Handmade soap embossing press with replaceable templates
The automated operation of the embossing machine is achieved by using a belt conveyor and an automated drive mechanism, which solves the problem of manual loading and unloading in the existing technology and improves production efficiency and finished product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JINZAOFANG (HANGZHOU) BIOTECHNOLOGY CO LTD
- Filing Date
- 2025-05-24
- Publication Date
- 2026-07-03
AI Technical Summary
Existing embossing machines require manual loading and unloading, which is labor-intensive and has low processing efficiency.
The system employs a belt conveyor in conjunction with a detachable embossing plate and an automated drive mechanism to achieve automatic replacement of the embossing plate and automation of the embossing process. The embossing plate is automatically pressed down and reset through a reset spring and a force application mechanism. The drive mechanism drives the rotating plate to rotate and switch templates.
It reduces labor intensity, improves production efficiency, ensures automation and precision in the embossing process, and enhances the aesthetics and quality stability of the finished product.
Smart Images

Figure CN224450618U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of embossing technology, specifically relating to a handmade soap relief embossing tool with replaceable templates. Background Technology
[0002] Handmade soaps are cleaning products made by hand. They are mainly made by saponifying natural oils (such as olive oil, coconut oil, and palm oil) with lye (usually sodium hydroxide or potassium hydroxide). Essential oils, herbs, and other natural ingredients can be added during the process. The core feature is that it retains the natural glycerin produced by the saponification reaction, so it has good moisturizing properties and is gentle on the skin, making it suitable for sensitive skin.
[0003] Embossing is a tool that uses physical pressure to create a three-dimensional relief effect on the surface of a material. It is widely used in handicrafts, industrial production and other fields. Its core principle is to use a mold or roller with raised patterns to apply pressure to the surface of the material, causing the material to be locally concave or deformed, thereby presenting a three-dimensional pattern or design. It is a commonly used piece of equipment in handmade soap making.
[0004] For example, in the prior art, Chinese utility model patent with authorization announcement number CN219789472U discloses "a paper embossing device", which includes an embossing device. The embossing device cover includes an upper cover body and a replacement structure. An opening is provided on one side of the upper cover body, and the replacement structure is fixedly connected in the opening. The embossing device base plate includes a base plate body, a spring and a metal pad. One end of the top of the base plate body is fixedly connected to one end of the spring, and the other end of the spring is fixedly connected to the bottom end of the upper cover body. The other end of the top of the base plate body is fixedly connected to the bottom end of the metal pad.
[0005] While existing embossing machines, including those mentioned above, can meet general processing needs, they require manual loading and unloading, resulting in high labor intensity and low processing efficiency.
[0006] To address the aforementioned issues, this utility model proposes a replaceable template handmade soap embossing tool. Utility Model Content
[0007] To address the aforementioned problems in the existing technology, this utility model provides a replaceable template handmade soap embossing tool, which is convenient to use and has high production efficiency.
[0008] To achieve the above objectives, this utility model provides the following technical solution: a replaceable template handmade soap embossing machine, including a belt conveyor, and further comprising:
[0009] Two side panels are symmetrically fixed to the top of the belt conveyor.
[0010] Top plate, the top plate being fixed to the top of the side upright plate;
[0011] A rotating plate, which is rotatably connected to the top plate;
[0012] Molding assembly, wherein the molding assembly includes:
[0013] Multiple embossed boards are distributed at equal intervals along the circumferential direction, and the bottom surface of the embossed boards has a raised pattern.
[0014] A connecting column, which is detachably fixed to the top surface of the embossed plate and passes through the rotating plate;
[0015] A lifting plate, which is fixed to the top of the connecting column;
[0016] A return spring is sleeved on the connecting column and located between the rotating plate and the lifting plate;
[0017] A force-applying mechanism, used to press down the lifting plate;
[0018] A drive mechanism is provided to drive the rotating plate to rotate.
[0019] In a preferred embodiment of this utility model, there are four connecting columns and four reset springs arranged diagonally.
[0020] As a preferred embodiment of this utility model, it further includes:
[0021] A flange, which is fixed to the bottom end of the connecting column;
[0022] The flange is connected to the embossed plate by a plurality of locking bolts that are equally spaced along the circumference.
