A special ironing board with printed positioning

By using a special ironing plate with printing positioning, and combining an operating base plate, push-pull rails, and positioning plates, the problem of difficult printing positioning in traditional garment production is solved. This achieves precise alignment of printed patterns and efficient ironing, reduces the risk of print damage, and improves production consistency and safety.

CN224337948UActive Publication Date: 2026-06-09SHANDONG BAOWENSI CLOTHING TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANDONG BAOWENSI CLOTHING TECHNOLOGY CO LTD
Filing Date
2025-07-31
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In traditional garment production, the positioning of printed patterns is difficult, resulting in skewed patterns or excessive distances, low efficiency, and repeated ironing may damage the print, making it difficult to ensure consistency in mass production.

Method used

It adopts a special hot stamping plate with printing positioning, including an operating base plate, push-pull rail, push-pull plate and positioning plate. It achieves precise alignment of the printed pieces through positioning grooves and printing positioning windows. Combined with high temperature resistant materials and guide slider structure, it optimizes the heat conduction path and provides an ergonomic operating interface and directional heat dissipation.

Benefits of technology

This improved the accuracy of printing positioning, increased the efficiency of hot stamping, reduced printing damage, and ensured the consistency and safety of products produced in batches.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a special ironing plate with printing positioning, relating to the field of garment processing equipment. The special ironing plate with printing positioning includes an operating base plate, push-pull rails, push-pull plates, and a positioning plate. The operating base plate has a positioning groove, and the positioning plate has a printing positioning window for observing and aligning the print on the cut pieces. The push-pull rails are fixedly connected to both sides of the upper surface of the operating base plate, and the push-pull plates are respectively disposed at both ends of the operating base plate and slidably connected to the push-pull rails. This utility model, through the cooperation of the operating base plate, positioning groove, and positioning plate, combined with the printing positioning window, achieves precise alignment of the print on the cut pieces, solving the problems of difficult positioning, low efficiency, and easy damage to the print in traditional ironing processes. It has the advantages of improving printing positioning accuracy, increasing ironing efficiency, and reducing print damage.
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Description

Technical Field

[0001] This utility model belongs to the technical field of garment processing equipment, specifically, it relates to a special ironing plate with printing positioning. Background Technology

[0002] In the garment production process, cut pieces with prints, embroidery, or patterns need to be ironed to ensure that the edges of the cut pieces are neat and that the printed pattern is kept at a fixed distance from the clean edge. Traditional ironing process mainly relies on ordinary ironing templates. These templates can only control the fold width by the edge guard and cannot achieve precise positioning of the printed pattern. Workers need to manually fold the edges of the cut pieces and align the printed pattern by visual inspection. This process has many problems.

[0003] First, traditional methods are difficult to position. Because the fabric is prone to stretching or shifting during folding, it is difficult to ensure that the distance between the printed pattern and the edge is consistent by visual observation alone. This often results in skewed patterns or excessive distance, affecting the aesthetics and consistency of the finished product. Second, it is inefficient. For complex patterns, workers need to adjust the position of the cut pieces multiple times, which is not only time-consuming and labor-intensive, but also makes it difficult to ensure consistency in mass production. In addition, repeated ironing may damage the print, such as heat-induced peeling or discoloration, further reducing product quality. Therefore, this utility model is proposed. Utility Model Content

[0004] The technical problem to be solved by this utility model is to overcome the shortcomings of the prior art and provide a special hot stamping plate with printing positioning that can overcome or at least partially solve the above problems.

[0005] To solve the above-mentioned technical problems, the basic concept of the technical solution adopted by this utility model is as follows:

[0006] A special hot stamping plate with printing positioning includes a special hot stamping plate for printing positioning composed of an operating base plate, push-pull rails, push-pull plates, and positioning clean plates. The operating base plate has a positioning groove, and the positioning clean plates have a printing positioning window for observing and aligning the printed pieces. The push-pull rails are fixedly connected to both sides of the upper surface of the operating base plate. The push-pull plates are respectively disposed at both ends of the operating base plate and are slidably connected to the push-pull rails. The positioning clean plates are placed in the positioning groove of the operating base plate.

