FOLDABLE AND MODULAR PHONE STAND WITH SECURE HELMET INTEGRATION

Description

COPYRIGHT AND TRADEMARK NOTICE

This application includes material which is subject or may be subject to copyright and/or trademark protection. The copyright and trademark owner(s) have no objection to the facsimile reproduction by any of the patent disclosure, as it appears in the Patent and Trademark Office files or records, but otherwise reserves all copyright and trademark rights whatsoever.

TECHNICAL FIELD

The present disclosure relates in general to hands-free holders of mobile phones and other portable electronic devices. More particularly, the present disclosure relates to a foldable and modular phone stand designed for secure integration with helmets. Additionally, the present disclosure pertains to securely attaching and positioning a phone in front of the user's face for hands-free applications, such as augmented reality (AR), navigation, or other viewing purposes, while maintaining adjustability, portability, and compatibility with various helmet designs.

BACKGROUND

Mobile phones and portable electronic devices have become essential tools in various fields, including construction, logistics, navigation, and augmented reality applications. While these devices provide significant utility, users in hands-on environments often face challenges when trying to use them efficiently and safely without compromising their tasks or mobility. This is particularly evident in industries where workers wear helmets, such as construction, mining, and field operations, and require hands-free access to their devices for operational purposes.

Existing solutions for hands-free phone usage, such as clip-on holders or wearable mounts, often lack secure integration with helmets and are unable to provide ergonomic positioning of the device directly in front of the user's face. Furthermore, many available holders rely on complex designs involving additional optical components like lenses or are limited to specific device sizes, reducing their versatility and usability. These drawbacks lead to issues such as device instability, poor adjustability, and limited portability, which hinder effective hands-free operation.

Additionally, current designs often fail to address the need for a modular and foldable structure, which is critical for portability and easy storage when not in use. For professionals who frequently move between sites, bulky and non-collapsible devices become impractical. The lack of a reliable attachment system tailored for helmets further exacerbates the problem, as generic solutions do not provide the required stability and safety for professional environments.

In the light of the aforementioned discussion, there is a need for a robust, foldable, and modular phone stand with a secure attachment mechanism for helmets.

SUMMARY

The following invention presents a simplified summary of the disclosure in order to provide a basic understanding to the reader. This summary is not an extensive overview of the disclosure and it does not identify key/critical elements of the invention or delineate the scope of the invention. Its sole purpose is to present some concepts disclosed herein in a simplified form as a prelude to the more detailed description that is presented later.

Exemplary embodiments of the present disclosure are directed towards a foldable and modular phone stand with secure helmet integration.

An objective of the present disclosure is directed towards enabling ergonomic positioning of a mobile phone directly in front of the user's face, allowing for comfortable and strain-free hands-free applications such as navigation or viewing.

Another objective of the present disclosure is directed towards incorporating a foldable design with hinge mechanisms, facilitating easy portability and compact storage for convenience during transport.

Another objective of the present disclosure is directed towards providing a modular construction that allows the phone stand to be easily disassembled and reassembled, enabling flexibility for customization, and upgrades.

Another objective of the present disclosure is directed towards providing a robust attachment mechanism for secure integration with helmets, using bolts, adhesives, or a head strap, to ensure reliable hands-free usage in professional environments.

Another objective of the present disclosure is directed towards ensuring universal compatibility with a variety of mobile phone sizes and models, eliminating the need for additional adjustments or specialized accessories.

Another objective of the present disclosure is directed towards eliminating the requirement for additional optical components, such as lenses, to provide a lightweight, cost-effective, and user-friendly design.

Another objective of the present disclosure is directed towards providing enhanced stability through a secure cube slot mechanism, ensuring the phone remains firmly in place during movement or vibrations.

Another objective of the present disclosure is directed towards offering customizable adjustments via adjustable arms, allowing users to modify the angle and distance of the phone stand to suit their ergonomic preferences.

Another objective of the present disclosure is directed towards facilitating hands-free operation to minimize distractions, enabling users to focus on tasks efficiently in various environments.

Another objective of the present disclosure is directed towards providing a compact and foldable phone stand that caters to professionals who frequently move between locations, ensuring easy transportation and deployment.

Another objective of the present disclosure is directed towards providing a quick and secure attachment mechanism that allows for fast installation and removal from the helmet, enhancing usability and reducing setup time.

Another objective of the present disclosure is directed towards providing a weather-resistant structure that ensures reliable performance in various conditions, such as rain, dust, and extreme temperatures.

Another objective of the present disclosure is directed towards improving user safety by securely holding the mobile phone in a stable position using a robust cube slot and helmet attachment mechanism, minimizing risks caused by loose or unstable mounts.

Another objective of the present disclosure is directed towards providing a robust attachment mechanism compatible with various helmet types, including construction, sports, and industrial helmets, to ensure reliable hands-free operation.

Another objective of the present disclosure is directed towards allowing the phone stand to support both portrait and landscape orientations, offering flexibility for different applications and user preferences.

Another objective of the present disclosure is directed towards providing a streamlined and aesthetically pleasing design that integrates seamlessly with the helmet, enhancing the professional appearance of the user.

Another objective of the present disclosure is directed towards ensuring that the phone stand is user-friendly, allowing for intuitive setup and operation without requiring technical expertise.

Another objective of the present disclosure is directed towards providing a robust phone holder mechanism that securely positions a mobile phone in front of the user's eyes, enabling hands-free augmented reality experiences, such as live overlays and navigation, through the phone's live camera.

Another objective of the present disclosure is directed towards incorporating adjustable arms to allow customization of both the angle and distance of the mobile phone, ensuring precise alignment with the user's eye level for enhanced ergonomic usability during augmented reality (AR) applications.

Another objective of the present disclosure is directed towards providing a collapsible design with hinge mechanisms, allowing the phone stand to fold into a compact form for easy portability and storage without compromising its structural integrity.

Another objective of the present disclosure is directed towards offering a cost-effective and lightweight solution for integrating augmented reality technology into daily activities, making it accessible to a wide range of users.

According to an exemplary aspect of the present disclosure, a cube slot configured to securely attach to a helmet using at least one of a bolting mechanism or an adhesive attachment, whereby the cube slot comprises a fitting groove designed to engage with a fitting jaw of an arm mount, and a cube slot groove configured to align with a fitting jaw groove on the fitting jaw, thereby facilitating an optional bolting mechanism for enhanced stability.

According to another exemplary aspect of the present disclosure, the arm mount comprising the fitting jaw is configured to engage with the fitting groove of the cube slot, thereby providing a stable and secure attachment between the modular phone stand and the helmet.

According to another exemplary aspect of the present disclosure, a first arm comprises a proximal end and a distal end, whereby the proximal end of the first arm is pivotally connected to the arm mount using the pins, wherein the pivotal connection provides the flexibility for extraction and retraction of the first arm.

According to another exemplary aspect of the present disclosure, a second arm comprises a proximal end and a distal end, whereby the proximal end of the second arm is pivotally connected to the distal end of the first arm using the pins, wherein the pivotal connection providing the flexibility for extraction and retraction of the second arm, the distal end of the second arm securely connected to a gripper using the connecting pins, whereby the gripper configured to securely hold a mobile device in better alignment with the user's eye level, the gripper comprising a gripper groove for accommodating fasteners to provide a stable attachment of mobile device with the gripper.

