CN223717760U

CN223717760U - A metal alloy rigidity testing device

Info

Publication number: CN223717760U
Application number: CN202423081457.8U
Authority: CN
Inventors: 穆吉增
Original assignee: Shandong Boxing County Ruihai Steel Plate Co ltd
Current assignee: Shandong Boxing County Ruihai Steel Plate Co ltd
Priority date: 2024-12-13
Filing date: 2024-12-13
Publication date: 2025-12-26
Anticipated expiration: 2034-12-13

Abstract

The utility model belongs to the technical field of metal detection equipment, and discloses a metal alloy rigidity detection device which comprises a processing table, wherein a push block is movably arranged on the left side of the top end of the processing table, a movable groove positioned below the right side of the push block is formed in the top of the processing table, and a movable cavity positioned below the movable groove is formed in the inner wall of the processing table. According to the utility model, the pushing block, the driving motor and the connecting arm are arranged, and the double-threaded screw rod rotates due to the operation of the driving motor, so that the two movable blocks can be driven to move in opposite directions, and at the moment, the two connecting arms deflect to drive the connecting plate and the pushing block to integrally move in the right direction due to the opposite directions of the two movable blocks, and then the pushing block pushes unqualified metal alloy on the right side to the right direction until the unqualified metal alloy is pushed into the collecting box to be collected, so that automatic pushing and collecting of waste materials are finally realized, and the labor intensity of operators is reduced.

Description

Metal alloy rigidity detection device

Technical Field

The utility model belongs to the technical field of metal detection equipment, and particularly relates to a metal alloy rigidity detection device.

Background

The alloy is a product with metal characteristics obtained by mixing and melting one metal and another or a plurality of metal or nonmetal materials and condensing and solidifying, corresponding detection plates are arranged on the rigidity detection devices of the existing metal alloy, the rigidity of the metal alloy is detected by pressing down the detection plates, and when the metal alloy is detected, when the detecting plate makes the alloy deform, namely when the rigidity detection of the product is unqualified, operators can directly take the unqualified product to discard the product, and the unqualified product is placed back and forth to discard the product, so that the labor intensity of the operators is increased, inconvenience is brought to the operation and the use of the operators, and the operators are required to be improved.

Disclosure of utility model

The utility model aims to solve the problems, and provides a metal alloy rigidity detection device which has the advantage of being convenient for collecting waste materials.

In order to achieve the above purpose, the metal alloy rigidity detection device comprises a processing table, wherein a push block is movably arranged on the left side of the top end of the processing table, a movable groove positioned below the right side of the push block is formed in the top of the processing table, a movable cavity positioned below the movable groove is formed in the inner wall of the processing table, a connecting plate positioned on the inner wall of the movable groove and the movable cavity is fixedly arranged at the bottom end of the push block, a driving motor positioned on the back surface of the right lower side of the movable cavity is arranged in the processing table, a double-thread screw rod is fixedly sleeved at one end of an output shaft of the driving motor, the front end of the double-thread screw rod is extended to the inner wall of the front end of the processing table and is movably sleeved with the inner wall of the front end and the rear end of the processing table, the top end of the movable block is extended to the inner wall of the movable cavity, a connecting arm is hinged to the left side of the top end of the movable block, the other end of the connecting arm is hinged with the front end and the rear end of the connecting plate, and the right side of the connecting plate is fixedly provided with a collecting box.

As the preferable one of the utility model, the top of the processing table is fixedly provided with a supporting plate positioned at the left side of the pushing block, the right side of the top end of the supporting plate is fixedly provided with a first pneumatic cylinder, and the bottom end of the first pneumatic cylinder penetrates through the supporting plate and is fixedly provided with a detection pressing plate.

As preferable in the utility model, the top of the processing table is fixedly provided with two positioning blocks positioned at the front and rear sides of the pushing block, and the two positioning blocks have the same size.

As the preferable mode of the utility model, the second pneumatic cylinder is fixedly arranged in the top end of the right side of the collecting box, and the baffle is fixedly arranged at the bottom end of the second pneumatic cylinder.

