An antenna compression mold and an antenna compression device

By designing an antenna pressing mold, and utilizing a groove structure and auxiliary bonding components, multi-faceted and efficient bonding of ferrite is achieved. This solves the problems of unstable manual bonding and complex automated mechanical structures in existing technologies, and realizes a low-cost multi-faceted bonding effect.

CN120438994BActive Publication Date: 2026-07-03HUIZHOU SPEED WIRELESS TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
HUIZHOU SPEED WIRELESS TECH CO LTD
Filing Date
2025-03-31
Publication Date
2026-07-03

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Abstract

The application belongs to the technical field of antenna manufacturing, and particularly relates to an antenna pressing die and an antenna pressing die. Through a lower die assembly, including a lower pressing die and an auxiliary fitting assembly; the lower pressing die is provided with a first adsorption site, the auxiliary fitting assembly is arranged on the periphery of the first adsorption site, a pressing groove is arranged in the first adsorption site, and an elastic supporting piece is arranged in the pressing groove; and through an upper die assembly, including an upper pressing die, the upper pressing die is provided with a second adsorption site; so that the first adsorption site and the second adsorption site are arranged in position, when the mold is closed, the ferrite is arranged on the first adsorption site, and the antenna is arranged on the second adsorption site, so that when the antenna is pressed into the pressing groove, the ferrite is partially lifted on the periphery of the antenna and is assisted in fitting by the auxiliary fitting assembly. Thus, efficient fitting of multiple surfaces of the antenna is realized, and the fitting is performed by a low-cost fitting structure without complex mechanical structures.
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Description

Technical Field

[0001] This invention belongs to the field of antenna manufacturing technology, and in particular relates to an antenna pressing mold and an antenna pressing mold. Background Technology

[0002] In the field of current communication and electronic equipment, antennas are key components for signal transmission and reception, and their performance is crucial to the overall functionality of the equipment. To improve antenna stability, ferrite is usually attached to the antenna. Ferrite possesses unique electromagnetic properties, and its high permeability can effectively change the magnetic field distribution around the antenna, thereby having a multifaceted positive impact on antenna performance.

[0003] Traditionally, the bonding of ferrite to existing antennas involves setting a single bonding point within the antenna. However, with the development of antennas, the bonding requirements for ferrite have shifted to multi-faceted bonding rather than fixed-point bonding.

[0004] The current manufacturing process for multi-faceted antennas typically involves manual bonding, which leads to unstable bonding and low efficiency, failing to meet current demands for antenna production speed and quality. While fully automated bonding technology for multi-faceted antennas often requires complex mechanical structures, it also contradicts the principles of cost reduction and efficiency improvement. Summary of the Invention

[0005] To address the aforementioned issues, this invention proposes an antenna pressing mold and an antenna pressing device. By setting a groove-like structure, when the antenna is pressed into the groove, the antenna is pressed against the center of the ferrite, causing the peripheral ferrite to lift up and wrap around the periphery of the antenna, thereby enabling auxiliary bonding through an auxiliary bonding component.

[0006] The purpose of this invention, which provides an antenna pressing mold, is achieved through the following technical solution:

[0007] In a first aspect, the present invention provides an antenna pressing mold, comprising:

[0008] The lower mold assembly includes a lower pressing mold and an auxiliary bonding assembly; the lower pressing mold is provided with a first adsorption position, the auxiliary bonding assembly is disposed around the first adsorption position, a pressing groove is provided within the first adsorption position, and an elastic support member is disposed within the pressing groove; and

[0009] The upper mold assembly includes an upper pressure mold, which is provided with a second adsorption position;

[0010] The first and second adsorption positions are aligned. During mold closing, the ferrite is placed on the first adsorption position and the antenna is placed on the second adsorption position, so that when the antenna is pressed into the pressing groove, the ferrite part is raised on the periphery of the antenna and is assisted in bonding by the auxiliary bonding component.