[0007] Preferably, the operating base plate, push-pull rail, push-pull plate, and positioning plate are all made of 0.5mm high-temperature resistant board.

[0008] Preferably, the push-pull track is provided with a guide groove, the side wall of the push-pull plate is provided with a groove, a guide slider is slidably connected in the groove, the guide slider is inserted into the guide groove, a spring is provided in the groove, one end of the spring is fixedly connected to the inner wall of the groove, and the other end is fixedly connected to the guide slider.

[0009] Furthermore, it also includes a push-pull groove, which is formed on the guide slider.

[0010] Preferably, the push-pull plate has multiple ventilation holes arranged in a U-shape, and the ventilation holes are round holes with a diameter of 8mm.

[0011] To facilitate the operation and movement of the push-pull plate, preferably, a push-pull hole is also included, which is formed on the push-pull plate.

[0012] In order to better adapt to different shapes of printed patterns and improve positioning accuracy, preferably, the shape of the printed positioning window is adapted to the outline of the printed pattern to be positioned.

[0013] By adopting the above technical solution, this utility model has the following beneficial effects compared with the prior art:

[0014] This invention achieves precise alignment of printed pieces by cooperating with the operating base plate, positioning groove and positioning plate, combined with the printing positioning window. It solves the problems of difficult positioning, low efficiency and easy damage to printing in traditional hot stamping process. It has the advantages of improving printing positioning accuracy, increasing hot stamping efficiency and reducing printing damage.

[0015] The replaceable positioning plate expands the applicability of the device, reduces repeated equipment investment, and reduces the risk of heat damage to the printed coating by a single ironing and shaping process. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the structure of this utility model. Figure 1 ;

[0017] Figure 2 This is a schematic diagram of the structure of this utility model. Figure 2 ;

[0018] Figure 3 This is a schematic diagram showing the unfolded structure of the operating base plate, push-pull slide rail, and push-pull plate of this utility model;

[0019] Figure 4 This is a cross-sectional view of the push-pull plate of this utility model;

[0020] Figure 5 This is a utility model Figure 4 Enlarged view of section A.

[0021] In the diagram: 1. Operating base plate; 101. Positioning groove; 2. Push-pull rail; 201. Push-pull plate; 202. Guide groove; 203. Groove; 204. Guide slider; 205. Spring; 206. Push-pull groove; 207. Ventilation hole; 208. Push-pull hole; 3. Positioning plate; 301. Printing positioning window. Detailed Implementation

[0022] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions in the embodiments will be clearly and completely described below with reference to the accompanying drawings. The following embodiments are used to illustrate this utility model, but are not intended to limit the scope of this utility model.

[0023] Example 1:

[0024] Reference Figure 1 , Figure 2 , Figure 3 A special hot stamping plate with printing positioning is provided, comprising an operating base plate 1, a push-pull rail 2, a push-pull plate 201, and a positioning plate 3. The operating base plate 1 is provided with a positioning groove 101, and the positioning plate 3 is provided with a printing positioning window 301 for observing and aligning the cutting piece for printing. The push-pull rail 2 is fixedly connected to both sides of the upper end face of the operating base plate 1. The push-pull plate 201 is respectively disposed on both ends of the operating base plate 1 and is slidably connected to the push-pull rail 2. The positioning plate 3 is placed in the positioning groove 101 of the operating base plate 1.

[0025] Among them, the operating base plate 1 refers to the main structure that supports the positioning groove 101 and the push-pull rail 2. Specifically, it can be made of high-temperature resistant sheet material to provide a stable installation reference for the positioning plate 3. The positioning groove 101 refers to the hollow area on the operating base plate 1. Specifically, it can be formed by milling or stamping process to accommodate the positioning plate 3 and limit its horizontal displacement. The push-pull rail 2 refers to the guide structure that extends along both sides of the operating base plate 1. Specifically, it can be made of metal profile or injection molded part and fixed to the surface of the base plate with high-temperature resistant glue to provide a linear movement path for the push-pull plate 201. The printing positioning window 301 refers to the hollow area on the positioning plate 3. Specifically, it can be formed by laser cutting to a shape that matches the pattern outline. During operation, the printing position of the cut piece can be observed through the window to achieve precise alignment.