As the preferable mode of the utility model, the right side of the bottom end of the inner wall of the collecting box is movably sleeved with the movable shaft, the outer surface of the movable shaft is fixedly sleeved with the guide plate, the front end of the movable shaft penetrates through the collecting box, and the outer surface of the movable shaft is fixedly sleeved with the driven gear.

As the preferable mode of the utility model, the front surface of the collecting box is fixedly provided with the power motor positioned at the left front part of the driven gear, one end of the output shaft of the power motor is fixedly sleeved with the rotating shaft, the outer surface of the rear end of the rotating shaft is fixedly sleeved with the driving gear, and the driving gear is meshed with the outer surface of the driven gear.

As the preferable mode of the utility model, the bottom end of the right side of the collecting box is fixedly provided with the discharging plate positioned at the right lower part of the baffle plate, and the top of the discharging plate is in a slope shape.

Compared with the prior art, the utility model has the following beneficial effects:

1. According to the utility model, the pushing block, the driving motor and the connecting arm are arranged, and the double-threaded screw rod rotates due to the operation of the driving motor, so that the two movable blocks can be driven to move in opposite directions, and at the moment, the two connecting arms deflect to drive the connecting plate and the pushing block to integrally move in the right direction due to the opposite directions of the two movable blocks, and then the pushing block pushes unqualified metal alloy on the right side to the right direction until the unqualified metal alloy is pushed into the collecting box to be collected, so that automatic pushing and collecting of waste materials are finally realized, and the labor intensity of operators is reduced.

2. According to the utility model, the second pneumatic cylinder is started firstly by arranging the guide plate, the driven gear and the driving gear, the baffle plate is integrally lifted due to the operation of the second pneumatic cylinder, the sealing effect on the right lower part of the collecting box is relieved, then the power motor can be started, the rotating shaft is enabled to rotate to drive the driving gear to rotate due to the operation of the power motor, at the moment, the driven gear, the movable shaft and the guide plate are further driven to integrally deflect due to the meshing relationship between the driving gear and the outer surface of the driven gear, and finally, the waste at the top of the guide plate slides down along the inclined plane and is discharged through the top of the discharge plate for subsequent treatment.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic cross-sectional view of the present utility model;

FIG. 3 is a schematic cross-sectional view of a connecting arm of the present utility model;

FIG. 4 is a schematic cross-sectional view of a double-threaded lead screw of the present utility model;

Fig. 5 is a schematic view of a partial enlarged structure at a in fig. 3.

The device comprises a machining table 1, a pushing block 2, a movable groove 3, a movable cavity 4, a movable cavity 5, a connecting plate 6, a driving motor 7, a double-threaded screw rod 8, a movable block 9, a connecting arm 10, a supporting plate 11, a first pneumatic cylinder 12, a detection pressing plate 13, a positioning block 14, a collecting box 15, a second pneumatic cylinder 16, a baffle plate 17, a movable shaft 18, a guide plate 19, a driven gear 20, a power motor 21, a rotating shaft 22, a driving gear 23 and a discharge plate.

Detailed Description

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

As shown in fig. 1 to 5, the utility model provides a metal alloy rigidity detection device, which comprises a processing table 1, wherein a push block 2 is movably installed on the left side of the top end of the processing table 1, a movable groove 3 positioned below the right side of the push block 2 is formed in the top of the processing table 1, a movable cavity 4 positioned below the movable groove 3 is formed in the inner wall of the processing table 1, a connecting plate 5 positioned on the inner wall of the movable groove 3 and the movable cavity 4 is fixedly installed at the bottom end of the push block 2, a driving motor 6 positioned on the back surface of the right lower side of the movable cavity 4 is formed in the processing table 1, a double-thread lead screw 7 is fixedly sleeved at one end of an output shaft of the driving motor 6, the front end of the double-thread lead screw 7 extends to the inner wall of the front end of the processing table 1 and is movably sleeved with the double-thread lead screw, the outer surfaces of the front end and the rear end of the double-thread lead screw 7 are respectively sleeved with a movable block 8, the top end of the movable block 8 extends to the inner wall of the movable cavity 4, a connecting arm 9 is hinged to the left side of the top end of the movable block 8, the connecting arm 9 is hinged with the left side of the top of the movable block 8, the connecting arm 9 is hinged with the front and rear end of the inner side of the connecting plate 5, and the right side of the connecting arm is fixedly installed with a collecting box 14.