[0011] The system utilizes a lower mold assembly, including a lower pressing mold and an auxiliary bonding assembly. The lower pressing mold has a first adsorption position, and the auxiliary bonding assembly is located around the first adsorption position. A pressing groove is provided within the first adsorption position, and an elastic support member is placed within the pressing groove. An upper mold assembly, including an upper pressing mold, has a second adsorption position. The first and second adsorption positions are aligned. During mold closing, the ferrite is positioned on the first adsorption position, and the antenna is positioned on the second adsorption position. When the antenna is pressed into the pressing groove, the ferrite portion protrudes around the antenna and is further bonded by the auxiliary bonding assembly. This achieves efficient multi-faceted bonding of the antenna simultaneously without the need for complex mechanical structures, using a low-cost bonding structure.

[0012] In some embodiments, the auxiliary bonding component includes an auxiliary roller; multiple rotating shafts are rotatably arranged around the first adsorption position, and the auxiliary roller is disposed on the rotating shafts so that the auxiliary roller is driven to rotate and perform rolling pressing during pressing.

[0013] By using auxiliary rollers, the ferrite is positioned between the antenna and the auxiliary rollers when the antenna is pressed down, forming a rolling and pressing motion. This achieves a flat and adhesive fit to the ferrite, avoiding wrinkles when the antenna and ferrite are attached.

[0014] In some embodiments, the auxiliary bonding component also includes a pressure plate that presses the ferrite during mold closing.

[0015] A pressure plate can be used to assist in pressing and bonding, which improves the bonding degree and efficiency of the ferrite, avoids wrinkles, and also makes the antennas produced less inconsistent.

[0016] In some embodiments, the first adsorption position is provided with a first adsorption component, which includes a first adsorption cylinder and a first adsorption template. The first adsorption template is provided with a first adsorption port, and the output port of the first adsorption cylinder is connected to the first adsorption port so that the first adsorption position adsorbs ferrite.

[0017] The first adsorption component can adsorb the ferrite, avoiding misalignment of the ferrite during the lower mold assembly closing, which would lead to inconsistent antenna specifications in production.

[0018] In some embodiments, the second adsorption position is provided with a second adsorption component, which includes a second adsorption cylinder and a second adsorption template. The second adsorption template is provided with a second adsorption port, and the output port of the second adsorption cylinder is connected to the second adsorption port so that the second adsorption position adsorbs the antenna.

[0019] The antenna can be attracted by the second adsorption component, allowing the antenna to follow the lower mold assembly as it is pressed into place.

[0020] In some embodiments, the elastic support includes an elastic element and a support element, with the support element disposed inside the pressing groove and the elastic element disposed between the bottom of the pressing groove and the support element.

[0021] The antenna is reset using an elastic support to achieve cyclic pressing.

[0022] In some implementations, the elastic element includes a spring.

[0023] The spring allows for automatic reset after mold closing, enabling repeated automatic production.

[0024] In some embodiments, a telescopic component is further provided around the first adsorption site to change the size and shape of the first adsorption site.

[0025] The size of the first adhesive site can be changed by using a telescopic component to accommodate various antenna sizes.

[0026] Secondly, the present invention also provides an antenna pressing device, comprising:

[0027] Such as the antenna pressing mold proposed in any of the first aspects;

[0028] The base has a base plate, and the lower mold assembly is mounted on the base plate; and

[0029] The pressing mechanism includes a bracket and a pressing assembly. The bracket is fixed on the base, the pressing assembly is mounted on the bracket, and the upper mold assembly is mounted on the pressing assembly to perform pressing and mold closing.

[0030] The lower mold assembly and the upper mold assembly are closed by a pressing mechanism.

[0031] In some implementations, the base plate is movably mounted on the base to allow for position adjustment of the lower mold assembly.

[0032] The beneficial effects of the antenna pressing mold and the antenna pressing mold of the present invention are:

[0033] This method enables ferrite bonding on multiple sides of the antenna, avoiding the inefficiency and inconsistent antenna specifications caused by manual bonding. It also reduces production costs by using simple molds to bond ferrite on multiple sides of the antenna, making it suitable for low-cost antenna manufacturing. Attached image description:

[0034] Figure 1 This is a perspective view of an antenna pressing mold according to the present invention;

[0035] Figure 2 This is a perspective view of an auxiliary bonding component of an antenna pressing mold according to the present invention;

[0036] Figure 3 This is a top view of the lower mold assembly of an antenna pressing mold according to the present invention;

[0037] Figure 4 This is a top view of the upper mold assembly of an antenna pressing mold according to the present invention;

[0038] Figure 5 This is a cross-sectional view of the lower mold assembly of an antenna pressing mold according to the present invention;

[0039] Figure 6 This is a top view of another embodiment of the lower mold assembly of an antenna pressing mold according to the present invention;

[0040] Figure 7 This is an exploded view of an antenna pressing mold according to the present invention.

