CN203419581U - Three-section automatic feeding device - Google Patents

Abstract

The utility model discloses a three-section automatic feeding device. Upper section plates, locating section plates and lower section plates are sequentially arranged from front to back in the length directions of installation plates, the upper section plates, the locating section plates and the lower section plates are used for conveying materials, and an upper section material conveying mechanism, a locating section material conveying mechanism and a lower section material conveying mechanism are sequentially arranged on each conveying section to be used for conveying materials. The materials are firstly conveyed between the upper section plates from the outside to be standby and then conveyed between the locating section plates to be processed. After being processing, the materials are conveyed between the lower section plates to the conveyed out and collected. Thus, the conveying time for the materials is short, transition between two adjacent conveying sections is achieved to avoid material stack phenomena, and continuous and effective production is guaranteed. The automatic feeding device is simple in structure, convenient to use, automatic in feeding process, capable of greatly reducing time for conveying the materials in feeding and capable of remarkably improving product producing efficiency.

Description

A kind of syllogic automatic feeder

Technical field

the utility model relates to a kind of syllogic automatic feeder.

Background technology

in the high volume production process of electronic product, need to adopt feedway to transmit pcb board, thereby realize Automatic-feeding and can after production completes, product be carried, to reach to enhance productivity, reduce the object of producers' labour intensity.Yet in prior art, feed normally adopts to carry and brings realization, under this feed mode the feed time longer, between two pcb boards, without transition, easily form the phenomenon of windrow, seriously affect the production efficiency of product.

Summary of the invention

the purpose of this utility model is to provide a kind of syllogic automatic feeder, thereby reduces the time that in process of producing product, material transmits, and improves the production efficiency of product.

for achieving the above object, the technical solution adopted in the utility model is: a kind of syllogic automatic feeder, described feeding device comprises two adapter plates that are arranged in parallel, described adapter plate comprises epimere plate, positioning section plate and hypomere plate successively along length bearing of trend, described feeding device also comprises the epimere feeding unit that is arranged on described epimere plate, be arranged on positioning section feeding unit on described positioning section plate, be arranged on the hypomere feeding unit on described hypomere plate

described epimere feeding unit comprises a plurality of two top tumblers in described epimere plate opposite side portion that are arranged on rotationally, on described top tumbler, be arranged with to tensioning epimere load-transfer device, on described epimere plate, be also provided with the epimere driver train for driving a plurality of described top tumblers to rotate around Pivot Point Center line, the front end of described epimere plate is provided with epimere and stops cylinder, the rear and front end of described epimere plate is respectively equipped with the first sensor for detection of described material position on described epimere load-transfer device, the second sensor, described first sensor is positioned at the rear that described epimere stops cylinder, described first sensor, described the second sensor is connected setting with described epimere driver train signal respectively,

described positioning section feeding unit comprises a plurality of two positioning section guide wheels on the relative both sides of described positioning section plate that are arranged on rotationally, on described positioning section guide wheel, be arranged with to tensioning positioning section load-transfer device, on described positioning section plate, be also provided with the positioning section driver train for driving a plurality of described positioning section guide wheels to rotate around Pivot Point Center line, the front end of described positioning section plate is provided with positioning section and stops cylinder, the front end of described positioning section plate, the rear end of described positioning section plate is respectively equipped with the 3rd sensor for detection of described material position on described positioning section load-transfer device, four-sensor, described the 3rd sensor is positioned at the rear that described positioning section stops cylinder, described the 3rd sensor, four-sensor is connected setting with described positioning section driver train signal respectively,

described hypomere feeding unit comprises a plurality of two lower tumblers in described hypomere plate opposite side portion that are arranged on rotationally, on described lower tumbler, be arranged with to tensioning hypomere load-transfer device, on described hypomere plate, be also provided with the hypomere driver train for driving a plurality of described lower tumblers to rotate around Pivot Point Center line, the front end of described hypomere plate is provided with hypomere and stops cylinder, the rear and front end of described hypomere plate is respectively equipped with the 5th sensor for detection of described material position on described hypomere load-transfer device, the 6th sensor, described the 5th sensor is positioned at the rear that described hypomere stops cylinder, described the 5th sensor, described the 6th sensor is connected setting with described hypomere driver train signal respectively, the rear end that is positioned at described the 6th sensor on described hypomere plate is also provided with discharging and stops cylinder,