According to another exemplary aspect of the present disclosure, the pivotal connections between the arm mount, the first arm, and the second arm enable the user to adjust and align the gripper with the user's eye level by extracting and retracting the first arm and second arm.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following, numerous specific details are set forth to provide a thorough description of various embodiments. Certain embodiments may be practiced without these specific details or with some variations in detail. In some instances, certain features are described in less detail so as not to obscure other aspects. The level of detail associated with each of the elements or features should not be construed to qualify the novelty or importance of one feature over the others.

FIG. 1A is a block diagram depicting a schematic representation of a foldable and modular phone stand with secure helmet integration, in accordance with one or more exemplary embodiments.

FIG. 1B is a block diagram depicting a schematic representation of a foldable and modular phone stand, in accordance with one or more exemplary embodiments.

FIG. 2 is an example block diagram depicting a schematic representation of a foldable and modular phone stand aligned with the cube slot attached to the helmet, in accordance with one or more exemplary embodiments.

FIG. 3 is an example block diagram depicting a side view of a foldable and modular phone stand aligned with the cube slot attached to the helmet, in accordance with one or more exemplary embodiments.

FIG. 4 is an example block diagram depicting a foldable and modular phone stand with the fitting jaw secured into the cube slot, and showing the optional bolting mechanism using the cube slot groove and fitting jaw groove, in accordance with one or more exemplary embodiments.

FIG. 5 is an example block diagram depicting a side view of a foldable and modular phone stand in an adjusted position, illustrating the ergonomic alignment of a gripper relative to the user's line of sight, in accordance with one or more exemplary embodiments.

FIG. 6 is an example block diagram depicting an embodiment of the foldable and modular phone stand with secure helmet integration, in accordance with one or more exemplary embodiments.

FIG. 7 is an example block diagram depicting a top view of the positional alignment of the modular phone stand on the helmet and a detailed view of the cube slot and its integration with the helmet, in accordance with one or more exemplary embodiments.

FIG. 8 is an example block diagram depicting the rear perspective view of a foldable and modular phone stand attached to the helmet, in accordance with one or more exemplary embodiments.

FIG. 9 is an example diagram depicting a side view of the cube slot permanently attached to the helmet in the absence of the modular phone stand, in accordance with one or more exemplary embodiments.

FIG. 10 is an example diagram depicting a side view of the cube slot with the inclusion of the cube slot groove for attaching to the helmet, in accordance with one or more exemplary embodiments.

FIG. 11 is an example diagram depicting a side view of the cube slot as it interacts with the helmet during assembly or adjustment and the alignment of the cube slot with the helmet's surface, in accordance with one or more exemplary embodiments.

FIG. 12 is an example diagram depicting a rear-side view of a cube slot secure attachment with the helmet, in accordance with one or more exemplary embodiments.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

It is to be understood that the present disclosure is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the drawings. The present disclosure is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.

The use of “including”, “comprising” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. The terms “a” and “an” herein do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced item. Further, the use of terms “first”, “second”, and “third”, and so forth, herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another.

Referring to FIG. 1A is a block diagram 100a depicting a schematic representation of a foldable and modular phone stand with secure helmet integration, in accordance with one or more exemplary embodiments. The block diagram 100a includes a user 101, an arm mount 102, a first arm 104, a second arm 106 a gripper 108, pins 110, 112, connecting pins 114, a gripper groove 116, a fitting jaw 118, a cube slot 120, a helmet 122, a fitting jaw groove 124a, and a cube slot groove 124b. The user 101 represents an individual wearing a helmet 122 equipped with a modular phone stand. The foldable and modular phone stand may provide hands-free operation for various applications, including augmented reality (AR), navigation, or other hands-free viewing purposes. The foldable and modular phone stand design aims to enhance the user's experience by offering stability, adjustability, and ergonomic positioning. The arm mount 102 may serve as a central connecting structure that pivotally couples with the first arm 104. The arm mount 102 may be configured to provide rotational flexibility, allowing the modular stand to fold or adjust for better alignment with the user's eye level. The arm mount 102 includes a fitting jaw 118 may be configured to engage with the fitting groove 302, as shown in FIG. 3, for secure placement within the cube slot 120. This coupling ensures a stable connection between the foldable and modular phone stand and the helmet 122.

The first arm 104 proximal end may be pivotally connected to the arm mount 102 through the pins 110. The first arm 104 may be configured to provide structural support while allowing angular adjustments to align the phone with the user's field of view. The pivot joint may provide flexibility for extraction and retraction of the first arm, enabling better alignment with the user's eye level. The pivot at the connection point facilitates smooth movement, enabling the modular stand to fold into a compact form when not in use.

The second arm 106 proximal end may be pivotally connected to the distal end of the first arm 104 through the pins 112. This pivotal connection may allow rotational flexibility, enabling the second arm to adjust its angle for improved alignment and stability. The second arm 106 may be configured to provide additional structural support and flexibility to the modular stand by acting as an intermediary structure between the first arm and the gripper 108. The distal end of the second arm 106 may be securely connected to the gripper 108 through the connecting pins 114, which may provide a stable attachment while allowing minor adjustments for accommodating various device sizes and orientations. The gripper 108 may be configured to securely hold a smartphone or similar portable electronic devices. The gripper 108 equipped with a gripper groove 116 may be configured to securely hold the mobile phone using fasteners or screws, ensuring a firm attachment and preventing unintended movement. The gripper 108 ensures that the smartphone is positioned firmly in front of the user's eyes, enabling seamless interaction with applications such as AR or navigation tools. The pins 110 and 112 may be configured to enable pivotal connections between the arm mount 102, the first arm 104, and the second arm 106. These pins may provide rotational flexibility, allowing the modular phone stand to be folded or adjusted as required. The pins 110 and 112 may allow smooth rotation and enable the modular stand to adjust its orientation or fold into a compact form for storage or portability. The connecting pins 114 may be configured to attach the gripper 108 to the second arm 106. The connecting pins 114 ensure a firm connection and may also allow for adjustments to accommodate different smartphone sizes or orientations.

The fitting jaw 118 may be an integral component of the arm mount 102. The fitting jaw 118 may be configured to securely fit into the fitting groove 302 (as shown in FIG. 3) within the cube slot 120. The fitting jaw 118 includes a fitting jaw groove 124a, which aligns with the cube slot groove 124b. This alignment allows for an optional bolting mechanism, further enhancing the stability of the connection between the arm mount 102 and the cube slot 120. The cube slot 120 may be a primary interface for attaching the modular phone stand to the helmet 122. The cube slot 120 may include a fitting groove 302 (as shown in FIG. 3) that accommodates the fitting jaw 118. The cube slot 120 also features a cube slot groove 124b, which works with the fitting jaw groove 124a to enable an optional bolted connection. This design ensures secure attachment, even under challenging conditions or vibrations. The helmet 122 may securely house the cube slot 120 using either a bolting mechanism or an adhesive attachment. In a bolted setup, holes may be drilled into the helmet to fasten the cube slot, whereas the adhesive method eliminates the need for drilling, ensuring compatibility with various helmet designs.

