a material correlation sensor, wherein the positioning and fixing plate is arranged on the rack, the jacking guide block is arranged on the side surface facing the workpiece jacking mechanism, the push-out guide block is arranged on the top surface of the positioning and fixing plate, the push-out in-place stop block is arranged on the positioning and fixing plate and is positioned at the tail end of the push-out guide block, the adjusting and positioning screw is arranged on the positioning and fixing plate and is opposite to the identification mounting plate, and the material correlation sensor is arranged on the top surface of the positioning and fixing plate and is positioned at two ends of the positioning and fixing plate.

According to the automatic feeding device, the feeding mechanism, the workpiece jacking mechanism, the pushing-out recognition mechanism and the positioning and fixing mechanism are arranged, so that automatic feeding of workpieces with different thicknesses can be realized, and the purposes of reducing the number of types to be changed, improving the production efficiency and reducing the working strength of operators are achieved.

Drawings

FIG. 1 is a schematic structural view of an automatic interval feeder according to the present invention;

FIG. 2 is another schematic view of an automatic gap feeder according to the present invention;

FIG. 3 is a schematic structural view of a feeding mechanism in an automatic interval feeder according to the present invention;

FIG. 4 is a schematic structural view of a feeding lifting mechanism in an automatic interval feeder according to the present invention;

FIG. 5 is a schematic structural view of a lift sensing mechanism in an automatic interval feeder according to the present invention;

FIG. 6 is a schematic structural view of a feed forward-backward movement mechanism in an automatic interval feeder according to the present invention;

FIG. 7 is a schematic structural view of a material supporting strip in an automatic interval feeding machine according to the present invention;

FIG. 8 is another schematic view of the structure of the carrier strip in an automatic gap feeder of the present invention;

FIG. 9 is a schematic structural view of a workpiece lifting mechanism in an automatic interval feeder according to the present invention;

FIG. 10 is a schematic view of the ejection recognition mechanism of the automatic interval feeder according to the present invention;

FIG. 11 is another schematic view of the ejecting identification mechanism in the automatic gap feeder of the present invention;

FIG. 12 is a schematic view of a positioning and fixing mechanism of an automatic interval feeder according to the present invention;

FIG. 13 is another schematic view of the positioning and fixing mechanism of the automatic gap feeder of the present invention;

FIG. 14 is a schematic view of the contact of a thick workpiece with a push-out spring pin in an automatic gap feeder of the present invention;

FIG. 15 is a schematic view of the contact of a thin workpiece with a push-out spring pin in an automatic space feeder of the present invention.

Fig. 1 to 15 include:

a frame 1;

a feeding mechanism 2; a feed lifting mechanism 21; a lift mounting base 211; a lift mount bearing 212; a lift drive shaft 213; an elevating driven shaft 214; a lifting sprocket chain 215; a lift drive motor 216; a sprocket 217; a cam 218; a lift sensing mechanism 219; an induction disc 2191; a groove type photosensor 2192; a first proximity switch 2193; a second proximity switch 2194; proximity trolley 2195; an induction well 2196; a proximity switch holder 2197; a feed forward-backward movement mechanism 22; a movable fixing seat 221; moving the slider 222; the movement driving cylinder 223; a carrier strip attachment plate 224; a moving slide 225; the moving slide bar 226; a holding strip 23; the retainer bar transverse plate 231; a bar slider 232; a strand slide 233; a cam dog slide 234; a retainer plate 24; a strand gap 25; a return mechanism 26; a return cylinder 261; a return connection plate 262; a first material sensor 27;

a workpiece jacking mechanism 3; jacking fixed plates 31; a jacking cylinder 32; a jacking structure 33; a lifting plate 331; a jack-up rod 332; a jacking block 333;

a push-out recognition mechanism 4; pushing out the fixed plate 41; a push-out slide rail 411; a push-out cylinder 42; pushing out the mounting plate 43; a push-out slider 431; a push-out spring pin 44; identifying the cylinder 45; identifying the mounting plate 46; a micro switch 47; a workpiece-direction recognition sensor 48; a second material sensor 49;

a positioning and fixing mechanism 5; a positioning fixing plate 51; a jacking guide block 52; the push-out guide block 53; a push-out to position stop 54; adjusting the set screw 55; there is a material correlation sensor 56.

