Titanium alloy rack strength detection device
The titanium alloy frame strength testing device, which integrates cylinders, support frames, and tensioning mechanisms, solves the problem of requiring two types of equipment for testing in existing technologies. It achieves integrated testing of compressive and tensile strength, improving testing efficiency and convenience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGXI SHENGFENG INTELLIGENT EQUIP CO LTD
- Filing Date
- 2025-04-30
- Publication Date
- 2026-06-16
AI Technical Summary
Existing titanium alloy frame strength testing requires the use of two different types of equipment, resulting in high testing costs and low efficiency.
Design a titanium alloy frame strength testing device that integrates a cylinder, support frame, pressure plate and tensioning mechanism to achieve dual-purpose use, capable of simultaneously performing compressive strength testing and tensile strength testing.
It improves the efficiency of strength testing of titanium alloy frames, reduces testing costs, and enhances ease of use.
Smart Images

Figure CN224365852U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of titanium alloy frame testing, and in particular to a titanium alloy frame strength testing device. Background Technology
[0002] Titanium alloy frames refer to frame structures made of titanium alloy materials. They are widely used in fields requiring high strength, lightweight, and corrosion resistance, such as aerospace, high-end bicycles, racing cars, photographic equipment, medical equipment, and the shell support structures of certain precision electronic devices.
[0003] Existing methods for testing the strength of titanium alloy frames typically involve first extruding the titanium alloy frame using extrusion equipment to test its compressive strength, and then using tensile equipment to test its tensile strength. This process is inconvenient, requiring the use of two different types of equipment, which increases testing costs and reduces the efficiency of titanium alloy frame strength testing.
[0004] Therefore, it is necessary to design a titanium alloy frame strength testing device that can perform compressive strength testing and tensile strength testing on the frame, achieving dual functionality, improving the efficiency of titanium alloy frame strength testing, reducing testing costs, and enhancing ease of use. Utility Model Content
[0005] To overcome the shortcomings of existing titanium alloy frame strength testing methods, which are inconvenient to operate and require two different devices for testing, resulting in high testing costs and reduced efficiency, this invention provides a titanium alloy frame strength testing device that can perform both compressive strength and tensile strength testing on the frame, achieving dual functionality in one machine. This improves the efficiency of titanium alloy frame strength testing, reduces testing costs, and enhances ease of use.
[0006] The technical implementation scheme of this utility model is as follows: a titanium alloy frame strength testing device, including a chassis, a support frame, a cylinder, a pressure plate and a tensioning mechanism. The upper sides of the left and right sides of the chassis are connected to the support frame, the upper part of the support frame is connected to the cylinder, the extension end of the cylinder is connected to the pressure plate, and a tensioning mechanism for frame strength testing is provided between the chassis and the pressure plate.
[0007] Furthermore, the support frame is U-shaped.
[0008] Furthermore, the stretching mechanism includes a slide rail, a sliding frame, a fixed frame, a rotating component, and a locking component. A slide rail is connected to the upper front side of the machine housing, and two sliding frames are slidably connected to the slide rail. Two fixed frames are connected to the front and rear sides of the pressure plate, and a rotating component is rotatably connected to each fixed frame. A rotating plate is rotatably provided at the lower part of each rotating component, and a locking component is connected to the outer side of each rotating frame.
[0009] Furthermore, all the locking components are L-shaped.
[0010] Furthermore, it also includes a data mechanism, which includes a clamp, a spring, a rotating frame, and a data disk. The upper part of the sliding frame is rotatably connected to the rotating frame, and the outside of the rotating frame is slidably connected to the clamp. The clamp is connected to the rotating frame on the same side by a spring, and the front of the rotating frame is connected to the data disk.
[0011] Furthermore, it also includes pointers, with pointers connected to each of the sliding frames.
[0012] This utility model has the following advantages: 1. This utility model uses a cylinder to drive the pressure plate to move and compress the frame until it is deformed. The fixed frame, rotating parts, rotating plate and locking parts move in opposite directions to stretch the frame until it is deformed and broken. This allows for testing the compressive strength and tensile strength of the frame, achieving dual-purpose functionality, improving the efficiency of titanium alloy frame strength testing, reducing testing costs and improving ease of use.
[0013] 2. In this invention, when the pressure plate moves to squeeze the frame, the frame deforms, causing the clamping plate to move downwards, which in turn causes the rotating frame to rotate, and the data disk to rotate. The rotation angle can then be read by the pointer indicating the position, thus enabling the operator to read the value and understand the degree of frame deformation. Attached Figure Description
[0014] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0015] Figure 2 This is a partial planar perspective three-dimensional structural diagram of the present invention.
[0016] Figure 3 This is a schematic diagram of the tensioning mechanism of this utility model.
[0017] Figure 4 This is a schematic diagram of the data mechanism structure of this utility model.
[0018] The components in the diagram are labeled as follows: 1-Chassis, 2-Support frame, 3-Cylinder, 4-Pressure plate, 5-Tensioning mechanism, 51-Slide rail, 52-Sliding frame, 53-Fixed frame, 54-Rotating component, 55-Clocking component, 6-Data mechanism, 61-Clamping plate, 62-Spring, 63-Rotating frame, 64-Data disk, 65-Pointer. Detailed Implementation
[0019] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to specific embodiments and accompanying drawings. It should be understood that these descriptions are merely exemplary and not intended to limit the scope of this utility model. Furthermore, descriptions of well-known structures and technologies are omitted in the following description to avoid unnecessarily obscuring the concept of this utility model.