[0023] As a preferred embodiment of this utility model, the force-applying mechanism includes:
[0024] An inverted L-shaped bracket, which is fixed to the top surface of the top plate;
[0025] A pressure block, located below the horizontal portion of the inverted L-shaped bracket and directly opposite the lifting plate;
[0026] A vertical cylinder is fixed to the top surface of the horizontal part of the inverted L-shaped bracket, and the piston rod of the vertical cylinder passes through the horizontal part of the inverted L-shaped bracket and is connected to the pressure block.
[0027] As a preferred embodiment of this utility model, the driving mechanism includes:
[0028] A rotating column, which is rotatably connected to the top plate, and the rotating plate is fixed to the bottom end of the rotating column;
[0029] Driven synchronous pulley, the driven synchronous pulley is fixed on the rotating column;
[0030] An inverted L-shaped fixing bracket is fixed to the top surface of the top plate;
[0031] A rotating shaft is rotatably mounted between the horizontal portion of the inverted L-shaped fixing frame and the top plate;
[0032] An active synchronizing pulley, which is fixed on the rotating shaft;
[0033] A timing belt, which is tensioned between the driven timing pulley and the driving timing pulley;
[0034] A drive motor is fixed to the top surface of the inverted L-shaped fixing frame and is used to drive the rotating shaft to rotate.
[0035] As a preferred embodiment of this utility model, it further includes limiting components, with two sets of the limiting components symmetrically fixed to the top surface of the belt conveyor, wherein the limiting components include:
[0036] A fixing plate, the fixing plate being fixed to the top surface of the belt conveyor;
[0037] A limiting plate, wherein the limiting plate is located on one side of the fixing plate;
[0038] A horizontal cylinder is fixed to the outer wall of the fixed plate, and the piston rod of the horizontal cylinder passes through the fixed plate and is fixedly connected to the limiting plate.
[0039] As a preferred embodiment of this utility model, the limiting component further includes:
[0040] Two guide rods are symmetrically fixed to the outer wall of the limiting plate and penetrate the fixing plate.
[0041] As a preferred embodiment of this utility model, both ends of the limiting plate have bent portions that bend outwards.
[0042] Compared with the prior art, the beneficial effects of this utility model are:
[0043] In this invention, material is fed by a belt conveyor and connected to a lifting plate via a connecting column and a return spring. A force-applying mechanism can press down the lifting plate to achieve embossing. A drive mechanism drives a rotating plate to rotate to switch templates. The embossing plate can be quickly installed via a flange and locking bolts. It is a replaceable template, highly automated, and can reduce labor intensity and improve production efficiency.
[0044] Other additional advantages and beneficial effects of this invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of this invention. Attached Figure Description
[0045] The accompanying drawings are provided to further illustrate the present invention and form part of the specification. They are used together with the embodiments of the present invention to explain the present invention, but do not constitute a limitation thereof. In the drawings:
[0046] Figure 1 This is a schematic diagram of the structure of this utility model;
[0047] Figure 2 This utility model Figure 1 A magnified schematic diagram of the molding component in the diagram;
[0048] Figure 3 This utility model Figure 1 A magnified schematic diagram of the force-applying mechanism in the diagram;
[0049] Figure 4 This utility model Figure 1 A magnified schematic diagram of the drive mechanism in the diagram;
[0050] Figure 5 This is an isometric structural diagram of the limiting component in this utility model.
[0051] In the diagram: 1. Belt conveyor; 2. Side plate; 3. Top plate; 4. Rotating plate; 5. Forming component; 51. Embossed plate; 52. Connecting column; 53. Lifting plate; 54. Return spring; 55. Flange; 56. Locking bolt; 6. Force application mechanism; 61. Inverted L-shaped bracket; 62. Pressure block; 63. Vertical cylinder; 7. Drive mechanism; 71. Rotating column; 72. Driven synchronous pulley; 73. Inverted L-shaped fixing frame; 74. Rotating shaft; 75. Driving synchronous pulley; 76. Synchronous belt; 77. Drive motor; 8. Limiting component; 81. Fixing plate; 82. Limiting plate; 821. Bending part; 83. Horizontal cylinder; 84. Guide rod. Detailed Implementation
[0052] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0053] Please see Figures 1-5The present invention provides the following technical solution: a replaceable template handmade soap embossing machine, including a belt conveyor 1, and further including: two side plates 2, a top plate 3, a rotating plate 4, a molding component 5, a force application mechanism 6 and a drive mechanism 7, wherein the molding component 5 includes: multiple embossing plates 51, a connecting column 52, a lifting plate 53 and a return spring 54.