described epimere load-transfer device, described positioning section load-transfer device, described hypomere load-transfer device are arranged after by forward direction successively along the length direction of described adapter plate, and the mass transport face of described epimere load-transfer device, described positioning section load-transfer device, described hypomere load-transfer device is in the same plane, described epimere stops that axial line that cylinder, described positioning section stop that cylinder, described hypomere stop that cylinder, described discharging stop the Telescopic-cylinder bar on cylinder is perpendicular to described mass transport face, and described Telescopic-cylinder bar while stretching out along the thickness direction of described material higher than described mass transport face.

preferably, described in each, the upper end of positioning section plate is fixedly provided with respectively pressing plate, described material on described positioning section feeding unit between described pressing plate and described positioning section load-transfer device.

preferably, on two blocks of described positioning section plates, wherein described positioning section plate is provided with for described material is pressed on to the compression cylinder on positioning section plate described in another piece along its Width, and the axial line of the expansion link of described compression cylinder extends along the Width of described material.

preferably, in two described adapter plates, wherein a described adapter plate is adapter plate, and adapter plate is for adjusting plate described in another piece, and described adjustment plate arranges by the relatively described adapter plate adjustable interval of width adjusting mechanism ground.

preferably, described width adjusting mechanism comprises that the fixed mount, the two ends that are fixedly connected with described adapter plate are arranged on rotationally respectively ball-screw on described adapter plate and described fixed mount, are fixedly installed on described adjustment plate and the feed screw nut matching with described ball-screw, and described width adjusting mechanism also comprises and being arranged on described fixed mount for driving the width adjustment driver train of described ball-screw rotation.

further preferably, described width adjustment driver train is for comprising motor, and the output shaft of described motor is in transmission connection by transmission device mutually with described ball-screw.

preferably, described epimere feeding unit also comprises the 7th sensor being installed on described epimere plate for detection of described material position on described epimere load-transfer device, described the 7th sensor is along the length direction of described epimere plate between described first sensor and described the second sensor, and described the 7th sensor is connected setting with described epimere driver train signal.

preferably, described positioning section feeding unit also comprises the 8th sensor, the 9th sensor being installed on described positioning section plate for detection of described material position on described positioning section load-transfer device, described the 8th sensor, described the 9th sensor are along the length direction of described positioning section plate between described the 3rd sensor and described four-sensor, and described the 8th sensor, described the 9th sensor are connected setting with described positioning section driver train signal.

preferably, described hypomere feeding unit also comprises and being installed on described hypomere plate for detection of the tenth sensor of described material position on described hypomere load-transfer device, and described the tenth sensor is between described the 5th sensor and described the 6th sensor.

utilization due to technique scheme, the utility model compared with prior art has following advantages: a kind of syllogic automatic feeder of the present utility model, wherein by the length bearing of trend along adapter plate, set gradually the epimere plate that material transmits after by forward direction, positioning section plate and hypomere plate, and in each delivery section, epimere feeding unit is set successively, positioning section feeding unit, hypomere feeding unit transmits material, first material imports between epimere plate stand-by by outside, be resent between positioning section plate and process, after completion of processing, be resent between hypomere plate and finally send out and collect, the delivery time of material is shorter, between two adjacent delivery sections, there is transition, be not easy to form folded material phenomenon, the continuous and effective of the production guaranteeing is carried out.This automatic feeder is simple in structure, easy to use, and feeder process automation has reduced the time that in feed, material transmits greatly, can improve significantly the production efficiency of product.

