阅读说明：本技术 一种高端电子智能测量仪器 (High-end electronic intelligent measuring instrument ) 是由 黄敏谊 于 2021-09-16 设计创作，主要内容包括：本发明涉及测量相关领域,特别涉及一种高端电子智能测量仪器,包括测量箱体,所述测量箱体内设有开口朝上的测量腔,所述测量腔朝上的开口处固设有固定块,所述测量腔端壁内固设有导轨块,本发明能对芯片、电子感应器等物品进行感应强度的测量,并将其按不同感应强度进行分离存放,从而对感应强度强的与感应强度弱的分类后进行使用,从而能使其使用场所的更精确,并且保证了合格率,防止有感应强度无法满足使用者要求的物品。(The invention relates to the field of measurement correlation, in particular to a high-end electronic intelligent measuring instrument, which comprises a measuring box body, wherein a measuring cavity with an upward opening is arranged in the measuring box body, a fixed block is fixedly arranged at the upward opening of the measuring cavity, and a guide rail block is fixedly arranged in the end wall of the measuring cavity.)

1. The utility model provides a high-end electron intelligent measurement instrument, includes measurement box (10), its characterized in that: a measuring cavity (18) with an upward opening is arranged in the measuring box body (10), a fixed block (61) is fixedly arranged at the upward opening of the measuring cavity (18), and a guide rail block (11) is fixedly arranged in the end wall of the measuring cavity (18);

a sliding groove (26) with an outward opening is formed in the end face of one side, close to the fixed block (61), of the guide rail block (11), a sliding block (48) is arranged in the sliding groove (26) in a sliding mode, a supporting block (57) is fixedly arranged on the end face of one side, far away from the end wall of the sliding groove (26), of the sliding block (48), a clamping block is fixedly arranged on the upper end face of the supporting block (57) to prevent a measuring object falling on the upper end face of the supporting block (57) from moving to fall off, and a transmission cavity (21) communicated with the upper end wall of the measuring cavity (18) is formed in one side, far away from the guide rail block (11), of the fixed block (61);

a connecting cylinder (20) is fixedly arranged in the upper end wall of the transmission cavity (21), an installation block (19) is fixedly arranged at the lower end of the connecting cylinder (20), an induction measurer (17) is installed in the lower end face of the installation block (19), and a protection support plate (14) is fixedly arranged on the lower end wall of the measurement cavity (18).

2. A high-end electronic intelligent measuring instrument according to claim 1, characterized in that: be equipped with deposit chamber (35) that run through from top to bottom in fixed block (61), be equipped with symmetry and opening groove (46) that slide down in fixed block (61) lower terminal surface, sliding installation is equipped with sliding block (45) in groove (46) that slides, sliding block (45) up end with through reset spring (44) fixed connection between groove (46) upper end wall slides, it is equipped with separating mechanism (66) to deposit chamber (35) end wall internal symmetry.

3. A high-end electronic intelligent measuring instrument according to claim 2, characterized in that: the separating mechanism (66) comprises a connecting cavity (39) which is communicated with the storage cavity (35) and is symmetrical up and down, a moving block (37) is arranged in the connecting cavity (39) in a sliding mode, one end, close to the center line of the storage cavity (35), of the moving block (37) on the upper side is an inclined surface, one end, close to the center line of the storage cavity (35), of the moving block (37) on the lower side is a triangular pyramid, a sliding rack (36) is fixedly arranged on the end face, far away from the center line of the storage cavity (35), of the moving block (37), the sliding rack (36) is arranged in the end wall, far away from the center line of the storage cavity (35), of the connecting cavity (39) in a sliding mode, and a connecting gear (38) meshed and connected with the sliding rack (36) is arranged in the connecting cavity (39).

4. A high-end electronic intelligent measuring instrument according to claim 3, characterized in that: the vertically symmetrical connecting cavities (39) are rotatably provided with connecting shafts (40), and the vertically symmetrical connecting gears (38) are respectively and fixedly arranged on the connecting shafts (40).

