CN211337818U - Upper and lower layer transfer mechanism for industrial X-ray detection - Google Patents

Abstract

The utility model discloses an upper and lower floor transport mechanism for industrial X-ray detection. The transfer mechanism comprises a bracket, a turning plate, a swing rod and a side locking plate, wherein one end of the turning plate is movably arranged in the middle of the bracket; the swing rod is arranged in the middle of the turning plate and can rotate, and one end of the swing rod penetrates through the side face of the turning plate; the upper end of the side locking plate is connected with the bracket, and the lower end of the side locking plate is locked by the clamping of the end part of the swing rod exposed out of the side surface of the turning plate; wherein, the middle part of support is installed one and can be overturned the cylinder, and the piston rod of cylinder is connected with turning over the board. The upper and lower layer transfer mechanism for industrial X-ray detection in the utility model is divided into an upper layer and a lower layer, thus reducing the floor area of the equipment; the carrier is transferred from the upper-layer conveying belt to the lower-layer conveying belt through the carrier falling mechanism, and the manual carrying is reduced, the labor intensity is reduced, and the production efficiency is improved by utilizing the gravity; in addition, the falling of the carrier is controlled through the air cylinder, so that the noise is reduced, and the abrasion consumption of related structures is reduced.

Description

Upper and lower layer transfer mechanism for industrial X-ray detection

Technical Field

The utility model relates to a detection device field, in particular to a transport mechanism on upper and lower layers for industrial X-ray detection.

Background

The industrial X-ray detection equipment detects products as assembly line operation, the products to be detected are placed on a flat carrier, then the products are conveyed to an X-ray detection machine in a lead room through devices such as a conveying belt and the like for detection, and after the detection is finished, the products are conveyed out through the conveying belt.

In the prior art, products are generally transported between devices such as an X-ray detector through a conveyor belt, and the conveyor belt is often long due to the large volume of the X-ray detector and a lead room where the X-ray detector is located, so that the conveyor belt occupies a large working space. For this reason, it is conceivable to further utilize the space occupied by the X-ray detection device.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a lower floor transport mechanism for industrial X-ray detection.

According to the utility model discloses an aspect provides a lower floor transport mechanism for industrial X-ray detection, include:

the upper layer conveying belt and the lower layer conveying belt are respectively paved above and below the support;

one end of the turning plate is movably arranged in the middle of the bracket and can rotate;

the swing rod is mounted in the middle of the turning plate and can rotate, and one end of the swing rod penetrates through the side face of the turning plate;

the upper end of the side locking plate is connected with the bracket, the lower end of the side locking plate is clamped and locked by the end part of the swing rod exposed out of the side surface of the turnover plate, and the side locking plate is unlocked when the swing rod rotates;

the middle part of the support is provided with a cylinder capable of turning, and a piston rod of the cylinder is connected with the turning plate.

The upper and lower layer transfer mechanism for industrial X-ray detection in the utility model is divided into an upper layer and a lower layer, thus reducing the floor area of the equipment; the carrier is transferred from the upper-layer conveying belt to the lower-layer conveying belt through the carrier falling mechanism, and the manual carrying is reduced, the labor intensity is reduced, and the production efficiency is improved by utilizing the gravity; in addition, the falling of the carrier is controlled through the air cylinder, so that the noise is reduced, and the abrasion consumption of related structures is reduced.

In some embodiments, the support comprises two opposite vertical frames, two upper frames are arranged at the tops of the two vertical frames, two lower frames are arranged at the lower parts of the two vertical frames, and the upper-layer conveyor belt and the lower-layer conveyor belt are respectively laid on the two upper frames and the two lower frames; the turning plate and the air cylinder are movably arranged between the two vertical frames, and one end of the side locking plate is connected with one upper frame. Thereby, the specific structure of the bracket and the direct connection relationship between the bracket and part of the mechanism are arranged.

In some embodiments, a transverse plate is arranged in the middle of the turning plate, a raised vertical plate is arranged on the transverse plate, and a through groove is arranged in the middle of the vertical plate; and the other end of the swing rod penetrates through the through groove. Therefore, the specific structure of the turning plate is arranged and used for receiving the carrier and turning over.

In some embodiments, the middle part of the swing rod is movably mounted on the transverse plate, one end of the swing rod is provided with a folded plate penetrating through the through groove, and the tail end of the folded plate is provided with an upward protruding pressing plate. Therefore, the specific structure and position of the swing rod are arranged, and the swing rod can be separated from the side locking plate to be unlocked when being pressed by the carrier.

