CN213240472U - Scalability magnetism detection device - Google Patents

Abstract

The utility model relates to a scalability magnetism detection device, which comprises a bedplate, wherein a bearing mechanism and a magnetism detection mechanism are arranged on the bedplate, the bearing mechanism comprises a bearing bottom plate, a fixed frame, a fixed block, a guide optical axis, bearing mold rods and a telescopic spring, the bearing bottom plate is arranged on the bedplate, the fixed frame and the fixed block are respectively arranged at two ends of the bearing bottom plate, the fixed block is close to the side surface of the bearing bottom plate, the guide optical axis is arranged on the fixed block, one end of the guide optical axis is fixedly connected with the corresponding fixed block, one end of the guide optical axis far away from the fixed block is fixedly connected with the fixed frame, the bearing mold rods are provided with a plurality of bearing mold rods, the bearing mold rods, and all perpendicular with the length direction of direction optical axis, expanding spring sets up between two adjacent load-bearing mold poles, has seted up a plurality of detection grooves on the load-bearing mold pole. The utility model has the advantages of detection efficiency is high.

Description

Scalability magnetism detection device

Technical Field

The utility model belongs to the technical field of the technique of magnetism detection device and specifically relates to a scalability magnetism detection device is related to.

Background

The existing device for carrying out magnetic detection on magnetic workpieces can generally realize N/S pole polarity detection on a single magnetic workpiece by using a single-pole Hall sensor, but when a plurality of magnetic workpieces are simultaneously subjected to polarity detection, if the arrangement distance between the magnetic workpieces is small, detection failure can be caused due to too close magnetic field distances of the adjacent magnetic workpieces (the fact that a magnetic pole of the adjacent magnetic workpiece triggers a Hall switch cannot be confirmed), and serious labor waste can be caused due to too low one-by-one detection efficiency of the single magnetic workpiece.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a scalability magnetism detection device, it has the advantage that detection efficiency is high.

The above utility model discloses an above-mentioned utility model purpose can realize through following technical scheme:

a scalability magnetic detection device comprises a bedplate, wherein four support legs are arranged on the bottom surface of the bedplate, the four support legs are respectively arranged at four corners of the bedplate, a bearing mechanism for holding a workpiece to be detected and a magnetic detection mechanism for detecting the workpiece in the bearing mechanism are arranged on the bedplate, the bearing mechanism comprises a bearing bottom plate, a fixing frame, fixing blocks, guide optical axes, bearing mold rods and a telescopic spring, the bearing bottom plate is arranged on the bedplate, the fixing frame and the fixing blocks are respectively arranged at two ends of the bearing bottom plate, the fixing blocks are provided with two fixing blocks, the two fixing blocks are respectively close to two sides of the bearing bottom plate, the two guide optical axes are respectively arranged on the two fixing blocks, one end of each guide optical axis is fixedly connected with the corresponding fixing block, one end of each guide optical axis far away from the fixing block is fixedly connected with the, many bear equal sliding connection of ejector half pole on two direction optical axes, bear and be parallel to each other between the ejector half pole, and all perpendicular with the length direction of direction optical axis, expanding spring sets up between two adjacent bearing half poles, two both sides faces that bear the ejector half pole and keep away from each other near the guide optical axis both ends respectively contradict with the both sides face that fixed block and fixed frame are close to each other, bear and set up a plurality of detection grooves that are used for holding the work piece of waiting to detect on the ejector half pole, detect the groove along the length direction evenly distributed of bearing the ejector half pole.

As a further aspect of the present invention: the magnetic detection mechanism comprises a Hall magnetic sensor, a PLC (programmable logic controller) and a display panel, a plurality of sensor mounting grooves are formed in the bearing die rod, the number of the sensor mounting grooves is equal to that of the detection grooves, the sensor mounting grooves correspond to the detection grooves one to one, the Hall magnetic sensor is mounted in the sensor mounting grooves and used for detecting magnetism of a workpiece to be detected in the adjacent detection grooves, the PLC and the display panel are arranged outside the bedplate, the PLC is electrically connected with the Hall magnetic sensor through a wire, and the display panel is electrically connected with the PLC through guiding.

