A diameter and height measuring mechanism

Abstract

The utility model relates to the technical field of precision measurement, especially to a diameter and height measuring mechanism. The utility model provides a diameter and height measuring mechanism which can measure the diameter and height of a product simultaneously, reduce the time required for measuring each parameter separately and improve the measuring efficiency. The diameter and height measuring mechanism comprises a base and a slide rail, and the front part of the base is connected with two slide rails. The diameter of the product is measured by a horizontal height gauge, the second cylinder is started, the height sensor is driven to move, the height of the workpiece is measured by the height sensor, the key part of the workpiece is measured in detail by using a vertical height gauge, and the diameter and height of the product can be measured simultaneously, the time required for measuring each parameter separately is reduced, and the measuring efficiency is improved.

Description

Technical Field

[0001] This utility model relates to the field of precision measurement technology, and in particular to a mechanism for measuring diameter and height. Background Technology

[0002] In the many production processes of manufacturing, the accurate measurement of key dimensional parameters of products is a crucial step in ensuring product quality, meeting design requirements, and achieving efficient production. Among these, the diameter and height of a product are two basic and important geometric parameters, and the accuracy and efficiency of their measurement directly affect the product qualification rate, production progress, and the economic benefits of the enterprise.

[0003] Existing diameter and height measurement mechanisms typically use different mechanisms to measure the product's diameter and height separately. During the measurement process, the product needs to be repeatedly picked up and clamped onto different measuring mechanisms, which is cumbersome and cannot measure the product's diameter and height simultaneously, resulting in wasted time and low measurement efficiency.

[0004] Therefore, it is necessary to design a diameter and height measuring mechanism that can simultaneously measure the diameter and height of a product, reducing the time required to measure each parameter individually and improving measurement efficiency. Utility Model Content

[0005] To overcome the shortcomings of existing diameter and height measuring mechanisms, which require repeated handling and clamping of the product onto different measuring devices during the measurement process, making the operation cumbersome, unable to simultaneously measure the product's diameter and height, time-consuming, and inefficient, this utility model provides a diameter and height measuring mechanism that can simultaneously measure the product's diameter and height, reducing the time required to measure each parameter individually and improving measurement efficiency.

[0006] The technical solution is as follows: A diameter and height measuring mechanism includes a base, slide rails, a sliding frame, a transplanting cylinder, a motor, a transmission assembly, a product carrier, a barcode scanning assembly, and a measuring assembly. Two slide rails are connected to the upper front of the base, and a sliding frame is slidably connected between the slide rails. A transplanting cylinder is connected to the upper right side of the base, and the transplanting cylinder and a processor are electrically connected via a control module. The telescopic end of the transplanting cylinder is connected to the sliding frame. A motor is connected to the upper left side of the sliding frame, and the motor and a processor are electrically connected via a control module. A product carrier is rotatably and detachably connected to the right side of the sliding frame, and the product carrier is detachably connected to the motor output shaft. A transmission assembly is provided between the product carrier and the motor output shaft. A barcode scanning assembly capable of scanning product codes is located at the rear right of the base, and a measuring assembly capable of simultaneously measuring the product diameter and height is located on the left side of the base.

[0007] Furthermore, all slide rails are of an I-beam shape.

[0008] Furthermore, the transmission assembly includes a synchronous pulley and a flat belt. The product carrier and the motor output shaft are both connected to synchronous pulleys, and a flat belt is wound between the synchronous pulleys.

[0009] Furthermore, the barcode scanning component includes a support frame, a first cylinder, and a barcode reader. The support frame is connected to the upper right rear side of the base, the first cylinder is connected to the upper front side of the support frame, and the barcode reader is connected to the telescopic end of the first cylinder.

[0010] Furthermore, it also includes a measuring component, which includes a second cylinder, a support member, a height sensor, a vertical height gauge, a third cylinder, a connecting frame, and a horizontal height gauge. The support member is connected to the upper left side of the base, and the second cylinder is connected to the right rear side of the support member. The height sensor is connected to the telescopic end of the second cylinder. The vertical height gauge is connected to the upper rear part of the support member, and the third cylinder is connected to the right front part of the support member. Both the second and third cylinders are electrically connected to the processor through a control module. The connecting frame is connected to the telescopic end of the third cylinder, and horizontal height gauges are connected to both the front and rear parts of the connecting frame.