Detailed Description

As shown in fig. 1 and 15, the utility model discloses an automatic interval feeding machine, which comprises a rack 1, a feeding mechanism 2, a workpiece jacking mechanism 3, a pushing identification mechanism 4 and a positioning fixing mechanism 5.

The feeding mechanism 2, the workpiece jacking mechanism 3, the pushing-out recognition mechanism 4 and the positioning fixing mechanism 5 are all arranged on the rack 1, the workpiece jacking mechanism 3 is located below the tail end of the feeding mechanism 2, the pushing-out recognition mechanism 4 is located above the feeding mechanism 3, and the positioning fixing mechanism 5 and the pushing-out recognition mechanism 4 are arranged oppositely.

The feeding mechanism 2 is used for conveying the workpiece forwards to the position above the workpiece jacking mechanism 3, the feeding mechanism 2 comprises a feeding lifting mechanism 21, a feeding back-and-forth moving mechanism 22, a material supporting strip 23 and a material supporting plate 24, the feeding back-and-forth moving mechanism 22 is arranged on the feeding lifting mechanism 21, the feeding lifting mechanism 21 is used for driving the feeding back-and-forth moving mechanism 22 to move up and down, more than two material supporting strips 23 are arranged, the material supporting strip 23 is arranged on the feeding back-and-forth moving mechanism 22, the feeding back-and-forth moving mechanism 22 is used for driving the material supporting strip 23 to move back and forth, the material supporting plate 24 is provided with a material strip gap 25, and the material supporting strip 23 is arranged in the material strip gap 25.

The feeding lifting mechanism 21 comprises a lifting installation base 211, a lifting installation bearing 212, a lifting driving shaft 213, a lifting driven shaft 214, a lifting chain wheel chain 215 and a lifting driving motor 216, wherein the lifting installation base 211 is arranged on the frame 1, the lifting installation bearing 212 is arranged on the top surface of the lifting installation base 211, the lifting driving shaft 213 and the lifting driven shaft 214 can be rotatably arranged on the lifting installation bearing 212, the lifting driving shaft 213 and the lifting driven shaft 214 are arranged in parallel, the same end of the lifting driving shaft 213 and the same end of the lifting driven shaft 214 are both provided with a chain wheel 217, the lifting chain wheel chain 215 is wound around the chain wheels 217 of the lifting driving shaft 213 and the lifting driven shaft 214 and is tensioned, the lifting driving motor 216 is connected with the end part of the lifting driving shaft 213 and is used for driving the lifting driving shaft 213 to rotate, the lifting driving shaft 213 and the lifting driven shaft 214 are both provided with a cam 218, and one end of the lifting driven shaft 214 is provided with a lifting induction mechanism 219, the lifting sensing mechanism 219 comprises a sensing disc 2191, a groove-type photoelectric sensor 2192, a first proximity switch 2193 and a second proximity switch 2194, the sensing disc 2191 is arranged at the end of the lifting driven shaft 214, the circle center of the sensing disc 2191 is located on the axis of the lifting driven shaft 214, the sensing disc rotates along with the rotation of the lifting driven shaft, a proximity touch rod 2195 is arranged on the outer side surface of the sensing disc 2191, a sensing groove 2196 is formed in the edge of the sensing disc 2191, the groove-type photoelectric sensor 2192 is located below the sensing disc 2191, the first proximity switch 2193 and the second proximity switch 2194 are fixed to one side of the sensing disc 2191 through a proximity switch fixing frame 2197, the proximity touch rod 2195 of the sensing disc 2191 can touch the first proximity switch 2193 and the second proximity switch 2194 in the rotating process, and the first proximity switch 2193 is located below the second proximity switch 2194.