As a further aspect of the present invention: the table plate is provided with an equidistant positioning mechanism for positioning the positions of the bearing mold rods, the equidistant positioning mechanism comprises two positioning cylinders, two positioning plates and two positioning cylinder mounting blocks, the two positioning cylinders, the two positioning plates and the two positioning cylinder mounting blocks are arranged, the two positioning plates are respectively mounted on output shafts of the two positioning cylinders, the two positioning cylinders are respectively mounted on the two positioning cylinder mounting blocks, the two positioning cylinder mounting blocks are respectively arranged on two sides of the bearing bottom plate, the two positioning plates are also arranged on two sides of the bearing bottom plate, and a plurality of separating slotted holes for uniformly separating the bearing mold rods are uniformly formed in the positions, close to each other, of the two positioning plates along the plate edge.

As a further aspect of the present invention: the pressing mechanism is used for enabling the adjacent bearing mold rods to be close to and pressed tightly and comprises a pressing cylinder, a stretching plate and a pressing plate, the pressing cylinder is installed on the platen through an installation plate, the pressing cylinder is located on the platen and located on one side, far away from the fixed block, of the fixed block, the stretching plate is fixed on an output shaft of the pressing cylinder, one end, far away from the pressing cylinder, of the stretching plate penetrates through an inner frame of the fixed frame and extends out from the lower portions of the bearing mold rods and is fixedly connected with the pressing plate, and one side, close to the stretching plate, of the pressing plate is abutted to one side, far away from the pressing cylinder, of the bearing.

As a further aspect of the present invention: the material transfer mechanism comprises a shifting cylinder, a shifting plate, two shifting shafts, two shifting guide shafts, a support plate, a guide plate and a delivery tinplate, wherein the shifting cylinder is installed on the bottom surface of the bedplate and is positioned under the bearing baseplate, the output shaft of the shifting cylinder faces to one side, far away from the pressing cylinder, of the fixed block, the shifting plate is fixed at one end, far away from the body of the shifting cylinder, of the output shaft of the shifting cylinder, the shifting plate is positioned at one side, far away from the pressing cylinder, of the fixed block, the shifting shafts are fixed at one side, far away from the ground, of the shifting plate, the two shifting guide shafts are fixed at one side, close to the fixed block, of the shifting plate and penetrate through the two fixed blocks respectively, the shifting guide shafts are in sliding connection with the corresponding fixed blocks, and one end, far away from the shifting plate, of the;

the carrier plate lid is established a plurality of on bearing the weight of the die rod, the carrier plate can attract the work piece that bears in the die rod, has seted up two and two on the carrier plate shift out the hole that shifts out axle adaptation, two shift out axles pass two respectively and shift out the hole, and then drive the carrier plate and remove, and the derivation plate lid is established and is kept away from at the carrier plate one side of bearing the die rod to realize the rigidity on fixed block and fixed frame through the location protruding axle, set up a plurality of and bear the weight of the corresponding shipment hole in detection slot on the die rod on the derivation plate, the shipment tinplate lid is established and is being kept away from one side of carrier plate in the derivation plate, and the work piece that the shipment tinplate can be in bearing the die rod is followed the detection slot and.

To sum up, the utility model discloses a beneficial technological effect does:

1. the plurality of detection grooves formed in the bearing die rod can accommodate a plurality of workpieces to be detected, the workpieces to be detected cannot be separated from the detection grooves due to mutual magnetic force in the detection grooves, and a subsequent magnetic detection mechanism can perform magnetic detection on the workpieces to be detected in the detection grooves more conveniently;

2. the Hall magnetic sensors are arranged in the sensor mounting grooves beside the detection grooves, can perform magnetic detection on the workpieces to be detected in the detection grooves, each detection groove corresponds to one sensor mounting groove, namely corresponds to one Hall magnetic sensor, and can detect all the workpieces to be detected on the bearing die rod, and signals obtained after detection of the Hall magnetic sensors are processed by the PLC controller and then displayed by the display panel to enable people to obtain detection results more intuitively;