Accompanying drawing explanation

the integral structure schematic diagram one that accompanying drawing 1 is automatic feeder of the present utility model;

the integral structure schematic diagram two that accompanying drawing 2 is automatic feeder of the present utility model.

The specific embodiment

below in conjunction with accompanying drawing and specific embodiment, the technical solution of the utility model is further elaborated.

referring to the syllogic automatic feeder shown in Fig. 1～2, this feeding device comprises the adapter plate being arranged in parallel, in two adapter plates, wherein an adapter plate is that adapter plate 1, another piece adapter plate are portable plate 2, and the spacing between adapter plate 1 and portable plate 2 is adjusted by width adjusting mechanism 7.Two adapter plates comprise epimere plate 11 and 21, positioning section plate 12 and 22, hypomere plate 13 and 23 successively along its length bearing of trend, and this feeding device also comprises the epimere feeding unit 3 that is arranged on epimere plate 11,21, be arranged on positioning section feeding unit 4 on positioning section plate 12,22, be arranged on the hypomere feeding unit 5 on hypomere plate 13,23.

epimere feeding unit 3 comprises a plurality of two blocks of epimere plates 11 that are arranged on rotationally, top tumbler 31 in 21 opposite side portions, on these a plurality of top tumblers 31, be arranged with to tensioning epimere load-transfer device 32, epimere plate 11, on 21, be also provided with the epimere driver train for driving above-mentioned a plurality of top tumbler 31 to rotate around Pivot Point Center line, epimere driver train comprises epimere drive motor 37, one tape handler is set on the output shaft of epimere drive motor 37, and make all to have on epimere plate 11 and epimere plate 21 rotating shaft of a top tumbler 31 and tape handler driven shaft coaxially to arrange, thereby drive top tumbler 31 rotate and make epimere load-transfer device 32 on top tumbler 31, be moved to transmit material 8 around Pivot Point Center line.Epimere plate 11 and 21 front end are provided with epimere and stop cylinder 33, epimere stops that the axial line of expansion link of cylinder 33 is perpendicular to the mass transport face of epimere load-transfer device 32, when epimere stops that the expansion link of cylinder 33 stretches out, material 8 can not be sent to epimere load-transfer device 32 from the front end of epimere plate 11,21.Epimere plate 11 and 21 front end are provided with first sensor 34, its rear end is provided with the second sensor 36, first sensor 34 is connected setting with epimere drive motor 37 signals respectively with the second sensor 36, two sensors is the position on epimere load-transfer device 32 for detection of material 8 all, and respectively the signal feedback of detection to epimere drive motor 37 is made it start respectively to rotate, stop operating, thereby control respectively starting transmission and stopping transmitting of epimere load-transfer device 32.

positioning section feeding unit 4 comprises a plurality of two blocks of positioning section plates 12 that are arranged on rotationally, positioning section guide wheel 41 in 22 opposite side portions, on positioning section guide wheel 41, be arranged with to tensioning positioning section load-transfer device 42, positioning section plate 12, on 22, be also provided with the positioning section driver train for driving above-mentioned a plurality of positioning section guide wheel 41 to rotate around Pivot Point Center line, this positioning section driver train comprises positioning section drive motor 48 and tape handler, thereby by tape handler, the propulsive effort of positioning section drive motor 48 is passed to the conveying that drives 42 pairs of materials 8 of positioning section load-transfer device on positioning section guide wheel 41.The front end of positioning section plate 12,22 is provided with positioning section and stops cylinder 43, positioning section stops that the expansion link axial line of cylinder 43 is perpendicular to the mass transport face of positioning section load-transfer device 42, and this expansion link can stop that material 8 is sent to positioning section load-transfer device 42 to avoid the generation of windrow phenomenon by epimere load-transfer device 32 while extending.Front end, the rear end of positioning section plate 12,22 is respectively equipped with the 3rd sensor 44 and the four-sensor 47 for detection of material 8 position on positioning section load-transfer device 42, the 3rd sensor 44 is positioned at the rear that positioning section stops cylinder 43, the 3rd sensor 44, four-sensor 47 are connected setting with positioning section drive motor 48 signals, monitoring point on material 8 arrives respectively the 3rd sensor 44, four-sensor 47, and two sensors makes signal feedback to positioning section drive motor 48 respectively it start respectively to rotate, stop operating.