The fitting jaw groove 124a and cube slot groove 124b are designed to interact with one another. This interaction may allow for an optional bolting mechanism, providing additional stability and security. This feature is particularly useful in environments where robust and secure connections are necessary, such as construction sites or industrial settings. The modular phone stand is depicted in FIG. 1A is designed to offer a highly versatile, foldable, and ergonomic solution for hands-free smartphone use. The pivotal connections between the arm mount 102, first arm 104, and second arm 106 provide flexibility for adjustments and folding. The gripper 108 ensures secure holding of the device, while the cube slot 120 facilitates seamless helmet integration. These features collectively enable professionals and users to operate hands-free in various environments, ensuring convenience, stability, and ergonomic usability.

Referring to FIG. 1B is a block diagram 100b depicting a schematic representation of a foldable and modular phone stand, in accordance with one or more exemplary embodiments. The foldable and modular phone stand 100b includes an arm mount 102, a first arm 104, a second arm 106, a gripper 108, pins 110 and 112, connecting pins 114, and a gripper groove 116. The arm mount 102 may serve as a central base for the foldable and modular phone stand 100b. The arm mount 102 be configured to provide pivotal support and structural stability. The arm mount 102 may include a fitting jaw 118 (as shown in FIG. 1A) designed to engage with the fitting groove 302 (as shown in FIG. 3) within the cube slot 120, allowing secure attachment to the helmet 122 (as shown in FIG. 1A. The arm mount 102 may include pivot holes for the pins 110, enabling the connection of the first arm 104. The first arm 104 may be configured to provide structural support and angular adjustability. The first arm 104 proximal end is pivotally connected to the arm mount 102 using pins 110, allowing for rotational flexibility. The first arm 104 enables the modular phone stand to align with the user's eye level while ensuring compact folding when not in use. The distal end of the first arm 104 is pivotally connected to the second arm 106 through the pins 112. The pins 110 and 112 serve as pivotal connection points. The pins 110 connect the arm mount 102 to the first arm 104, while the pins 112 connect the first arm 104 to the second arm 106. The pins 110 and 112 may be configured to allow smooth rotation, enabling the modular phone stand to be adjusted or folded as required. The second arm 106 may be an intermediary structure that connects the first arm 104 to the gripper 108. The second arm 106 proximal end is pivotally connected to the distal end of the first arm 104 using the pins 112, providing additional flexibility and adjustability. The second arm 106 enhances stability and ensures proper positioning of the gripper. The distal end of the second arm 106 is securely attached to the gripper 108 through the connecting pins 114. The gripper 108 may be configured to securely hold a smartphone or similar electronic device. The gripper 108 features the gripper groove 116, which may be designed to accommodate fasteners or screws, ensuring a stable and firm attachment of the device. This design prevents unintended movement of the smartphone and maintains its position relative to the user's line of sight. The gripper 108 may be connected to the second arm 106 through the connecting pins 114, allowing adjustments to accommodate devices of varying sizes and orientations. The connecting pins 114 may be configured to attach the gripper 108 to the second arm 106. The connecting pins 114 provide a secure and stable connection while allowing for minor adjustments. The modular design ensures that the gripper 108 may hold devices of different sizes and orientations without compromising stability. The gripper groove 116 may be configured to securely hold the smartphone using fasteners or screws. The gripper groove 116 ensures that the phone remains firmly in place during use, even in dynamic or high-vibration environments. The design may include threaded holes or similar features to accommodate fasteners or screws for enhanced stability. The modular phone stand is depicted in FIG. 1B is designed to provide a robust and ergonomic solution for securely holding electronic devices. The pivotal connections between the arm mount 102, first arm 104, and second arm 106 enable angular adjustments, facilitating alignment with the user's line of sight. The gripper 108, equipped with the gripper groove 116, ensures a firm hold on the device, while the overall modular design allows the stand to be folded into a compact form for portability.

Referring to FIG. 2 is an example block diagram 200 depicting a schematic representation of a foldable and modular phone stand aligned with the cube slot attached to the helmet, in accordance with one or more exemplary embodiments. The user 101 may be an individual wearing the helmet 122, which is equipped with the cube slot 120 for integrating the foldable and modular phone stand 100b. The foldable and modular phone stand 100b is shown aligned with the helmet 122, indicating its readiness for secure attachment. The helmet 122 may serve as the foundational structure for integrating the modular phone stand. The cube slot 120, permanently affixed to the helmet 122, facilitates the attachment of the foldable and modular phone stand 100b. The cube slot 120 may be permanently attached to the helmet 122 using either a bolt-through mechanism (requiring drilling) or adhesive for a non-invasive option, ensuring stability while maintaining compatibility with various helmet designs. The cube slot 120 acts as the primary interface for securely connecting the foldable and modular phone stand 100b to the helmet 122. The cube slot 120 includes a fitting groove 302 (as shown in FIG. 3) designed to engage with the fitting jaw 118 of the arm mount 102. This interaction ensures a stable attachment while enabling rotational and angular adjustments of the phone stand. The arm mount 102 may be a central connection point between the foldable and modular phone stand 100b and the cube slot 120. The arm mount 102 includes the fitting jaw 118, which is designed to slide into the fitting groove 302 (as shown in FIG. 3) of the cube slot 120. This mechanism ensures the secure placement of the foldable and modular phone stand 100b on the helmet and provides rotational flexibility for ergonomic alignment. The arm mount 102 also includes pivot holes that house the pins 110, enabling the connection of the first arm 104 to the arm mount. This pivotal connection allows the foldable and modular phone stand 100b to rotate or fold, providing compactness when not in use.

The first arm 104 may be pivotally connected to the arm mount 102 using pins 110, facilitating smooth angular adjustments. This pivotal connection enables the first arm 104 to rotate, align, or retract and extract as needed to suit the user's eye level. The first arm 104 provides primary structural support to the foldable and modular phone stand 100b. The distal end of the first arm 104 is pivotally connected to the second arm 106 through the pins 112, ensuring seamless alignment and flexibility. The second arm 106 may be an intermediary structure between the first arm 104 and the gripper 108. The second arm 106 may be pivotally connected to the distal end of the first arm 104 through the pins 112, allowing for rotational flexibility. This connection ensures that the phone stand may adjust its angle to align with the user's eye level for optimal viewing. The distal end of the second arm 106 is securely connected to the gripper 108 using connecting pins 114, ensuring stable attachment while enabling minor adjustments to accommodate different device sizes. The gripper 108 may be configured to securely hold the smartphone or similar electronic device. The gripper 108 includes a gripper groove 116, which is designed to accommodate fasteners or screws, ensuring a stable and firm attachment of the device. This design prevents unintended movement, maintaining the smartphone's position relative to the user's line of sight. The gripper 108 ensures seamless interaction with augmented reality (AR) applications, navigation tools, or other hands-free applications. The gripper 108 connects to the second arm 106 using connecting pins 114, which enables minor adjustments to support varying device sizes and orientations. The pins 110 and 112 facilitate pivotal connections between the arm mount 102, first arm 104, and second arm 106, enabling angular adjustments and folding mechanisms. The connecting pins 114 provide a secure link between the second arm 106 and the gripper 108, ensuring stability while accommodating different device configurations. The diagram 200 showcases the alignment of the foldable and modular phone stand 100b with the cube slot 120 attached to the helmet 122. This alignment demonstrates the modular stand's ability to integrate seamlessly with the helmet 122 while maintaining adjustability and ergonomic usability. The pivotal connections between the arm mount 102, first arm 104, and second arm 106 enable precise angular adjustments, allowing the modular stand 100b to align the smartphone with the user's line of sight. The gripper 108 ensures secure and stable holding of the device, enabling hands-free interaction in various environments, such as augmented reality applications or navigation tasks. This modular design emphasizes ease of use, portability, and versatility, catering to professional and personal use cases. The alignment with the cube slot also highlights the stand's capability to attach securely to helmets without compromising stability, even under challenging conditions or vibrations.