In some embodiments, the side lock plate is provided with a hook body protruding upwards on the lower end side, and the hook body can be locked with the end part of the swing rod exposed on the side of the turning plate in a clamping manner. From this, set up the concrete structure of side jam plate, it can pin the board that turns over to it breaks away from the unblock with it when the pendulum rod receives the carrier to press.

In some embodiments, an end locking piece is movably installed at the other end of the turning plate, and an unlocking frame corresponding to the end locking piece is installed at the lower part of the bracket. Therefore, after the turnover plate is turned to the lower side through the end locking piece and the unlocking frame, the carriers on the turnover plate slide onto the lower-layer conveying belt smoothly.

In some embodiments, one end of the end lock is a side piece movably mounted on the outer side of the flap and connected with the flap through a spring; wherein, a bump is also formed on the side sheet. Thereby, a portion of the structure of the end lock is provided.

In some embodiments, the other end of the end lock is a bottom plate extending to the bottom of the flap, and a stop is formed above the bottom plate. Thereby, another partial structure of the end lock is provided, wherein the catch can be used to limit the position of the carrier.

In some embodiments, the unlocking frame comprises a vertical support, and the top of the support is provided with a sloping plate which corresponds to the side piece. Therefore, the specific structure of the unlocking frame is provided, wherein the inclined plate can be contacted with the side plate by turning the corresponding finger turning plate.

In some embodiments, the cylinder is mounted on a mounting bar, the mounting bar being movably mounted on the bracket; the piston rod of the air cylinder is connected with a connecting rod, and the connecting rod is connected with the turning plate. From this, set up the mounting means of cylinder, it can control the board and overturn.

Drawings

Fig. 1 is a schematic structural view of an upper and lower layer transfer mechanism for industrial X-ray detection according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of the stent shown in FIG. 1;

FIG. 3 is a schematic structural view of the turnover mechanism shown in FIG. 1;

FIG. 4 is a schematic structural view of the turning plate shown in FIG. 3;

FIG. 5 is a schematic structural diagram of the swing link shown in FIG. 3;

FIG. 6 is a schematic view of the end lock of FIG. 3;

FIG. 7 is a schematic view of the connection of the flap of FIG. 3 with the end lock;

fig. 8 is a schematic structural view of the unlocking frame shown in fig. 3.

In the figure: the device comprises a support 1, an upper layer conveyor belt 2, a turning plate 3, a swing rod 4, a side locking plate 5, an end locking piece 6, an unlocking frame 7, a cylinder 8, a carrier 9, a vertical frame 11, an upper frame 12, a lower frame 13, a cross beam 14, a lower layer conveyor belt 21, a transverse plate 31, a vertical plate 32, a through groove 33, a spring 34, a folded plate 41, a pressing plate 42, a hook body 51, a side plate 61, a convex block 62, a bottom plate 63, a blocking piece 64, a support 71, an inclined plate 72, an installation rod 81 and a connecting rod 82.

Detailed Description

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

Fig. 1 schematically shows a structure of a structure schematic of an upper and lower layer transfer mechanism for industrial X-ray detection according to an embodiment of the present invention, and fig. 2 shows a structure of a support in fig. 1; FIG. 3 shows the construction of the flap turnover mechanism of FIG. 1; FIG. 4 shows the construction of the flap of FIG. 3; FIG. 5 shows the structure of the rocker in FIG. 3; FIG. 6 shows the end lock configuration of FIG. 3; FIG. 7 shows the arrangement of FIG. 3 with the flap connected to the end lock; fig. 8 shows the structure of the unlocking frame in fig. 3. As shown in fig. 1-8, the transfer mechanism mainly comprises a bracket 1, and other mechanisms are directly or indirectly arranged on the bracket 1. The support 1 comprises two opposite vertical frames 11, two upper frames 12 are arranged at the tops of the two vertical frames 11, two lower frames 13 are arranged at the lower parts of the two vertical frames 11, and a turning plate 3 and an air cylinder 8 which are connected are movably arranged in the middle of the support 1. Wherein, upper conveyer belt 2 and lower floor's conveyer belt 21 have been laid respectively on two upper framves 12 and two lower framves 13, and the type shape of upper conveyer belt 2 and lower floor's conveyer belt 21 can be different, for example upper conveyer belt 2 is two thin bands that are parallel to each other, and lower floor's conveyer belt 21 is a wider band, and each conveyer belt all is used for conveying the carrier 9 that can carry the product. In addition, cross members 14 may be provided between the two uprights 11 for improved stability and rigidity.