[0054] Furthermore, by Figure 1 and Figure 2 As shown, in this embodiment, two side plates 2 are symmetrically fixed to the top of the belt conveyor 1, the top plate 3 is fixed to the top of the side plates 2, the rotating plate 4 is rotatably connected to the top plate 3, multiple embossed plates 51 are evenly distributed along the circumferential direction, and the bottom surface of the embossed plates 51 has a raised pattern. The connecting column 52 is detachably fixed to the top surface of the embossed plate 51 and passes through the rotating plate 4. The lifting plate 53 is fixed to the top of the connecting column 52. The return spring 54 is sleeved on the connecting column 52 and is located between the rotating plate 4 and the lifting plate 53. The force application mechanism 6 is used to press down the lifting plate 53, and the drive mechanism 7 is used to drive the rotating plate 4 to rotate. With the above scheme adopted, when the handmade soap blank to be processed is conveyed by the belt conveyor 1 to the area directly below the embossing plate 51, the drive mechanism 7 starts to work. Its output shaft drives the rotating plate 4 to rotate at a constant speed around the central axis of the top plate 3. Since multiple embossing plates 51 are evenly distributed along the circumference, the rotation of the rotating plate 4 will cause the embossing plates 51 with different patterns to rotate to the processing position directly below in sequence. The target embossing plate 51 can be switched according to the processing needs (or the drive mechanism 7 can be started first, and the belt conveyor 1 can be started to convey the handmade soap blank to be processed after switching to the target embossing plate 51).
[0055] When the target embossing plate 51 is aligned with the handmade soap blank, the force application mechanism 6 is activated. Its force application component moves downward and acts on the lifting plate 53. After the lifting plate 53 is subjected to downward pressure, it drives the embossing plate 51 to descend synchronously through the connecting column 52. At this time, the return spring 54 sleeved on the connecting column 52 is compressed and stored by the pressure of the lifting plate 53 and the rotating plate 4.
[0056] As the embossing plate 51 descends, the raised pattern on its bottom surface gradually contacts and presses into the surface of the handmade soap blank, completing the pressing of the relief pattern under pressure.
[0057] When the force-applying mechanism 6 reaches the preset downward stroke, it begins to reset upward. At this time, the reset spring 54 releases the stored elastic potential energy, pushing the lifting plate 53 and the embossing plate 51 to move upward, so that the embossing plate 51 is separated from the surface of the handmade soap blank and returns to the initial position.
[0058] At the same time, the belt conveyor 1 simultaneously transports the completed handmade soap blanks to the next process, while also transporting new soap blanks to be processed to the bottom of the embossing plate 51 to enter the next round of embossing cycle.
[0059] Throughout the entire process, the return spring 54 ensures that the embossing plate 51 automatically resets after each embossing. The drive mechanism 7 and the force application mechanism 6 work in coordination to achieve automation and precision in the embossing process.
[0060] Preferably, by Figure 1 and Figure 2 As shown in this embodiment, there are four connecting posts 52 and four return springs 54 arranged diagonally. With the above solution, when the force application mechanism 6 presses down the lifting plate 53, the diagonally distributed connecting posts 52 can evenly transmit the pressure to the embossing plate 51, avoiding tilting or local wear of the embossing plate 51 due to single-point or asymmetrical force, thereby ensuring that the depth and clarity of the relief pattern on the surface of the handmade soap are consistent, and improving the aesthetics and quality stability of the finished product.