Referring to FIG. 3 is an example block diagram 300 depicting a side view of a foldable and modular phone stand aligned with the cube slot attached to the helmet, in accordance with one or more exemplary embodiments. The block diagram 300 includes a user 101, an arm mount 102, a first arm 104, a second arm 106, a gripper 108, pins 110 and 112, a fitting jaw 118, a cube slot 120, a helmet 122, and a fitting groove 302.

The user 101 may be an individual wearing the helmet 122, which is equipped with the modular phone stand 100b for hands-free use. The helmet 122 may serve as the foundational structure for securely attaching the foldable and modular phone stand 100b. The helmet 122 provides support and stability for the entire assembly, allowing the user to engage in hands-free activities, such as augmented reality (AR) applications, navigation, or other viewing tasks. The cube slot 120 may be permanently attached to the helmet 122 and serve as the primary interface for integrating the modular phone stand. The cube slot 120 may include a fitting groove 302 designed to accommodate the fitting jaw 118 of the arm mount 102. This design provides a secure connection between the cube slot 120 and the modular phone stand, enabling stability during use. The cube slot 120 may be attached to the helmet 122 using a bolting mechanism that involves drilling holes in the helmet or using adhesive for non-invasive attachment. Both methods provide necessary stability while accommodating different helmet designs.

The arm mount 102 may be the central connecting structure of the modular phone stand. The arm mount 102 may be pivotally coupled with the first arm 104 using pins 110, which allows rotational flexibility. The arm mount 102 includes the fitting jaw 118, which securely engages with the fitting groove 302 of the cube slot 120. This interaction ensures that the modular phone stand remains firmly attached to the helmet 122 while allowing rotational and angular adjustments for ergonomic alignment with the user's eye level. The first arm 104 is pivotally connected to the arm mount 102 through the pins 110. This pivotal connection facilitates smooth rotational adjustments, enabling the first arm 104 to be extracted, retracted, or folded as needed. The first arm 104 provides primary structural support to the modular phone stand. The distal end of the first arm 104 is pivotally connected to the second arm 106 using pins 112, enabling additional angular flexibility and seamless integration. The second arm 106 serves as an intermediary structure between the first arm 104 and the gripper 108. The second arm 106 is pivotally connected to the distal end of the first arm 104 through the pins 112. This pivotal connection allows the second arm 106 to adjust its angle, enhancing the modular phone stand's flexibility and alignment. The distal end of the second arm 106 is securely attached to the gripper 108 using connecting pins 114, which ensure stable attachment while allowing minor adjustments to accommodate devices of varying sizes and orientations. The gripper 108 is designed to securely hold a smartphone or similar portable electronic devices. The gripper 108 includes a gripper groove 116, which may be configured to accommodate fasteners or screws for enhanced stability. This ensures that the device remains firmly attached to the modular phone stand, even in environments with high vibration or dynamic movements. The gripper 108 ensures precise positioning of the smartphone in front of the user's eyes, enabling seamless interaction with AR applications, navigation tools, or other hands-free functionalities. The pins 110 and 112 facilitate pivotal connections between the arm mount 102, the first arm 104, and the second arm 106. These pivotal points enable angular adjustments and folding mechanisms, allowing the modular phone stand to adapt to various user requirements or fold into a compact form for portability.

The fitting jaw 118, integrated into the arm mount 102, interacts with the fitting groove 302 within the cube slot 120. This mechanism provides a stable connection between the modular phone stand and the helmet 122. Additionally, this configuration allows for angular adjustments, enabling the user to achieve an optimal ergonomic alignment for hands-free viewing. The diagram 300 demonstrates the modular phone stand's ability to integrate seamlessly with the helmet 122 while maintaining stability, adjustability, and ergonomic usability. The pivotal connections between the arm mount 102, first arm 104, and second arm 106 facilitate precise angular adjustments, allowing the modular phone stand to align the smartphone with the user's line of sight. The gripper 108 ensures the secure and stable holding of the device, enabling hands-free interaction in various environments, including professional and personal use cases. The modular design emphasizes user convenience, portability, and versatility, catering to diverse applications such as construction, navigation, and augmented reality.

Referring to FIG. 4 is an example block diagram 400 depicting a foldable and modular phone stand with the fitting jaw secured into the cube slot, and showing the optional bolting mechanism using the cube slot groove and fitting jaw groove, in accordance with one or more exemplary embodiments.

The block diagram 400 includes a user 101, an arm mount 102, a first arm 104, a second arm 106, a gripper 108, pins 110 and 112, connecting pins 114, a gripper groove 116, a fitting jaw 118, a cube slot 120, a helmet 122, a fitting jaw groove 124a, and a cube slot groove 124b. The user 101 may be an individual wearing the helmet 122, which provides the foundational structure for securely integrating the foldable and modular phone stand. The helmet 122 may equipped with the cube slot 120. The cube slot 120 may be securely mounted on the helmet 122 through a bolting mechanism requiring drilled holes or by using an adhesive for a non-invasive attachment. This dual-attachment design ensures compatibility with various helmet types while maintaining stability under different environmental conditions. The cube slot 120 may include a fitting groove 302 (as shown in FIG. 3) designed to accommodate the fitting jaw 118 of the arm mount 102. The fitting jaw 118 slides into the fitting groove 302, creating a secure connection. Additionally, the fitting jaw 118 includes a fitting jaw groove 124a, which aligns with the cube slot groove 124b. These grooves may enable an optional bolting mechanism to provide enhanced stability and prevent dislodgement during use, particularly in high-vibration or dynamic environments such as construction sites or industrial settings. The arm mount 102 may be pivotally connected to the first arm 104 using pins 110, enabling angular adjustments and rotational flexibility. This pivotal connection allows the modular phone stand to adapt to various ergonomic requirements and align with the user's line of sight. The first arm 104 provides primary structural support and is pivotally connected to the arm mount 102 at its proximal end using pins 110. This connection facilitates extraction, retraction, and folding of the first arm 104. The distal end of the first arm 104 is pivotally connected to the second arm 106 through pins 112, allowing seamless angular adjustments. The second arm 106 serves as an intermediary structure between the first arm 104 and the gripper 108. The second arm 106 is pivotally connected to the distal end of the first arm 104 using pins 112, providing additional rotational flexibility and alignment capabilities. The distal end of the second arm 106 is securely attached to the gripper 108 using connecting pins 114.