3. when the separating slotted holes on the positioning plate can force the bearing mold rods to be arranged at equal intervals, the intervals are set by people according to the fact that the adjacent workpieces to be detected are not interacted, the bearing mold rods are forcedly positioned through the separating slotted holes, so that the workpieces to be detected on the adjacent bearing mold rods are not influenced, and the result measured by the Hall magnetic sensor is more accurate;

4. after the workpiece is detected, the pressing air cylinder can drive the plurality of bearing die rods to mutually approach, so that the detected workpiece is more concentrated, and the subsequent workpiece collection is more convenient;

5. the support plate can absorb the work piece after being located the detection in detecting the groove, start and shift out the cylinder, it drives and shifts out the board action to shift out the cylinder, and then drive and shift out the axle action, it can take out the support plate from deriving the board and bearing between the die rod to shift out the axle, at this moment, the work piece that originally adsorbs on the support plate can pass on the derivation board corresponding shipment hole adsorb onto shipment tin plate, later people will adsorb the shipment tin plate that has the work piece and take off from deriving the board, the collection of work piece has been accomplished promptly, it is next material support plate that handles the work piece to adsorb the shipment tin plate that has the work piece, can directly be used for the work of next processing work piece.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention with the carrier plate, the guide plate and the delivery tin plate removed;

fig. 3 is a schematic sectional structure of the present invention;

FIG. 4 is an enlarged schematic view of portion A of FIG. 2;

fig. 5 is an enlarged schematic view of a portion B in fig. 1.

In the figure, 1, a platen; 2. a support leg; 3. a carrying mechanism; 31. a load floor; 32. a fixing frame; 33. a fixed block; 34. guiding the optical axis; 35. carrying a mold rod; 36. a tension spring; 351. a spring mounting groove; 353. a detection tank; 41. a Hall magnetic sensor; 42. a display panel; 352. a sensor mounting groove; 5. an equidistant positioning mechanism; 51. positioning the air cylinder; 52. positioning a plate; 53. positioning a cylinder mounting block; 521. separating the slots; 6. a hold-down mechanism; 61. a pressing cylinder; 62. stretching the plate; 63. a compression plate; 611. mounting a plate; 7. a material transfer mechanism; 71. moving out the cylinder; 72. removing the plate; 73. removing the shaft; 74. moving out the guide shaft; 75. a carrier plate; 76. a lead-out plate; 77. discharging tin plate; 761. positioning the convex shaft; 762. and (7) a goods outlet.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1-5, a scalable magnetic detection device comprises a bedplate 1, wherein four support legs 2 are mounted on the bottom surface of the bedplate 1, and the four support legs 2 are respectively fixed at four corners of the bedplate 1. The bedplate 1 is provided with a bearing mechanism 3 for containing a workpiece to be detected and a magnetic detection mechanism for detecting the workpiece in the bearing mechanism 3. The bearing mechanism 3 comprises a bearing bottom plate 31, a fixing frame 32, a fixing block 33, a guide optical axis 34, a bearing mold rod 35 and an expansion spring 36. The load floor 31 is mounted on the deck 1, and the fixing frame 32 and the fixing block 33 are fixed to both ends of the load floor 31, respectively. The two fixing blocks 33 are arranged, and the two fixing blocks 33 are respectively close to two sides of the bearing bottom plate 31. Two guide optical axes 34 are provided, the two guide optical axes 34 are respectively fixed on the two fixing blocks 33, one end of each guide optical axis 34 is fixedly connected with the corresponding fixing block 33, and one end of each guide optical axis 34 far away from the corresponding fixing block 33 is fixedly connected with the fixing frame 32. The mold carrying rods 35 are provided with a plurality of pieces, and the length directions of the plurality of mold carrying rods 35 are parallel to each other. Bear and offer two and the mutual direction slide opening that corresponds of two direction optical axes 34 on the mould pole 35, direction optical axis 34 passes the corresponding direction slide opening on a plurality of mould poles 35 that bear in proper order for many bear mould poles 35 homoenergetic sliding connection on two direction optical axes 34. The length direction of the mold-carrying rod 35 is perpendicular to the length direction of the guide optical axis 34.

