CN116495413A - Quantitative conveying device for chip detection - Google Patents

Abstract

The invention belongs to the technical field of chip detection, in particular to a quantitative conveying device for chip detection, which comprises a base, a supporting plate fixedly connected to the upper surface of the base, a detector body arranged on the surface of the supporting plate, and a conveying mechanism arranged on the surface of the base, wherein the conveying mechanism comprises a conveying component, a transferring component, a yielding component, a guiding component and an adsorption component, the conveying component is arranged on the upper surface of the base, the transferring component is arranged on the surface of the conveying component, and the yielding component is arranged above the conveying component; is beneficial to intermittently and intermittently conveying chips, thereby providing detection time during conveying and detecting the chips, improving working efficiency, the chip is pushed to move rightwards by the abdicating rod in the process of conveying the disc to rotate, and the phenomenon that the chip is blocked in the clamping groove to rotate the conveying disc is avoided.

Description

Quantitative conveying device for chip detection

Technical Field

The invention belongs to the technical field of chip detection, and particularly relates to a quantitative conveying device for chip detection.

Background

At present, the integrated circuit manufacturing industry rapidly develops in China, along with the continuous improvement of the technological level and the design level, the functions of chips are more and more complex, parameters such as direct current, alternating current and the like of the chips need to be detected before the chips are packaged, the chips are transported by using conveying equipment in the processing process so as to detect the parameters, and the existing conveying equipment is conveyed by using a conveying belt;

although the chip can be conveyed through the conveying belt, when the chip is detected, the chip can be detected only by stopping the operation of the conveying equipment, the position of the chip in the detection process is required to be regulated to be right below the detection head, the repeated start and stop of the conveying equipment easily damage a motor, the difficulty of stopping the movement of the chip right below the detection head is high through the start and stop of the conveying equipment, and the chip conveying effect is reduced;

for this purpose, a quantitative transfer device for chip inspection is designed to solve the above problems.

Disclosure of Invention

To solve the problems set forth in the background art. The invention provides a quantitative conveying device for chip detection, which is beneficial to intermittent conveying of chips, so that detection time is provided when the chips are conveyed and detected, working efficiency is improved, the position of chip conveying is regulated, the chips are pushed to move rightwards by a yielding rod in the rotating process of a conveying disc, and the chip card is prevented from obstructing the rotation of the conveying disc in a clamping groove.

In order to achieve the above purpose, the present invention provides the following technical solutions: the quantitative conveying device for chip detection comprises a base, a supporting plate fixedly connected to the upper surface of the base, a detector body mounted on the surface of the supporting plate, and a conveying mechanism arranged on the surface of the base;

the conveying mechanism comprises a conveying component, a transferring component, a yielding component, a guiding component and an adsorption component, wherein the conveying component is arranged on the upper surface of the base, the transferring component is arranged on the surface of the conveying component, the yielding component is arranged above the conveying component and is connected with the conveying component, the guiding component is arranged on the surface of the transferring component, and the adsorption component is arranged inside the conveying component.

As the quantitative conveying device for chip detection, the quantitative conveying device for chip detection is preferable, the conveying assembly comprises a round barrel, arc-shaped blocking rings, a conveying disc, a rotating shaft and a bearing, wherein the round barrel is fixedly connected to the upper surface of a base, the two arc-shaped blocking rings are symmetrically and fixedly connected to the upper surface of the round barrel, the conveying disc is arranged in the two arc-shaped blocking rings, the bearing is arranged on the upper surface of the base, the rotating shaft is inserted into the bearing, the rotating shaft is rotatably connected with the base through the bearing, a through circular groove is formed in the upper surface of the round barrel, the rotating shaft is inserted into the through circular groove, the rotating shaft is rotatably connected with the round barrel, one end, far away from the base, of the rotating shaft is fixedly connected with the conveying disc, and a clamping groove in an annular array is formed in the surface of the conveying disc.

As the quantitative conveying device for chip detection, preferably, a gear is sleeved on the surface of the rotating shaft, a rotating disk is arranged on the left side of the gear, teeth are fixedly connected to the surface of the rotating disk, a first motor is arranged below the rotating disk and is fixedly connected with the base, and an output shaft of the first motor is fixedly connected with the rotating disk.