hypomere feeding unit 5 comprises a plurality of lower tumblers 51 that are arranged on rotationally in two blocks of hypomere plates, 13,23 opposite side portions, on lower tumbler 51, be arranged with to tensioning hypomere load-transfer device 52, on hypomere plate 13,23, be also provided with the hypomere driver train for driving above-mentioned a plurality of lower tumbler 51 to rotate around Pivot Point Center line, hypomere driver train comprises hypomere drive motor 58 and tape handler, by tape handler, transmit the propulsive effort of hypomere drive motor 58, thereby driving lower tumbler 51 rotates and make hypomere load-transfer device 52 move to transmit material 8.The front end of hypomere plate 13,23 is provided with hypomere and stops cylinder 53, its rear end is provided with discharging and stops cylinder 57, hypomere stops that expansion link axial line that cylinder 53, discharging stop cylinder 57, all perpendicular to the mass transport face of hypomere load-transfer device 52, is respectively used to stop that material 8 enters on hypomere load-transfer device 52, stops that material 8 is admitted in subsequent processing.Hypomere plate 13, 23 rear and front end is respectively equipped with the 5th sensor 54 for detection of material 8 position on hypomere load-transfer device 52, the 6th sensor 56, the 5th sensor 54 is positioned at the rear that hypomere stops cylinder 53, the 6th sensor 56 is positioned at the place ahead that discharging stops cylinder 57, the 5th sensor 54, the 6th sensor 56 is connected setting with hypomere drive motor 58 signals respectively, monitoring point on material 8 arrives respectively the 5th sensor 54, during the position of the 6th sensor 56, the 5th sensor 54, the 6th sensor 56 makes signal feedback to hypomere drive motor 58 respectively it start respectively rotate and stop operating.

in this feeding device, epimere load-transfer device 32, positioning section load-transfer device 42, hypomere load-transfer device 52 are arranged after by forward direction successively along adapter plate 1 and the length direction of adjusting plate 2, and the mass transport face of epimere load-transfer device 32, positioning section load-transfer device 42, hypomere load-transfer device 52 is in the same plane.This feeding device is before transmitting material 8, material 8 is positioned at epimere plate 11, 21 front end also stops that by epimere cylinder 33 stops, when needs transmit material 8, epimere stops that the expansion link of cylinder 33 shortens, material 8 is entered on epimere load-transfer device 32 by front end, first sensor 32 detects material 8, just sending signal to epimere drive motor 37 makes it start 31 rotations of rotating drive top tumbler, epimere load-transfer device 32 just moves along its length bearing of trend the transmission realizing material 8, when the second sensor 36 detects material 8 and while not needing material 8 to be delivered to positioning section, 37 stalls of epimere drive motor, material 8 is placed on epimere load-transfer device 32 stand-by, positioning section stops that 43 pairs of materials 8 of cylinder stop simultaneously, prevent that material 8 is transferred on positioning section load-transfer device 42 and form the impact of windrow phenomenon and produce.When needs transmit material 8 to positioning section, positioning section stops that cylinder 33 releasings stop, material 8 is admitted on positioning section load-transfer device 42 by epimere load-transfer device 32, next material 8 to be transmitted starts to enter on epimere load-transfer device 32 simultaneously, when the 3rd sensor 44 detects material 8, positioning section drive motor 48 rotating drive positioning section load-transfer devices 42 move along material direction of transfer, when four-sensor 47 detects material 8, 48 stalls of positioning section drive motor, hypomere stops that cylinder 53 forms stopping material 8 simultaneously, material 8 is accepted processing and is processed on positioning section load-transfer device 42.While needing to transmit to hypomere after processing is disposed, hypomere stops that cylinder 53 removes the stopping of material 8, material 8 is transmitted to hypomere load-transfer device 52 by positioning section load-transfer device 42, and next material 8 to be transmitted starts to be conveyed on positioning section load-transfer device 42 simultaneously.When the 5th sensor 54 detects material 8, hypomere drive motor 58 starts rotating drive hypomere load-transfer device 52 and moves along material direction of transfer, when the 6th sensor 56 detects material 8, hypomere load-transfer device 52 stops mobile, discharging stops that cylinder 57 keeps stopping material 8, when needs carry out discharging, discharging stops that cylinder 57 removes the stopping of material 8 again, by hypomere load-transfer device 52, material 8 is transferred out and carries out discharging collection.