[0041] Figure label:

[0042] 1. Lower mold assembly; 11. Lower pressure mold; 111. First suction position; 112. Pressing groove; 113. Elastic support; 1131. Support; 1132. Elastic component; 114. First suction plate; 115. First suction port; 12. Auxiliary bonding assembly; 121. Auxiliary roller; 122. Rotating shaft; 123. Pressure plate; 13. Telescopic assembly;

[0043] 2. Upper mold assembly; 21. Upper pressure mold; 211. Second suction position; 212. Second suction platen; 213. Second suction port;

[0044] 3. Base; 31. Base plate;

[0045] 4. Pressing mechanism; 41. Bracket; 42. Pressing assembly. Detailed implementation method:

[0046] It should be noted that, unless otherwise specified, the embodiments and technical features in the embodiments of the present invention can be combined with each other, and the detailed descriptions in the specific embodiments should be understood as explanations of the spirit of the present invention and should not be regarded as undue limitations on the present invention.

[0047] To make the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, the specific technical solutions of the present invention will be further described in detail below with reference to the accompanying drawings of the embodiments of the present invention. The following embodiments are used to illustrate the present invention, but are not intended to limit the scope of the present invention.

[0048] In the embodiments of the present invention, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the embodiments of the present invention, unless otherwise stated, "a plurality of" means two or more.

[0049] Furthermore, in the embodiments of the present invention, directional terms such as "upper," "lower," "left," and "right" are defined relative to the positions in which the components are schematically placed in the accompanying drawings. It should be understood that these directional terms are relative concepts, used for relative description and clarification, and can change accordingly depending on the position of the components in the accompanying drawings.

[0050] In the embodiments of the present invention, unless otherwise explicitly specified and limited, the term "connection" should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral part; it can be a direct connection or an indirect connection through an intermediate medium.

[0051] In embodiments of the present invention, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion. Without further limitation, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes that element.

[0052] In embodiments of the present invention, the terms "exemplary" or "for example" are used to indicate that something is an example, illustration, or description. Any embodiment or design described as "exemplary" or "for example" in embodiments of the present invention should not be construed as being more preferred or advantageous than other embodiments or designs. Specifically, the use of the terms "exemplary" or "for example" is intended to present the relevant information in a specific manner.

[0053] Example 1:

[0054] like Figure 1 As shown, this embodiment proposes an antenna pressing mold, including:

[0055] The lower mold assembly 1 includes a lower pressing mold 11 and an auxiliary bonding assembly 12; the lower pressing mold 11 is provided with a first adsorption position 111, the auxiliary bonding assembly 12 is disposed around the first adsorption position 111, a pressing groove 112 is provided in the first adsorption position 111, and an elastic support member 113 is disposed in the pressing groove 112; and

[0056] The upper mold assembly 2 includes an upper pressure mold 21, which is provided with a second adsorption position 211;

[0057] The first adsorption position 111 and the second adsorption position 211 are aligned. During mold closing, the ferrite is placed on the first adsorption position 111 and the antenna is placed on the second adsorption position 211, so that when the antenna is pressed into the pressing groove 112, the ferrite part is raised on the periphery of the antenna and is assisted in bonding by the auxiliary bonding component 12.

[0058] Specifically, the lower mold assembly 1 is used to carry the ferrite. The ferrite is further disposed on the first adsorption position 111 of the lower pressing mold 11. The shape of the ferrite is changed according to the number of surfaces that the antenna needs to be attached to. The principle is that when the upper mold assembly 2 and the lower mold assembly 1 are molded together, the antenna adsorbed on the upper mold assembly 2 is pressed and adsorbed on the middle part of the ferrite in the lower mold assembly 1. When the antenna is pressed into the pressing groove 112, the peripheral part of the ferrite outside the pressing groove 112 is raised, so that the ferrite wraps around the periphery of the antenna. The ferrite is then pressed onto the antenna by the auxiliary bonding assembly 12 to achieve bonding.