[0026] Specifically, the special ironing plate for printing positioning is fixed on the breathable workbench to ensure that the operating base plate 1 is stable. Then, according to the specifications of the printed pattern on the cut piece, the positioning plate 3 corresponding to the printing positioning window 301 is selected and placed into the positioning groove 101 for fixation. The printed garment cut piece is placed with the reverse side facing up. Taking advantage of the light transmission of the fabric, the position of the printed pattern is observed and aligned through the printing positioning window 301. Then, the push-pull plates 201 at both ends of the operating base plate 1 are pushed to move them horizontally towards the middle along the push-pull track 2. The edges of the cut piece are folded to the preset width using the edges of the push-pull plates 201, and the pattern alignment and edge shaping are completed simultaneously. After the edge is folded, ironing is performed. After the ironing is completed, the positioning plate 3 is gently pushed to remove the processed cut piece. The operating base plate 1 and the push-pull track 2 remain fixed to avoid repeated calibration of the basic structure.

[0027] Compared with existing technologies, traditional methods require folding the edges of the cut pieces first and then manually adjusting the pattern position. This solution directly aligns the pattern with the printing positioning window 301 and completes the folding simultaneously, eliminating the cumulative error between the two operations. In existing technologies, the fixed edge guard cannot adapt to different folding widths. The sliding structure of the push-pull plate 201 in this solution allows for continuous adjustment, avoiding the need to change templates of different specifications. Traditional processes can easily damage the print by repeatedly ironing the same area. This solution can complete the shaping after one positioning, reducing the number of hot pressing times.

[0028] Through the above technical solution, this application achieves synchronous control of the fold width of the cut piece and the printing position, eliminating the pattern offset caused by manual visual inspection deviation. At the same time, the sliding structure of the push-pull plate 201 simplifies the operation steps, improves the ironing efficiency, and the replaceable positioning plate 3 expands the applicable range of the device, reduces repeated equipment investment, and reduces the risk of heat damage to the printing coating by high temperature in a single ironing and shaping process.

[0029] Example 2:

[0030] Reference Figure 1 , Figure 2 , Figure 3 A special hot stamping plate with printing positioning is basically the same as that in Example 1. Furthermore, the operating base plate 1, the push-pull track 2, the push-pull plate 201, and the positioning plate 3 are all made of 0.5mm high temperature resistant board.

[0031] High-temperature resistant boards refer to boards that have the ability to resist deformation under high-temperature environments. Specifically, they can be made of polyimide composite materials or ceramic matrix composite materials. These materials can maintain mechanical strength and dimensional stability under continuous heating conditions. The thickness parameter is determined by balancing structural strength and thermal conductivity. Specifically, it can be achieved by using thin boards on the order of 0.5 mm. This thickness can withstand ironing pressure and accelerate heat diffusion.

[0032] Specifically, the operating base plate 1, push-pull rail 2, push-pull plate 201, and positioning plate 3 are made of the same high-temperature resistant board, which ensures that each component has a consistent coefficient of thermal expansion during high-temperature operation, eliminating assembly gaps or movement jams caused by material differences. The high-temperature resistant properties keep the board flat during repeated ironing, avoiding printing positioning deviation caused by local deformation. The thin design optimizes the heat conduction path while ensuring structural rigidity, shortens the time heat stays on the board surface, and reduces the risk of printing material being damaged by overheating.

[0033] Compared with existing technologies, traditional ironing templates are made of ordinary metal or plastic, which are prone to thermal deformation during high-temperature ironing, causing the positioning reference to fail. In addition, push-pull components made of different materials are prone to movement stagnation due to differences in their expansion coefficients. This solution fundamentally solves the problems of component deformation and movement stability under high-temperature environments by using high-temperature resistant homogeneous materials throughout.

[0034] Through the above technical solutions, this application achieves the long-term stability of the hot plate structure in high-temperature operations, ensuring that the positioning accuracy of the printed pattern and the clean edge is always maintained within the process requirements. At the same time, by optimizing the heat conduction path, it reduces heat damage to the printing material and improves the batch production qualification rate and product consistency.