5. A high-end electronic intelligent measuring instrument according to claim 3, characterized in that: the downside link up chamber (39) and keep away from deposit chamber (35) central line one side's end wall internal fixation has transmission cylinder (41), transmission cylinder (41) are close to deposit chamber (35) central line one end and downside movable block (37) fixed connection, downside link up chamber (39) lower end wall with fixed mounting is equipped with air pump (42) between sliding groove (46), sliding block (45) are close to trigger block (43) have set firmly on the terminal surface of air pump (42) one side.

6. A high-end electronic intelligent measuring instrument according to claim 1, characterized in that: keep away from fixed block (61) transmission chamber (21) one side be equipped with measure slide chamber (25) of chamber (18) intercommunication, slide chamber (25) slidable mounting is equipped with sliding plate (22), sliding plate (22) up end with through extension spring (23) fixed connection between slide chamber (25) the upper end wall, sliding plate (22) are close to set firmly rope (24) on the terminal surface of guide rail piece (11) one side.

7. A high-end electronic intelligent measuring instrument according to claim 1, characterized in that: slider (48) are close to the symmetry is equipped with removal roller set (47) in the terminal surface of sliding tray (26) end wall one side, the symmetry be equipped with between removal roller set (47) and be located slider (48) are close to open slot (49) in the terminal surface of sliding tray (26) end wall one side, open slot (49) opening is towards being close to sliding tray (26) end wall one side, it is equipped with driven roller (50) to rotate the installation between open slot (49) end wall, rope (24) other end extend to in sliding tray (26) and through driven roller (50) with open slot (49) are close to the end wall fixed connection of sliding tray (26) end wall one side.

8. A high-end electronic intelligent measuring instrument according to claim 7, characterized in that: the arc-shaped end wall of the sliding groove (26) is provided with a rotatable connecting roller group (34), so that the rope (24) can not rub against the end wall of the sliding groove (26) when passing through the arc-shaped end wall of the sliding groove (26), and the service life of the rope (24) is prolonged.

9. A high-end electronic intelligent measuring instrument according to claim 1, characterized in that: it is equipped with removal chamber (29) to measure intercommunication in chamber (18) lower terminal wall, remove chamber (29) with it is equipped with classification case (12) to measure slidable mounting between chamber (18), be equipped with six classification groove (55) that set gradually and open side up in classification case (12) up end, classification case (12) are kept away from fixed plate (13) have set firmly on the terminal surface of guide rail piece (11) one side, fixed plate (13) are kept away from it has set firmly on the terminal surface of measuring chamber (18) one side and move rack (30), be equipped with in removal chamber (29) with rotating gear (31) that removal rack (30) meshing is connected.

10. A high-end electronic intelligent measuring instrument according to claim 1, characterized in that: the upper side of the moving cavity (29) is provided with a gear cavity (28), the gear cavity (28) and the moving cavity (29) are rotatably provided with a rotating shaft (32), a rotating gear (31) is fixedly arranged on the rotating shaft (32), a transmission shaft (33) is rotatably arranged between the transmission cavity (21) and the gear cavity (28), the gear cavity (28) is internally provided with a transmission gear set (27) for connecting the transmission shaft (33) and the rotating shaft (32), the transmission cavity (21) is internally provided with a transmission gear (59) fixedly arranged on the transmission shaft (33), the upper end face of the mounting block (19) is fixedly provided with a connecting rack (58) which is slidably arranged in the upper end wall of the transmission cavity (21), the transmission gear (59) is connected with the connecting rack (58) in a meshing manner, the measuring cavity (18) is far away from the end wall on one side of the guide rail block (11) and is fixedly provided with a connecting cylinder (16), the connecting air cylinder (16) is close to one end of the guide rail block (11), a pushing block (15) is fixedly arranged, and the pushing block (15) can push a measured object which is measured on the upper end face of the protective supporting plate (14) to enter the corresponding classification groove (55).

Technical Field

The invention relates to the technical field of measurement correlation, in particular to a high-end electronic intelligent measuring instrument.