Firstly, when the disqualification of the product is detected, the driving motor 6 can be started, the double-threaded screw rod 7 rotates due to the operation of the driving motor 6, and at the moment, the two movable blocks 8 are driven to face each other due to the double-threaded design of the double-threaded screw rod 7, so that the two connecting arms 9 deflect and pull the connecting plate 5 and the push block 2 to integrally move rightwards at the same time, and finally the push block 2 can push the product rightwards to the inside of the collecting box 14 to be collected.

Referring to fig. 1 and 2, a support plate 10 positioned at the left side of the push block 2 is fixedly installed at the top of the processing table 1, a first pneumatic cylinder 11 is fixedly installed at the right side of the top end of the support plate 10, and a detection press plate 12 is fixedly installed at the bottom end of the first pneumatic cylinder 11 penetrating through the support plate 10.

As a technical optimization scheme of the utility model, by arranging the first pneumatic cylinder 11, the whole detection pressing plate 12 is downward due to the operation of the first pneumatic cylinder 11, so that the rigidity detection treatment of the metal alloy is performed.

Referring to fig. 1 and 2, the top of the processing table 1 is fixedly provided with two positioning blocks 13 positioned at the front and rear of the push block 2, and the two positioning blocks 13 have the same size.

As a technical optimization scheme of the utility model, by arranging the positioning blocks 13, the metal alloy can be positioned due to the design of the two positioning blocks 13, so that the subsequent operation is convenient.

Referring to fig. 2, a second pneumatic cylinder 15 is fixedly installed inside the right top of the collection box 14, and a baffle 16 is fixedly installed at the bottom of the second pneumatic cylinder 15.

As a technical optimization scheme of the utility model, by arranging the second pneumatic cylinder 15, the baffle 16 is driven to move up and down integrally due to the operation of the second pneumatic cylinder 15, so that the closing and opening operation of the right lower part of the collecting box 14 can be realized.

Referring to fig. 2 and 5, a movable shaft 17 is movably sleeved on the right side of the bottom end of the inner wall of the collecting box 14, a guide plate 18 is fixedly sleeved on the outer surface of the movable shaft 17, the front end of the movable shaft 17 penetrates through the collecting box 14, and a driven gear 19 is fixedly sleeved on the outer surface of the movable shaft.

As a technical optimization scheme of the utility model, by arranging the material guide plate 18, when the driven gear 19 and the movable shaft 17 integrally rotate, the baffle 16 releases the sealing effect on the right lower part of the collecting box 14, and the material guide plate 18 integrally tilts at the moment, so that the waste at the top of the material guide plate 18 quickly slides along the inclined plane to be collected.

Referring to fig. 5, the front surface of the collecting box 14 is fixedly provided with a power motor 20 positioned at the left front of the driven gear 19, one end of an output shaft of the power motor 20 is fixedly sleeved with a rotating shaft 21, the outer surface of the rear end of the rotating shaft 21 is fixedly sleeved with a driving gear 22, and the driving gear 22 is meshed with the outer surface of the driven gear 19.

As a technical optimization scheme of the utility model, by arranging the power motor 20, the running of the power motor 20 can lead the rotating shaft 21 to rotate so as to drive the driving gear 22 to rotate, thereby driving the driven gear 19, the movable shaft 17 and the guide plate 18 to deflect integrally.

Referring to fig. 1 to 5, a discharge plate 23 is fixedly installed at the bottom of the right side of the collecting box 14 at the right lower side of the baffle 16, and the top of the discharge plate 23 is sloped.

As a technical optimization scheme of the utility model, by arranging the discharging plate 23, the waste materials sliding off the top of the material guiding plate 18 can be well supported and guided due to the design of the discharging plate 23.

The working principle and the using flow of the utility model are as follows:

Firstly, an operator can fix the metal alloy between the positioning blocks 13, then can start the first pneumatic cylinder 11, and because of the operation of the first pneumatic cylinder 11, the whole detection pressing plate 12 is pushed to apply pressure to the metal alloy downwards to detect the rigidity, if the alloy is not obviously deformed, the product is qualified, otherwise, the alloy is obviously deformed, namely, the alloy is disqualified, at the moment, the driving motor 6 can be started, the double-threaded screw rod 7 can rotate to drive the two movable blocks 8 to face each other, and then the two connecting arms 9 can deflect and pull the connecting plate 5 and the whole push block 2 backwards simultaneously, and finally, the unqualified metal alloy on the right side of the push block 2 can be pushed to the inside of the collecting box 14 to be collected.