[0061] Optionally, by Figure 1 and Figure 2 As shown, this embodiment further includes: a flange 55 and a plurality of locking bolts 56. The flange 55 is fixed to the bottom end of the connecting column 52. The flange 55 is connected to the embossing plate 51 by a plurality of locking bolts 56 evenly distributed along the circumference. With the above solution, in use, the embossing plate 51 of this new type of embossing device is fixedly installed by the flange 55 and a plurality of locking bolts 56. While ensuring installation stability, it is also convenient to disassemble and replace embossing plates 51 of different specifications and types to meet different embossing needs.
[0062] Optionally, by Figure 1 and Figure 3 As shown, in this embodiment, the force-applying mechanism 6 includes: an inverted L-shaped bracket 61, a pressure block 62, and a vertical cylinder 63. The inverted L-shaped bracket 61 is fixed to the top surface of the top plate 3. The pressure block 62 is located below the horizontal part of the inverted L-shaped bracket 61 and faces the lifting plate 53. The vertical cylinder 63 is fixed to the top surface of the horizontal part of the inverted L-shaped bracket 61, and the piston rod of the vertical cylinder 63 passes through the horizontal part of the inverted L-shaped bracket 61 and is connected to the pressure block 62. With the above scheme, when the target embossed plate 51 is aligned with the handmade soap blank on the belt conveyor 1, the vertical cylinder 63 is activated. The vertical cylinder 63 is connected to compressed air through a solenoid valve. After the upper chamber is filled with air, the piston rod extends downward at a uniform speed, pushing the pressure block 62 to move vertically downward along the guide hole of the horizontal part of the inverted L-shaped bracket 61.
[0063] During the downward movement of the pressure block 62, it acts on the lifting plate 53 first. After the lifting plate 53 is subjected to downward pressure, it drives the embossing plate 51 to descend synchronously through the connecting column 52.
[0064] Optionally, by Figure 1 and Figure 4As shown, in this embodiment, the drive mechanism 7 includes: a rotating column 71, a driven synchronous wheel 72, an inverted L-shaped fixing frame 73, a rotating shaft 74, a driving synchronous wheel 75, a synchronous belt 76, and a drive motor 77. The rotating column 71 is rotatably connected to the top plate 3, the rotating plate 4 is fixed to the bottom end of the rotating column 71, the driven synchronous wheel 72 is fixed on the rotating column 71, the inverted L-shaped fixing frame 73 is fixed to the top surface of the top plate 3, the rotating shaft 74 is rotatably installed between the horizontal part of the inverted L-shaped fixing frame 73 and the top plate 3, the driving synchronous wheel 75 is fixed on the rotating shaft 74, and the synchronous belt 76 is tensioned to the driving synchronous wheel 75 through the driven synchronous wheel 72. The drive motor 77 is fixed to the top surface of the inverted L-shaped fixing frame 73 and is used to drive the rotating shaft 74 to rotate. With the above scheme, when it is necessary to switch the embossed plate 51, the drive motor 77 starts, and its output shaft drives the rotating shaft 74 to rotate around its own axis through a coupling or direct key connection.
[0065] Since the driving synchronizing pulley 75 and the rotating shaft 74 are rigidly fixed, the rotation of the rotating shaft 74 will synchronously drive the driving synchronizing pulley 75 to rotate at the same speed. At this time, the synchronizing belt 76 tensioned between the driving synchronizing pulley 75 and the driven synchronizing pulley 72 is pulled, and the rotational motion of the driving synchronizing pulley 75 is transmitted to the driven synchronizing pulley 72 through tooth meshing.
[0066] Since the driven synchronous wheel 72 is fixed to the rotating column 71, the rotation of the driven synchronous wheel 72 will directly drive the rotating column 71 to make a circular motion around the rotation fulcrum of the top plate 3. Since the rotating plate 4 is fixed to the bottom of the rotating column 71, the rotation of the rotating column 71 will synchronously drive the rotating plate 4 to rotate around its central axis, thereby causing multiple embossing plates 51 distributed along the circumference to rotate and switch different embossing plates 51 to the embossing station.
