An alloy plate strip calibration template with multi-specification and positioning measurement function
By designing a calibration template for alloy plates and strips with multi-specification and positioning measurement functions, the problem of existing tools being unable to adapt to multi-specification sampling was solved, achieving precise positioning and efficient calibration of alloy plate and strip sampling, and improving the accuracy of test results and production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHINALCO LUOYANG COPPER PROCESSING CO LTD
- Filing Date
- 2025-05-28
- Publication Date
- 2026-06-05
AI Technical Summary
Existing sampling and calibration tools and methods for alloy plates and strips are limited in function and cannot meet diverse production needs. This makes it difficult to accurately determine the sampling location and size, affecting the accuracy and reliability of the test results.
A calibration template for alloy strip with multiple specifications and positioning measurement functions was designed, including a rectangular main base plate, an operating handle, fastening components, scale lines and calibration through-hole slots. These components enable accurate positioning and scribing calibration of alloy strip with multiple specifications.
It significantly improves the accuracy and efficiency of alloy plate and strip sampling, reduces material waste and defect rate, and is suitable for industrial production and scientific research measurement.
Smart Images

Figure CN224327658U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of alloy plate and strip processing technology, specifically to an alloy plate and strip calibration template with multiple specifications and positioning measurement functions. Background Technology
[0002] Sampling and analysis of alloy sheet and strip materials is a crucial and routine operation in many fields, including production, quality inspection, and scientific research. Through component analysis and physical property testing of samples, the quality and performance of alloy sheet and strip materials can be effectively assessed to determine whether they meet relevant standards and usage requirements. However, existing sampling and calibration tools and methods for alloy sheet and strip materials have many shortcomings and are insufficient to meet the ever-increasing demands of production and testing.
[0003] Currently, most common calibration tools and methods are single-function, only suitable for sampling and calibration of alloy strips of specific specifications. With the continuous expansion of applications for alloy strips, the variety of sampling and calibration specifications is increasing, and single-specification sampling and calibration tools cannot meet diverse production needs. Taking the sampling and calibration of copper alloy strips in actual production as an example: traditional sampling and calibration are all simple manual processes, involving tracing lines using a single template or measuring with a tape measure. Existing calibration tools generally lack multi-specification and positioning measurement functions. During the sampling and calibration process, operators often find it difficult to accurately determine the sampling position and size, which can easily lead to deviations in subsequent sampling and shearing. This results in the sample not truly representing the overall performance of the alloy strip, thus affecting the accuracy and reliability of the test results. Inaccurate test results may lead to misjudgments of the alloy strip material quality, posing potential risks to production and use.
[0004] In summary, existing sampling and calibration tools and methods for alloy strips, especially copper alloy strips, have significant shortcomings in terms of multi-specification adaptability, positioning and measurement capabilities, and operational efficiency. Therefore, it is necessary to propose a calibration template for alloy strips that possesses multi-specification and positioning measurement functions. Utility Model Content
[0005] The purpose of this invention is to provide a calibration template for alloy plates and strips with multi-specification and positioning measurement functions. This calibration template is suitable for multi-specification sampling of alloy plates and strips. It is not only easy to operate and highly efficient, but also significantly reduces material waste and sampling defect rate caused by mismatched specifications and positioning measurement deviations. It is suitable for industrial production and scientific research measurement sampling.
[0006] The technical solution adopted by this utility model is: an alloy plate and strip calibration template with multiple specifications and positioning measurement functions, including a rectangular main substrate, the main substrate having a bonding surface that is bonded to the alloy plate and strip and a non-bonding surface opposite to the bonding surface;
[0007] The main substrate is provided with an operating handle and a fastening assembly for aligning the side of the alloy strip, wherein the operating handle is located on the non-adhesive surface, and the fastening assembly extends at least to one side of the non-adhesive surface of the main substrate.
[0008] The main substrate has scale lines for positioning. There are two sets of scale lines, which are perpendicular to each other.