Spring mounting grooves 351 have been all seted up on two sides that adjacent two bear mould pole 35 is close to each other, and spring mounting grooves 351 on two adjacent bear mould pole 35 correspond and communicate with each other to spring mounting grooves 351 can set up a plurality ofly on the side that bears mould pole 35, and a plurality of spring mounting grooves 351 are along the length direction evenly distributed who bears mould pole 35. The extension spring 36 is disposed between two adjacent mold bars 35, and both ends of the extension spring 36 are respectively fixed in two corresponding spring mounting grooves 351 of the two mold bars 35. The extension springs 36 can space the adjacent mold bars 35 apart from each other, so as to prevent the adjacent mold bars 35 from being too close to each other, thereby achieving a coarse positioning of the mold bars 35.

Two sides of the two mold-carrying rods 35 close to the two ends of the guide optical axis 34, which are far away from each other, respectively abut against two sides of the fixed block 33 and the fixed frame 32, which are close to each other. The bearing mold rod 35 is provided with a plurality of detection grooves 353 used for accommodating workpieces to be detected, and the detection grooves 353 are uniformly distributed along the length direction of the bearing mold rod 35. The workpiece to be detected is placed in the detection tank 353.

The magnetism detection mechanism includes a hall magnetic sensor 41, a PLC controller, and a display panel 42. Bearing the weight of and having seted up a plurality of sensor mounting grooves 352 on the mould pole 35, the quantity of sensor mounting groove 352 equals with the quantity that detects groove 353 to the one-to-one, sensor mounting groove 352 is close to the detection groove 353 that corresponds. The hall magnetic sensor 41 is installed in the sensor installation groove 352 for performing magnetic detection on the workpiece to be detected in the adjacent detection groove 353. A PLC controller (not shown in the figure) and a display panel 42 are provided outside the platen 1, and the PLC controller is electrically connected to the hall magnetic sensors 41 through wires, and the display panel 42 is electrically connected to the PLC controller through a guide. The hall magnetic sensor 41 can detect the polarity of the workpiece in the adjacent detection groove 353, the detection result is displayed by the display panel 42 after the signal obtained by detection is processed by the PLC controller, and people can easily know the detection result through the display panel 42.

The bedplate 1 is provided with an equidistant positioning mechanism 5 for positioning the position of the carrying mold rod 35, and the equidistant positioning mechanism 5 comprises a positioning cylinder 51, a positioning plate 52 and a positioning cylinder mounting block 53. The positioning cylinders 51, the positioning plates 52 and the positioning cylinder mounting blocks 53 are all provided with two, the two positioning plates 52 are respectively mounted on the output shafts of the two positioning cylinders 51, the two positioning cylinders 51 are respectively mounted on the two positioning cylinder mounting blocks 53, the two positioning cylinder 51 mounting blocks are respectively arranged on two sides of the bearing bottom plate 31, the two positioning plates 52 are respectively located on two sides of the bearing bottom plate 31, and a plurality of separating slotted holes 521 which can uniformly separate a plurality of bearing mold rods 35 are uniformly formed in the positions of the plates which are close to each other of the two positioning plates 52. The positioning cylinder 51 can drive the positioning plate 52 to be close to the bearing mold rod 35, the positioning plate 52 is close to the in-process of bearing mold rod 35, the groove rods on two sides of the partition groove hole 521 can be inserted into the gap between the adjacent bearing mold rods 35 after coarse positioning, the equidistant positioning of the bearing mold rods 35 is realized, and further the proper distance for installing the workpieces to be tested is arranged, the precise positioning of the workpieces to be tested is realized, the mutual influence between the workpieces to be tested on the adjacent bearing mold rods 35 is reduced, and the correctness of the polarity detection of the workpieces to be tested by the Hall magnetic sensor 41 is ensured.

The platen 1 is provided with a pressing mechanism 6 for approaching and pressing the adjacent carrying mold rods 35, and the pressing mechanism 6 comprises a pressing cylinder 61, a stretching plate 62 and a pressing plate 63. The pressing cylinder 61 is installed on the bedplate 1 through the installation plate 611, the pressing cylinder 61 is located on the bedplate 1 on one side of the fixing frame 32 far away from the fixing block 33, the stretching plate 62 is fixed on an output shaft of the pressing cylinder 61, one end, far away from the pressing cylinder 61, of the stretching plate 62 penetrates through the inner frame of the fixing frame 32 and extends out from the lower portion of the plurality of bearing mold rods 35 and is fixedly connected with the pressing plate 63, and one side, close to the stretching plate 62, of the pressing plate 63 is abutted against one side, far away from the pressing cylinder 61, of the bearing bottom.