The gripper 108 may be configured to securely hold a smartphone or similar portable electronic device. The gripper 108 may include a gripper groove 116 designed to accommodate fasteners or screws for stable attachment. This design ensures that the device remains firmly in place, even in environments with high vibrations or dynamic movement. The gripper 108 allows minor adjustments to accommodate devices of various sizes and orientations, enabling precise positioning in front of the user's eyes for seamless interaction with applications such as augmented reality (AR) or navigation tools. The optional bolting mechanism showcased in FIG. 4 highlights the additional security features of the modular phone stand. The alignment of the fitting jaw groove 124a with the cube slot groove 124b enables the use of bolts or similar fasteners to lock the arm mount 102 securely into the cube slot 120. This feature enhances stability, particularly in professional settings requiring robust and secure connections. The block diagram 400 demonstrates the secure integration of the modular phone stand with the helmet 122. The pivotal connections between the arm mount 102, first arm 104, and second arm 106 provide angular flexibility, enabling precise alignment of the smartphone with the user's eye level. The gripper 108 ensures the secure and stable holding of the device, allowing hands-free interaction in various environments. The modular design emphasizes portability, stability, and versatility, making it suitable for applications in construction, navigation, augmented reality, and other professional or personal use cases.

Referring to FIG. 5 is an example block diagram 500 depicting a side view of a foldable and modular phone stand in an adjusted position, illustrating the ergonomic alignment of a gripper relative to the user's line of sight, in accordance with one or more exemplary embodiments. The block diagram 500 includes a user 101, an arm mount 102, a first arm 104, a second arm 106, a gripper 108, pins 110 and 112, a fitting jaw 118, a cube slot 120, and a helmet 122. The user 101 may be an individual wearing the helmet 122. The helmet 122 may include the cube slot 120 that acts as the primary interface for attaching the modular phone stand. The cube slot 120 may be permanently secured to the helmet 122 through either a bolting mechanism (requiring drilled holes) or adhesive for a non-invasive attachment method. The cube slot 120 ensures stability and compatibility across various helmet designs while maintaining a strong connection under diverse environmental conditions.

The cube slot 120 may be configured to accommodate the fitting jaw 118 of the arm mount 102. The fitting jaw 118 slides into the fitting groove 302 (as depicted in FIG. 3) of the cube slot 120, ensuring a secure connection. This interaction allows for stable attachment of the modular phone stand to the helmet 122 while enabling angular adjustments for ergonomic positioning. The cube slot 120 may include cube slot groove 124b, which may enable an optional bolting mechanism for enhanced stability in high-vibration environments.

The arm mount 102 is pivotally connected to the first arm 104 through the pins 110, allowing rotational flexibility and smooth adjustments. This pivotal connection enables the first arm 104 to be extracted, retracted, or folded into a compact form when not in use. The arm mount 102 ensures that the modular phone stand can be aligned with the user's line of sight for optimal ergonomic usability. The first arm 104 is pivotally attached to the arm mount 102 at its proximal end through the pins 110, facilitating angular adjustments. This pivotal connection allows the first arm 104 to align with the user's field of view and provides structural support to the modular phone stand. The distal end of the first arm 104 is pivotally connected to the second arm 106 through the pins 112, ensuring seamless angular flexibility. The first arm 104 also ensures smooth extraction or retraction, allowing the stand to accommodate users of varying heights and ergonomic requirements.

The second arm 106 serves as an intermediary structure between the first arm 104 and the gripper 108. The second arm 106 is pivotally connected to the distal end of the first arm 104 through the pins 112, providing additional rotational flexibility. This pivotal connection enables the modular phone stand to maintain precise alignment with the user's line of sight. The distal end of the second arm 106 is securely attached to the gripper 108 using connecting pins 114, ensuring stable attachment while allowing minor adjustments to accommodate smartphones or other electronic devices of various sizes and orientations.

The gripper 108 may be configured to securely hold a smartphone or similar portable electronic devices. The gripper 108 includes a gripper groove 116, which may be designed to accommodate fasteners or screws, ensuring a stable and firm attachment of the device. This design prevents unintended movement, even in high-vibration or dynamic environments. The gripper 108 ensures precise positioning of the smartphone relative to the user's line of sight, enabling seamless interaction with applications such as augmented reality (AR), navigation, or other hands-free functionalities. The modular phone stand depicted in FIG. 5 demonstrates its suitability for professional and personal applications, including but not limited to construction, navigation, and augmented reality. The robust attachment mechanism, coupled with its adjustability and ergonomic features, makes it a versatile solution for hands-free smartphone use in dynamic environments. The integration of the gripper 108 with the second arm 106 further highlights the design's ability to accommodate varying device sizes and orientations, ensuring usability across a wide range of scenarios.

Referring to FIG. 6 is an example block diagram 600 depicting an embodiment of the foldable and modular phone stand with secure helmet integration, in accordance with one or more exemplary embodiments. The block diagram 600 includes a user 101, an arm mount 102, a first arm 104, a second arm 106, a gripper 108, pins 110 and 112, connecting pins 114, a fitting jaw 118, a cube slot 120, a helmet 122, a cube slot groove 124b, and an optional bolting mechanism for secure integration. The user 101 may be an individual utilizing the helmet 122 equipped with the foldable and modular phone stand. The cube slot 120 may be permanently affixed to the helmet 122 through either a bolting mechanism requiring drilled holes or an adhesive attachment for non-invasive integration. This dual-attachment configuration ensures stability and compatibility with various helmet designs, even in dynamic or high-vibration environments. The cube slot 120 may include a fitting groove 302 (as shown in FIG. 3), designed to accommodate the fitting jaw 118 of the arm mount 102. The fitting jaw 118, which is part of the arm mount 102, may slide securely into the fitting groove 302 of the cube slot 120, ensuring a stable and firm attachment. The fitting jaw 118 may include a fitting jaw groove 124a, which aligns with the cube slot groove 124b. These grooves may optionally enable a bolting mechanism to enhance stability and prevent dislodgement during use.

The arm mount 102 may be pivotally connected to the first arm 104 using pins 110, allowing for smooth angular adjustments and rotational flexibility. This pivotal connection ensures that the foldable and modular phone stand may be adjusted to accommodate various ergonomic requirements, including alignment with the user's eye level. The first arm 104 provides primary structural support to the foldable and modular phone stand and is pivotally attached to the arm mount 102 at its proximal end using pins 110. This pivotal connection enables smooth extraction, retraction, and folding of the first arm 104, enhancing the stand's portability and adaptability. The distal end of the first arm 104 is pivotally connected to the second arm 106 using pins 112, ensuring seamless angular adjustments. The second arm 106 serves as an intermediary structure between the first arm 104 and the gripper 108. The second arm 106 is pivotally connected to the distal end of the first arm 104 through pins 112, allowing for rotational flexibility and precise alignment. The distal end of the second arm 106 is securely attached to the gripper 108 using connecting pins 114. These pivotal connections ensure that the foldable and modular phone stand maintains its stability and alignment during use while allowing minor adjustments to accommodate varying device sizes and orientations. The gripper 108 may securely hold a smartphone or similar portable electronic devices. The gripper 108 may include a gripper groove 116, which may accommodate fasteners or screws to ensure a firm and stable attachment of the device. This design prevents unintended movement of the smartphone, even in high-vibration environments. The gripper 108 ensures that the device is precisely positioned relative to the user's line of sight, enabling seamless interaction with applications such as augmented reality (AR), navigation tools, or other hands-free functionalities.