[0009] The main substrate has a calibration through-hole groove in the middle that connects the bonding surface and the non-bonding surface. The calibration through-hole grooves are all rectangular grooves. At least one calibration through-hole groove is provided with a slider that slides with it to adjust the size of the calibration through-hole groove.
[0010] As a preferred embodiment, the calibration through-hole groove includes a calibration through-hole groove for bending test specimens, a calibration through-hole groove for cleanliness test specimens, a calibration through-hole groove for hardness test specimens, a calibration through-hole groove for conductivity test specimens, and a calibration through-hole groove for tensile test specimens.
[0011] As a preferred embodiment, the slider is located in the tensile specimen calibration through-hole groove, and the edge of the tensile specimen calibration through-hole groove is provided with scale lines that cooperate with the slider indication.
[0012] As a preferred embodiment, the operating handle and the fastening assembly are respectively located on two opposite sides of the main body substrate.
[0013] As a preferred embodiment, there are at least two fastening components, and the center line connecting all the fastening components is parallel to one set of scale lines.
[0014] As a preferred embodiment, the main substrate is provided with mounting holes corresponding to the fastening components;
[0015] The fastening assembly includes a bolt passing through the mounting hole of the main substrate, a washer fitted in the middle of the bolt, and a nut threaded to the end of the bolt.
[0016] As a preferred option, the bonding surface of the main substrate is provided with adhesive felt cloth.
[0017] As a preferred embodiment, the main substrate is a transparent plate.
[0018] As a preferred embodiment, the slider has an extension that fits with the calibration through-hole groove, and the bottom surface of the extension is flush with the contact surface of the main substrate.
[0019] Compared with the prior art, the beneficial effects of this utility model are:
[0020] 1. This utility model has a simple structure and is easy to operate. It can perform scribing and calibration of alloy plate and strip samples of multiple specifications at one time. It has significant practical value in actual production, especially in the sampling and calibration of copper alloy plate and strip.
[0021] 2. The fastening components and the operating handle interact to prevent the sample from shifting and ensure the accuracy of the sampling marking. The fastening components can contact and position the side of the alloy plate or strip for easy sample calibration. The fastening components can be disassembled or installed according to the usage environment.
[0022] 3. The 3M felt cloth on the back of the main substrate can also effectively prevent scratches;
[0023] 4. The slider of the through-hole groove for tensile specimen calibration can handle the scribing calibration of specimens of different lengths;
[0024] 5. The calibration template has low manufacturing cost and is easy to operate for sampling and calibration, making it suitable for widespread use and greatly improving the efficiency and accuracy of alloy plate and strip sampling and calibration. Attached Figure Description
[0025] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0026] Figure 1 This is an axonometric view of the present invention;
[0027] Figure 2 This is a top view of the present invention;
[0028] Figure 3 This is a side view of the present invention;
[0029] Figure 4 This is a schematic diagram of the slider in this utility model.
[0030] Reference numerals: 1. Main substrate; 2. Operating handle; 3. Bend test sample calibration through-hole groove; 4. Cleanliness test sample calibration through-hole groove; 5. Hardness test sample calibration through-hole groove; 6. Conductivity test sample calibration through-hole groove; 7. Tensile test sample calibration through-hole groove; 8. Fastening assembly; 801. Bolt; 802. Washer; 803. Nut; 9. Slider; 901. Extension; 10. Scale line; 11. Adhesive-backed felt cloth. Detailed Implementation
[0031] The present invention will now be described in detail through exemplary embodiments. However, it should be understood that, without further description, elements, structures, and features in one embodiment may be advantageously incorporated into other embodiments.
[0032] It should be noted that, unless otherwise defined, the technical or scientific terms used herein should have the ordinary meaning understood by one of ordinary skill in the art to which this utility model pertains. The terms "a," "an," or "the," etc., used in this utility model patent application specification and claims do not express a quantity limitation, but rather indicate the presence of at least one; the terms "first," "second," and "third," as used herein, should not be considered as a limitation on the order of components, but are merely for distinguishing different components; the terms "comprising" or "including," etc., indicate that the elements or objects preceding "comprising" or "including" encompass the elements or objects listed following "comprising" or "including" and their equivalents, but do not exclude other elements or objects having the same function.