[0020] A titanium alloy frame strength testing device, such as Figures 1-3 As shown, the machine includes a housing 1, a support frame 2, a cylinder 3, a pressure plate 4, and a tensioning mechanism 5. The upper sides of the left and right sides of the housing 1 are connected to the support frame 2, which is U-shaped. The upper part of the support frame 2 is connected to the cylinder 3, and the extension end of the cylinder 3 is connected to the pressure plate 4. A tensioning mechanism 5 for testing the strength of the frame is provided between the housing 1 and the pressure plate 4.
[0021] like Figure 1 and Figure 3 As shown, the stretching mechanism 5 includes a slide rail 51, a sliding frame 52, a fixed frame 53, a rotating component 54, and a locking component 55. The upper front side of the housing 1 is connected to the slide rail 51, and two left and right sliding frames 52 are slidably connected to the slide rail 51. The front and rear sides of the pressure plate 4 are connected to two left and right fixed frames 53, and each fixed frame 53 is rotatably connected to a rotating component 54. Each rotating component 54 has a rotating plate rotatably provided at its lower part. The outer side of each rotating frame 63 is connected to a locking component 55, and the locking components 55 are all L-shaped.
[0022] like Figure 1 and Figure 4 As shown, it also includes a data mechanism 6, which includes a clamping plate 61, a spring 62, a rotating frame 63, a data disk 64, and a pointer 65. The upper part of the sliding frame 52 is rotatably connected to the rotating frame 63, and the outside of the rotating frame 63 is slidably connected to the clamping plate 61. The clamping plate 61 is connected to the rotating frame 63 on the same side by a spring 62. The front part of the rotating frame 63 is connected to the data disk 64, and the sliding frame 52 is connected to the pointer 65 for easy data reading.
[0023] When strength testing of a titanium alloy frame is required, this device can be used. Bring the device to the location where the strength test is needed, ensuring the chassis 1 is in contact with the ground. Then, according to the dimensions of the titanium alloy frame, manually pull the sliding frame 52 along the slide rail 51 to the appropriate position. Insert the titanium alloy frame into the chassis 1 from the rear, allowing it to pass through the rear of the sliding frame 52, thus contacting the clamping plate 61. This causes the clamping plate 61 to move, compressing the spring 62 and clamping the frame. Then, activate the support frame 2. The cylinder 3 and the support frame 2 are U-shaped. The cylinder 3 drives the pressure plate 4 to move, and then the rotating component 54 rotates along the fixed frame 53, causing the rotating plate and the locking component 55 to rotate. The locking components 55 are both L-shaped. When the pressure plate 4 contacts the frame, the rotating component 54 is released. Under the action of gravity, the rotating component 54 rotates back to its original position, which in turn drives the rotating plate and the locking component 55 to rotate back to their original position and contact the frame. The locking component 55 limits the rotation plate, allowing the pressure plate 4 to continue moving and compressing the frame until it deforms, thereby testing the compressive strength of the frame. After the compression test is completed, the fixed frame 53, rotating component 54, rotating plate, and locking component 55 are disengaged from the titanium alloy frame. The deformed titanium alloy frame is then removed, spring 62 returns to its original position, and clamping plate 61 moves back to its original position. The new titanium alloy frame is then reinstalled. Next, cylinder 3 is activated in reverse, causing cylinder 3 to move pressure plate 4 in the opposite direction. This, in turn, causes the fixed frame 53, rotating component 54, rotating plate, and locking component 55 to move in the opposite direction, thus stretching the frame until it deforms and breaks. The tensile strength of the frame is then tested, thereby enabling... The machine performs compressive strength and tensile strength tests on the frame, achieving dual functionality and improving the efficiency of strength testing for titanium alloy frames. This reduces testing costs and enhances ease of use. When the pressure plate 4 moves to compress the frame, the frame deforms, causing the clamping plate 61 to move downwards, which in turn causes the rotating frame 63 to rotate, and the data disk 64 to rotate. The rotation angle is then read by the pointer 65, allowing operators to easily read the values and understand the degree of frame deformation. After the test is completed, the frame can be removed.
[0024] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this utility model should be included within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the protection scope of the claims.
Claims
1. A titanium alloy frame strength testing device, characterized in that: It includes a chassis (1), a support frame (2), a cylinder (3), a pressure plate (4) and a tensioning mechanism (5). The upper sides of the left and right sides of the chassis (1) are connected to the support frame (2). The upper part of the support frame (2) is connected to the cylinder (3). The extension end of the cylinder (3) is connected to the pressure plate (4). A tensioning mechanism (5) for testing the strength of the frame is provided between the chassis (1) and the pressure plate (4). The stretching mechanism (5) includes a slide rail (51), a sliding frame (52), a fixed frame (53), a rotating component (54), and a locking component (55). The upper front side of the housing (1) is connected to the slide rail (51), and two sliding frames (52) are slidably connected to the slide rail (51). The front and rear sides of the pressure plate (4) are connected to two fixed frames (53), and rotating components (54) are rotatably connected to the fixed frames (53). Rotating plates are rotatably provided at the bottom of the rotating components (54), and locking components (55) are connected to the outer side of the rotating frame (63).
2. The titanium alloy frame strength testing device according to claim 1, characterized in that: The support frame (2) is U-shaped.
3. The titanium alloy frame strength testing device according to claim 1, characterized in that: All the card slots (55) are L-shaped.
4. The titanium alloy frame strength testing device according to claim 1, characterized in that: It also includes a data mechanism (6), which includes a clamp (61), a spring (62), a rotating frame (63) and a data disk (64). The upper part of the sliding frame (52) is rotatably connected to the rotating frame (63), and the outside of the rotating frame (63) is slidably connected to the clamp (61). The clamp (61) is connected to the rotating frame (63) on the same side by a spring (62), and the front of the rotating frame (63) is connected to the data disk (64).
5. The titanium alloy frame strength testing device according to claim 4, characterized in that: It also includes a pointer (65), and the sliding frame (52) is connected to a pointer (65).