The feeding front-back moving mechanism 22 comprises a moving fixing seat 221, a moving sliding block 222, a moving driving cylinder 223 and a supporting strip connecting plate 224, wherein the moving fixing seat 221 is arranged on the rack 1, a moving sliding seat 225 is arranged on the side face of the moving fixing seat 221, the moving sliding block 222 can be arranged on the moving sliding seat 225 in a vertically moving mode, the telescopic end of the moving driving cylinder 223 is connected with the moving sliding block 222, the other end of the moving driving cylinder 223 is connected with the supporting strip connecting plate 224, the supporting strip connecting plate 224 is connected with the supporting strip 23 through a supporting strip transverse plate 231, moving sliding rods 226 are arranged at two ends of the moving sliding block 222, and the moving sliding rods 226 are connected with the supporting strip connecting plate 224 in a sliding mode through linear bearings.

The bottom of the material supporting strip 23 is fixedly provided with a material strip sliding block 232, specifically, the material strip sliding block 232 is fixedly connected with a material supporting strip transverse plate 231, the bottom of the material strip sliding block 232 is slidably provided with a material strip sliding seat 233, the bottom of the material strip sliding seat 233 is provided with a cam fixture block sliding rail 234, and the cam fixture block sliding rail 234 is abutted to the cam 218.

The feeding mechanism 2 further comprises a return mechanism 26, the return mechanism 26 is used for pushing the cam fixture block slide rail 234 to return, the return mechanism 26 comprises a return cylinder 261 and a return connecting plate 262, the telescopic end of the return cylinder 261 is fixedly connected with the return connecting plate 262, the other end of the return cylinder 261 is fixedly connected with the support strip transverse plate 231, and the return connecting plate 262 is connected with the cam fixture block slide rail 234.

The position of the tail end of each material supporting plate 24, which is aligned with the workpiece, is correspondingly provided with a first material sensor 27, and the first material sensor 27 is used for sensing whether the workpiece exists at the tail end of the material supporting plate 24.

When the feeding mechanism is used, the feeding mechanism is in an original position, a workpiece is manually placed on the material supporting plate, the lifting driving motor rotates to drive the cam to rotate, so that the material supporting strip is lifted, when the approaching contact rod touches the first proximity switch (at the moment, the workpiece is lifted by the material supporting strip and is supported away from the material supporting plate), the driving cylinder is moved to push out, the material supporting strip is driven to push the workpiece forwards to the position above the workpiece jacking mechanism, the material supporting strip descends after the lifting driving motor rotates for a certain time, when the approaching contact rod touches the second proximity switch (at the moment, the workpiece is in contact with the material supporting plate and is supported away from the material supporting strip), the material supporting strip is independently returned to the original position when the driving cylinder is moved to contract, when the induction groove is rotated to the groove-type photoelectric sensor, the cam returns to the original position, at the moment, the cam clamping block sliding rail moves forwards without returning, the return cylinder works to drive the cam clamping block to move to return, so that one-time displacement feeding is completed, when any first material sensor does not sense the workpiece, the feeding mechanism repeats the feeding action until all first material sensors sense signals, so that feeding of all stations is completed. Through setting up structures such as material strip slide and cam fixture block slide rail, material strip slide and cam fixture block slide rail are in free moving state, make this mechanism reduce the contact friction of cam and cam fixture block slide rail at the in-process that rises feeding forward simultaneously to improve the durability.