[0033] To more clearly describe the specific structural composition of this alloy strip calibration template with multi-specification and positioning measurement functions, in conjunction with the attached... Figure 1-4 This embodiment is described as follows:
[0034] like Figure 1-3 As shown, an alloy strip calibration template with multiple specifications and positioning measurement functions includes a rectangular main substrate 1. The main substrate 1 has a bonding surface that is in contact with the alloy strip and a non-bonding surface opposite to the bonding surface. The main substrate 1 is provided with an operating handle 2 and a fastening component 8 for aligning the side of the alloy strip. The operating handle 2 is located on the non-bonding surface, and the fastening component 8 extends at least to one side of the non-bonding surface of the main substrate 1.
[0035] The main substrate 1 is provided with scale lines 10 for positioning. There are two sets of scale lines 10, which are perpendicular to each other. The scale lines 10 are generally located at the edge of the main substrate 1, but can also be located in the middle of the main substrate 1. When the scale lines are in the middle, the main substrate 1 is made of a transparent plate to ensure that the scale lines 10 can be utilized.
[0036] The main substrate 1 has a calibration through-hole groove in the middle that connects the bonding surface and the non-bonding surface. The calibration through-hole grooves are all rectangular grooves. At least one calibration through-hole groove is provided with a slider 9 that slides with it to adjust the size of the calibration through-hole groove.
[0037] During actual sampling, the main substrate 1 is placed on the alloy strip to be calibrated. The corresponding calibration through-hole groove is selected according to the type of sample to be calibrated. The position of the main substrate 1 relative to the strip is adjusted according to the scale line 10 as needed. Then, the strip is fixed to the worktable with the fastening assembly 8. The two bolts are on the same vertical line, which can make the side of the alloy strip to be calibrated contact and position aligned with the fastening assembly 8, ensuring that the position of the main substrate 1 and the strip sample will not change and the sample will not warp. This prevents the bending of the strip from affecting the sampling position and accuracy. The fastening assembly 8 can be disassembled or installed according to the usage environment. The sampling personnel operate the handle 2 with one hand and use a marker to mark the calibrated through-hole groove according to the selected type of calibration. Multiple markings can be made at once for different samples. Then, the marking sample is cut with a shearing device, which greatly improves the accuracy and efficiency of alloy strip sampling.
[0038] See Figure 3 To prevent the main substrate 1 from scratching or abrading the alloy strip, an adhesive felt cloth 11 is provided on the bonding surface of the main substrate 1. The adhesive is 3M adhesive and can be replaced after wear and dirt.
[0039] In actual use, the calibration through-hole slots are roughly divided into the following categories according to requirements: bending test sample calibration through-hole slot 3 (size 10mm×120mm), cleanliness test sample calibration through-hole slot 4 (size 60mm×150mm), hardness test sample calibration through-hole slot 5 (size 40mm×40mm), conductivity test sample calibration through-hole slot 6 (size 40mm×60mm), and tensile test sample calibration through-hole slot 7 (size 40mm×(0-300)mm); the distance between two adjacent calibration through-hole slots is approximately 10mm.
[0040] The slider 9 is placed in the tensile specimen calibration through hole groove 7, and the edge of the tensile specimen calibration through hole groove 7 is provided with a scale line 10 that matches the slider 9. When the slider 9 moves, it can always be aligned with the scale line, which helps to improve the adjustment accuracy.
[0041] See Figure 4 The slider 9 has an extension 901 that fits with the clearance of the calibration through-hole groove, and the dimensional tolerance between the slider and the groove is [missing information]. mm; the bottom surface of the extension 901 is flush with the bonding surface of the main substrate 1, which is beneficial for marking along the slider 9.
