A stabilizer for stacking silicon steel sheets
By designing an adjustable silicon steel sheet stabilizer, and utilizing a servo motor to drive a threaded rod and a locking structure, the problem of poor applicability of existing stabilizers to silicon steel sheets of different sizes is solved, achieving neat stacking and high adaptability of silicon steel sheets.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WUHAN WANCHANG ELECTROMECHANICAL EQUIP CO LTD
- Filing Date
- 2025-07-18
- Publication Date
- 2026-06-30
AI Technical Summary
Existing stabilizers are not suitable for silicon steel sheets of different sizes, resulting in large slippage space and poor uniformity when smaller silicon steel sheets are stacked.
A stabilizer comprising a base, a main clamping plate, a secondary clamping plate, an adjustment assembly, and a mounting assembly is designed. The clamping plate is adjusted by sliding a threaded rod driven by a servo motor, and combined with a rubber pad and a locking structure, it achieves flexible positioning and orderly pushing of silicon steel sheets of different sizes.
It enables the neat stacking of silicon steel sheets of different sizes, avoids wear, improves applicability, and adapts to changes in the overall height of different numbers of silicon steel sheets.
Smart Images

Figure CN224437386U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of silicon steel sheet stacking technology, and in particular relates to a stabilizer for silicon steel sheet stacking. Background Technology
[0002] Silicon steel sheets are a type of silicon-iron soft magnetic alloy with extremely low carbon content. They are widely used in the manufacture of cores for transformers, motors, and generators. In the process of producing and processing them, multiple silicon steel sheets need to be stacked together. In order to ensure the neatness of the stacked silicon steel sheets, a corresponding stabilizer is required to limit their stacking.
[0003] Chinese patent discloses a silicon steel sheet stacking device, publication number CN220684016U. The document states that it "includes a box; a second guide rail is provided on the upper side wall of the box, a first rotating shaft is provided on both sides of the box, a partition block is provided on the first rotating shaft, a torsion spring is provided at the connection between the partition block and the first rotating shaft, a slide is provided below the front end of the partition block, a groove is provided above the partition block, a feeding plate is provided on the second guide rail, and the feeding plate is moved by a hydraulic rod; by setting the partition block, the silicon steel sheets are layered during stacking, so that the first silicon steel sheet falls into the first groove for positioning, and then the second silicon steel sheet is stacked on top of the first silicon steel sheet. After stacking, the silicon steel sheets are moved upward by the hydraulic rod, so that the holes on the silicon steel sheets pass through the fixing rod, thereby achieving stacking and fixing of the silicon steel sheets."
[0004] However, the above solution is inconvenient to limit the silicon steel sheets of different sizes. This makes it difficult to stack smaller silicon steel sheets neatly because the limiting space is large. Therefore, it is necessary to design a stabilizer for stacking silicon steel sheets. Utility Model Content
[0005] This utility model provides a stabilizer for stacking silicon steel sheets, which aims to solve the problem that some currently used stabilizers are inconvenient to use with silicon steel sheets of different sizes.
[0006] This utility model is implemented as follows: a stabilizer for stacking silicon steel sheets includes a base; a controller fixedly connected to one side of the front of the base; a main support plate fixedly connected to the middle position of the top of the base; a secondary support plate fixedly connected to the top of the base at equal angles; a main clamping plate equally angled at the top of the base; a secondary clamping plate at the top of the main clamping plate; an installation assembly mounted on the main clamping plate and the secondary clamping plate, the installation assembly being used to assemble different numbers of secondary clamping plates; a cavity formed inside the base; and an adjustment assembly mounted inside the cavity, the adjustment assembly being used to achieve sliding adjustment of the four main clamping plates.