As the quantitative conveying device for chip detection, the transfer assembly comprises a first material guiding plate and an inclined plate, wherein the inclined plate is fixedly connected to the surface of the circular barrel, the upper surface of the inclined plate is symmetrically and fixedly connected with two first material guiding plates, and the two first material guiding plates are respectively and fixedly connected with two arc-shaped blocking rings.

As the quantitative conveying device for chip detection, preferably, the surface of the circular barrel is provided with the mounting groove, the inside of the mounting groove is inserted with the U-shaped plate, the U-shaped plate is fixedly connected with the circular barrel, the upper surface of the circular barrel is provided with the blanking groove, the blanking groove is communicated with the inside of the mounting groove, the inside of the U-shaped plate is provided with the two conveying rollers, the two ends of the two conveying rollers are respectively inserted into round holes formed in the surface of the U-shaped plate, the two conveying rollers are respectively connected with the U-shaped plate in a rotating way, the surfaces of the two conveying rollers are sleeved with the conveying belt, the front surface of the U-shaped plate is provided with the second motor, and the second motor is fixedly connected with one end of one conveying roller.

As the quantitative conveying device for chip detection, the yielding component comprises a U-shaped rod, a lower arc-shaped plate, an upper arc-shaped plate and a transverse plate, wherein two second rectangular slots are symmetrically formed in the upper surface of the circular barrel, a first rectangular slot communicated with the second rectangular slot is formed in the surface of the arc-shaped blocking ring, the U-shaped rod penetrates through the first rectangular slot and is inserted into the second rectangular slot, the U-shaped rod is in sliding connection with the arc-shaped blocking ring, the U-shaped rod is in sliding connection with the circular barrel, the transverse plate is fixedly connected to the left surface of the U-shaped rod, the upper arc-shaped plate is fixedly connected to the bottom surface of the transverse plate, and the lower arc-shaped plate which is in an annular array is fixedly connected to the upper surface of the conveying disc.

As the quantitative conveying device for chip detection, the bottom surface of the transverse plate is fixedly connected with the U-shaped clamping block, the abdication rod is inserted into the U-shaped clamping block and is rotationally connected with the U-shaped clamping block, the bottom surface of the U-shaped rod is provided with the rope, and two ends of the rope are respectively and fixedly connected with the abdication rod and the U-shaped rod.

As the quantitative conveying device for chip detection, the guide assembly comprises a second material guiding plate, a U-shaped clamping plate, a rectangular sleeve, side support plates and a positioning rod, wherein the two side support plates are symmetrically and fixedly connected to the upper surface of the U-shaped plate, the positioning rod is arranged between the two side support plates and fixedly connected with the side support plates, the two rectangular sleeves are sleeved on the surface of the positioning rod, the rectangular sleeve is in sliding connection with the positioning rod, the U-shaped clamping plate is arranged on the left side of the positioning rod, the two second material guiding plates are symmetrically and fixedly connected to the surface of the U-shaped clamping plate, and the two second material guiding plates are respectively and fixedly connected with the two rectangular sleeves.

In the quantitative conveying device for chip detection of the present invention, preferably, a top plate is disposed above the rectangular sleeve, the top plate is fixedly connected with the two rectangular sleeves, a threaded knob is inserted into the surface of the top plate, and the threaded knob penetrates through the top plate and is in threaded connection with the top plate.

As the quantitative conveying device for chip detection, the adsorption assembly comprises an air pump and an L-shaped pipe, wherein the L-shaped pipe is arranged on the upper surface of the conveying disc, a circular groove is formed in the conveying disc, the L-shaped pipe is inserted into the upper surface of the conveying disc, the L-shaped pipe is communicated with the inner part of the circular groove, the L-shaped pipe is arranged at the air inlet end of the air pump, an air inlet groove communicated with the clamping groove is formed in the conveying disc, and the clamping groove is communicated with the inner part of the circular groove through the air inlet groove.