[0035] Example 3:

[0036] Reference Figure 1 , Figure 4 , Figure 5 A special hot stamping plate with printing positioning is basically the same as in Embodiment 1. Furthermore, the push-pull track 2 is provided with a guide groove 202, and the side wall of the push-pull plate 201 is provided with a groove 203. A guide slider 204 is slidably connected in the groove 203. The guide slider 204 is inserted into the guide groove 202. A spring 205 is provided in the groove 203. One end of the spring 205 is fixedly connected to the inner wall of the groove 203, and the other end is fixedly connected to the guide slider 204.

[0037] Among them, the guide groove 202 refers to the linear groove structure formed on the surface of the push-pull track 2, which can be realized by milling or stamping process, and is used to limit the movement path of the guide slider 204. The groove 203 refers to the cavity structure formed on the side wall of the push-pull plate 201, which can be realized by machining or molding, and is used to accommodate the guide slider 204 and provide sliding space. The guide slider 204 refers to the rigid component that slides with the groove 203, which can be made of metal or high-temperature resistant plastic, and is used to connect the push-pull plate 201 and the push-pull track 2 and transmit motion. The spring 205 refers to the element with elastic deformation capability, which can be realized by a spring 205 arranged in a spiral shape, and is used to absorb the impact force when the push-pull plate 201 moves and generate a reset effect.

[0038] Specifically, during the movement of the push-pull plate 201, the guide slider 204 slides linearly along the guide groove 202 to avoid path deviation. When the push-pull plate 201 is impacted by an external force, the guide slider 204 slides in the groove 203 and compresses the spring 205. The impact energy is buffered by elastic deformation. After the external force is released, the spring 205 pushes the guide slider 204 to automatically reset to the initial position. This process ensures the stability and reset accuracy of the push-pull plate 201 movement through the synergistic effect of mechanical guidance and elastic buffering.

[0039] Compared with existing technologies, the traditional push-pull structure of the hot stamping template lacks a buffer device. During the sliding process, it is easy to cause positioning deviation due to rigid collision, requiring repeated adjustment of the position of the push-pull plate 201. However, this solution absorbs impact energy and automatically resets during the sliding process through the cooperation of spring 205 and guide slider 204, reducing the number of manual interventions.

[0040] Through the above technical solution, this application can reduce the positioning deviation when the push-pull plate 201 slides, avoid the problem of misalignment of the printed pattern caused by repeated adjustments, and reduce the risk of heat damage to the printed material caused by repeated ironing.

[0041] Example 4:

[0042] Reference Figure 5 A special hot stamping plate with printing positioning is basically the same as that in Example 1. Furthermore, it also includes a push-pull groove 206, which is formed on the guide slider 204.

[0043] Among them, the push-pull groove 206 refers to the through hole structure set on the surface of the guide slider 204. Specifically, it can be realized by milling or stamping. This structure forms an operating interface that can be used to apply force. Its opening position is perpendicular to the slider movement axis, so that the direction of the operating force is consistent with the direction of slider movement.

[0044] Specifically, when the position of the push-pull plate 201 needs to be adjusted, the operator inserts his finger or a special tool into the push-pull groove 206 to apply a pushing or pulling force. The depth and width of the push-pull groove 206 are designed according to ergonomics. For example, the groove depth can be 3-5mm and the width can be 8-12mm. The applied force is transmitted to the guide slider 204 through the groove wall, causing it to move in the groove 203.

[0045] Compared with existing technologies, traditional hot stamping templates lack a dedicated user interface for their guide components. When adjusting them, users need to directly grasp the high-temperature metal parts, which poses a risk of burns and makes it difficult to apply precise control force. This solution improves the mechanical structure and adds an ergonomic user interface while maintaining the original sliding function.

[0046] Through the above technical solution, this application realizes the operation mode of precise single-handed control of push-pull stroke, solves the safety hazards of manual operation in high temperature environment, and the structural design of push-pull groove 206 makes the operation force transmission path completely coincide with the slider movement trajectory, avoiding positioning deviation caused by lateral component force.

[0047] Example 5:

[0048] Reference Figure 4 A special hot stamping plate with printing positioning is basically the same as that in Example 1. Furthermore, the push-pull plate 201 has multiple ventilation holes 207 distributed in a U-shape, and the ventilation holes 207 are round holes with a diameter of 8mm.