[0007] The adjustment assembly includes: a limiting groove formed in the top wall of the cavity; a first threaded rod rotatably connected to the upper end of the cavity inner wall, with first threaded blocks threaded to both ends of the surface of the first threaded rod, and the top end of the first threaded block fixedly connected to the bottom end of two of the main clamping plates; a second threaded rod rotatably connected to the lower end of the cavity inner wall, with second threaded blocks threaded to both ends of the surface of the second threaded rod, and the top end of the second threaded block fixedly connected to the bottom end of two of the main clamping plates; and a first servo motor and a second servo motor fixedly connected to the surface of the base, the first servo motor and the second servo motor being fixedly connected to one end of the first threaded rod and the second threaded rod respectively via couplings.
[0008] Preferably, the upper ends of the first threaded block and the second threaded block respectively form a sliding structure with the interior of the limiting groove, and there are four limiting grooves distributed at equal angles.
[0009] Preferably, the secondary support plates are distributed at equal angles at the top of the base, and the top of the secondary support plates and the top of the main support plates are in the same horizontal plane.
[0010] Preferably, a second rubber pad is fixedly connected to one side of the main clamping plate, and a first rubber pad is fixedly connected to one side of the auxiliary clamping plate.
[0011] Preferably, the mounting assembly includes: symmetrically formed slots at the top of the main clamping plate and the auxiliary clamping plate; a fixing groove formed at the upper end of one side of the main clamping plate and the auxiliary clamping plate, wherein a reserved groove penetrating the main clamping plate and the auxiliary clamping plate is formed on one side of the fixing groove; symmetrically slidably connected sliding blocks inside the fixing groove, one end of the sliding blocks extending into the interior of the slot, and a lever penetrating the reserved groove is fixedly connected to one side of the sliding blocks; a mounting spring fixedly connected between the two sliding blocks; and symmetrically fixedly connected locking blocks at the bottom of the auxiliary clamping plate, wherein one end of the locking blocks has a mounting hole.
[0012] Preferably, the card block and the inside of the card slot form an engaging structure, and the shape of the card block is cylindrical.
[0013] Preferably, it further includes a mounting rod, one end of which forms an engaging structure with the interior of the mounting hole, and the other end of which is integrally welded to one side of the sliding block.
[0014] Preferably, one end of the lever is a ball, and the lever and the interior of the reserved groove form a sliding structure.
[0015] Preferably, the inner top wall and inner bottom wall of the fixing groove are provided with sliding grooves, and the two ends of the sliding block are fixedly connected with sliders that slide and cooperate with the inside of the sliding groove.
[0016] Compared with related technologies, the stabilizer for stacking silicon steel sheets provided by this utility model has the following beneficial effects:
[0017] 1. When a certain number of silicon steel sheets are stacked, the actuators can be started and driven to rotate, causing the actuators to slide. This, in turn, drives the four actuators to slide and push the stacked silicon steel sheets, making the stacked silicon steel sheets more neat. The actuators and drive can achieve flexible contact between the actuators and the silicon steel sheets, avoiding excessive pushing that could cause wear on the surface of the silicon steel sheets. At the same time, the sliding actuators and drive can push silicon steel sheets of different sizes neatly, avoiding the cumbersome inconvenience of traditional stacking only silicon steel sheets of the same size, thus improving its applicability.
[0018] 2. By utilizing the internal locking mechanism and the elasticity, the sliding mechanism drives the locking mechanism inward or outward, thereby enabling quick assembly and disassembly between the locking mechanism and the other mechanism. Furthermore, by installing different numbers of locking mechanisms, the overall height of the locking mechanism can be changed, allowing it to accommodate different numbers of stacked silicon steel sheets. This ensures the flatness of pushing different numbers of silicon steel sheets and avoids the limitation that a large number of stacked silicon steel sheets would result in excessive height and prevent the upper part from being pushed neatly. Attached Figure Description
[0019] Figure 1 This is a front view structural diagram of the present utility model;
[0020] Figure 2 This is a partial cross-sectional structural diagram of the present invention from another perspective;
[0021] Figure 3 This is a top view of the base structure of this utility model;
[0022] Figure 4 This is a partial exploded cross-sectional view of the main clamping plate and the auxiliary clamping plate of this utility model;
[0023] Figure 5 For the present utility model Figure 4 Enlarged structural diagram at point A in the middle.