[0067] Preferably, by Figure 1 and Figure 5 As shown, this embodiment further includes a limiting component 8. Two sets of limiting components 8 are symmetrically fixed to the top surface of the belt conveyor 1. The limiting component 8 includes: a fixed plate 81, a limiting plate 82, and a horizontal cylinder 83. The fixed plate 81 is fixed to the top surface of the belt conveyor 1, the limiting plate 82 is located on one side of the fixed plate 81, and the horizontal cylinder 83 is fixed to the outer wall of the fixed plate 81. The piston rod of the horizontal cylinder 83 passes through the fixed plate 81 and is fixedly connected to the limiting plate 82. With the above solution, in use, depending on the width of the handmade soap blank to be processed, the horizontal cylinders 83 on both sides are activated simultaneously. The piston rod of the horizontal cylinder 83 drives the limiting plate 82 to move closer to or away from the conveying center line of the belt conveyor 1, adjusting the distance between the two limiting plates 82. The two limiting plates 82 are used to limit and guide the handmade soap blank to be processed.
[0068] Two limiting plates 82 are used to effectively restrict the horizontal displacement freedom of the soap blank, ensuring that the central axis of the soap blank is strictly aligned with the central axis of the embossing plate 51.
[0069] Preferably, by Figure 1 and Figure 5 As shown in this embodiment, the limiting component 8 further includes two guide rods 84. The two guide rods 84 are symmetrically fixed to the outer wall of the limiting plate 82 and pass through the fixing plate 81. With the above solution, the limiting plate 82 is guided by the two guide rods 84 during use, which improves the stability of the limiting plate 82.
[0070] Preferably, by Figure 1 and Figure 5 As shown in this embodiment, both ends of the limiting plate 82 have bending portions 821 that bend outwards. With the above solution, the bending portions 821 play a guiding role during use. During the soap blank conveying process, its edge can be guided to the inside of the limiting plate 82 along the inclined surface of the bending portion 821, reducing the probability that the soap blank cannot enter the limiting area due to inaccurate alignment, improving the success rate of soap blank positioning, and thus improving the overall production efficiency.
[0071] It should be noted that the belt conveyor 1, vertical cylinder 63, drive motor 77 and horizontal cylinder 83 are all commercially available conventional equipment with built-in power switches. Those skilled in the art can make conventional selections according to their needs. Their working principles are common knowledge known to those skilled in the art and have been fully disclosed in the prior art, so they will not be elaborated on further in this article.
[0072] The circuit connection involved in this utility model is a common method used by those skilled in the art, and technical inspiration can be obtained through a limited number of experiments. It belongs to the widely used prior art.
[0073] Components not described in detail in this article are existing technologies.
[0074] The working principle and usage process of this utility model: When the handmade soap blank to be processed is conveyed by the belt conveyor 1 to the area directly below the embossing plate 51, the drive mechanism 7 starts to work. Its output shaft drives the rotating plate 4 to rotate at a constant speed around the central axis of the top plate 3. Since multiple embossing plates 51 are evenly distributed along the circumference, the rotation of the rotating plate 4 will cause the embossing plates 51 with different patterns to rotate to the processing position directly below in sequence. The target embossing plate 51 can be switched according to the processing needs.
[0075] When the target embossing plate 51 is aligned with the handmade soap blank, the force application mechanism 6 is activated. Its force application component moves downward and acts on the lifting plate 53. After the lifting plate 53 is subjected to downward pressure, it drives the embossing plate 51 to descend synchronously through the connecting column 52. At this time, the return spring 54 sleeved on the connecting column 52 is compressed and stored by the pressure of the lifting plate 53 and the rotating plate 4.
[0076] As the embossing plate 51 descends, the raised pattern on its bottom surface gradually contacts and presses into the surface of the handmade soap blank, completing the pressing of the relief pattern under pressure.
[0077] When the force application mechanism 6 reaches the preset downward stroke, it begins to reset upward. At this time, the reset spring 54 releases the stored elastic potential energy, pushing the lifting plate 53 and the embossing plate 51 to move upward, so that the embossing plate 51 is separated from the surface of the handmade soap blank and returns to the initial position.
[0078] At the same time, the belt conveyor 1 simultaneously transports the completed handmade soap blanks to the next process, and at the same time transports the new soap blanks to be processed to the bottom of the embossing plate 51 to enter the next round of embossing cycle;
[0079] Throughout the entire process, the return spring 54 ensures that the embossing plate 51 automatically resets after each embossing. The drive mechanism 7 and the force application mechanism 6 work in coordination to achieve automation and precision in the embossing process.