[0049] The U-shaped distribution refers to the symmetrical arrangement of the ventilation holes 207 along the edge of the push-pull plate 201, which can be achieved by stamping. This layout guides the high-temperature steam to form a uniform convection path when the push-pull plate 201 moves, avoiding excessive heat concentration in a specific area. The round holes refer to the circular opening structure of the ventilation holes 207, which can be achieved by laser cutting. The circular structure ensures the heat dissipation area while maintaining the overall strength of the push-pull plate 201 and preventing deformation under high temperature conditions.

[0050] Specifically, ventilation holes 207 are distributed along a U-shaped trajectory on the edge area of ​​the push-pull plate 201. When high-temperature steam passes through the push-pull plate 201, the symmetrically distributed holes allow the steam flow to diffuse evenly to the operating area, forming a stable heat exchange environment. The circular hole structure optimizes the stress distribution on the hole wall, maintaining the structural integrity of the push-pull plate 201 under continuous high-temperature conditions and avoiding a decrease in mechanical performance due to the opening. This solution improves heat dissipation efficiency while ensuring operational stability through the synergistic effect of layout and structure.

[0051] Compared with existing technologies, traditional hot stamping plates lack directional heat dissipation structures. Steam can easily form local high temperatures in the contact area between the push-pull plate 201 and the cut piece, causing heat damage to the print. This solution forms directional heat dissipation channels through U-shaped ventilation holes 207. Combined with the structural advantages of circular openings, it effectively reduces the risk of heat accumulation and avoids weakening the strength of the board due to openings.

[0052] Through the above technical solution, this application achieves uniform distribution of high-temperature steam during the hot plate operation, preventing local overheating from causing the print to fall off or change color, while ensuring the mechanical stability of the push-pull plate 201 in a high-temperature environment and avoiding the impact of structural deformation on positioning accuracy.

[0053] Example 6:

[0054] Reference Figure 1 , Figure 4A special hot stamping plate with printing positioning is basically the same as that in Example 1, but further includes a push-pull hole 208, which is formed on the push-pull plate 201.

[0055] Among them, the push-pull hole 208 refers to the through hole structure set on the push-pull plate 201. Specifically, it can be implemented by circular or elliptical holes. Its diameter or major axis size is adapted to the insertion needs of the operator's fingers or auxiliary tools. The position and layout of the hole must conform to the ergonomic principle to ensure that the direction of force is consistent with the sliding trajectory of the push-pull plate 201.

[0056] Specifically, the push-pull hole 208 serves as a force application fulcrum, allowing the operator to apply pushing or pulling force by inserting fingers or tools into the hole. When the push-pull plate 201 moves along the track, the force application point and the center of gravity of the push-pull plate 201 form a mechanical balance, thereby preventing deviation or jamming during the push-pull process. The inner wall of the push-pull hole 208 can be provided with anti-slip texture or covered with heat insulation material to enhance operational stability and reduce the risk of heat conduction.

[0057] Compared with existing technologies, the traditional hot stamping template's push-pull plate 201 lacks a dedicated force-applying structure. During operation, the plate surface needs to be pressed directly, which can easily cause the cut pieces to shift due to uneven force application. In contrast, this solution forms a clear force transmission path through the push-pull hole 208, ensuring that the vector direction of the push-pull action is strictly aligned with the track guide, thus eliminating positioning errors caused by manual force application deviations.

[0058] Through the above technical solution, this application realizes that the push-pull plate 201 can complete precise positioning in a single operation, reducing the number of repeated adjustments. During the operation, there is no need to directly contact the high-temperature area, reducing the risk of burns. At the same time, the mechanical limiting function provided by the push-pull hole 208 ensures the consistency of the distance between the printed piece and the clean edge.

[0059] Example 7:

[0060] Reference Figure 1 , Figure 3 A special hot stamping plate with printing positioning is basically the same as that in Example 1. Furthermore, the shape of the printing positioning window 301 is adapted to the outline of the printing pattern to be positioned.