[0024] In the diagram: 1. First rubber pad; 2. Mounting assembly; 201. Mounting hole; 202. Locking block; 203. Locking groove; 204. Mounting rod; 205. Lever; 206. Mounting spring; 207. Slider; 208. Sliding block; 209. Reserved groove; 210. Fixing groove; 211. Sliding groove; 3. Second rubber pad; 4. Secondary support plate; 5. Controller; 6. Main support plate; 7. Base; 8. Adjustment assembly; 801. First servo motor; 802. First threaded block; 803. First positive and negative threaded rod; 804. Second positive and negative threaded rod; 805. Second servo motor; 806. Second threaded block; 807. Limiting groove; 9. Main clamping plate; 10. Secondary clamping plate; 11. Cavity. Detailed Implementation
[0025] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs; the terminology used herein in the specification of the application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application; the terms "comprising" and "having," and any variations thereof, in the specification, claims, and foregoing drawings of this application are intended to cover non-exclusive inclusion. The terms "first," "second," etc., in the specification, claims, or foregoing drawings of this application are used to distinguish different objects, not to describe a particular order.
[0026] In this document, the term "embodiment" means that a particular feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of this application. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.
[0027] Example 1
[0028] A preferred embodiment of the silicon steel sheet stacking stabilizer provided by this utility model is, for example... Figures 1 to 5 As shown: A stabilizer for stacking silicon steel sheets includes a base 7; a controller 5 fixedly connected to one side of the front of the base 7; a main support plate 6 fixedly connected to the middle position of the top of the base 7; a secondary support plate 4 fixedly connected to the top of the base 7 at equal angles; a main clamping plate 9 set at equal angles at the top of the base 7; a secondary clamping plate 10 set at the top of the main clamping plate 9; an installation assembly 2 assembled on the main clamping plate 9 and the secondary clamping plate 10, the installation assembly 2 being used to splice and assemble different numbers of secondary clamping plates 10; a cavity 11 opened inside the base 7; and an adjustment assembly 8 assembled inside the cavity 11, the adjustment assembly 8 being used to realize the sliding adjustment of the four main clamping plates 9.
[0029] The adjustment assembly 8 includes: a limiting groove 807 formed in the top wall of the cavity 11; a first threaded rod 803 rotatably connected to the upper end of the inner wall of the cavity 11, with first threaded blocks 802 threaded to both ends of the surface of the first threaded rod 803, the top of the first threaded blocks 802 being fixedly connected to the bottom ends of two main clamping plates 9; a second threaded rod 804 rotatably connected to the lower end of the inner wall of the cavity 11, with second threaded blocks 806 threaded to both ends of the surface of the second threaded rod 804, the top of the second threaded blocks 806 being fixedly connected to the bottom ends of two main clamping plates 9; and a first servo motor 801 and a second servo motor 805 respectively fixedly connected to the surface of the base 7, the first servo motor 801 and the second servo motor 805 being fixedly connected to one end of the first threaded rod 803 and the second threaded rod 804 respectively via couplings.
[0030] It should be noted that some existing stabilizers for stacking silicon steel sheets still have certain shortcomings in actual use. They are not convenient for limiting the position of silicon steel sheets of different sizes. This means that when some smaller silicon steel sheets are stacked, the larger limiting space allows for a certain amount of slippage, which is not conducive to the neat stacking of smaller silicon steel sheets.