Compared with the prior art, the invention has the beneficial effects that: the chip intermittent pause is facilitated, the chip is conveyed to the position right below the detection head of the detector body, detection time is provided when the chip is conveyed and detected, working efficiency is improved, adjustment of the chip conveying position is facilitated, the use effect of the quantitative conveying device is improved, the chip is pushed to move rightwards through the abdicating rod in the conveying disc rotation process, and the chip card is prevented from obstructing rotation of the conveying disc in the clamping groove.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is an enlarged view of the invention at A in FIG. 2;

FIG. 4 is a schematic view of the structure of the gear and the rotating shaft according to the present invention;

FIG. 5 is a schematic view of the structure of the yielding rod and the cross plate according to the present invention;

FIG. 6 is a schematic view of a rectangular sleeve and a second guide plate according to the present invention;

FIG. 7 is a schematic view of the structure of the U-shaped plate and the circular barrel in the present invention;

in the figure:

1. a base; 2. a conveying mechanism; 3. a support plate; 4. a detector body;

21. a transport assembly; 211. a circular barrel; 212. an arc-shaped blocking ring; 213. a conveying disc; 214. a clamping groove; 215. a rotation shaft; 216. a gear; 217. a bearing; 218. a rotating disc; 219. teeth; 2110. a first motor; 2111. a through circular groove;

22. a transfer assembly; 221. an inclined plate; 222. a first guide plate; 223. a U-shaped plate; 224. a mounting groove; 225. discharging groove; 226. a conveying roller; 227. a conveyor belt; 228. a second motor;

23. a yielding component; 231. a U-shaped rod; 232. a first rectangular slot; 233. a lower arc plate; 234. an upper arc plate; 235. a cross plate; 236. a rope; 237. a yielding rod; 238. a U-shaped clamping block; 239. a second rectangular slot;

24. a guide assembly; 241. a second guide plate; 242. a U-shaped clamping plate; 243. a rectangular sleeve; 244. a top plate; 245. a threaded knob; 246. a side support plate; 247. a positioning rod;

25. an adsorption assembly; 251. an air pump; 252. an L-shaped tube; 253. a circular groove; 254. an air inlet groove.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1 to 7;

the quantitative conveying device for chip detection comprises a base 1, a supporting plate 3 fixedly connected to the upper surface of the base 1, a detector body 4 arranged on the surface of the supporting plate 3, and a conveying mechanism 2 arranged on the surface of the base 1;

the conveying mechanism 2 comprises a conveying component 21, a transferring component 22, a yielding component 23, a guiding component 24 and an adsorbing component 25, wherein the conveying component 21 is arranged on the upper surface of the base 1, the transferring component 22 is arranged on the surface of the conveying component 21, the yielding component 23 is arranged above the conveying component 21 and is connected with the conveying component 21, the guiding component 24 is arranged on the surface of the transferring component 22, and the adsorbing component 25 is arranged inside the conveying component 21.

In an alternative embodiment, the conveying assembly 21 includes a circular tub 211, an arc-shaped blocking ring 212, a conveying disc 213, a rotating shaft 215 and a bearing 217, the circular tub 211 is fixedly connected to the upper surface of the base 1, the upper surface of the circular tub 211 is symmetrically and fixedly connected with the two arc-shaped blocking rings 212, the conveying disc 213 is arranged in the two arc-shaped blocking rings 212, the bearing 217 is mounted on the upper surface of the base 1, the rotating shaft 215 is inserted in the bearing 217, the rotating shaft 215 is rotationally connected with the base 1 through the bearing 217, a through circular groove 2111 is formed in the upper surface of the circular tub 211, the rotating shaft 215 is inserted in the through circular groove 2111, the rotating shaft 215 is rotationally connected with the circular tub 211, one end of the rotating shaft 215, which is far away from the base 1, is fixedly connected with the conveying disc 213, and a clamping groove 214 in an annular array is formed in the surface of the conveying disc 213.

In an alternative embodiment, the surface of the rotating shaft 215 is sleeved with a gear 216, a rotating disk 218 is arranged on the left side of the gear 216, teeth 219 are fixedly connected to the surface of the rotating disk 218, a first motor 2110 is arranged below the rotating disk 218, the first motor 2110 is fixedly connected with the base 1, and an output shaft of the first motor 2110 is fixedly connected with the rotating disk 218.

In an alternative embodiment, the transfer assembly 22 includes a first guide plate 222 and an inclined plate 221, the inclined plate 221 is fixedly connected to the surface of the circular barrel 211, two first guide plates 222 are symmetrically and fixedly connected to the upper surface of the inclined plate 221, and the two first guide plates 222 are fixedly connected to the two arc-shaped blocking rings 212 respectively.