[0059] In some more specific embodiments, the antenna is provided with a rectangular stainless steel component. One side of the stainless steel component is attached to the antenna, and the other five sides need to be bonded with ferrite. Using the mold proposed in this embodiment, the ferrite can be shaped into an unfolded form excluding the rectangular side, i.e., a rectangle in the middle, with each of the four sides connected to another rectangle. During mold closing, the antenna is aligned with the central rectangle and pressed down. After the antenna has penetrated a certain distance into the pressing groove 112, the first adsorption position 111 stops adsorbing the ferrite, causing the four peripheral sides of the ferrite to lift up. The auxiliary bonding component 12 then bonds the ferrite to the periphery of the stainless steel component of the antenna, achieving multi-sided bonding. The auxiliary bonding component 12 can have various structures, as long as it serves to press the ferrite and stainless steel component, such as a push rod. Alternatively, the auxiliary bonding component 12 can be omitted, and the same effect can be achieved simply by pressing against the sidewall of the pressing groove 112. However, this method is prone to stress wear on the ferrite.

[0060] It is understood that the above-described embodiments are only one antenna implementation method, and more surfaces such as 8 or 10 surfaces can be attached, which can be accomplished by simply changing the shape of the ferrite.

[0061] The lower mold assembly 1 includes a lower pressing mold 11 and an auxiliary bonding assembly 12. The lower pressing mold 11 is provided with a first adsorption position 111, and the auxiliary bonding assembly 12 is located around the first adsorption position 111. A pressing groove 112 is provided in the first adsorption position 111, and an elastic support member 113 is provided in the pressing groove 112. The upper mold assembly 2 includes an upper pressing mold 21, which is provided with a second adsorption position 211. The first adsorption position 111 and the second adsorption position 211 are aligned. When the mold is closed, the ferrite is placed on the first adsorption position 111, and the antenna is placed on the second adsorption position 211. When the antenna is pressed into the pressing groove 112, the ferrite part is raised on the periphery of the antenna and is assisted in bonding by the auxiliary bonding assembly 12. This achieves efficient bonding of multiple sides of the antenna simultaneously without the need for a complex mechanical structure, using a low-cost bonding structure.

[0062] Example 2:

[0063] like Figures 2-6 As shown, this embodiment further explains and optimizes the antenna pressing mold proposed in Embodiment 1.

[0064] In some embodiments, the auxiliary bonding component 12 includes an auxiliary roller 121; multiple rotating shafts 122 are rotatably arranged around the first adsorption position 111, and the auxiliary roller 121 is arranged on the rotating shafts 122 so that the auxiliary roller 121 is driven to rotate and perform rolling pressing during pressing.

[0065] Specifically, the auxiliary bonding component 12 can be an auxiliary roller 121. Multiple rotating shafts 122 are rotatably arranged around the first adsorption position 111. The rotating shafts 122 can be arranged parallel to the side of the antenna to be bonded, so that when the antenna is pressed into the pressing groove 112, the auxiliary rollers 121 on the rotating shafts 122 can roll and press the ferrite and the antenna. When the auxiliary bonding component 12 is an auxiliary roller 121, the auxiliary roller 121 can serve as one sidewall of the pressing groove 112, allowing the auxiliary roller 121 to fully roll and press the ferrite. To ensure complete pressing and prevent the auxiliary roller 121 from not abutting against one side of the antenna when the antenna is pressed into the pressing groove 112, a spring force towards the antenna can be applied to the rotating shaft 122, such as applying a spring perpendicular to the rotating shaft 122. When the antenna is pressed, stress accumulates on the auxiliary roller 121, causing the rotating shaft 122 to move away from the antenna and applying pressure to the spring, causing the spring to compress. The spring force ensures that the auxiliary roller 121 abuts against one surface of the antenna during the pressing process.