[0061] The printing positioning window 301 refers to a transparent or hollowed-out area set on the positioning plate 3. Its boundary shape matches the outer contour of the target printing pattern. Specifically, the window shape can be made consistent with the pattern by laser cutting or mold forming process. The visual reference boundary provides a physical alignment benchmark for the placement of the cut piece. The matching means that the outline of the window and the outline of the printing pattern are complementary or mirrored in shape and size. Specifically, the window boundary can be designed in reverse after measuring the edge features of the pattern, so that the edge of the pattern on the cut piece can completely coincide with the window boundary, thereby eliminating the positioning error caused by manual estimation.

[0062] Specifically, during the placement of the cut pieces, the operator covers the cut pieces onto the positioning blank plate 3 and observes the position of the printed pattern below through the printing positioning window 301. Since the shape of the window perfectly matches the outline of the pattern, when the edge of the pattern coincides with the boundary of the window, it indicates that the cut piece is in the correct position. At this time, the edge of the cut piece is fixed by the push-pull plate 201 and ironed to ensure that the distance between the printed pattern and the blank edge after folding meets the preset requirements. This adaptation structure directly uses the outline of the pattern itself as the alignment reference, avoiding visual judgment deviations caused by fabric deformation or folding errors, while reducing the operation time loss caused by repeated adjustments.

[0063] Compared with existing technologies, traditional methods rely on operators to visually estimate the relative position of the pattern and the edge, which is easily affected by factors such as fabric elasticity and folding angle, resulting in pattern offset or distance exceeding tolerance. In contrast, this solution transforms subjective visual judgment into objective shape comparison by accurately matching the physical window boundary with the pattern outline, making the alignment process repeatable and consistent, and is especially suitable for positioning printed patterns with complex outlines.

[0064] Through the above technical solution, this application solves the problem of printed pattern offset caused by inaccurate visual alignment in traditional processes, realizes precise control of the distance between the printed pattern and the clean edge when folding the cut pieces, and reduces the number of ironing times caused by repeated adjustments, thereby reducing the risk of heat damage to the printed coating caused by high temperature.

[0065] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model in any way. Although the present utility model has been disclosed above with reference to a preferred embodiment, it is not intended to limit the present utility model.

Claims

1. A custom ironing board with printed positioning, characterized in that, The printing positioning special hot stamping plate is composed of an operating base plate (1), a push-pull rail (2), a push-pull plate (201), and a positioning plate (3). The operating base plate (1) is provided with a positioning groove (101), and the positioning plate (3) is provided with a printing positioning window (301) for observing and aligning the cutting pieces for printing. The push-pull rail (2) is fixedly connected to both sides of the upper end face of the operating base plate (1). The push-pull plate (201) is respectively set on both ends of the operating base plate (1) and is slidably connected to the push-pull rail (2). The positioning plate (3) is placed in the positioning groove (101) of the operating base plate (1).

2. A custom ironing board with printed positioning according to claim 1, characterized in that, The operating base plate (1), push-pull rail (2), push-pull plate (201), and positioning plate (3) are all made of 0.5mm high-temperature resistant board.

3. A custom ironing board with printed positioning according to claim 1, characterized in that, The push-pull track (2) is provided with a guide groove (202), and the side wall of the push-pull plate (201) is provided with a groove (203). A guide slider (204) is slidably connected in the groove (203). The guide slider (204) is inserted into the guide groove (202). A spring (205) is provided in the groove (203). One end of the spring (205) is fixedly connected to the inner wall of the groove (203), and the other end is fixedly connected to the guide slider (204).

4. A special hot stamping plate with printing positioning according to claim 3, characterized in that, It also includes a push-pull groove (206) which is formed on the guide slider (204).

5. A special hot stamping plate with printing positioning according to claim 1, characterized in that, The push-pull plate (201) has multiple ventilation holes (207) arranged in a U-shape, and the ventilation holes (207) are round holes with a diameter of 8mm.

6. A special hot stamping plate with printing positioning according to claim 1, characterized in that, It also includes a push-pull hole (208) which is formed on the push-pull plate (201).

7. A special hot stamping plate with printing positioning according to claim 1, characterized in that, The shape of the printing positioning window (301) is adapted to the outline of the printing pattern to be positioned.