[0031] In this embodiment, the base 7 is first installed and fixed in a suitable position, then an external power supply is connected. Then, different numbers of sub-clamping plates 10 are assembled according to the final height of the stacked silicon steel sheets. At this time, the mounting assembly 2 is used to install the sub-clamping plates 10 with the main clamping plates 9 or between sub-clamping plates 10. Then, the silicon steel sheets are stacked on top of the sub-support plate 4 and the main support plate 6, positioned between the four main clamping plates 9 and the sub-clamping plates 10. After a certain number of silicon steel sheets are stacked, the first servo motor 801 and the second servo motor 805 can be started respectively, driving the first forward and reverse... The rotation of threaded rod 803 and the second positive and negative threaded rod 804 causes the first threaded block 802 and the second threaded block 806 to slide, which in turn drives the four main clamping plates 9 and the auxiliary clamping plates 10 to slide and push the stacked silicon steel sheets, making the stacked silicon steel sheets more neat. The sliding main clamping plates 9 and auxiliary clamping plates 10 can push silicon steel sheets of different sizes neatly, improving their applicability. Furthermore, by using the first rubber pad 1 and the mounting component 2, the main clamping plates 9 and auxiliary clamping plates 10 can achieve flexible contact with the silicon steel sheets, avoiding excessive pushing that could cause wear on the surface of the silicon steel sheets.
[0032] In a further preferred embodiment of the present invention, the upper ends of the first threaded block 802 and the second threaded block 806 respectively form a sliding structure with the interior of the limiting groove 807, and there are four limiting grooves 807 distributed at equal angles.
[0033] In this embodiment, the sliding of the upper ends of the first threaded block 802 and the second threaded block 806 with the inside of the limiting groove 807 is used to prevent the first positive and negative threaded rod 803 and the second positive and negative threaded rod 804 from rotating and thus causing the first threaded block 802 and the second threaded block 806 to rotate.
[0034] In a further preferred embodiment of this utility model, the secondary support disks 4 are distributed at equal angles on the top of the base 7, and the top of the secondary support disks 4 and the top of the main support disks 6 are in the same horizontal plane.
[0035] In this embodiment, the secondary support plate 4 and the main support plate 6 are on the same horizontal plane, which facilitates the support and placement of larger silicon steel sheets.
[0036] In a further preferred embodiment of the present invention, a second rubber pad 3 is fixedly connected to one side of the main clamping plate 9, and a first rubber pad 1 is fixedly connected to one side of the auxiliary clamping plate 10.
[0037] In this embodiment, by using the first rubber pad 1 and the mounting component 2, flexible contact between the main clamping plate 9 and the secondary clamping plate 10 and the silicon steel sheet can be achieved, avoiding excessive pushing that could cause wear on the surface of the silicon steel sheet.
[0038] Example 2
[0039] Based on Example 1, a preferred embodiment of the stabilizer for stacking silicon steel sheets provided by this utility model is, for example... Figures 1 to 5 As shown: The mounting assembly 2 includes: slots 203 symmetrically formed at the top of the main clamping plate 9 and the auxiliary clamping plate 10; a fixing groove 210 formed at the upper end of one side of the main clamping plate 9 and the auxiliary clamping plate 10, with a reserved groove 209 through the main clamping plate 9 and the auxiliary clamping plate 10 on one side of the fixing groove 210; sliding blocks 208 symmetrically slidably connected inside the fixing groove 210, with one end of the sliding block 208 extending into the inside of the slot 203, and a lever 205 through the reserved groove 209 fixedly connected to one side of the sliding block 208; a mounting spring 206 fixedly connected between the two sliding blocks 208; and a locking block 202 symmetrically fixedly connected to the bottom of the auxiliary clamping plate 10, with a mounting hole 201 at one end of the locking block 202.
[0040] In this embodiment, by moving the lever 205, the sliding block 208 is slidably compressed and the mounting spring 206 is compressed, and the mounting rod 204 is slid until it is fully inserted into the fixing groove 210. Then, the locking block 202 on the sub-clamping plate 10 is locked into the slot 203. Then, the lever 205 is released, and the elastic force of the mounting spring 206 is used to make the sliding block 208 slide and drive the mounting rod 204 to slide and lock into the mounting hole 201, so that the locking block 202 and the slot 203 are firmly locked together. This allows the sub-clamping plate 10 to be locked together with the top of the main clamping plate 9. By repeating the above operation, different numbers of sub-clamping plates 10 can be assembled, thereby changing the overall height of the main clamping plate 9 and the sub-clamping plate 10, so that it can be adapted to the overall height of different numbers of silicon steel sheets stacked together, ensuring the flatness of pushing different numbers of silicon steel sheets.