[0042] In the above embodiment, the operating handle 2 and the fastening assembly 8 are located on two opposite sides of the main substrate 1, which helps to ensure stability during use. There are at least two fastening assemblies 8, and the center line connecting all the fastening assemblies 8 is parallel to one set of scale lines 10. After the two fastening assemblies 8 abut against the side of the alloy strip, the tilting of the main substrate 1 and the scale lines 10 can be avoided, ensuring the accuracy of the sample calibration.
[0043] Specifically, the main substrate 1 is provided with mounting holes corresponding to the fastening assembly 8. The fastening assembly 8 includes a bolt 801 that passes through the mounting hole of the main substrate 1, a washer 802 that is sleeved in the middle of the bolt 801, and a nut 803 that is threaded to the end of the bolt 801.
[0044] The parts not described in detail in the above embodiments are existing technologies.
[0045] It should be noted that although the present invention has been described through the above embodiments, there may be other various embodiments of the present invention. Without departing from the spirit and scope of the present invention, those skilled in the art can obviously make various corresponding changes and modifications to the present invention, but all such changes and modifications should fall within the scope of protection of the appended claims and their equivalents.
Claims
1. A calibration template for alloy plate and strip with multiple specifications and positioning measurement functions, characterized in that: It includes a rectangular main substrate (1), which has a bonding surface that is bonded to the alloy strip and a non-bonding surface opposite to the bonding surface. The main substrate (1) is provided with an operating handle (2) and a fastening assembly (8) for aligning the side of the alloy strip, wherein the operating handle (2) is located on the non-adhesive surface, and the fastening assembly (8) extends at least to one side of the non-adhesive surface of the main substrate (1). The main substrate (1) is provided with scale lines (10) for positioning. There are two sets of scale lines (10) that are perpendicular to each other. The main substrate (1) has a calibration through-hole groove in the middle that connects the bonding surface and the non-bonding surface. The calibration through-hole grooves are all rectangular grooves. At least one calibration through-hole groove is provided with a slider (9) that slides with it to adjust the size of the calibration through-hole groove.
2. The alloy plate and strip calibration template with multi-specification and positioning measurement functions according to claim 1, characterized in that: The calibration through-hole grooves include a calibration through-hole groove for bending test specimens (3), a calibration through-hole groove for cleanliness test specimens (4), a calibration through-hole groove for hardness test specimens (5), a calibration through-hole groove for conductivity test specimens (6), and a calibration through-hole groove for tensile test specimens (7).
3. The alloy plate and strip calibration template with multi-specification and positioning measurement functions according to claim 2, characterized in that: The slider (9) is located in the tensile specimen calibration through hole groove (7), and the edge of the tensile specimen calibration through hole groove (7) is provided with a scale line (10) that matches the slider (9).
4. The alloy plate and strip calibration template with multi-specification and positioning measurement functions according to claim 1, characterized in that: The operating handle (2) and the fastening assembly (8) are located on two opposite sides of the main substrate (1).
5. The alloy plate and strip calibration template with multi-specification and positioning measurement functions according to claim 1, characterized in that: There are at least two fastening components (8), and the center line of all fastening components (8) is parallel to one set of scale lines (10).
6. The alloy plate and strip calibration template with multi-specification and positioning measurement functions according to claim 1, characterized in that: The main substrate (1) is provided with mounting holes corresponding to the fastening assembly (8); The fastening assembly (8) includes a bolt (801) that passes through the mounting hole of the main substrate (1), a washer (802) is fitted in the middle of the bolt (801), and a nut (803) is threaded to the end of the bolt (801).
7. The alloy plate and strip calibration template with multi-specification and positioning measurement functions according to claim 1, characterized in that: Adhesive-backed felt cloth (11) is provided on the bonding surface of the main substrate (1).
8. The alloy plate and strip calibration template with multi-specification and positioning measurement functions according to claim 1, characterized in that: The main substrate (1) is a transparent plate.
9. A calibration template for alloy plate and strip with multi-specification and positioning measurement functions according to claim 1, characterized in that: The slider (9) has an extension (901) that is clearance-fitted with the calibration through-hole groove, and the bottom surface of the extension (901) is flush with the bonding surface of the main substrate (1).