Background

At the present stage, induction objects such as chips produced in the same batch are only subjected to induction testing, induction feedback can be guaranteed, but induction intensity of the induction objects is not measured, so that the chips in the same batch are used, but induction intensity of each chip is still different, the chips cannot be used as much as possible, and a large difference exists between chips with strong induction intensity and chips with weak induction intensity, so that accidents can occur when a user uses the induction objects, for example, when the induction chips are used for scanning quantity, when the scanning objects are placed into a scanner, the chips with large induction intensity outside the scanner on a conveyor belt interfere with the quantity scanned in the scanner, and scanning quantity data errors are caused.

The application sets forth a high-end electronic intelligence measuring instrument can solve above-mentioned problem.

Disclosure of Invention

The invention provides a high-end electronic intelligent measuring instrument for solving the technical problems, and solves the problem of poor use effect caused by different chip induction strengths.

The above object of the present invention is achieved by the following technical solutions: a high-end electronic intelligent measuring instrument comprises a measuring box body, wherein a measuring cavity with an upward opening is arranged in the measuring box body, a fixed block is fixedly arranged at the upward opening of the measuring cavity, and a guide rail block is fixedly arranged in the end wall of the measuring cavity;

a sliding groove with an outward opening is formed in the end face of the guide rail block close to one side of the fixed block, a sliding block is arranged in the sliding groove in a sliding mode, a supporting block is fixedly arranged on the end face of the sliding block far away from one side of the end wall of the sliding groove, a clamping block is fixedly arranged on the upper end face of the supporting block, and a transmission cavity communicated with the upper end wall of the measurement cavity is formed in one side of the fixed block far away from the guide rail block;

the measuring device is characterized in that a connecting cylinder is fixedly arranged in the upper end wall of the transmission cavity, an installation block is fixedly arranged at the lower end of the connecting cylinder, an induction measurer is arranged in the lower end face of the installation block, and a protection support plate is fixedly arranged on the lower end wall of the measuring cavity.

Preferably, a storage cavity which penetrates through the fixed block from top to bottom is formed in the fixed block, sliding grooves which are symmetrical and have downward openings are formed in the lower end face of the fixed block, sliding blocks are arranged in the sliding grooves in a sliding mode, the upper end faces of the sliding blocks are fixedly connected with the upper end walls of the sliding grooves through reset springs, and separating mechanisms are symmetrically arranged in the end walls of the storage cavity.

Preferably, the separating mechanism includes a linking cavity which is communicated with the storage cavity and is symmetrical up and down, a moving block is arranged in the linking cavity in a sliding manner, one end, close to the central line of the storage cavity, of the moving block on the upper side is an inclined plane, one end, close to the central line of the storage cavity, of the moving block on the lower side is a triangular pyramid, a sliding rack is fixedly arranged on the end surface of the moving block on one side, away from the central line of the storage cavity, of the linking cavity in a sliding manner, and a connecting gear which is in meshed connection with the sliding rack is arranged in the linking cavity.

Preferably, the connecting cavities which are symmetrical up and down are rotatably provided with connecting shafts, the connecting gears which are symmetrical up and down are respectively and fixedly arranged on the connecting shafts, and the connecting gears which are symmetrical up and down are opposite to the sliding rack in installation position, so that the moving blocks which are symmetrical up and down are opposite in moving direction when the connecting shafts rotate.

Preferably, a transmission cylinder is fixedly arranged in an end wall of the lower side of the connecting cavity far away from the central line of the storage cavity, one end of the transmission cylinder close to the central line of the storage cavity is fixedly connected with the lower side of the moving block, an air pump is fixedly arranged between the lower end wall of the connecting cavity and the sliding groove, and a trigger block is fixedly arranged on an end face of the sliding block close to one side of the air pump.

Preferably, a sliding cavity communicated with the measuring cavity is formed in one side, far away from the transmission cavity, of the fixed block, a sliding plate is arranged in the sliding cavity in a sliding mode, the upper end face of the sliding plate is fixedly connected with the upper end wall of the sliding cavity through an extension spring, and a rope is fixedly arranged on the end face, close to one side of the guide rail block, of the sliding plate.