The workpiece jacking mechanism 3 is used for jacking a workpiece to the position of the pushing identification mechanism 4, the workpiece jacking mechanism 3 comprises a jacking fixing plate 31, a jacking cylinder 32 and a jacking structure 33, the jacking fixing plate 31 is arranged on the rack 1, the jacking cylinder 32 is fixedly arranged on the bottom surface of the jacking fixing plate 31, the telescopic end of the jacking cylinder 32 is connected with the jacking structure 33 and used for driving the jacking structure 33 to move up and down, jacking guide posts 34 are arranged on two sides of the jacking fixing plate 31, one end of each jacking guide post 34 is slidably connected with the jacking fixing plate 31 through a linear bearing, the other end of each jacking guide post 34 is fixedly connected with the jacking structure 33, each jacking structure 33 comprises a jacking plate 331, a jacking rod 332 and jacking blocks 333, each jacking rod 332 is arranged on the top surface of each jacking plate 331, the number of the jacking rods 332 is matched with the number of the material supporting strips 23, and each jacking block 333 is arranged at the tail end of each jacking rod 332; when the workpiece jacking mechanism is used, signals are sensed by all the first material sensors, the jacking cylinder works to drive the jacking structure to ascend, and the jacking block pushes a workpiece to the pushing-out recognition mechanism.

The push-out recognition mechanism 4 is used for pushing the workpiece to the positioning and fixing mechanism 5 and recognizing whether the workpiece is a thin workpiece or a thick workpiece, the push-out recognition mechanism 4 comprises a push-out fixing plate 41, a push-out cylinder 42, a push-out mounting plate 43, a push-out spring pin 44, a recognition cylinder 45, a recognition mounting plate 46, a micro switch 47, a workpiece direction recognition sensor 48 and a second material sensor 49, the push-out fixing plate 41 is fixedly arranged on the top surface of the material supporting plate 24, the push-out cylinder 42 is fixedly arranged on the top surface of the push-out fixing plate 41, the telescopic end of the push-out cylinder 42 is fixedly connected with the push-out mounting plate 43 and used for driving the push-out mounting plate 43 to move forwards and backwards, the push-out mounting plate 43 is slidably connected with the push-out fixing plate 41, specifically, a push-out sliding block 431 is arranged at the bottom of the push-out mounting plate 43, a push-out sliding rail 411 is arranged at a position, corresponding to the top surface of the push-out fixing plate 41, and a push-out spring pin 44 is arranged at the front end of the push-out mounting plate 43, the recognition cylinder 45 is fixedly arranged on the top surface of the push-out mounting plate 43, the telescopic end of the recognition cylinder 45 is fixedly connected with the recognition mounting plate 46 and used for driving the recognition mounting plate 46 to move back and forth, the microswitch 47, the workpiece direction recognition sensor 48 and the second material sensor 49 are all arranged on the recognition mounting plate 46, when the recognition cylinder 45 is pushed out, the microswitch 47 is located in front of a workpiece, and the workpiece direction recognition sensor 48 and the second material sensor 49 are located above the workpiece.

The positioning and fixing mechanism 5 is used for positioning workpieces, the positioning and fixing mechanism 5 comprises a positioning and fixing plate 51, a jacking guide block 52, a pushing guide block 53, a pushing in-place stop block 54, an adjusting and positioning screw 55 and a material correlation sensor 56, the positioning and fixing plate 51 is arranged on the frame 1, the jacking guide block 52 is arranged on the side surface facing the workpiece jacking mechanism 3, two jacking guide blocks 52 are in a group to guide when jacking one workpiece, the pushing out guide block 53 is arranged on the top surface of the positioning and fixing plate 51, the shape of the pushing out guide block 53 is matched with that of the bottom of the workpiece, the pushing in-place stop block 54 is arranged on the positioning and fixing plate 51 and is positioned at the tail end of the pushing out guide block 53, the adjusting and positioning screw 55 is arranged on the positioning and fixing plate 51 and is opposite to the identification mounting plate 46, the material correlation sensor 56 is arranged on the top surface of the positioning and fixing plate 51 and is positioned at two ends of the positioning and fixing plate 51, the first material sensor 27 is disposed on a side surface of the positioning fixing plate 51.