[0066] In other alternative embodiments, the elastic support 113 can be moved in conjunction with the movement of the other two components. In this implementation, each rotating shaft 122 is equipped with a small cylinder, with a push rod connected to the cylinder drive. The push rod is connected to the non-auxiliary roller 121 connection portion of the rotating shaft 122, allowing the small cylinder to push the rotating shaft 122 closer to or away from the antenna. The elastic support 113 can be connected to a limit switch. When pressed into the pressing groove 112 by the antenna, the limit switch is triggered, causing the small cylinder to push the rotating shaft 122 closer to the antenna, thereby causing the auxiliary roller 121 to abut against a surface of the antenna. In other alternative embodiments, a linkage structure can be provided between the elastic support 113 and the rotating shaft 122. By pressing the elastic support 113, the linkage structure pushes the rotating shaft 122 closer to the antenna, causing the auxiliary roller 121 to abut against the antenna.

[0067] It should be further explained that since the auxiliary roller 121 does not require a drive, but is passively driven by friction, the auxiliary roller 121 and the rotating shaft 122 can rotate relative to each other. The rotating shaft 122 can be configured to rotate or not rotate. The auxiliary roller 121 can be limited to the required position on the rotating shaft 122 by a limiting member. The rotating shaft 122 can be pushed by the non-rotating rotating shaft 122.

[0068] By using the auxiliary roller 121, when the antenna is pressed down, the ferrite is positioned between the antenna and the auxiliary roller 121 to form a rolling press, thereby achieving the bonding and flattening of the ferrite and avoiding wrinkles when the antenna and ferrite are bonded together.

[0069] In some embodiments, the auxiliary bonding component 12 further includes a pressure plate 123, which presses the ferrite during mold closing.

[0070] Specifically, the pressure plate 123 can also be equipped with a cylinder. The pressure plate 123 can be set as one side wall of the pressing groove 112. When the antenna is pressed into the pressing groove 112, the cylinder can push the pressure plate 123 to press the raised ferrite onto the antenna, thereby achieving ferrite bonding on one side. Alternatively, a structure similar to the above-mentioned auxiliary roller 121 can be set up so that when the antenna is pressed down into the pressing groove 112, the pressure plate 123 moves toward the antenna.

[0071] In some alternative embodiments, the pressure plate 123 is configured as a flip structure, which also has a rotating shaft 122, and one side of the pressure plate 123 is fixed to the rotating shaft 122, so that the pressure plate 123 rotates with the rotating shaft 122. In the normal unclosed state, the pressure plate 123 is arranged parallel to the surface of the lower mold 11. When the mold is closed, the rotating shaft 122 rotates so that the pressure plate 123 is parallel to a ferrite bonding surface of the antenna and abuts against the antenna to achieve the pressing function.

[0072] The pressure plate 123 can be set to assist in pressing and bonding, which improves the bonding degree and efficiency of the ferrite, avoids wrinkles, and also makes the antennas produced less different.

[0073] In some embodiments, the first adsorption position 111 is provided with a first adsorption component, which includes a first adsorption cylinder and a first adsorption template 114. The first adsorption template 114 is provided with a first adsorption port 115, and the output port of the first adsorption cylinder is connected to the first adsorption port 115 so that the first adsorption position 111 adsorbs ferrite.

[0074] Specifically, the first adsorption position 111 is provided with a first adsorption assembly, which includes a first adsorption cylinder and a first adsorption template 114. The first adsorption template 114 is provided with a first adsorption port 115, through which ferrite is adsorbed. It should be noted that, under normal circumstances, the first adsorption port 115 is only for facilitating the alignment and fixing of the ferrite, not for misalignment during mold closing. Misalignment during mold closing is usually limited and fixed by a slot with the same shape as the ferrite provided in the first adsorption position 111. During the mold closing process, the first adsorption port 115 generally has no adsorption function to prevent the ferrite from being unable to lift up during pressing. Furthermore, for ease of installation, multiple additional mounting slots are provided on the slot with the same shape as the ferrite in the first adsorption position 111. The mounting slots are connected to the slot to facilitate the installation of the ferrite.