Preferably, the sliding block is close to the symmetry is equipped with the removal gyro wheel group in the terminal surface of sliding groove end wall one side, the symmetry be equipped with between the removal gyro wheel group and be located the sliding block is close to the open slot in the terminal surface of sliding groove end wall one side, the open slot opening is towards being close to sliding groove end wall one side, it is equipped with driven gyro wheel to rotate the installation between the open groove end wall, the rope other end extension extremely in the sliding groove and through driven gyro wheel with the open slot is close to the end wall fixed connection of sliding groove end wall one side.

Preferably, the arc-shaped end wall of the sliding groove is provided with a rotatable connecting roller group, so that the rope cannot rub against the end wall of the sliding groove when passing through the arc-shaped end wall of the sliding groove, and the service life of the rope is prolonged.

Preferably, the intercommunication is equipped with the removal chamber in measuring the chamber lower extreme wall, remove the chamber with slidable mounting is equipped with the classification case between the measurement chamber, be equipped with six classification groove that set gradually and opening up in the classification case up end, the classification case is kept away from the fixed plate has set firmly on the terminal surface of guide rail piece one side, the fixed plate is kept away from set firmly the removal rack on the terminal surface of measurement chamber one side, remove the intracavity be equipped with the running gear that the meshing of removal rack is connected.

Preferably, a gear cavity is arranged on the upper side of the moving cavity, a rotating shaft is rotatably arranged between the gear cavity and the moving cavity, the rotating gear is fixedly arranged on the rotating shaft, a transmission shaft is rotatably arranged between the transmission cavity and the gear cavity, a helical gear set which is in transmission connection with the transmission shaft and the rotating shaft is arranged in the gear cavity, a transmission gear which is fixedly arranged on the transmission shaft is arranged in the transmission cavity, the upper end surface of the mounting block is fixedly provided with a connecting rack which is slidably mounted in the upper end wall of the transmission cavity, the transmission gear is meshed with the connecting rack, a connecting cylinder is fixedly arranged in the end wall of the measuring cavity far away from one side of the guide rail block, and one end of the connecting cylinder, which is close to the guide rail block, is fixedly provided with a pushing block, and the pushing block can push a measured object which is measured on the upper end surface of the protective supporting plate to enter the corresponding classification groove.

The invention has the beneficial effects that: the invention can measure the induction intensity of the chip, the electronic inductor and other articles, and store the articles separately according to different induction intensities, thereby classifying the articles with strong induction intensity and weak induction intensity for use, thus ensuring more accuracy of the use place, ensuring the qualification rate and preventing the articles with induction intensity which can not meet the requirements of users.

Drawings

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

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic view of A-A of FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic view of B-B in FIG. 2 according to an embodiment of the present invention;

FIG. 4 is a schematic view of C-C in FIG. 1 according to an embodiment of the present invention;

FIG. 5 is an enlarged schematic view of the structure at D in FIG. 1 according to an embodiment of the present invention;

FIG. 6 is an enlarged schematic view of the structure at E in FIG. 5 according to an embodiment of the present invention;

FIG. 7 is an enlarged schematic view of the structure at F in FIG. 1 according to an embodiment of the present invention;

FIG. 8 is a schematic diagram of G-G of FIG. 7 according to an embodiment of the present invention.

In the figure: 10-measuring box body, 11-guide rail block, 12-sorting box, 13-fixing plate, 14-protective supporting plate, 15-pushing block, 16-connecting cylinder, 17-induction measuring device, 18-measuring cavity, 19-mounting block, 20-connecting cylinder, 21-transmission cavity, 22-sliding plate, 23-tension spring, 24-rope, 25-sliding cavity, 26-sliding groove, 27-bevel gear group, 28-gear cavity, 29-moving cavity, 30-moving rack, 31-rotating gear, 32-rotating shaft, 33-driving shaft, 34-connecting roller group, 35-storage cavity, 36-sliding rack, 37-moving block, 38-connecting gear, 39-connecting cavity and 40-connecting shaft, 41-transmission air cylinder, 42-air pump, 43-trigger block, 44-return spring, 45-sliding block, 46-sliding groove, 47-moving roller group, 48-sliding block, 49-open groove, 50-driven roller, 55-classification groove, 57-supporting block, 58-connecting rack, 59-transmission gear, 61-fixed block and 66-separation mechanism.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings. The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