referring to Fig. 1, shown in Fig. 2, in the present embodiment, the positioning section plate 12 of both sides, 22 upper ends are respectively equipped with pressing plate 14, 24, material 8 is positioned at pressing plate 14 on positioning section feeding unit 4, 24 and positioning section load-transfer device 42 between, thereby formation is spacing to material 8, on the positioning section plate 22 of adjusting plate 2, be also provided with a compression cylinder 6, the axial line of the expansion link of this compression cylinder 6 extends along the Width of material 8, this expansion link can be pressed on material 8 on the positioning section plate 12 of adapter plate 1 along the Width of material 8 when extending, while arranging, can be using positioning section plate 12 medial surfaces as reference plane, thereby for the location of material 8 provides benchmark, guarantee the accuracy of material 8 Working positions.

referring to Fig. 1, shown in Fig. 2, in the present embodiment, width adjusting mechanism 7 comprises the fixed mount 71 being fixedly connected with adapter plate 1, two ends are arranged on respectively the ball-screw 72 on adapter plate 1 and fixed mount 71 rotationally, adjust on plate 2 and be fixedly provided with the feed screw nut 73 for matching with ball-screw 72, ball-screw 72 is located in the tapped bore of feed screw nut 73 ordinatedly, on fixed mount 71, be also provided with for driving the width adjustment driver train of ball-screw 72 rotations, this width driver train comprises motor 74 and tape handler 75, by tape handler 75, the propulsive effort of motor 74 is passed on ball-screw 72, when ball-screw 72 rotation, feed screw nut 73 is moved along the length direction of ball-screw 72, like this, adjustment plate 2 just relative adapter plate 1 is moved, thereby realized the adjusting of width between adapter plate 1 and adjustment plate 2.In the time need to positioning the material 8 between positioning section plate 12,22, also can realize by width adjusting mechanism 7, by motor 74, drive adjustment plate 2 to move relative to adapter plate 1, thereby the Width along material 8 is pressed between two positioning section plates 12,22, realize the clamping and positioning to material 8.Such locate mode has more commonality, is applicable to the clamping and positioning of the material 8 of different size, and the problems such as location inconvenience of simultaneously also having avoided adopting traditional thimble-type locate mode to cause because of the interference of components and parts are more convenient to the location of material 8.

shown in Fig. 1, Fig. 2, in the present embodiment, in order to make material 8 can carry out pulsation-free transmission on each section of load-transfer device, prevent the jiggly problem of transmission causing because of the unexpected deceleration of load-transfer device, in epimere feeding unit 3, on epimere plate 11,21, be also provided with the 7th sensor 35, the seven sensors 35 along on the length direction of epimere plate 11,21 between first sensor 34 and the second sensor 36, the 7th sensor 35 is connected setting with epimere drive motor 37 signals.When material 8 is transferred into the position of the 7th sensor 35, the 7th sensor 35 sends feedback signal epimere drive motor 37 is slowed down, epimere load-transfer device 32 is slowed down to be transmitted, make material 8 stop there is the process of a buffering between transmission by being sent to, thereby while making 37 stall of epimere drive motor, material 8 can be parked on epimere load-transfer device by pulsation-free.In positioning section feeding unit 4, on positioning section plate 12,22, be fixedly provided with the 8th sensor 45 and the 9th sensor 46 for detection of material 8 position on positioning section load-transfer device 42, the 8th sensor 45 and the 9th sensor 46 are along positioning section plate 12,22 length directions between the 3rd sensor 44 and four-sensor 47, and the 8th sensor 45 is connected setting with positioning section drive motor signal respectively with the 9th sensor 46.When material 8 arrives the position of the 8th sensor 45, positioning section load-transfer device accelerates for 42 2 times, when material 8 arrives the position of the 9th sensor 46, positioning section load-transfer device 42 slows down, material 8 not only can be transmitted rapidly, and can slow down, to guarantee the stationarity of material 8 transport process. in good timeIn line segment feeding unit 5, on hypomere plate 13,23, be also provided with the tenth sensor 55, the ten sensors 55 and slow down when material 8 runs to this place between the 5th sensor 54 and the 6th sensor 56.