The optional bolting mechanism depicted in FIG. 6 highlights the additional security features of the foldable and modular phone stand. The alignment of the fitting jaw groove 124a with the cube slot groove 124b enables the use of bolts or similar fasteners to secure the arm mount 102 firmly into the cube slot 120. This feature ensures enhanced stability, particularly in professional environments where robust and secure connections are essential.

The modular design of the phone stand, as depicted in FIG. 6, emphasizes ease of use, portability, and stability. The pivotal connections between the arm mount 102, first arm 104, and second arm 106 enable precise angular adjustments and folding mechanisms, ensuring ergonomic alignment with the user's line of sight. The gripper 108 accommodates various device sizes and orientations, further enhancing the versatility of the stand. This embodiment demonstrates the suitability of the foldable and modular phone stand for a wide range of applications, including construction, navigation, augmented reality, and other hands-free functionalities. The secure integration with the helmet 122 ensures reliable performance in diverse environmental conditions, making the modular phone stand an essential tool for both professional and personal use cases.

Referring to FIG. 7 is an example block diagram 700 depicting a top view of the positional alignment of the modular phone stand on the helmet and a detailed view of the cube slot and its integration with the helmet, in accordance with one or more exemplary embodiments. The block diagram 700 includes a helmet 122, a cube slot 120, an arm mount 102, a first arm 104, and a second arm 106. The helmet 122 serves as the foundational structure for attaching the foldable and modular phone stand. FIG. 7 illustrates a top-down perspective, emphasizing the central placement of the cube slot 120 on the helmet 122. This placement ensures that the modular phone stand is properly aligned with the user's field of view for optimal ergonomic usability.

The cube slot 120 is shown as the primary interface between the helmet 122 and the modular phone stand. The cube slot 120 may be securely attached to the helmet 122 through either a bolting mechanism (requiring drilled holes) or adhesive for non-invasive attachment. This dual-attachment design provides compatibility with various helmet types and ensures stability under different environmental conditions, including high-vibration or dynamic use cases. The cube slot 120 includes a fitting groove 302 (as shown in FIG. 3), designed to accommodate the fitting jaw 118 of the arm mount 102. The fitting jaw 118 may securely slide into the fitting groove 302, ensuring a firm attachment. The cube slot 120 may also include a cube slot groove 124b, which interacts with the fitting jaw groove 124a. This alignment facilitates an optional bolting mechanism for enhanced stability and security, particularly in demanding environments. The arm mount 102 is centrally aligned with the cube slot 120 in FIG. 7, ensuring that the modular phone stand remains securely positioned. The arm mount 102 serves as the pivotal base for the first arm 104, which is attached to the arm mount 102 through the pins 110. The alignment shown in FIG. 7 highlights the modular design of the phone stand, enabling angular adjustments to ensure proper positioning of the phone relative to the user's eye level. The first arm 104 extends from the arm mount 102 and is pivotally connected to the second arm 106 through pins 112. The second arm 106 extends outward, forming the intermediary structure that supports the gripper (not fully visible in the top view). This configuration ensures that the modular phone stand maintains its ergonomic alignment while accommodating devices of various sizes and orientations. The top-down perspective in FIG. 7 showcases the compact and centered design of the modular phone stand. The alignment of the cube slot 120, arm mount 102, and the arms (104, 106) emphasizes the balance and stability of the setup. This ensures that the phone stand remains firmly in place, even during dynamic movements or high-vibration scenarios. The integration of the cube slot 120 with the helmet 122, as depicted in FIG. 7, underscores the robustness of the attachment mechanism. The combination of the fitting groove 302 and the optional bolting mechanism using cube slot groove 124b ensures a secure and stable connection. This design prioritizes user safety and convenience, making the modular phone stand suitable for professional and personal applications such as augmented reality, navigation, and other hands-free functionalities. The block diagram 700 demonstrates the meticulous alignment and integration of the modular phone stand with the helmet 122. The top view provides a clear perspective on how the cube slot 120, arm mount 102, and arms (104, 106) work together to deliver a stable, adjustable, and ergonomic solution for hands-free smartphone use. This embodiment highlights the design's adaptability, portability, and suitability for diverse applications in construction, navigation, and augmented reality.

Referring to FIG. 8 is an example block diagram 800 depicting rear perspective view of a foldable and modular phone stand attached to the helmet, in accordance with one or more exemplary embodiments. The block diagram 800 includes a user 101, an arm mount 102, a first arm 104, a second arm 106, a gripper 108, pins 110 and 112, a cube slot 120, and a helmet 122.

The user 101 may be an individual and wearing the helmet 122, which serves as the foundational structure for integrating the foldable and modular phone stand. This rear perspective highlights the modular stand's attachment mechanism and structural alignment with the helmet 122. The helmet 122 provides stability and support for the entire modular phone stand, ensuring ergonomic usability for hands-free interaction. The cube slot 120, securely affixed to the helmet 122, acts as the interface between the modular phone stand and the helmet 122. The cube slot 120 may be attached to the helmet 122 using either a bolting mechanism, requiring drilled holes for a robust connection, or an adhesive method for a non-invasive attachment. This dual-attachment mechanism ensures compatibility across various helmet designs while maintaining stability under dynamic or high-vibration environments. The cube slot 120 features a fitting groove 302 (as illustrated in FIG. 3) designed to securely engage the fitting jaw 118 of the arm mount 102. This engagement ensures a stable connection, allowing the modular phone stand to remain firmly attached to the helmet 122. The fitting jaw 118 may slide into the fitting groove 302, facilitating seamless integration between the modular phone stand and the helmet. Additionally, the cube slot 120 may include a cube slot groove 124b, which aligns with the fitting jaw groove 124a (as shown in FIG. 4). This alignment enables an optional bolting mechanism to further enhance the stability and security of the connection. The arm mount 102, as depicted in the rear perspective, serves as the central structural base for the modular phone stand. The arm mount 102 is pivotally connected to the first arm 104 through pins 110. This pivotal connection enables rotational flexibility, allowing the modular phone stand to be adjusted for optimal alignment with the user's field of view or folded into a compact form when not in use.

The first arm 104 extends from the arm mount 102 and is shown pivotally connected to the second arm 106 through the pins 112. This pivotal connection allows the first arm 104 to facilitate angular adjustments, ensuring proper positioning of the phone relative to the user's eye level. The first arm 104 provides the primary structural support necessary for maintaining stability during use. The second arm 106 acts as an intermediary component between the first arm 104 and the gripper 108. The second arm 106, pivotally connected to the distal end of the first arm 104 through the pins 112, enhances the adjustability of the modular phone stand. This connection ensures the second arm 106 may accommodate various ergonomic configurations and alignments. The distal end of the second arm 106 is securely attached to the gripper 108 using connecting pins 114, which provide both stability and minor adjustment capabilities. The gripper 108 is designed to securely hold a smartphone or similar portable electronic devices. The rear perspective in FIG. 8 showcases the gripper 108, which features a gripper groove 116 that can accommodate fasteners or screws. This design ensures the secure attachment of the device, even in environments with high vibrations or dynamic movements. The gripper 108 maintains the smartphone's position in front of the user's eyes, enabling seamless interaction with applications such as augmented reality (AR), navigation tools, or other hands-free functionalities. The modular phone stand's pivotal connections, as highlighted in FIG. 8, demonstrate the flexibility and adaptability of its design. The pins 110 and 112 enable angular adjustments and smooth rotation of the arms (104 and 106), facilitating precise alignment with the user's field of view. These features enhance the modular phone stand's usability and portability, making it suitable for various professional and personal applications. The block diagram 800 emphasizes the robust and ergonomic design of the foldable and modular phone stand. The integration of the cube slot 120 with the helmet 122 ensures secure attachment and stability, while the modular components (arm mount 102, first arm 104, second arm 106, and gripper 108) provide flexibility for alignment and usability. This embodiment underscores the design's versatility and practicality for diverse environments, such as construction sites, navigation, and augmented reality applications. The rear perspective further illustrates how the modular phone stand seamlessly integrates with the helmet without compromising comfort or functionality.