[0080] In another aspect of this utility model, during use, depending on the width of the handmade soap blank to be processed, the horizontal cylinders 83 on both sides are activated simultaneously. The piston rods of the horizontal cylinders 83 drive the limiting plates 82 to move closer to or further away from the conveying center line of the belt conveyor 1, adjusting the distance between the two limiting plates 82, and using the two limiting plates 82 to limit and guide the handmade soap blank to be processed.
[0081] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.
Claims
1. A handcrafted soap embossing machine with replaceable templates, comprising a belt conveyor (1), characterized in that, Further includes: Two side plates (2) are symmetrically fixed to the top of the belt conveyor (1); Top plate (3), the top plate (3) is fixed to the top of the side plate (2); Rotating plate (4), the rotating plate (4) is rotatably connected to the top plate (3); Molding component (5), wherein the molding component (5) includes: Multiple embossed boards (51) are distributed at equal intervals along the circumferential direction, and the bottom surface of the embossed boards (51) has a raised pattern. A connecting column (52) is detachably fixed to the top surface of the embossed plate (51) and passes through the rotating plate (4); A lifting plate (53) is fixed to the top of the connecting column (52); A return spring (54) is sleeved on the connecting post (52) and located between the rotating plate (4) and the lifting plate (53); Force application mechanism (6), the force application mechanism (6) is used to press down the lifting plate (53); A drive mechanism (7) is used to drive the rotating plate (4) to rotate.
2. The replaceable template soap embossing stamp of claim 1, wherein: There are four connecting posts (52) and four reset springs (54) arranged diagonally.
3. The replaceable template soap embossing stamp of claim 1, wherein: Further includes: A flange (55) is fixed to the bottom end of the connecting column (52); Multiple locking bolts (56) are used to connect the flange (55) to the embossed plate (51).
4. The replaceable template soap embossing stamp of claim 1, wherein: The force-applying mechanism (6) includes: An inverted L-shaped bracket (61) is fixed to the top surface of the top plate (3); Pressure block (62), the pressure block (62) is located below the horizontal part of the inverted L-shaped bracket (61) and directly opposite the lifting plate (53); A vertical cylinder (63) is fixed to the top surface of the horizontal part of the inverted L-shaped bracket (61), and the piston rod of the vertical cylinder (63) passes through the horizontal part of the inverted L-shaped bracket (61) and is connected to the pressure block (62).
5. The replaceable template soap embossing stamp of claim 1, wherein: The drive mechanism (7) includes: A rotating column (71) is rotatably connected to the top plate (3), and a rotating plate (4) is fixed to the bottom end of the rotating column (71). Driven synchronous pulley (72), the driven synchronous pulley (72) is fixed on the rotating column (71); An inverted L-shaped fixing bracket (73) is fixed to the top surface of the top plate (3); A rotating shaft (74) is rotatably mounted between the horizontal part of the inverted L-shaped fixing frame (73) and the top plate (3); An active synchronizing pulley (75) is fixed on the rotating shaft (74); A timing belt (76) is tensioned to the driving timing belt (75) via the driven timing pulley (72); A drive motor (77) is fixed to the top surface of the inverted L-shaped bracket (73) and is used to drive the rotating shaft (74) to rotate.
6. The replaceable stencil handcrafted soap embossing machine according to claim 1, characterized in that: The system further includes limiting components (8), two sets of which are symmetrically fixed to the top surface of the belt conveyor (1), wherein the limiting components (8) include: A fixing plate (81) is fixed to the top surface of the belt conveyor (1); A limiting plate (82) is located on one side of the fixing plate (81); A horizontal cylinder (83) is fixed to the outer wall of the fixed plate (81), and the piston rod of the horizontal cylinder (83) passes through the fixed plate (81) and is fixedly connected to the limiting plate (82).
7. The replaceable template soap embossing stamp of claim 6, wherein: The limiting component (8) further includes: Two guide rods (84) are symmetrically fixed to the outer wall of the limiting plate (82) and penetrate the fixing plate (81).
8. The replaceable template soap embossing stamp of claim 7, wherein: Both ends of the limiting plate (82) have bent portions (821) that bend outwards.