in sum, a kind of syllogic automatic feeder of the present utility model, wherein by the length bearing of trend along adapter plate, set gradually the epimere plate that material transmits after by forward direction, positioning section plate and hypomere plate, and in each delivery section, epimere feeding unit 3 is set successively, positioning section feeding unit 4, hypomere feeding unit 5 transmits material 8, first material 8 imports epimere plate 11 into by outside, stand-by between 21, be resent to positioning section plate 12, between 22, process, after completion of processing, be resent to hypomere plate 13, between 23, also finally send out and collect, the delivery time of material 8 is shorter, between two adjacent delivery sections, there is transition, be not easy to form folded material phenomenon, the continuous and effective of the production guaranteeing is carried out.This automatic feeder is simple in structure, easy to use, and feeder process automation has reduced time of feed greatly, can improve significantly the production efficiency of product.

above-described embodiment is only explanation technical conceive of the present utility model and feature, and its object is to allow person skilled in the art can understand content of the present utility model and implement according to this, can not limit protection domain of the present utility model with this.All equivalences of doing according to the utility model Spirit Essence change or modify, within all should being encompassed in protection domain of the present utility model.

Claims (9)

1. a syllogic automatic feeder, it is characterized in that: described feeding device comprises two adapter plates that are arranged in parallel, described adapter plate comprises epimere plate, positioning section plate and hypomere plate successively along length bearing of trend, described feeding device also comprises the epimere feeding unit that is arranged on described epimere plate, be arranged on positioning section feeding unit on described positioning section plate, be arranged on the hypomere feeding unit on described hypomere plate

Described epimere feeding unit comprises a plurality of two top tumblers in described epimere plate opposite side portion that are arranged on rotationally, on described top tumbler, be arranged with to tensioning epimere load-transfer device, on described epimere plate, be also provided with the epimere driver train for driving a plurality of described top tumblers to rotate around Pivot Point Center line, the front end of described epimere plate is provided with epimere and stops cylinder, the rear and front end of described epimere plate is respectively equipped with the first sensor for detection of described material position on described epimere load-transfer device, the second sensor, described first sensor is positioned at the rear that described epimere stops cylinder, described first sensor, described the second sensor is connected setting with described epimere driver train signal respectively,

Described positioning section feeding unit comprises a plurality of two positioning section guide wheels on the relative both sides of described positioning section plate that are arranged on rotationally, on described positioning section guide wheel, be arranged with to tensioning positioning section load-transfer device, on described positioning section plate, be also provided with the positioning section driver train for driving a plurality of described positioning section guide wheels to rotate around Pivot Point Center line, the front end of described positioning section plate is provided with positioning section and stops cylinder, the front end of described positioning section plate, the rear end of described positioning section plate is respectively equipped with the 3rd sensor for detection of described material position on described positioning section load-transfer device, four-sensor, described the 3rd sensor is positioned at the rear that described positioning section stops cylinder, described the 3rd sensor, four-sensor is connected setting with described positioning section driver train signal respectively,