[0075] The antenna can be attracted by the first adsorption component, so that the antenna can follow the lower mold component 1 to press and close the mold.

[0076] In some embodiments, the second adsorption position 211 is provided with a second adsorption component, which includes a second adsorption cylinder and a second adsorption template 212. The second adsorption template 212 is provided with a second adsorption port 213, and the output port of the second adsorption cylinder is connected to the second adsorption port 213 so that the second adsorption position 211 adsorbs ferrite.

[0077] Specifically, the second adsorption position 211 is provided with a second adsorption assembly, which includes a second adsorption cylinder and a second adsorption template 212. The second adsorption ports 213 of the second adsorption template 212 are distributed according to the shape of the antenna, and each antenna has a corresponding second adsorption template 212, so that the antenna can be stably adsorbed and avoid falling off during mold closing. The output port of the second adsorption cylinder is connected to the second adsorption port 213 to provide negative pressure for adsorption of the antenna.

[0078] The second adsorption component can adsorb the ferrite, avoiding misalignment of the ferrite during the closing of the lower mold component 1, which would lead to inconsistent antenna specifications in production.

[0079] In some embodiments, the elastic support includes an elastic element and a support element, the support element being disposed inside the pressing groove, and the elastic element being disposed between the bottom of the pressing groove and the support element.

[0080] Specifically, the elastic element is positioned between the support and the bottom of the pressing groove, so that the antenna presses the elastic element during pressing and automatically pops out of the pressing groove when the pressing is removed.

[0081] The antenna is reset using an elastic support to achieve cyclic pressing.

[0082] In some embodiments, the elastic element 1132 includes a spring.

[0083] The elastic element 1132 is set as a spring, which can not only reduce the need for additional power sources, but also play a role in shock absorption. The spring can also automatically reset after mold closing for repeated automatic production.

[0084] In some embodiments, a telescopic component 13 is further provided around the first adsorption position 111 to change the size and shape of the first adsorption position 111.

[0085] Specifically, by providing the telescopic component 13, the size and shape of the first adsorption position 111 can be changed to adapt to ferrites of different sizes, and the installation and fixation of different ferrites can be completed simply by telescopic movement.

[0086] In other embodiments, the first adsorption position 111 can be disposed on the mounting plate, and the first adsorption position 111 can be replaced as a whole through the mounting plate to achieve the fixation of ferrite of different sizes.

[0087] The size of the first suction position 111 can be changed by the telescopic component 13 to accommodate various antenna sizes.

[0088] Example 3:

[0089] like Figure 7 As shown, this embodiment proposes an antenna pressing device, including:

[0090] Antenna pressing mold as provided in either Example 1 or Example 2;

[0091] Base 3, base plate 31 is provided on base 3, lower mold assembly 1 is provided on base plate 31; and

[0092] The pressing mechanism 4 includes a bracket 41 and a pressing component 42. The bracket 41 is fixed on the base 3, the pressing component 42 is mounted on the bracket 41, and the pressing component is mounted on the pressing component 42 to perform pressing and mold closing.

[0093] Specifically, a base 3 is provided, on which a base plate 31 is fixed or integrally formed. The lower mold assembly 1 is fixed to the base plate 31 with screws, allowing the lower mold assembly 1 to be detached and fixed to the base plate 31. The base 3 is also provided with a bracket 41 and a pressing assembly 42. The bracket 41 is fixed to the base 3 with screws, and a pressing fixing plate can be provided on the bracket 41. The pressing fixing plate fixes the pressing assembly 42, which is preferably a cylinder. The upper mold assembly 2 is placed on the driving end of the cylinder to push the upper mold assembly 2 down to close the mold. The base consists of an upper plate, a front plate, a rear plate, a left side plate, a right side plate, a lower base plate, and pads. The upper plate of the base is connected to the electrical box.

[0094] In some embodiments, the base plate 31 is movably mounted on the base 3 to allow for position adjustment of the lower mold assembly 1.

[0095] Specifically, the base plate 31 can be fixed or limited by screws or other means. When the position needs to be adjusted, the limiting screws are removed and the base plate 31 is moved to the required position, and the limiting screws are re-fixed for fixation.