Referring to FIG. 9 is an example diagram 900 depicting a side view of the cube slot permanently attached to the helmet in the absence of the modular phone stand, in accordance with one or more exemplary embodiments. The diagram 900 includes a user 101, a helmet 122, and a cube slot 120. The user 101 may be an individual wearing the helmet 122, which acts as the foundational structure for the modular phone stand integration. The cube slot 120 may be permanently affixed to the helmet 122 using one of two possible attachment methods: a bolting mechanism or adhesive. In the bolting mechanism, holes may be drilled into the helmet 122, allowing bolts to secure the cube slot 120. This approach provides a robust and stable connection, particularly useful for environments requiring durability, such as construction sites or industrial settings. Alternatively, an adhesive may be used as a non-invasive method to attach the cube slot 120 to the helmet 122, ensuring compatibility with helmet designs that do not permit drilling. This adhesive method offers ease of installation and ensures a secure attachment under various conditions. The cube slot 120 serves as the interface between the modular phone stand and the helmet 122. Designed for seamless integration, the cube slot 120 includes a fitting groove 302 (as shown in FIG. 3) that accommodates the fitting jaw 118 of the modular phone stand. This configuration ensures that the modular phone stand can be easily attached or detached as needed, providing flexibility and convenience for the user. The cube slot 120 includes a cube slot groove 124b, which is aligned to interact with the fitting jaw groove 124a of the modular phone stand's arm mount 102 (as shown in FIG. 4). This alignment allows for an optional bolting mechanism to enhance the stability of the connection when the modular phone stand is attached. This feature ensures that the modular phone stand remains securely in place during use, even in dynamic or high-vibration environments. The side view depicted in FIG. 9 emphasizes the lightweight and compact design of the cube slot 120, which minimizes interference with the helmet's ergonomics. Its streamlined profile ensures that the cube slot 120 does not compromise the user's comfort or mobility when the modular phone stand is not in use. This design allows the helmet 122 to retain its primary functionality while providing the infrastructure for attaching the modular phone stand when needed. FIG. 9 demonstrates the versatility and adaptability of the cube slot 120 as an integral component of the foldable and modular phone stand system. The permanent attachment to the helmet 122 ensures readiness for the modular phone stand's deployment, catering to hands-free applications such as augmented reality (AR), navigation, and other professional or personal tasks.

Referring to FIG. 10 is an example diagram 1000 depicting a side view of the cube slot with the inclusion of the cube slot groove for attaching to the helmet, in accordance with one or more exemplary embodiments. The diagram 1000 includes a user 101, a helmet 122, a cube slot 120, and a cube slot groove 124b. The user 101 may be an individual wearing the helmet 122, which provides the foundational structure for the attachment of the cube slot 120. The helmet 122 is depicted as a conventional design, demonstrating the modularity and adaptability of the cube slot 120 for integration with various helmet types. The cube slot 120 is shown securely attached to the helmet 122, highlighting its readiness for interfacing with the modular phone stand. The cube slot 120 acts as the primary attachment interface for the modular phone stand. Permanently affixed to the helmet 122, the cube slot 120 may be attached using either a bolting mechanism or adhesive. For bolting, holes may be drilled into the helmet 122 to securely fasten the cube slot 120 using bolts or screws. This method ensures a robust connection, ideal for high-vibration environments such as construction or industrial sites. Alternatively, adhesive can be used as a non-invasive attachment method, providing compatibility with helmet designs that do not permit drilling while ensuring stability during use. The cube slot 120 includes the cube slot groove 124b, which serves as an alignment and attachment feature. The cube slot groove 124b is designed to interface with the fitting jaw groove 124a (as shown in FIG. 4) of the modular phone stand's arm mount. This alignment mechanism allows for the secure placement of the modular phone stand onto the cube slot 120 while enabling an optional bolting mechanism for enhanced stability. This optional bolting mechanism involves inserting bolts through the aligned cube slot groove 124b and the fitting jaw groove 124a, ensuring a tight and secure connection that prevents dislodgement during operation. The side view depicted in FIG. 10 emphasizes the cube slot 120's streamlined and compact design, ensuring minimal interference with the user's mobility and comfort. The cube slot 120 is designed to seamlessly integrate with the helmet 122 while providing a robust platform for attaching the modular phone stand. Its placement ensures ergonomic alignment when the modular phone stand is in use, enabling hands-free applications such as augmented reality (AR), navigation, or other tasks requiring a smartphone or similar device. FIG. 10 showcases the functional and structural aspects of the cube slot 120, demonstrating its critical role in securely interfacing the modular phone stand with the helmet 122. The inclusion of the cube slot groove 124b highlights its modular and adaptable design, allowing for flexible attachment options based on the user's requirements and environmental conditions. This embodiment underlines the durability and versatility of the system, ensuring reliable operation in various professional and personal use scenarios.

Referring to FIG. 11 is an example diagram 1100 depicting a side view of the cube slot as it interacts with the helmet during assembly or adjustment and the alignment of the cube slot with the helmet's surface, in accordance with one or more exemplary embodiments. The diagram 1100 includes a user 101, a helmet 122, and a cube slot 120. The user 101 may be an individual wearing the helmet 122 for integration with the modular phone stand. The helmet 122 serves as the foundational structure for securely attaching the cube slot 120, ensuring a stable and ergonomic platform for modular phone stand operation. The helmet 122 is depicted with its standard design, showcasing its adaptability to accommodate the attachment of the cube slot 120. The cube slot 120 acts as the primary interface for connecting the modular phone stand to the helmet 122. The diagram illustrates the precise alignment required during assembly or adjustment to ensure the cube slot 120 is securely affixed to the helmet's surface. This alignment is crucial for maintaining the stability and durability of the system, particularly in environments prone to dynamic movements or vibrations. The cube slot 120 may be permanently attached to the helmet 122 using one of two methods: a bolting mechanism or an adhesive attachment. In the bolting mechanism, holes are drilled into the helmet 122 to accommodate bolts or screws that securely fasten the cube slot 120 to the helmet. This method ensures maximum stability and is particularly suited for high-vibration environments such as construction or industrial sites. Alternatively, an adhesive may be used for a non-invasive attachment, providing a seamless and damage-free option for helmets that do not permit drilling. This adhesive method offers compatibility across various helmet designs while maintaining a strong and reliable connection. The side view depicted in FIG. 11 emphasizes the interaction of the cube slot 120 with the helmet's surface during assembly. The alignment of the cube slot 120 is critical to ensuring proper functionality and ergonomic positioning of the modular phone stand when in use. This alignment ensures that the cube slot 120 is correctly positioned to engage with the fitting jaw (as depicted in other figures), enabling seamless integration of the modular phone stand. The cube slot 120 is designed with a flat base to ensure even contact with the helmet's surface, minimizing gaps and potential movement. The design accommodates varying helmet contours, ensuring a snug and secure fit during assembly. This feature is essential for ensuring the reliability and stability of the modular phone stand when attached. FIG. 11 showcases the detailed interaction and alignment of the cube slot 120 with the helmet 122 during assembly or adjustment. This embodiment highlights the versatility and adaptability of the system, ensuring it can be securely attached to a wide range of helmet designs. The diagram emphasizes the importance of proper alignment during assembly to maintain the system's stability and functionality, making it suitable for professional and personal applications.