[0041] In a further preferred embodiment of the present invention, the card block 202 and the card slot 203 form an engaging structure, and the shape of the card block 202 is cylindrical.
[0042] In this embodiment, the engagement between the card block 202 and the card slot 203 is used to achieve the initial engagement and fixation between the secondary clamping plate 10 and the main clamping plate 9 or between the secondary clamping plate 10 and the secondary clamping plate 10.
[0043] In a further preferred embodiment of the present invention, one end of the mounting rod 204 and the interior of the mounting hole 201 form a locking structure, and one end of the mounting rod 204 and one side of the sliding block 208 form a welded integrated structure.
[0044] In this embodiment, the engagement of one end of the mounting rod 204 with the inside of the mounting hole 201 ensures the limiting and locking of the locking block 202 after it engages with the slot 203.
[0045] In a further preferred embodiment of the present invention, one end of the lever 205 is a ball, and a sliding structure is formed between the lever 205 and the interior of the reserved groove 209.
[0046] In this embodiment, a lever 205 with a ball is used to avoid discomfort caused by the user's finger touching one end of the lever 205.
[0047] In a further preferred embodiment of the present invention, the inner top wall and inner bottom wall of the fixing groove 210 are provided with sliding grooves 211, and the two ends of the sliding block 208 are fixedly connected with sliders 207 that slide and cooperate with the inside of the sliding groove 211.
[0048] In this embodiment, the sliding smoothness of the sliding block 208 is improved by utilizing the sliding of the slider 207 and the inside of the groove 211.
[0049] In summary, the sliding of the four adjustment components 8 is achieved by using the adjustment components 8, which facilitates the pushing of silicon steel sheets of different sizes, making it suitable for the neat pushing of stacked silicon steel sheets of different sizes. At the same time, the installation components 2 are used to realize the disassembly and assembly between the main clamping plate 9 and the secondary clamping plate 10 or between the secondary clamping plates 10. In this way, by assembling different numbers of secondary clamping plates 10, the overall height of the main clamping plate 9 and the secondary clamping plates 10 can be changed, making it suitable for the overall height of stacked silicon steel sheets of different numbers.
[0050] It is worth noting that the circuits, electronic components, and modules involved in this utility model are all existing technologies, which can be fully implemented by those skilled in the art, and need not be elaborated upon. The content protected by this utility model does not involve any improvement to the software and methods.
[0051] It should be understood that the disclosed apparatus can be implemented in other ways, given the several embodiments provided in this application. For example, the apparatus embodiments described above are merely illustrative; the division of units described above is only a logical functional division, and in actual implementation, there may be other division methods. For example, multiple units or components may be combined or integrated into another system, or some features may be ignored or not executed. Furthermore, the coupling or communication connections shown or discussed may be through some interfaces; the indirect coupling or communication connections between devices or units may be telecommunications or other forms.
[0052] The above embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit the scope of protection of this utility model. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on these embodiments, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model. Although this utility model has been described in detail with reference to the above embodiments, those skilled in the art can still combine, add, delete, or otherwise adjust the features of the various embodiments of this utility model according to the circumstances without conflict or creative effort, thereby obtaining different technical solutions that do not fundamentally depart from the concept of this utility model. These technical solutions are also within the scope of protection of this utility model.