The flap 3 is substantially rectangular, with one short side of the flap being movably mounted between the two vertical supports 11 and the other end being able to rotate about this end, the upper and lower limits of rotation being close to the upper and lower conveyors 21, respectively. Wherein, a transverse plate 31 parallel to the short side is arranged in the middle of the turning plate 3, a raised vertical plate 32 is arranged on the transverse plate 31, and a through groove 33 is arranged in the middle of the vertical plate 32.

A swing rod 4 is movably arranged in the middle of the turning plate 3, wherein the swing rod 4 is arranged on the transverse plate 31 through the middle part. The swing rod 4 is roughly in a long strip shape, one end of the swing rod is provided with a folded plate 41, the folded plate 41 penetrates through the through groove 33 on the turning plate 3, the tail end of the folded plate 41 extends to the other side of the vertical plate 32, and the tail end of the folded plate 41 is provided with a pressing plate 42 protruding upwards; and the other end of the swing rod 4 penetrates through the long edge of one side face of the turning plate 3. Wherein, when the pressing plate 42 is pressed to move towards the vertical plate 32, the swing link 4 can rotate.

And a vertical side locking plate 5 is arranged outside the side surface of the turning plate 3, wherein the upper end of the side locking plate 5 is connected with one upper frame 12 of the bracket 1, and the lower end of the side locking plate 5 is clamped and locked by the end part of the swing rod 4 exposed out of the side surface of the turning plate 3, and can be separated and unlocked after the swing rod 4 rotates. The side lock plate 5 has a hook 51 protruding upward on a lower end side thereof, and the end of the rocker 4 can be engaged with the hook 51.

An end lock 6 is mounted at the free end of the flap 3. One end of the end locking piece 6 is a side piece 61, the side piece 61 is movably arranged outside one long side of the turning plate 3 and can rotate in a vertical plane, and the long side of the turning plate 3 is connected through a spring 34. In addition, a projection 62 is formed on the side piece 61.

And the other end of end lock 6 is a bottom plate 63, bottom plate 63 extending to the bottom of flap 3 and a stop 64 formed above bottom plate 63. Wherein, in a normal condition, the spring 34 is compressed so that the upper end of the catch 64 is higher than the movable end of the flap 3 and descends when the side piece 61 rotates.

An unlocking frame 7 is arranged on the lower frame 13 at the lower part of the bracket 1, the unlocking frame 7 comprises a vertical support 71, the top of the support 71 is provided with a sloping plate 72, and the top surface of the sloping plate 72 is inclined upwards and corresponds to the lug 62 on the side piece 61 of the end locking piece 6. The correspondence here means that when the flap 3 is rotated to move the movable end thereof downward, the sloping plate 72 can come into contact with the side sheet 61 so that the side sheet 61 rotates.

The cylinder 8 is mounted on a horizontal mounting rod 81, the mounting rod 81 being mounted between the two uprights 11 of the support 1 and being able to rotate. The piston rod of the cylinder 8 is connected to a horizontal connecting rod 82, and the connecting rod 82 is connected to the flap 3. Wherein, the cylinder 8 can control the overturning speed of the turnover plate 3 through the connecting rod 82.

Furthermore, the carrier 9 for carrying the products is a square plate, the size of which is approximately half of the size of the flap 3.

When using this transport mechanism, set up pendulum rod 4 and side locking plate 5 block and pin for turning over board 3 and stably placing in the slant, its expansion end is located the top and is relative with upper conveyer belt 2, and the carrier 9 that bears the weight of the product at this moment moves to this department through the transmission of upper conveyer belt 2, and can fall on turning over board 3.

And when carrier 9 falls to turning over board 3 on, carrier 9 can be in the centre by the diaphragm 31 of turning over board 3 and the separation blade 64 restriction of tip latch fitting 6, and the front end of carrier 9 can contact the clamp plate 42 of pendulum rod 4 and exert pressure to it for pendulum rod 4 rotates and breaks away from the unblock with side jam plate 5, then turn over board 3 and overturn downwards at the action of gravity, drive carrier 9 and product upset together simultaneously, can turn over the speed that board 3 overturned through cylinder 8 control this moment, in order to avoid its expansion end direct whereabouts to send great noise, and produce great impact and cause wearing and tearing to relevant structure.