The utility model discloses still include material transport mechanism 7, material transport mechanism 7 is including removing cylinder 71, removing plate 72, removing axle 73, removing guiding axle 74, support plate 75, derivation board 76 and shipment tin plate 77. The removing cylinder 71 is mounted on the bottom surface of the platen 1 and is located right below the bearing bottom plate 31, and the output shaft of the removing cylinder 71 faces the side of the fixed block 33 away from the pressing cylinder 61. The moving-out plate 72 is fixed at one end of the output shaft of the moving-out cylinder 71 far away from the cylinder body of the moving-out cylinder 71, and the moving-out plate 72 is positioned at one side of the fixed block 33 far away from the pressing cylinder 61. Two moving-out shafts 73 are provided, and both the two moving-out shafts 73 are fixed on the side of the moving-out plate 72 away from the ground. Two shift-out guide shafts 74 are provided, and both of the shift-out guide shafts 74 are fixed to the side of the shift-out plate 72 near the fixed block 33. The two fixing blocks 33 are respectively provided with sliding holes matched with the two moving-out guide shafts 74, the two moving-out guide shafts 74 respectively penetrate through the two corresponding sliding holes, and the moving-out guide shafts 74 are in sliding connection with the corresponding fixing blocks 33. The end of the removal guide shaft 74 remote from the removal plate 72 is close to the fixed frame 32.

The carrier plate 75 covers the plurality of carrying mold rods 35, the carrier plate 75 can attract workpieces in the carrying mold rods 35, two moving-out holes matched with the two moving-out shafts 73 are formed in the carrier plate 75, and the two moving-out shafts 73 respectively penetrate through the two moving-out holes. The leading-out plate 76 is covered on one side of the carrier plate 75 far away from the mold-supporting rod 35, a positioning hole is formed in the leading-out plate 76, a positioning convex shaft 761 matched with the positioning hole is fixed on the fixed block 33 and the fixed frame 32, and the positioning convex shaft 761 is inserted into the corresponding positioning hole to fix the position of the leading-out plate 76 on the fixed block 33 and the fixed frame 32. The delivery plate 76 is provided with a plurality of delivery holes matched with the size of the notch of the detection groove 353 on the bearing mold rod 35. The delivery carriage 77 covers the side of the output plate 76 remote from the carrier plate 75.

The shipment saddle 77 is a material carrier plate used in the next processing step after the magnetism of the workpiece is detected, and the detected workpiece is adsorbed on the shipment saddle and can be directly used for the production of the next step.

The implementation principle of the embodiment is as follows: when people use the utility model to perform magnetic detection on a workpiece to be detected, firstly, the positioning cylinder 51 is started, the positioning cylinder 51 pushes the positioning plate 52 to be close to the carrying mold rod 35, the separating slotted hole 521 on the positioning plate 52 accurately positions the carrying mold rod 35, then the workpiece to be detected is sequentially arranged on the carrier plate 75 according to the positions between the detection grooves 353 on the carrying mold rod 35, the workpiece to be detected is sucked on the carrier plate 75, then the carrier plate 75 with the sucked workpiece to be detected is reversely buckled on the carrying mold rod 35, the moving shaft 73 is inserted into the corresponding moving-out hole on the carrier plate 75, the carrier plate 75 is reversely buckled on the carrying mold rod 35 to enable the workpiece to be detected to be accurately placed into the corresponding detection groove 353, then the Hall magnetic sensor 41 performs magnetic detection on the workpiece in the detection groove 353, the Hall magnetic sensor 41 obtains a signal and displays a detection result by the display panel 42 after being processed by PLC control, the magnetic detection of the workpieces is realized, when the magnetic detection is carried out, all the workpieces to be detected in the multiple bearing die rods 35 can be detected simultaneously, the detection speed is far higher than the speed of manual single detection, and the detection speed of the workpieces to be detected is improved;