In an alternative embodiment, the surface of the circular barrel 211 is provided with a mounting groove 224, a U-shaped plate 223 is inserted in the mounting groove 224, the U-shaped plate 223 is fixedly connected with the circular barrel 211, a blanking groove 225 is formed in the upper surface of the circular barrel 211, the blanking groove 225 is communicated with the inside of the mounting groove 224, two conveying rollers 226 are arranged in the U-shaped plate 223, two ends of each conveying roller 226 are respectively inserted in round holes formed in the surface of the U-shaped plate 223, the two conveying rollers 226 are respectively connected with the U-shaped plate 223 in a rotating mode, a conveyor belt 227 is sleeved on the surface of each conveying roller 226, a second motor 228 is mounted on the front surface of the U-shaped plate 223, and one end of each conveying roller 226 is fixedly connected with the second motor 228.

In an alternative embodiment, the yielding assembly 23 includes a U-shaped rod 231, a lower arc plate 233, an upper arc plate 234 and a cross plate 235, two second rectangular slots 239 are symmetrically formed on the upper surface of the circular barrel 211, a first rectangular slot 232 communicated with the second rectangular slot 239 is formed on the surface of the arc-shaped blocking ring 212, the U-shaped rod 231 penetrates through the first rectangular slot 232 and is inserted into the second rectangular slot 239, the U-shaped rod 231 is slidably connected with the arc-shaped blocking ring 212, the U-shaped rod 231 is slidably connected with the circular barrel 211, the cross plate 235 is fixedly connected to the left surface of the U-shaped rod 231, the upper arc plate 234 is fixedly connected to the bottom surface of the cross plate 235, and the lower arc plate 233 in an annular array is fixedly connected to the upper surface of the conveying disc 213.

In an alternative embodiment, the bottom surface of the transverse plate 235 is fixedly connected with a U-shaped clamping block 238, a yielding rod 237 is inserted in the U-shaped clamping block 238, the yielding rod 237 is rotationally connected with the U-shaped clamping block 238, a rope 236 is arranged on the bottom surface of the U-shaped rod 231, and two ends of the rope 236 are fixedly connected with the yielding rod 237 and the U-shaped rod 231 respectively.

In an alternative embodiment, the guiding assembly 24 includes a second guide plate 241, a U-shaped clamping plate 242, a rectangular sleeve 243, a side support 246 and a positioning rod 247, where the two side support 246 are symmetrically and fixedly connected to the upper surface of the U-shaped plate 223, the positioning rod 247 is disposed between the two side support 246, the positioning rod 247 is fixedly connected to the side support 246, the two rectangular sleeves 243 are sleeved on the surface of the positioning rod 247, the rectangular sleeve 243 is slidably connected to the positioning rod 247, the U-shaped clamping plate 242 is disposed on the left side of the positioning rod 247, the two second guide plates 241 are symmetrically and fixedly connected to the surface of the U-shaped clamping plate 242, and the two second guide plates 241 are fixedly connected to the two rectangular sleeves 243.

In an alternative embodiment, a top plate 244 is disposed above the rectangular sleeves 243, the top plate 244 is fixedly connected to the two rectangular sleeves 243, a threaded knob 245 is inserted into the surface of the top plate 244, and the threaded knob 245 penetrates the top plate 244 and is in threaded connection with the top plate 244.

In an alternative embodiment, the adsorption assembly 25 includes an air pump 251 and an L-shaped tube 252, the L-shaped tube 252 is mounted on the upper surface of the conveying disc 213, a circular groove 253 is formed in the conveying disc 213, the L-shaped tube 252 is inserted into the upper surface of the conveying disc 213, the L-shaped tube 252 is communicated with the inside of the circular groove 253, the L-shaped tube 252 is mounted at the air inlet end of the air pump 251, an air inlet groove 254 communicated with the clamping groove 214 is formed in the conveying disc 213, and the clamping groove 214 is communicated with the inside of the circular groove 253 through the air inlet groove 254.