The invention relates to a high-end electronic intelligent measuring instrument, which comprises a measuring box body 10, wherein a measuring cavity 18 with an upward opening is arranged in the measuring box body 10, a fixed block 61 is fixedly arranged at the upward opening of the measuring cavity 18, a guide rail block 11 is fixedly arranged in the end wall of the measuring cavity 18, a sliding groove 26 with an outward opening is arranged in the end surface of the guide rail block 11 close to one side of the fixed block 61, a sliding block 48 is arranged in the sliding groove 26 in a sliding manner, a supporting block 57 is fixedly arranged on the end surface of the sliding block 48 far away from one side of the end wall of the sliding groove 26, a clamping block is fixedly arranged on the upper end surface of the supporting block 57 to prevent a measuring object falling on the upper end surface of the supporting block 57 from moving to fall off, a transmission cavity 21 communicated with the upper end wall of the measuring cavity 18 is arranged on one side of the fixed block 61 far away from the guide rail block 11, and a linking cylinder 20 is fixedly arranged in the upper end wall of the transmission cavity 21, the lower end of the connecting cylinder 20 is fixedly provided with an installation block 19, the lower end face of the installation block 19 is internally provided with an induction measurer 17, and the lower end wall of the measurement cavity 18 is fixedly provided with a protective supporting plate 14.

Beneficially, a storage cavity 35 penetrating up and down is arranged in the fixed block 61, sliding grooves 46 with symmetrical openings facing down are arranged in the lower end face of the fixed block 61, sliding blocks 45 are arranged in the sliding grooves 46 in a sliding mode, the upper end face of each sliding block 45 is fixedly connected with the upper end wall of each sliding groove 46 through a return spring 44, and separating mechanisms 66 are symmetrically arranged in the end walls of the storage cavity 35.

Beneficially, the separating mechanism 66 includes an engaging cavity 39 which is communicated with the storage cavity 35 and is symmetrical up and down, a moving block 37 is installed in the engaging cavity 39 in a sliding manner, one end, close to the center line of the storage cavity 35, of the moving block 37 on the upper side is an inclined surface, one end, close to the center line of the storage cavity 35, of the moving block 37 on the lower side is a triangular pyramid, a sliding rack 36 is fixedly arranged on an end surface of one side, away from the center line of the storage cavity 35, of the moving block 37, the sliding rack 36 is installed in an end wall of one side, away from the center line of the storage cavity 35, of the engaging cavity 39 in a sliding manner, and a connecting gear 38 which is connected with the sliding rack 36 in a meshing manner is arranged in the engaging cavity 39.

Advantageously, the connecting cavities 39 which are symmetrical up and down are rotatably provided with connecting shafts 40, the connecting gears 38 which are symmetrical up and down are respectively fixedly arranged on the connecting shafts 40, and the connecting gears 38 which are symmetrical up and down are arranged at positions opposite to the mounting positions of the sliding racks 36, so that the moving blocks 37 which are symmetrical up and down move in opposite directions when the connecting shafts 40 rotate.

Beneficially, a transmission cylinder 41 is fixedly arranged in an end wall of the side, away from the center line of the storage cavity 35, of the lower joining cavity 39, a portion, close to the center line of the storage cavity 35, of the transmission cylinder 41 is fixedly connected with the moving block 37, the portion, close to the center line of the storage cavity 35, of the transmission cylinder 41 is fixedly connected with the lower moving block 46, an air pump 42 is fixedly arranged between a lower end wall of the lower joining cavity 39 and the sliding groove 46, a trigger block 43 is fixedly arranged on an end surface of the sliding block 45, close to the side of the air pump 42, of the sliding block, the transmission cylinder 41 can be started after the trigger block 43 is inserted into the air pump 42, and the air pump 42 cannot drive the transmission cylinder 41 to be started when the trigger block 43 is not inserted into the air pump 42, so that the measured object in the storage cavity 35 is prevented from falling out when the sliding block 48 drives the measured object to move.