when people need to take out a detected workpiece from the die-bearing rods 35, firstly, the positioning cylinder 51 is started to enable the positioning cylinder 51 to drive the positioning plate 52 to be far away from the die-bearing rods 35, the position fixing of the die-bearing rods 35 is cancelled, then the positioning holes on the leading-out plate 76 are aligned with the positioning convex shafts 761 on the fixed block 33 and the fixed frame 32, the leading-out plate 76 is covered on the carrier plate 75, then the goods-discharging tinplate 77 is covered on the leading-out plate 76, then the pressing cylinder 61 is started, the pressing cylinder 61 drives the pressing plate 63 to push the die-bearing rods 35 to move towards the direction close to the pressing cylinder 61 through the stretching plate 62, the expansion springs 36 between the die-bearing rods 35 are compressed into the corresponding spring mounting grooves 351, the adjacent die-bearing rods 35 are finally abutted against each other, then the shifting-out cylinder 71 is started, the shifting-out cylinder 71 drives the carrier plate 75 to be pulled out from between the fixed block 33 and the leading, the detected workpiece can be slowly separated from the detection groove 353 under the attraction of the goods outlet tinplate 77 after being separated from the carrier plate 75, and passes through the corresponding goods outlet hole 762 on the lead-out plate 76 to be sucked onto the goods outlet tinplate 77, then the goods outlet tinplate 77 is taken down to realize the taking-out of the detected workpiece, the detected workpiece sucked on the goods outlet tinplate 77 can be directly used for the application of subsequent equipment, and the time for people to manually take the detected workpiece out of the detection groove 353 is greatly saved.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (5)

1. A scalable magnetic assay device comprising a platen (1), characterized by: four supporting legs (2) are installed on the bottom surface of a bedplate (1), the four supporting legs (2) are respectively arranged at four corners of the bedplate (1), a bearing mechanism (3) used for containing a workpiece to be detected and a magnetic detection mechanism used for detecting the workpiece in the bearing mechanism (3) are arranged on the bedplate (1), the bearing mechanism (3) comprises a bearing bottom plate (31), a fixed frame (32), fixed blocks (33), guide optical axes (34), bearing mold rods (35) and a telescopic spring (36), the bearing bottom plate (31) is installed on the bedplate (1), the fixed frame (32) and the fixed blocks (33) are respectively arranged at two ends of the bearing bottom plate (31), the fixed blocks (33) are provided with two blocks, the two fixed blocks (33) are respectively close to two sides of the bearing bottom plate (31), the guide optical axes (34) are provided with two blocks, the two guide optical axes (34) are respectively arranged on the two fixed blocks (33), one end of each guide optical axis (34) is fixedly connected with the corresponding fixed block (33), one end of each guide optical axis (34) far away from the corresponding fixed block (33) is fixedly connected with the fixed frame (32), a plurality of bearing mold rods (35) are arranged, the bearing mold rods (35) are all connected to the two guide optical axes (34) in a sliding manner, the bearing mold rods (35) are parallel to each other, and all perpendicular with the length direction of direction optical axis (34), expanding spring (36) set up and bear between two adjacent die rod (35), two both sides face that bear die rod (35) keeping away from each other that are close to direction optical axis (34) both ends respectively contradict with the both sides face that fixed block (33) and fixed frame (32) are close to each other, bear and offer a plurality of detection groove (353) that are used for holding the work piece of waiting to detect on die rod (35), detect groove (353) along the length direction evenly distributed who bears die rod (35).

2. A scalable magnetic test device according to claim 1, wherein: the magnetic detection mechanism comprises a Hall magnetic sensor (41), a PLC (programmable logic controller) and a display panel (42), a plurality of sensor mounting grooves (352) are formed in the bearing mold rod (35), the number of the sensor mounting grooves (352) is equal to that of the detection grooves (353), the sensor mounting grooves (352) are in one-to-one correspondence with the detection grooves (353), the Hall magnetic sensor (41) is mounted in the sensor mounting grooves (352) and used for carrying out magnetic detection on a workpiece to be detected in the adjacent detection grooves (353), the PLC and the display panel (42) are both arranged outside the bedplate (1), the PLC is electrically connected with the Hall magnetic sensor (41) through a wire, and the display panel (42) is electrically connected with the PLC through guiding.