[0011] Furthermore, the lower part of the connecting frame has a U-shaped structure.

[0012] The beneficial effects are as follows: This utility model measures the diameter of the product by using a horizontal height gauge, starts the second cylinder to move the height sensor, measures the height of the workpiece by the height sensor, and then uses a vertical height gauge to measure the key parts of the workpiece in detail. This achieves the effect of simultaneously measuring the diameter and height of the product, reducing the time required to measure each parameter individually, and improving measurement efficiency. Attached Figure Description

[0013] Figure 1 This is a three-dimensional structural diagram of the present invention.

[0014] Figure 2 This is a three-dimensional structural diagram of the base and slide rail components of this utility model.

[0015] Figure 3 This is a three-dimensional structural diagram of the support frame and barcode reader components of this utility model.

[0016] Figure 4 This is a three-dimensional structural diagram of the height sensor and level gauge components of this utility model.

[0017] Component names and numbers in the diagram: 1_Base, 2_Slide rail, 3_Sliding frame, 4_Transplanting cylinder, 5_Motor, 6_Transmission assembly, 7_Product carrier, 8_Support frame, 9_First cylinder, 10_Code reader, 11_Second cylinder, 111_Support component, 12_Height sensor, 13_Vertical height gauge, 14_Third cylinder, 141_Connecting frame, 15_Horizontal height gauge. Detailed Implementation

[0018] The technical solution of this utility model will be further described below with reference to the accompanying drawings.

[0019] A mechanism for measuring diameter and height, such as Figure 1 and Figure 2 As shown, the device includes a base 1, slide rails 2, sliding frame 3, transplanting cylinder 4, motor 5, transmission assembly 6, product carrier 7, barcode scanning assembly, and measuring assembly. The upper front of the base 1 is connected to two slide rails 2, both of which are I-shaped. A sliding frame 3 is slidably connected between the slide rails 2. The upper right side of the base 1 is connected to the transplanting cylinder 4, which is electrically connected to the processor via a control module. The telescopic end of the transplanting cylinder 4 is connected to the sliding frame 3. The upper left side of the sliding frame 3 is connected to the motor 5, which is also electrically connected to the processor via a control module. The right side of the sliding frame 3 is rotatably and detachably connected to the product carrier 7, which is detachably connected to the output shaft of the motor 5. A transmission assembly 6 is located between the product carrier 7 and the output shaft of the motor 5. A barcode scanning assembly is located at the rear right of the base 1, and a measuring assembly is located at the left side of the base 1.

[0020] like Figure 2 As shown, the transmission assembly 6 includes a synchronous pulley and a flat belt. The product carrier 7 and the output shaft of the motor 5 are both connected to synchronous pulleys, and a flat belt is wound between the synchronous pulleys.

[0021] like Figure 1 and Figure 3 As shown, the barcode scanning assembly includes a support frame 8, a first cylinder 9, and a barcode reader 10. The support frame 8 is connected to the upper right rear part of the base 1, the first cylinder 9 is connected to the upper front part of the support frame 8, and the barcode reader 10 is connected to the telescopic end of the first cylinder 9.

[0022] like Figure 1 and Figure 4 As shown, it also includes a measuring component, which includes a second cylinder 11, a support member 111, a height sensor 12, a vertical height gauge 13, a third cylinder 14, a connecting frame 141, and a horizontal height gauge 15. The support member 111 is connected to the upper left side of the base 1, and the second cylinder 11 is connected to the right rear side of the support member 111. The height sensor 12 is connected to the telescopic end of the second cylinder 11. The vertical height gauge 13 is connected to the upper rear part of the support member 111, and the third cylinder 14 is connected to the right front part of the support member 111. Both the second cylinder 11 and the third cylinder 14 are electrically connected to the processor through a control module. The connecting frame 141 is connected to the telescopic end of the third cylinder 14. The lower part of the connecting frame 141 has a U-shaped structure to facilitate product placement. Horizontal height gauges 15 are connected to both the front and rear parts of the connecting frame 141.