In this embodiment: when the device is used, the connecting wires of the second motor 228 and the first motor 2110 are connected by a power supply, the operation controller starts the first motor 2110, the operation of the first motor 2110 drives the rotating disc 218 to rotate, the rotation of the rotating disc 218 drives the teeth 219 to rotate, the rotation of the teeth 219 drives the gears 216 to rotate, because only one tooth 219 is arranged on the surface of the rotating disc 218, sixteen clamping grooves 214 are formed on the surface of the conveying disc 213, when the rotating disc 218 rotates for one circle, the gears 216 can rotate for one sixteenth circle, and after the teeth 219 slide out from the surface of the gears 216, the gears 216 stop rotating until the rotating disc 218 drives the teeth 219 to be attached to the surface of the gears 216, so that the gears 216 continue to rotate, the rotation of the gears 216 drives the rotating shaft 215 to rotate, and the rotation of the rotating shaft 215 drives the conveying disc 213 to rotate, the conveying disc 213 can intermittently rotate under the cooperation of the teeth 219 and the gears 216, and the conveying disc 213 can enable different clamping grooves 214 to be positioned under the detection head of the detector body 4 once every rotation, so that chips to be detected are placed on the surface of the inclined plate 221 and between the two first material guiding plates 222, the chips slide on the surface of the inclined plate 221 and slide into the clamping grooves 214, the chips in the clamping grooves 214 are driven to intermittently and intermittently stop transmission by the conveying disc 213, the chips can be rapidly detected, intermittent and intermittent conveying of the chips is facilitated, the chips are conveyed to the position under the detection head of the detector body 4, the detection time is provided when the chips are conveyed and detected, the working efficiency is improved, after the chips are detected, the chips are driven to slide on the surface of the circular barrel 211 along with intermittent and intermittent transmission of the conveying disc 213, along with the sliding of the chip, until the chip slides into the blanking groove 225, the chip passes through the blanking groove 225 and falls to the surface of the conveying belt 227, the chip can be driven to move under the action of the second motor 228 and is conveyed to the next procedure, the arrangement of the second material guiding plate 241 can guide the chip, the problem that the chip falls at the edge position of the conveying belt 227 and slides out of the surface of the conveying belt 227 is avoided, when the conveying position of the chip is required to be regulated according to the subsequent procedure, the second material guiding plate 241 is applied with a force, the rectangular sleeve 243 can slide on the surface of the positioning rod 247, the movement of the second material guiding plate 241 drives the U-shaped clamping plate 242 to move, the positions of the U-shaped clamping plate 242 are different, after the position of the U-shaped clamping plate 242 is regulated, the threaded knob 245 is rotated, the threaded knob 245 is propped against the positioning rod 247 under the action of threads, the U-shaped clamping plate 242 after the adjustment of the position can be fixed, which is favorable for conveying chips, and the position of the chip conveying is adjusted, so that the use effect of the quantitative conveying device is improved, in the process of conveying the chips, the arc plate 233 is driven to rotate along with the rotation of the conveying disc 213, when the clamping groove 214 is about to slide between the two arc-shaped blocking rings 212, the lower arc plate 233 is driven to rotate along with the conveying disc 213, so that the surfaces of the lower arc plate 233 and the upper arc plate 234 are attached, in the process of rotating the lower arc plate 233, the upper arc plate 234 is jacked up, the transverse plate 235 is driven to move by the movement of the upper arc plate 234, the U-shaped rod 231 is driven to move by the movement of the transverse plate 235, the U-shaped rod 237 is driven to move upwards by the lifting of the U-shaped rod 231, the chip between the two arc-shaped blocking rings 212 is propped up by the yielding rod 237 before the U-shaped rod 231 is not lifted, avoid the removal of chip, when U-shaped rod 231 drove the pole 237 that gives up, the pole 237 that gives up does not exert effort to the chip, the slope setting of hang plate 221 exerts effort to the chip of below, after the pole 237 that gives up leaves the chip, the chip between two arc baffle rings 212 slides into the card silo 214 of corresponding position department, and along with the rotation of lower arc 233, can make the upper arc 234 slide out from the surface of lower arc 233, thereby make upper arc 234 drop suddenly, because the pole 237 that gives up is in the slope state under the pulling of rope 236, can promote the chip in two arc baffle ring 212 gaps to move towards the direction of keeping away from conveying disc 213 in the in-process that gives up the pole 237 suddenly drops, be favorable to pushing the chip to move rightwards through the pole 237 that gives up in conveying disc 213 pivoted in-process, avoid the chip card to cause the hindrance to the rotation of conveying disc 213 in the inside of card silo 214.

It should be noted that: in the process of conveying and detecting the chip, the connecting wire of the air pump 251 is connected with an external power supply, the operation controller starts the air pump 251, the operation of the air pump 251 enables external air to flow into the air inlet groove 254 along the inside of the clamping groove 214 and flow into the circular groove 253 along the inside of the air inlet groove 254, the air in the circular groove 253 flows along the inside of the L-shaped pipe 252 and flows to the outside, and in the process of flowing in the air inlet groove 254, the air flows into the circular groove 253 along the inside of the clamping groove 214, so that a certain suction force is provided for the chip in the clamping groove 214, and the problem that the chip is damaged due to the fact that the chip is attached to the arc-shaped blocking ring 212 is avoided.