When the push-out recognition mechanism and the positioning and fixing mechanism are used, after the workpiece is pushed out by the workpiece positioning mechanism, the push-out cylinder works to drive the push-out spring pin to push the workpiece forward, the workpiece is pushed to the push-out in-place stop block along the push-out guide block, the material-containing opposite-jet sensor senses a material-containing signal at the moment, the jacking cylinder descends and resets, the recognition cylinder is pushed to the position where the recognition mounting plate abuts against the adjusting and positioning screw, if the micro switch contacts with the workpiece, the thick workpiece is recognized, if the micro switch does not contact with the workpiece, the thin workpiece is recognized, the workpiece direction recognition sensor recognizes whether the workpiece to be machined is correctly placed, the second material-containing sensor is used for recognizing whether the workpiece is located at the position, and finally, the signal is transmitted to the PLC system for machining of subsequent workpieces.

According to the automatic feeding device, the feeding mechanism, the workpiece jacking mechanism, the pushing-out recognition mechanism and the positioning and fixing mechanism are arranged, so that automatic feeding of workpieces with different thicknesses can be realized, and the purposes of reducing the number of types to be changed, improving the production efficiency and reducing the working strength of operators are achieved.

The foregoing is a more detailed description of the utility model in connection with specific preferred embodiments and it is not intended that the utility model be limited to these specific details. For those skilled in the art to which the utility model pertains, several simple deductions or substitutions can be made without departing from the spirit of the utility model, and all shall be considered as belonging to the scope of the utility model.

Claims (10)

1. An automatic interval material loading machine which characterized in that: the automatic feeding device comprises a rack, a feeding mechanism, a workpiece jacking mechanism, a pushing identification mechanism and a positioning and fixing mechanism, wherein the workpiece jacking mechanism is positioned below the tail end of the feeding mechanism, the pushing identification mechanism is positioned above the feeding mechanism, and the positioning and fixing mechanism and the pushing identification mechanism are arranged oppositely;

the feeding mechanism is used for conveying the workpiece to the upper part of the workpiece jacking mechanism; the workpiece jacking mechanism is used for jacking the workpiece to the pushing identification mechanism; the pushing identification mechanism is used for pushing the workpiece to the positioning fixing mechanism and identifying whether the workpiece is a thin workpiece or a thick workpiece; the positioning and fixing mechanism is used for positioning the workpiece.

2. The automated space feeder of claim 1, wherein: the feeding mechanism comprises a feeding lifting mechanism, a feeding front-and-back moving mechanism, a material supporting strip and a material supporting plate, the feeding front-and-back moving mechanism is arranged on the feeding lifting mechanism and is used for driving the feeding front-and-back moving mechanism to move up and down, the material supporting strip is arranged on the feeding front-and-back moving mechanism and is used for driving the material supporting strip to move back and forth, a material strip gap is formed in the material supporting plate, and the material supporting strip is arranged in the material strip gap.

3. The automated space feeder of claim 2, wherein: feeding elevating system includes lift installation base, lift installation bearing, lift driving shaft, lift driven shaft, lift sprocket chain, lift driving motor, and the lift mount pad sets up in the frame, lift installation bearing sets up on lift mount pad top surface, lift driving shaft and lift driven shaft all can rotate and set up in lift installation bearing, lift driving shaft and the mutual parallel arrangement of lift driven shaft, the same end of lift driving shaft and lift driven shaft all is provided with the sprocket, lift sprocket chain is around the sprocket and the tensioning of locating lift driving shaft and lift driven shaft, lift driving motor is used for driving the lift driving shaft with lift driving shaft end connection and rotates, all be provided with the cam on lift driving shaft and the lift driven shaft.

4. The automated space feeder of claim 3, wherein: lift driven shaft one end is provided with lift response mechanism, lift response mechanism is including response disc, cell type photoelectric sensor, first proximity switch, second proximity switch, the response disc sets up in the tip of lift driven shaft, the centre of a circle of response disc is located the axis of lift driven shaft, response disc lateral surface is provided with the proximity feeler lever, response disc edge is provided with the response recess, cell type photoelectric sensor is located response disc below, first proximity switch and second proximity switch are fixed in response disc one side through the proximity switch mount, the proximity feeler lever of response disc can touch first proximity switch and second proximity switch at the pivoted in-process, first proximity switch is located the second proximity switch below.