Claims
1. A stabilizer for stacking silicon steel sheets, characterized in that, include: Base (7); A controller (5) is fixedly connected to one side of the front of the base (7). A main support plate (6) is fixedly connected to the middle position of the top of the base (7). A secondary support plate (4) is fixedly connected to the top of the base (7) at the same angle. A main clamping plate (9) is set at the top of the base (7) at equal angles, and a secondary clamping plate (10) is set at the top of the main clamping plate (9). Mounting assembly (2) is mounted on the main clamping plate (9) and the sub-clamping plate (10), the mounting assembly (2) being used to splice and assemble different numbers of sub-clamping plates (10). A cavity (11) is formed inside the base (7); An adjustment assembly (8) is assembled inside the cavity (11), the adjustment assembly (8) being used to achieve sliding adjustment of the four main clamping plates (9); The adjustment component (8) includes: A limiting groove (807) is formed in the top wall of the cavity (11). A first positive and negative threaded rod (803) is rotatably connected to the upper end of the inner wall of the cavity (11). The two ends of the surface of the first positive and negative threaded rod (803) are threaded with a first threaded block (802). The top end of the first threaded block (802) is fixedly connected to the bottom end of two of the main clamping plates (9). A second positive and negative threaded rod (804) is rotatably connected to the lower end of the inner wall of the cavity (11). The two ends of the surface of the second positive and negative threaded rod (804) are threaded with a second threaded block (806). The top end of the second threaded block (806) is fixedly connected to the bottom end of two of the main clamping plates (9). A first servo motor (801) and a second servo motor (805) are fixedly connected to the surface of the base (7), respectively. The first servo motor (801) and the second servo motor (805) are fixedly connected to one end of the first positive and negative threaded rod (803) and the second positive and negative threaded rod (804) through couplings.
2. The stabilizer for stacking silicon steel sheets as described in claim 1, characterized in that, The upper ends of the first threaded block (802) and the second threaded block (806) respectively form a sliding structure with the interior of the limiting groove (807), and there are four limiting grooves (807) distributed at equal angles.
3. The stabilizer for stacking silicon steel sheets as described in claim 1, characterized in that, The secondary support disks (4) are distributed at equal angles at the top of the base (7), and the top of the secondary support disks (4) and the top of the main support disks (6) are on the same horizontal plane.
4. The stabilizer for stacking silicon steel sheets as described in claim 1, characterized in that, A second rubber pad (3) is fixedly connected to one side of the main clamping plate (9), and a first rubber pad (1) is fixedly connected to one side of the auxiliary clamping plate (10).
5. The stabilizer for stacking silicon steel sheets as described in claim 1, characterized in that, The installation component (2) includes: The slots (203) are symmetrically opened at the top of the main clamping plate (9) and the auxiliary clamping plate (10). A fixing groove (210) is formed on the upper side of one side of the main clamping plate (9) and the auxiliary clamping plate (10), and a reserved groove (209) is formed on one side of the fixing groove (210) that penetrates the main clamping plate (9) and the auxiliary clamping plate (10). A sliding block (208) is symmetrically slidably connected inside the fixed groove (210). One end of the sliding block (208) extends into the inside of the slot (203). A lever (205) that passes through the reserved groove (209) is fixedly connected to one side of the sliding block (208). A mounting spring (206) is fixedly connected between the two sliding blocks (208); A locking block (202) is symmetrically fixedly connected to the bottom end of the auxiliary clamping plate (10), and one end of the locking block (202) is provided with a mounting hole (201).
6. The stabilizer for stacking silicon steel sheets as described in claim 5, characterized in that, The card block (202) and the card slot (203) form an engaging structure, and the card block (202) is cylindrical in shape.
7. The stabilizer for stacking silicon steel sheets as described in claim 5, characterized in that, It also includes a mounting rod (204), one end of which forms a locking structure with the interior of the mounting hole (201), and the other end of which is welded to one side of the sliding block (208).
8. The stabilizer for stacking silicon steel sheets as described in claim 5, characterized in that, One end of the lever (205) is a ball, and the lever (205) and the interior of the reserved groove (209) form a sliding structure.
9. The stabilizer for stacking silicon steel sheets as described in claim 5, characterized in that, The inner top wall and inner bottom wall of the fixed groove (210) are provided with sliding grooves (211), and the two ends of the sliding block (208) are fixedly connected with sliders (207) that slide in cooperation with the inside of the sliding groove (211).