Referring to FIG. 12 is an example diagram 1200 depicting a rear-side view of a cube slot secure attachment with the helmet, in accordance with one or more exemplary embodiments. The block diagram 1200 includes a user 101, a helmet 122, and a cube slot 120, highlighting the secure integration and alignment of the cube slot with the helmet's surface. The user 101 may be an individual wearing the helmet 122, which serves as the foundational structure for attaching the cube slot 120. The rear-side perspective provides a clear view of the alignment and secure attachment of the cube slot 120 to the helmet's surface. This view emphasizes the stability and compatibility of the attachment system. The helmet 122 may be designed to accommodate the cube slot 120 using either a bolting mechanism or adhesive attachment. The bolting mechanism involves creating holes in the helmet 122, allowing bolts or screws to pass through and securely fasten the cube slot 120. This method ensures maximum stability, especially in high-vibration or dynamic environments. Alternatively, the adhesive attachment offers a non-invasive method, eliminating the need for drilling while maintaining a firm bond between the cube slot 120 and the helmet 122. This design provides flexibility for users with helmets that cannot be drilled. The cube slot 120 acts as the primary interface for integrating the foldable and modular phone stand. The rear-side view highlights the flat base of the cube slot 120, ensuring even contact with the helmet's surface. This flat design minimizes gaps and potential movement, enhancing stability during use. The cube slot 120 is securely aligned with the curvature of the helmet 122 to ensure a snug fit, preventing dislodgement even in dynamic or high-impact conditions. The cube slot 120 may include a cube slot groove (124b), which facilitates the insertion and secure engagement of the fitting jaw. This groove is integral to the cube slot's ability to securely connect with the modular phone stand, ensuring that the phone stand remains firmly attached during operation. The groove may also accommodate an optional bolting mechanism, providing an additional layer of security for professional or industrial applications. The rear-side view of the helmet 122 and cube slot 120 depicted in FIG. 12 demonstrates the robustness and reliability of the attachment system. The alignment of the cube slot 120 with the helmet 122 ensures that the modular phone stand can be seamlessly integrated without compromising the helmet's structural integrity or the user's safety. FIG. 12 emphasizes the versatility of the attachment mechanism, which is compatible with various helmet designs and allows for secure and stable integration of the cube slot 120. This embodiment highlights the adaptability of the system, making it suitable for a range of applications, including construction, augmented reality, and navigation. The cube slot's secure attachment to the helmet ensures a reliable platform for hands-free operation, catering to both professional and personal use cases.

According to an exemplary aspect of the present disclosure, the cube slot is affixed to the helmet using a bolting mechanism, the bolting mechanism comprising drilled holes in the helmet and bolts or screws configured to securely fasten the cube slot, ensuring stability in high-vibration environments.

According to an exemplary aspect of the present disclosure, the cube slot is affixed to the helmet using an adhesive attachment, the adhesive configured to provide a non-invasive and durable bond, enabling compatibility with helmets that do not permit drilling.

According to an exemplary aspect of the present disclosure, the fitting jaw of the arm mount is slidably engaged with the fitting groove of the cube slot, the sliding engagement configured to allow quick assembly and disassembly of the foldable and modular phone stand.

According to an exemplary aspect of the present disclosure, the cube slot groove and the fitting jaw groove are configured to align and accommodate a bolt, the alignment providing an optional bolting mechanism for enhanced stability during use.

According to an exemplary aspect of the present disclosure, the first arm and the second arm are configured to fold into a compact form, facilitating portability and storage when the foldable and modular phone stand is not in use.

According to an exemplary aspect of the present disclosure, the gripper is configured to rotate about its connection to the second arm, the rotation enabling precise alignment of a mobile device relative to the user's line of sight.

According to an exemplary aspect of the present disclosure, the gripper groove is configured to accommodate fasteners or screws, the fasteners or screws providing a stable attachment of the mobile device to the gripper.

According to an exemplary aspect of the present disclosure, the first arm and the second arm are constructed from lightweight and durable materials, the materials providing structural strength and reducing the overall weight of the foldable and modular phone stand.

According to an exemplary aspect of the present disclosure, the pivotal connections between the arm mount, first arm, and second arm are configured to provide angular adjustments, the adjustments allowing the phone stand to align with varying user preferences and ergonomic requirements.

According to an exemplary aspect of the present disclosure, the gripper is configured to accommodate mobile devices of varying sizes and orientations, the gripper includes adjustable components to securely hold devices in both portrait and landscape orientations.

According to an exemplary aspect of the present disclosure, the foldable and modular phone stand is configured to support hands-free applications, including augmented reality, navigation, and other functionalities that require stable alignment of the mobile device.

According to an exemplary aspect of the present disclosure, the cube slot comprises a flat base to ensure even contact with the helmet's surface, the flat base minimizing movement and enhancing stability during use.

According to an exemplary aspect of the present disclosure, the pivotal connections are equipped with friction control mechanisms, the mechanisms configured to maintain the adjusted position of the arms without unintended movement.

According to an exemplary aspect of the present disclosure, the modular design allows for disassembly of the arm mount, arms, and gripper, the disassembly enabling easy transportation and reassembly.

According to an exemplary aspect of the present disclosure, the gripper is configured to provide rotational adjustments about its axis, allowing the mobile device to be oriented in portrait, landscape, or intermediate angles.

According to an exemplary aspect of the present disclosure, the gripper is configured with a quick-lock mechanism, the mechanism allowing for secure and rapid attachment or detachment of the mobile device without the need for additional tools, enabling user convenience in dynamic environments.

According to an exemplary aspect of the present disclosure, the cube slot groove and the fitting jaw groove are configured to align and accommodate a bolt, the alignment providing additional stability specifically for use in high-vibration or dynamic environments, such as construction sites or industrial applications.

According to an exemplary aspect of the present disclosure, the arm mount, first arm, second arm, and gripper collectively form the foldable and modular phone stand, the modular foldable and the modular phone stand are configured to enable angular adjustments and alignment of a portable electronic device with the user's line of sight, ensuring ergonomic usability across various applications.

According to an exemplary aspect of the present disclosure, the fitting jaw of the arm mount is configured with a contoured design that aligns precisely with the fitting groove of the cube slot, the alignment enhancing lateral stability and reducing unintended movement during high-impact or vibration-prone activities.