It should be noted that: the surface of the rotating disc 218 is only provided with one tooth 219, sixteen clamping grooves 214 are formed in the surface of the conveying disc 213, when the rotating disc 218 drives the tooth 219 to rotate for one circle, the gear 216 can rotate for one sixteenth circle, after the tooth 219 slides out of the surface of the gear 216, the gear 216 stops rotating, the conveying disc 213 is attached to the surface of the circular barrel 211, corresponding friction force exists, and accordingly after the tooth 219 slides out of the surface of the gear 216, the rotating shaft 215 does not continue to rotate until the rotating disc 218 drives the tooth 219 to attach to the surface of the gear 216 again, so that the gear 216 continues to rotate, the rotation of the gear 216 drives the rotating shaft 215 to rotate, and the rotation of the rotating shaft 215 drives the conveying disc 213 to rotate, and intermittent rotation of the conveying disc 213 can be achieved under the cooperation of the tooth 219 and the gear 216.

It should be noted that: the lower arc plate 233 and the upper arc plate 234 are both in quarter-circle structures, the structures of the upper arc plate 234 and the lower arc plate 233 are shown in fig. 4, when the lower arc plate 233 rotates, the upper arc plate 234 can slide on the surface of the lower arc plate 233, the upper arc plate 234 is jacked up in the rotating process of the lower arc plate 233, and after the upper arc plate 234 slides out from the surface of the lower arc plate 233, the upper arc plate 234 suddenly descends, so that the upper arc plate 234 can prop against the chip to move right through the abdicating rod 237.

It should be noted that: the detector body 4 belongs to the prior art in the field, the detector body 4 is a tool for detecting a chip, the model of the detected chip is input through a keyboard, for example, the detected chip is 74LS04, the detection chip is input 04, then a determination key is pressed, and the system can detect the working parameters of the chip.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a quantitative conveyor that chip detection used, includes base (1) and fixed connection be in backup pad (3) of base (1) upper surface and install detector body (4) on backup pad (3) surface, its characterized in that: the device also comprises a conveying mechanism (2) arranged on the surface of the base (1);

conveying mechanism (2) are including conveying subassembly (21), transfer subassembly (22), component (23) of stepping down, direction subassembly (24) and adsorption component (25), conveying subassembly (21) set up the upper surface of base (1), transfer subassembly (22) set up the surface of conveying subassembly (21), component (23) of stepping down set up the top of conveying subassembly (21), and with conveying subassembly (21) are connected, direction subassembly (24) set up the surface of transferring subassembly (22), adsorption component (25) set up the inside of conveying subassembly (21).

2. The quantitative transfer device for chip test according to claim 1, wherein: the conveying assembly (21) comprises a round barrel (211), arc-shaped blocking rings (212), a conveying disc (213), a rotating shaft (215) and bearings (217), wherein the round barrel (211) is fixedly connected to the upper surface of the base (1), the two arc-shaped blocking rings (212) are symmetrically and fixedly connected to the upper surface of the round barrel (211), the conveying disc (213) is arranged in the two arc-shaped blocking rings (212), the bearings (217) are arranged on the upper surface of the base (1), the rotating shaft (215) is inserted into the bearings (217), the rotating shaft (215) is connected with the base (1) in a rotating mode, a through circular groove (2111) is formed in the upper surface of the round barrel (211), the rotating shaft (215) is inserted into the through circular groove (2111), the rotating shaft (215) is connected with the round barrel (211) in a rotating mode, one end of the rotating shaft (215) is far away from the base (1) and the conveying disc (213) is fixedly connected with the disc (213), and the disc (213) is provided with the annular groove (213).

3. The quantitative transfer device for chip test according to claim 2, wherein: the rotary shaft (215) is characterized in that a gear (216) is sleeved on the surface of the rotary shaft (215), a rotary disc (218) is arranged on the left side of the gear (216), teeth (219) are fixedly connected to the surface of the rotary disc (218), a first motor (2110) is arranged below the rotary disc (218), the first motor (2110) is fixedly connected with the base (1), and an output shaft of the first motor (2110) is fixedly connected with the rotary disc (218).