Advantageously, a sliding cavity 25 communicated with the measuring cavity 18 is arranged on the side, away from the transmission cavity 21, of the fixed block 61, a sliding plate 22 is arranged in the sliding cavity 25 in a sliding mode, the upper end face of the sliding plate 22 is fixedly connected with the upper end wall of the sliding cavity 25 through a tension spring 23, and a rope 24 is fixedly arranged on the end face, close to the guide rail block 11, of the sliding plate 22.

Beneficially, moving roller sets 47 are symmetrically arranged in the end face of the sliding block 48 on the side close to the end wall of the sliding groove 26, an open slot 49 is arranged between the symmetrical moving roller sets 47 and located in the end face of the sliding block 48 on the side close to the end wall of the sliding groove 26, the open slot 49 is open towards the side close to the end wall of the sliding groove 26, a driven roller 50 is rotatably arranged between the end walls of the open slot 49, and the other end of the rope 24 extends into the sliding groove 26 and is fixedly connected with the end wall of the open slot 49 on the side close to the end wall of the sliding groove 26 through the driven roller 50.

Advantageously, the sliding groove 26 is provided at the curved end wall with a rotatable connecting roller set 34, so that the rope 24 passing through the curved end wall of the sliding groove 26 does not rub against the end wall of the sliding groove 26, thereby prolonging the service life of the rope 24.

Beneficially, the measurement chamber 18 is provided with a movable chamber 29 in the lower end wall thereof, the movable chamber 29 and the measurement chamber 18 are provided with a classification box 12 in a sliding installation manner, six classification grooves 55 which are sequentially arranged and have upward openings are formed in the upper end face of the classification box 12, the classification box 12 is far away from the end face of one side of the guide rail block 11, a fixed plate 13 is fixedly arranged on the end face of one side of the measurement chamber 18, the fixed plate 13 is far away from the end face of one side of the measurement chamber 18, and a rotating gear 31 which is meshed with the movable rack 30 is arranged in the movable chamber 29.

Beneficially, a gear cavity 28 is arranged on the upper side of the moving cavity 29, a rotating shaft 32 is rotatably installed between the gear cavity 28 and the moving cavity 29, the rotating gear 31 is fixedly installed on the rotating shaft 32, a transmission shaft 33 is rotatably installed between the transmission cavity 21 and the gear cavity 28, a bevel gear set 27 for driving and connecting the transmission shaft 33 and the rotating shaft 32 is arranged in the gear cavity 28, a transmission gear 59 fixedly installed on the transmission shaft 33 is arranged in the transmission cavity 21, a connecting rack 58 slidably installed in the upper end wall of the transmission cavity 21 is fixedly arranged on the upper end surface of the installation block 19, the transmission gear 59 is in meshed connection with the connecting rack 58, a connecting cylinder 16 is fixedly arranged in the end wall of the measuring cavity 18 far away from the guide rail block 11, a pushing block 15 is fixedly arranged at one end of the connecting cylinder 16 close to the guide rail block 11, the pushing block 15 can push the measured object on the upper end surface of the protection supporting plate 14 into the corresponding sorting groove 55.

The following describes in detail the use steps of the high-end electronic intelligent measuring instrument in the present disclosure with reference to fig. 1 to 8:

initial state: the return spring 44 is in a compressed state; the extension spring 23 is in a normal state; the trigger block 43 is inserted into the air pump 42;

when the work is started:

1. the induction measurer 17 can be exchanged to measure different induction strengths.