[0096] Furthermore, a guide rail connects the base plate 31 and the base 3. By fixing the guide rail to the base 3, the base plate 31 can be slidably fixed to the base 3 for movement. When stability is required, a locking block can be set for locking and fixing. Alternatively, a linear motor can be used to control the movement of the base plate 31, thereby realizing the movement of the base plate 31 relative to the base 3.

[0097] The sequence numbers of the embodiments are for descriptive purposes only and do not represent the superiority or inferiority of the embodiments. The above are merely preferred embodiments of the present invention and do not limit the patent scope of the present invention. Any equivalent device or equivalent process transformation made based on the content of the present invention specification and drawings, or direct or indirect application in other related technical fields, are similarly included within the patent protection scope of the present invention.

Claims

1. An antenna pressing mold, characterized in that, include: The lower mold assembly (1) includes a lower pressing mold (11) and an auxiliary bonding assembly (12); the lower pressing mold (11) is provided with a first adsorption position (111), the auxiliary bonding assembly (12) is provided on the periphery of the first adsorption position (111), a pressing groove (112) is provided in the first adsorption position (111), and an elastic support member (113) is provided in the pressing groove (112); and The upper mold assembly (2) includes an upper pressure mold (21), wherein the upper pressure mold (21) is provided with a second adsorption position (211); The first adsorption position (111) and the second adsorption position (211) are aligned. When the mold is closed, the ferrite is placed on the first adsorption position (111) and the antenna is placed on the second adsorption position (211), so that when the antenna is pressed into the pressing groove (112), the ferrite part is raised on the periphery of the antenna and is assisted in being bonded by the auxiliary bonding component (12).

2. The antenna pressing mold according to claim 1, characterized in that, The auxiliary bonding component (12) includes an auxiliary roller (121); multiple rotating shafts (122) are rotatably arranged around the first adsorption position (111), and the auxiliary roller (121) is arranged on the rotating shaft (122) so that the auxiliary roller (121) is driven to rotate and roll and press during pressing.

3. The antenna pressing mold according to claim 1, characterized in that, The auxiliary bonding component (12) also includes a pressure plate (123), which presses the ferrite when the mold is closed.

4. The antenna pressing mold according to claim 1, characterized in that, The first adsorption position (111) is provided with a first adsorption component, which includes a first adsorption cylinder and a first adsorption template (114). The first adsorption template (114) is provided with a first adsorption port (115). The output port of the first adsorption cylinder is connected to the first adsorption port (115) so that the first adsorption position (111) adsorbs ferrite.

5. The antenna pressing mold according to claim 1, characterized in that, The second adsorption position (211) is provided with a second adsorption component, which includes a second adsorption cylinder and a second adsorption template (212). The second adsorption template (212) is provided with a second adsorption port (213). The output port of the second adsorption cylinder is connected to the second adsorption port (213) so that the second adsorption position (211) adsorbs the antenna.

6. The antenna pressing mold according to claim 1, characterized in that, The elastic support (113) includes an elastic element (1132) and a support element (1131). The support element (1131) is disposed inside the pressing groove (112), and the elastic element (1132) is disposed between the bottom of the pressing groove (112) and the support element (1131).

7. The antenna pressing mold according to claim 6, characterized in that, The elastic element (1132) includes a spring.

8. The antenna pressing mold according to claim 1, characterized in that, A telescopic component (13) is also provided around the first adsorption site (111) to change the size and shape of the first adsorption site (111).

9. An antenna pressing device, characterized in that, include: The antenna pressing mold as described in any one of claims 1-8; A base (3), on which a base plate (31) is provided, and the lower mold assembly (1) is disposed on the base plate (31); and The pressing mechanism (4) includes a bracket (41) and a pressing assembly (42). The bracket (41) is fixed on the base (3), the pressing assembly (42) is disposed on the bracket (41), and the upper mold assembly (2) is disposed on the pressing assembly (42) for pressing and closing the mold.

10. The antenna pressing device according to claim 9, characterized in that, The base plate (31) is movably mounted on the base (3) to adjust the position of the lower mold assembly (1).