4. The quantitative transfer device for chip test according to claim 2, wherein: the transfer assembly (22) comprises a first material guiding plate (222) and an inclined plate (221), wherein the inclined plate (221) is fixedly connected to the surface of the circular barrel (211), two first material guiding plates (222) are symmetrically and fixedly connected to the upper surface of the inclined plate (221), and the two first material guiding plates (222) are respectively and fixedly connected with the two arc-shaped blocking rings (212).

5. The quantitative transfer device for chip test according to claim 2, wherein: the utility model discloses a novel automatic feeding device for a plastic bottle, including circular bucket (211), mounting groove (224) have been seted up on the surface of circular bucket (211), the inside of mounting groove (224) has been inserted and has been had U template (223), U template (223) with circular bucket (211) fixed connection, silo (225) have been seted up on the upper surface of circular bucket (211), silo (225) with the inside of mounting groove (224) is linked together, the inside of U template (223) is provided with two conveying rollers (226), two the both ends of conveying roller (226) are inserted respectively and are established in the round hole of U template (223) surface seting up, and two conveying rollers (226) respectively with U template (223) swivelling joint, two the surface cover of conveying roller (226) is equipped with conveyer belt (227), the front surface mounting of U template (223) has second motor (228), second motor (228) and one of them conveying roller (226) one end fixed connection.

6. The quantitative transfer device for chip test according to claim 2, wherein: the utility model provides a subassembly (23) of stepping down, includes U type pole (231), lower arc (233), goes up arc (234) and diaphragm (235), two second rectangle slot (239) have been seted up to the upper surface symmetry of circular bucket (211), first rectangle slot (232) that arc baffle ring (212) surface seted up with second rectangle slot (239) are linked together, U type pole (231) run through first rectangle slot (232) to insert and establish the inside of second rectangle slot (239), U type pole (231) with arc baffle ring (212) sliding connection, U type pole (231) with circular bucket (211) sliding connection, diaphragm (235) fixed connection is in the left surface of U type pole (231), go up arc (234) fixed connection be in the bottom surface of diaphragm (235), the upper surface fixedly connected with of delivery disc (213) is annular array arc (233) down.

7. The quantitative transfer device for chip test according to claim 6, wherein: the bottom surface fixedly connected with U type fixture block (238) of diaphragm (235), the inside of U type fixture block (238) is inserted and is equipped with the pole of stepping down (237), step down pole (237) with U type fixture block (238) rotate to be connected, the bottom surface of U type pole (231) is provided with rope (236), the both ends of rope (236) respectively with step down pole (237) with U type pole (231) fixed connection.

8. The quantitative transfer device for chip test according to claim 5, wherein: the guide assembly (24) comprises a second guide plate (241), a U-shaped clamping plate (242), rectangular sleeves (243), side support plates (246) and positioning rods (247), wherein the upper surface of the U-shaped plate (223) is symmetrically and fixedly connected with two side support plates (246), the positioning rods (247) are arranged between the two side support plates (246), the positioning rods (247) are fixedly connected with the side support plates (246), the two rectangular sleeves (243) are sleeved on the surfaces of the positioning rods (247), the rectangular sleeves (243) are in sliding connection with the positioning rods (247), the left side of each positioning rod (247) is provided with the U-shaped clamping plate (242), the surface of each U-shaped clamping plate (242) is symmetrically and fixedly connected with the two second guide plates (241), and the two second guide plates (241) are respectively fixedly connected with the two rectangular sleeves (243).

9. The quantitative transfer device for chip test according to claim 8, wherein: the top of rectangle cover (243) is provided with roof (244), roof (244) and two rectangle cover (243) fixed connection, the surface of roof (244) is inserted and is equipped with screw knob (245), screw knob (245) run through roof (244) and with roof (244) threaded connection.

10. The quantitative transfer device for chip test according to claim 2, wherein: the adsorption component (25) comprises an air pump (251) and an L-shaped pipe (252), the L-shaped pipe (252) is arranged on the upper surface of the conveying disc (213), a circular groove (253) is formed in the conveying disc (213), the L-shaped pipe (252) is inserted into the upper surface of the conveying disc (213), the L-shaped pipe (252) is communicated with the inner part of the circular groove (253), the L-shaped pipe (252) is arranged at the air inlet end of the air pump (251), an air inlet groove (254) communicated with the clamping groove (214) is formed in the conveying disc (213), and the clamping groove (214) is communicated with the inner part of the circular groove (253) through the air inlet groove (254).