[0023] When using this device, first place the base 1 in the product diameter and height measurement area, then place the product in the product carrier 7. Next, the processor, through the control module, activates the first cylinder 9, causing the barcode reader 10 to move up and down, aligning it with the product. The barcode reader 10 scans the code on the product to read the product information. After scanning, the motor 5 is turned off. The processor, through the control module, activates the transfer cylinder 4, causing the sliding frame 3 to move to the left on the slide rail 2, positioning the product carrier 7 within the connecting frame 141. Then, the third cylinder 14 is activated, causing the connecting frame 141 to move upwards, causing the horizontal height gauge 15 to move upwards, positioning the product between the horizontal height gauges 15. The product is then positioned using the horizontal height gauge 15. The probe extends to measure the diameter of the product. Then, the second cylinder 11 is activated, which moves the height sensor 12. The height sensor 12 measures the height of the workpiece. Then, the vertical height gauge 13 is used to measure the key parts of the workpiece in detail. At the same time, the motor 5 is activated, which drives the synchronous pulley to rotate, causing the flat belt to rotate and driving the product carrier 7 to rotate. This allows the vertical height gauge 13 to take values ​​at multiple positions on the diameter. Combining the measurement results of the vertical height gauge 13 and the height sensor 12, a complete workpiece size report is generated. This allows for simultaneous measurement of the product diameter and height, reducing the time required to measure each parameter individually and improving measurement efficiency. When different products need to be measured, the product carrier 7 can be disassembled.

[0024] The above description is only a preferred embodiment of the present utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the principle of the present utility model, and these improvements and modifications should also be considered within the protection scope of the present utility model.

Claims

1. A mechanism for measuring diameter and height, characterized in that, The system includes a base (1), slide rails (2), sliding frame (3), transplanting cylinder (4), motor (5), transmission assembly (6), product carrier (7), barcode scanning assembly, and measuring assembly. The upper front of the base (1) is connected to two slide rails (2), with the sliding frame (3) slidably connected between the slide rails (2). The upper right side of the base (1) is connected to the transplanting cylinder (4). The transplanting cylinder (4) and the processor are electrically connected via a control module. The telescopic end of the transplanting cylinder (4) is connected to the sliding frame (3). The upper left side of the frame (3) is connected to a motor (5). The motor (5) and the processor are electrically connected through a control module. The right side of the sliding frame (3) is rotatably connected to a product carrier (7). The product carrier (7) is detachably connected to the output shaft of the motor (5). A transmission component (6) is provided between the product carrier (7) and the output shaft of the motor (5). The rear right side of the base (1) is provided with a barcode scanning component that can scan the product code. The left side of the base (1) is provided with a measuring component that can simultaneously measure the diameter and height of the product.

2. The diameter and height measuring mechanism according to claim 1, characterized in that, The slide rails (2) are all of I-shaped structure.

3. The diameter and height measuring mechanism according to claim 1, characterized in that, The transmission assembly (6) includes a synchronous pulley and a flat belt. The product carrier (7) and the output shaft of the motor (5) are both connected to synchronous pulleys, and a flat belt is wound between the synchronous pulleys.

4. The diameter and height measuring mechanism according to claim 1, characterized in that, The scanning component includes a support frame (8), a first cylinder (9) and a barcode reader (10). The support frame (8) is connected to the upper right rear part of the base (1), and the first cylinder (9) is connected to the upper front part of the support frame (8). The barcode reader (10) is connected to the telescopic end of the first cylinder (9).

5. The diameter and height measuring mechanism according to claim 1, characterized in that, It also includes a measuring component, which includes a second cylinder (11), a support (111), a height sensor (12), a vertical height gauge (13), a third cylinder (14), a connecting frame (141), and a horizontal height gauge (15). The support (111) is connected to the upper left side of the base (1), the second cylinder (11) is connected to the right rear side of the support (111), the height sensor (12) is connected to the telescopic end of the second cylinder (11), the vertical height gauge (13) is connected to the upper rear part of the support (111), and the third cylinder (14) is connected to the right front part of the support (111). The second cylinder (11) and the third cylinder (14) are both electrically connected to the processor through the control module. The connecting frame (141) is connected to the telescopic end of the third cylinder (14), and the horizontal height gauge (15) is connected to both the front and rear parts of the connecting frame (141).

6. A diameter and height measuring mechanism according to claim 5, characterized in that, The lower part of the connecting frame (141) has a U-shaped structure.

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