After the movable end of the turning plate 3 is turned to the lower part, the projection 62 of the side piece 61 of the end locking piece 6 is in contact with the inclined plate 72 of the support 71, and presses the side piece 61 to rotate through the projection 62, so that the blocking piece 64 of the end locking piece 6 rotates and descends, and then the carrier 9 can slide and be transferred onto the lower layer conveyor belt 21, and other equipment is conveyed for subsequent detection and processing.

Finally, the transfer mechanism is manually reset, and then the next carrier 9 and the products thereon can be transferred.

The upper and lower layer transfer mechanism for industrial X-ray detection in the utility model is divided into an upper layer and a lower layer, thus reducing the floor area of the equipment; the carrier is transferred from the upper-layer conveying belt to the lower-layer conveying belt through the carrier falling mechanism, and the manual carrying is reduced, the labor intensity is reduced, and the production efficiency is improved by utilizing the gravity; in addition, the falling of the carrier is controlled through the air cylinder, so that the noise is reduced, and the abrasion consumption of related structures is reduced.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (10)

1. The utility model provides a lower floor transport mechanism for industrial X-ray detection which characterized in that:

the device comprises a support (1), wherein an upper layer conveyor belt (2) and a lower layer conveyor belt (21) are respectively paved above and below the support (1);

one end of the turning plate (3) is movably arranged in the middle of the bracket (1) and can rotate;

the swing rod (4) is mounted in the middle of the turning plate (3) and can rotate, and one end of the swing rod (4) penetrates through the side face of the turning plate (3);

the upper end of the side locking plate (5) is connected with the bracket (1), the lower end of the side locking plate (5) is clamped and locked by the end part of the swing rod (4) exposed out of the side surface of the turning plate (3), and the side locking plate is unlocked when the swing rod (4) rotates;

the middle part of the bracket (1) is provided with a cylinder (8) capable of turning, and a piston rod of the cylinder (8) is connected with the turning plate (3).

2. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 1, wherein: the support (1) comprises two vertical frames (11) which are oppositely arranged, two horizontal upper frames (12) are arranged at the tops of the two vertical frames (11), two horizontal lower frames (13) are arranged at the lower parts of the two vertical frames (11), and the upper-layer conveyor belt (2) and the lower-layer conveyor belt (21) are respectively laid on the two upper frames (12) and the two lower frames (13); the turning plate (3) and the air cylinder (8) are movably arranged between the two vertical frames (11), and one end of the side locking plate (5) is connected with one upper frame (12).

3. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 1, wherein: a transverse plate (31) is arranged in the middle of the turning plate (3), a raised vertical plate (32) is arranged on the transverse plate (31), and a through groove (33) is arranged in the middle of the vertical plate (32); the other end of the swing rod (4) penetrates through the through groove (33).

4. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 3, wherein: the middle part of the swing rod (4) is movably arranged on the transverse plate (31), one end of the swing rod is provided with a folded plate (41) penetrating through the through groove (33), and the tail end of the folded plate (41) is provided with a pressing plate (42) protruding upwards.

5. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 1, wherein: the side lock is characterized in that a hook body (51) protruding upwards is arranged on the side face of the lower end of the side lock plate (5), and the hook body (51) can be clamped and locked with the end part, exposed out of the side face of the turning plate (3), of the swing rod (4).

6. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 1, wherein: an end part locking piece (6) is movably installed at the other end of the turning plate (3), and an unlocking frame (7) corresponding to the end part locking piece (6) is installed at the lower part of the support (1).

7. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 6, wherein: one end of the end locking piece (6) is provided with a side piece (61), the side piece (61) is movably arranged on the outer side of the turning plate (3) and is connected with the turning plate (3) through a spring (34); wherein, a bump (62) is also formed on the side piece (61).

8. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 7, wherein: the other end of the end locking piece (6) is a bottom plate (63) extending to the bottom of the turning plate (3), and a blocking piece (64) is formed above the bottom plate (63).

9. An upper and lower layer transfer mechanism for industrial X-ray detection according to claim 7, wherein: the unlocking frame (7) comprises a vertical support (71), an inclined plate (72) is arranged at the top of the support (71), and the inclined plate (72) corresponds to the side piece (61).

10. An upper and lower layer transfer mechanism for industrial X-ray detection according to any one of claims 1 to 9, wherein: the cylinder (8) is arranged on an installation rod (81), and the installation rod (81) is movably arranged on the bracket (1); the piston rod of the air cylinder (8) is connected with a connecting rod (82), and the connecting rod (82) is connected with the turning plate (3).

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