Described hypomere feeding unit comprises a plurality of two lower tumblers in described hypomere plate opposite side portion that are arranged on rotationally, on described lower tumbler, be arranged with to tensioning hypomere load-transfer device, on described hypomere plate, be also provided with the hypomere driver train for driving a plurality of described lower tumblers to rotate around Pivot Point Center line, the front end of described hypomere plate is provided with hypomere and stops cylinder, the rear and front end of described hypomere plate is respectively equipped with the 5th sensor for detection of described material position on described hypomere load-transfer device, the 6th sensor, described the 5th sensor is positioned at the rear that described hypomere stops cylinder, described the 5th sensor, described the 6th sensor is connected setting with described hypomere driver train signal respectively, the rear end that is positioned at described the 6th sensor on described hypomere plate is also provided with discharging and stops cylinder,

Described epimere load-transfer device, described positioning section load-transfer device, described hypomere load-transfer device are arranged after by forward direction successively along the length direction of described adapter plate, and the mass transport face of described epimere load-transfer device, described positioning section load-transfer device, described hypomere load-transfer device is in the same plane, described epimere stops that axial line that cylinder, described positioning section stop that cylinder, described hypomere stop that cylinder, described discharging stop the Telescopic-cylinder bar on cylinder is perpendicular to described mass transport face, and described Telescopic-cylinder bar while stretching out along the thickness direction of described material higher than described mass transport face.

2. a kind of syllogic automatic feeder according to claim 1, it is characterized in that: described in each, the upper end of positioning section plate is fixedly provided with respectively pressing plate, described material on described positioning section feeding unit between described pressing plate and described positioning section load-transfer device.

3. a kind of syllogic automatic feeder according to claim 1, it is characterized in that: on two blocks of described positioning section plates, wherein described positioning section plate is provided with for described material is pressed on to the compression cylinder on positioning section plate described in another piece along its Width, and the axial line of the expansion link of described compression cylinder extends along the Width of described material.

4. a kind of syllogic automatic feeder according to claim 1, it is characterized in that: in two described adapter plates, wherein a described adapter plate is adapter plate, described in another piece, adapter plate is for adjusting plate, and described adjustment plate arranges by the relatively described adapter plate adjustable interval of width adjusting mechanism ground.

5. a kind of syllogic automatic feeder according to claim 4, it is characterized in that: described width adjusting mechanism comprises that the fixed mount, the two ends that are fixedly connected with described adapter plate are arranged on rotationally respectively ball-screw on described adapter plate and described fixed mount, are fixedly installed on described adjustment plate and the feed screw nut matching with described ball-screw, described width adjusting mechanism also comprises and being arranged on described fixed mount for driving the width adjustment driver train of described ball-screw rotation.

6. a kind of syllogic automatic feeder according to claim 5, is characterized in that: described width adjustment driver train comprises motor, and the output shaft of described motor is in transmission connection by transmission device mutually with described ball-screw.

7. a kind of syllogic automatic feeder according to claim 1, it is characterized in that: described epimere feeding unit also comprises the 7th sensor being installed on described epimere plate for detection of described material position on described epimere load-transfer device, described the 7th sensor is along the length direction of described epimere plate between described first sensor and described the second sensor, and described the 7th sensor is connected setting with described epimere driver train signal.

8. a kind of syllogic automatic feeder according to claim 1, it is characterized in that: described positioning section feeding unit also comprises the 8th sensor, the 9th sensor being installed on described positioning section plate for detection of described material position on described positioning section load-transfer device, described the 8th sensor, described the 9th sensor are along the length direction of described positioning section plate between described the 3rd sensor and described four-sensor, and described the 8th sensor, described the 9th sensor are connected setting with described positioning section driver train signal.

9. a kind of syllogic automatic feeder according to claim 1, it is characterized in that: described hypomere feeding unit also comprises and being installed on described hypomere plate for detection of the tenth sensor of described material position on described hypomere load-transfer device, described the tenth sensor is between described the 5th sensor and described the 6th sensor.

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