2. A measured object needing to measure induction strength is placed into the storage cavity 35, then the air pump 42 is used for starting the transmission air cylinder 41, the transmission air cylinder 41 drives the moving block 37 at the lower side to move towards one side far away from the central line of the storage cavity 35, the moving block 37 at the lower side moves towards one side far away from the central line of the storage cavity 35 so as to drive the sliding rack 36 at the lower side to move towards one side far away from the central line of the storage cavity 35, the sliding rack 36 at the lower side moves towards one side far away from the central line of the storage cavity 35 so as to drive the connecting gear 38 at the lower side to rotate, the connecting gear 38 at the lower side rotates so as to drive the connecting shaft 40 to rotate, the connecting gear 38 at the upper side rotates so as to drive the sliding rack 36 at the upper side to move towards one side close to the central line of the storage cavity 35, and the sliding rack 36 moves towards one side close to the central line of the storage cavity 35 so as to drive the moving block 37 at the upper side to move towards one side close to the central line of the storage cavity 35, therefore, the upper moving block 37 extends into the storage cavity 35 and separates the overlapped measuring objects, and after the lower moving block 37 moves into the lower connecting cavity 39, the lowest measuring object in the storage cavity 35 falls on the upper end face of the supporting block 57.

3. The support block 57 is influenced by gravity to drive the slide block 48 to move downward, the slide block 48 moves downward to drive the slide plate 22 to move downward through the rope 24, the slide plate 22 moves downward to stretch the extension spring 23, and after the slide block 48 moves downward to incline the support block 57, a measurement object on the upper end surface of the support block 57 slides down to the upper end surface of the protective support plate 14.

4. At the same time, the transmission cylinder 41 drives the lower moving block 37 to return to the initial position, so that the upper moving block 37 moves back to the initial position toward the upper engaging chamber 39.

5. When the measurement object slides to the upper end face of the protective supporting plate 14, the linking cylinder 20 drives the mounting block 19 to move downwards, the mounting block 19 moves downwards to drive the induction measuring device 17 and the connecting rack 58 to move downwards, the connecting rack 58 moves downwards to drive the transmission gear 59 to rotate, the transmission gear 59 rotates to drive the transmission shaft 33 to rotate, the transmission shaft 33 rotates to drive the rotation shaft 32 to rotate through the bevel gear set 27, the rotation shaft 32 rotates to drive the rotation gear 31 to rotate, the rotation gear 31 rotates to drive the moving rack 30 to move towards one side close to the sliding groove 26, the moving rack 30 moves towards one side close to the sliding groove 26 to drive the fixing plate 13 to move towards one side close to the sliding groove 26, and the fixing plate 13 moves towards one side close to the sliding groove 26 to drive the classification box 12 to move towards one side close to the sliding groove 26.

6. After induction measurement device 17 senses the measurement object, connect cylinder 16 and start to drive and promote piece 15 and to being close to guide rail piece 11 one side and remove, thereby promote piece 15 and to being close to guide rail piece 11 one side and remove and promote the measurement object of protection backup pad 14 up end and drop to the categorised groove 55 of corresponding induction intensity, after the measurement object of protection backup pad 14 up end got into categorised groove 55, link up cylinder 20 and drive installation piece 19 upward movement and get back to initial position, thereby installation piece 19 upward movement makes categorised case 12 get back to initial position.

7. When the mounting block 19 moves downwards to the limit position and does not sense the measuring object on the upper end surface of the protection supporting plate 14, it is indicated that the sensing intensity of the measuring object is too low and unqualified, so that the connecting cylinder 16 drives the pushing block 15 to move towards the side close to the guide rail block 11, and the pushing block 15 moves towards the side close to the guide rail block 11 so as to push the measuring object on the upper end surface of the protection supporting plate 14 to fall into the classification groove 55 at the side farthest from the guide rail block 11.

8. When the gravity on the upper end surface of the supporting block 57 disappears, the sliding block 48 moves upwards to return to the initial position under the driving of the resilience force of the extension spring 23, and when the supporting block 57 moves upwards to drive the sliding block 45 to move upwards, the sliding block 45 moves upwards to compress the return spring 44 and drive the trigger block 43 to be inserted into the air pump 42, so that the transmission cylinder 41 is started again to enable the next measured object to fall to the upper end surface of the supporting block 57.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.