5. The automated space feeder of claim 3, wherein: the feeding front-and-back moving mechanism comprises a moving fixing seat, a moving sliding block, a moving driving cylinder and a supporting strip connecting plate, wherein the moving fixing seat is arranged on the rack, a moving sliding seat is arranged on the side face of the moving fixing seat, the moving sliding block can be arranged on the moving sliding seat in a vertically moving mode, the telescopic end of the moving driving cylinder is connected with the moving sliding block, the other end of the moving driving cylinder is connected with the supporting strip connecting plate, and the supporting strip connecting plate is connected with the supporting strip.

6. The automated space feeder of claim 3, wherein: the material supporting device is characterized in that a material strip sliding block is arranged at the bottom of the material supporting strip, a material strip sliding seat is slidably arranged at the bottom of the material strip sliding seat, a cam fixture block sliding rail is arranged at the bottom of the material strip sliding seat and is abutted to a cam, the feeding mechanism further comprises a return mechanism, the return mechanism is used for pushing the cam fixture block sliding rail to return, the return mechanism comprises a return cylinder and a return connecting plate, the telescopic end of the return cylinder is fixedly connected with the return connecting plate, the other end of the return cylinder is fixedly connected with a supporting strip transverse plate, and the return connecting plate is connected with the cam fixture block sliding rail.

7. The automated space feeder of claim 1, wherein: the work piece climbing mechanism includes jacking fixed plate, jacking cylinder and jacking structure, the jacking fixed plate sets up in the frame, the jacking cylinder is fixed to be set up in jacking fixed plate bottom surface, the flexible end and the jacking structural connection of jacking cylinder are used for driving jacking structure up-and-down motion, the jacking structure includes jacking board, jacking pole and jacking piece, the jacking pole sets up in the top surface of jacking board, the quantity of jacking pole and the quantity phase-match of holding in the palm the material strip, the jacking piece sets up in the end of jacking pole.

8. The automated space feeder of claim 1, wherein: the ejecting identification mechanism is including ejecting fixed plate, ejecting cylinder, ejecting mounting panel, ejecting spring catch, discernment cylinder, discernment mounting panel, micro-gap switch, ejecting fixed plate is fixed to be set up in holding in the palm the flitch top surface, ejecting cylinder sets up in ejecting fixed plate top surface, ejecting cylinder's flexible end is used for driving ejecting mounting panel seesaw with ejecting mounting panel fixed connection, ejecting mounting panel and ejecting fixed plate sliding connection, ejecting spring catch sets up in the front end of ejecting mounting panel, the discernment cylinder sets up in the top surface of ejecting mounting panel, the flexible end and the discernment mounting panel fixed connection of discernment cylinder are used for driving discernment mounting panel seesaw, micro-gap switch sets up on the discernment mounting panel.

9. The automated space feeder of claim 8, wherein: the push-out recognition mechanism further comprises a workpiece direction recognition sensor and a second material sensor, and the workpiece direction recognition sensor and the second material sensor are both arranged on the recognition mounting plate.

10. The automated space feeder of claim 1, wherein: the utility model discloses a positioning fixing mechanism, including location fixed plate, jacking guide block, release dog, adjusting position screw and have the material correlation sensor that targets in place, the location fixed plate sets up in the frame, the jacking guide block sets up on the side towards work piece climbing mechanism, the release guide block sets up in location fixed plate top surface, the release dog that targets in place sets up on the location fixed plate and is located the end of releasing the guide block, and adjusting position screw sets up on the location fixed plate and sets up relatively with the discernment mounting panel, have the material correlation sensor to set up in location fixed plate top surface and be located location fixed plate both ends.

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