3. A scalable magnetic test device according to claim 2, wherein: the bedplate (1) is provided with an equidistant positioning mechanism (5) for positioning the position of the bearing mold rod (35), the equidistant positioning mechanism (5) comprises two positioning cylinders (51), two positioning plates (52) and two positioning cylinder mounting blocks (53), the two positioning cylinders (51), the two positioning plates (52) and the two positioning cylinder mounting blocks (53) are respectively arranged on output shafts of the two positioning cylinders (51), the two positioning cylinders (51) are respectively arranged on the two positioning cylinder mounting blocks (53), the two positioning cylinder mounting blocks (51) are respectively arranged on two sides of the bearing bottom plate (31), the two positioning plates (52) are also arranged on two sides of the bearing bottom plate (31), a plurality of separating slotted holes (521) used for uniformly separating the plurality of bearing die rods (35) are uniformly formed at the plate edges of the two positioning plates (52) close to each other.

4. A scalable magnetic test device according to claim 2, wherein: a pressing mechanism (6) used for enabling the adjacent bearing mold rods (35) to approach and press is arranged on the bedplate (1), the pressing mechanism (6) comprises a pressing cylinder (61), the pressing mechanism comprises a stretching plate (62) and a pressing plate (63), wherein the pressing cylinder (61) is installed on the bedplate (1) through an installation plate (611), the pressing cylinder (61) is located on one side, away from the fixed block (33), of the fixed frame (32) on the bedplate (1), the stretching plate (62) is fixed on an output shaft of the pressing cylinder (61), one end, away from the pressing cylinder (61), of the stretching plate (62) penetrates through an inner frame of the fixed frame (32) and extends out of the lower portions of the bearing mold rods (35) and is fixedly connected with the pressing plate (63), and one side, close to the stretching plate (62), of the pressing plate (63) is abutted to one side, away from the pressing cylinder (61), of the bearing bottom plate (31).

5. The scalable magnetic test device of claim 4, wherein: the material transferring mechanism (7) comprises a shifting-out air cylinder (71), a shifting-out plate (72), a shifting-out shaft (73), a shifting-out guide shaft (74), a carrier plate (75), a lead-out plate (76) and a goods outlet tinplate (77), wherein the shifting-out air cylinder (71) is installed on the bottom surface of the bedplate (1) and is positioned under the bearing bottom plate (31), an output shaft of the shifting-out air cylinder (71) faces to one side, away from the pressing air cylinder (61), of the fixed block (33), the shifting-out plate (72) is fixed at one end, away from the body of the shifting-out air cylinder (71), of the output shaft of the shifting-out air cylinder (71), the shifting-out plate (72) is positioned at one side, away from the pressing air cylinder (61), of the fixed block (33), the shifting-out shaft (73) is fixed at one side, away from the ground, of the shifting-out plate (72), the shifting-out guide shaft (74) is provided with two shifting-out, the two fixing blocks (33) are respectively penetrated through, the moving-out guide shaft (74) is in sliding connection with the corresponding fixing block (33), and one end, far away from the moving-out plate (72), of the moving-out guide shaft (74) is close to the fixing frame (32);

the carrier plate (75) is covered on the plurality of the carrying mold rods (35), the carrier plate (75) can attract workpieces in the carrying mold rods (35), two moving-out holes matched with the two moving-out shafts (73) are formed in the carrier plate (75), the two moving-out shafts (73) respectively penetrate through the two moving-out holes, thereby driving the carrier plate (75) to move, the lead-out plate (76) is covered on one side of the carrier plate (75) far away from the carrying mold rod (35), the position fixing on the fixing block (33) and the fixing frame (32) is realized through the positioning protruding shaft (761), a plurality of goods outlet holes (762) corresponding to the detection grooves (353) on the bearing mold rod (35) are formed in the guide-out plate (76), the goods outlet tinplate (77) is arranged on one side, far away from the carrier plate (75), of the guide-out plate (76) in a covering mode, and the goods outlet tinplate (77) can suck workpieces in the bearing mold rod (35) from the detection grooves (353).

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