Then when a large amount of unqualified products exist in the collecting box 14 and at the top of the material guiding plate 18, the second pneumatic cylinder 15 can be started to drive the baffle 16 upwards, the closing effect on the right lower part of the collecting box 14 is relieved, the power motor 20 is started again, the rotating shaft 21 is enabled to rotate to drive the driving gear 22 to rotate, and due to the meshing connection relationship between the driving gear 22 and the outer surface of the driven gear 19, the movable shaft 17 and the material guiding plate 18 are driven to integrally deflect, and finally waste at the top of the material guiding plate 18 can be discharged along the inclined plane and the material discharging plate 23 for processing.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A metal alloy rigidity detection device comprises a processing table (1) and is characterized in that a push block (2) is movably mounted on the left side of the top end of the processing table (1), a movable groove (3) located below the right side of the push block (2) is formed in the top of the processing table (1), a movable cavity (4) located below the movable groove (3) is formed in the inner wall of the processing table (1), a connecting plate (5) located on the inner wall of the movable groove (3) and the movable cavity (4) is fixedly mounted at the bottom end of the push block (2), a driving motor (6) located on the back side of the right side of the movable cavity (4) is arranged in the processing table (1), a double-threaded lead screw (7) is fixedly arranged at one end of an output shaft of the driving motor (6) in a sleeved mode, the front end of the double-threaded lead screw (7) extends to the inner wall of the front end of the processing table (1) and is movably sleeved with the inner wall of the double-threaded lead screw, a movable block (8) is sleeved on the outer surface of the front end and the rear end of the double-threaded lead screw (7), a connecting plate (5) located on the inner wall of the movable cavity (4), a connecting plate (9) is arranged on the inner side of the movable cavity (4), and a connecting plate (9) is fixedly connected with the front end of the processing table (9).

2. The metal alloy rigidity detection device according to claim 1, wherein a supporting plate (10) positioned on the left side of the pushing block (2) is fixedly arranged at the top of the processing table (1), a first pneumatic cylinder (11) is fixedly arranged on the right side of the top end of the supporting plate (10), and the bottom end of the first pneumatic cylinder (11) penetrates through the supporting plate (10) and is fixedly provided with a detection pressing plate (12).

3. The metal alloy rigidity detection device according to claim 1, wherein the top of the processing table (1) is fixedly provided with two positioning blocks (13) positioned at the front and rear sides of the pushing block (2), and the two positioning blocks (13) have the same size.

4. The metal alloy rigidity detection device according to claim 1, wherein a second pneumatic cylinder (15) is fixedly arranged in the top end of the right side of the collecting box (14), and a baffle plate (16) is fixedly arranged at the bottom end of the second pneumatic cylinder (15).

5. The metal alloy rigidity detection device according to claim 1, wherein a movable shaft (17) is movably sleeved on the right side of the bottom end of the inner wall of the collecting box (14), a material guide plate (18) is fixedly sleeved on the outer surface of the movable shaft (17), the front end of the movable shaft (17) penetrates through the collecting box (14), and a driven gear (19) is fixedly sleeved on the outer surface of the movable shaft.

6. The metal alloy rigidity detection device according to claim 1, wherein the front surface of the collection box (14) is fixedly provided with a power motor (20) positioned at the left front side of the driven gear (19), one end of an output shaft of the power motor (20) is fixedly sleeved with a rotating shaft (21), the outer surface of the rear end of the rotating shaft (21) is fixedly sleeved with a driving gear (22), and the driving gear (22) is meshed with the outer surface of the driven gear (19).

7. The metal alloy rigidity detecting device according to claim 1, wherein a discharging plate (23) positioned at the lower right side of the baffle plate (16) is fixedly arranged at the bottom end of the right side of the collecting box (14), and the top of the discharging plate (23) is in a gradient shape.