Description:FIELD OF THE INVENTION

[0001] The present invention relates to a custom apparel crafting device that enables a user to obtain personalized garments based on their preferences and body measurements while ensuring minimal fabric wastage and efficient garment production through an automated process.

BACKGROUND OF THE INVENTION

[0002] Custom clothing is designed to provide individuals with garments that fit their body measurements and personal preferences. People often struggle with finding perfectly fitted clothing that complements their body shape, style preferences, and fashion trends. In such cases, individuals either rely on standard-sized garments, which may not fit well, or seek professional tailoring services that require time and additional effort. However, professional tailoring services may not always be readily available, and standard-sized clothing often fails to provide the desired fit and comfort, leading to dissatisfaction among users.

[0003] Additionally, selecting the right fabric, color, and design that aligns with an individual’s preferences and current fashion trends can be challenging. Without expert guidance, users may find it difficult to choose garments that enhance their appearance. Moreover, even after selecting a fabric and design, users cannot visualize how the final outfit will look on them before it is made, which can lead to uncertainty and potential disappointment.

[0004] Furthermore, traditional garment-making processes involve manual measurements, cutting, and stitching, which are prone to errors and inconsistencies. Users may also face delays in the delivery of custom garments, especially when relying on tailors who work manually. Additionally, excessive fabric waste during garment production contributes to inefficiency and increased costs.

[0005] US20080249652A1 discloses a unique methodology for apparel mass-customization is provided. Tracers, precision garments designed for fitting at a store site, are provided. Tracers work in conjunction with a unique Clip and Alteration Point relationship. A database of customers' unique digital fit data is provided. Such data are used by a configured system to generate patterns reflecting a customer's personal size as well as level of comfort. [Virtual inventory is enabled by such stored data and are applied to electronic patterns with no shelf life.] The database allows customers to reorder additional pants in new styles and fabrics at any time. Automated patternmaking algorithms are used that dynamically adjust patterns to the data; core style patterns are adjusted to fabric specifications. A sophisticated manufacturing process provides separates and independent sub-processing, such as kitting, enabling cost-effective and rapid one-at-a-time apparel creation. An exemplary channel kiosk and channel kiosk with scanning are provided.

[0006] US10366175B2 discloses a centralized command and control network system for the automated manufacture of a personalized custom-fit garment comprises a centralized control system; automated programmable manufacturing equipment configured for assembling and stitching the personalized custom-fit garment from a digital pattern; and automated programmable material handling equipment configured for transporting the personalized custom-fit garment or its components through each step of the manufacturing equipment. After the customer has had his or her body scanned, and selected and personalized a garment design, the inventive manufacturing system will then manufacture the garment upon receipt of the order in an automated manner without requiring further substantive manual intervention or touch labor. The resultant personalized custom-fit garment is based on the customer's three-dimensional body shape and style and fit preferences. The system can be used to prepare any kind of garments.

[0007] Conventionally, there exists many devices that are available for fabric selection, design, and tailoring, however these traditional approaches do not provide an efficient and automated solution for personalized garment creation. Moreover, these existing methods lack precision in body measurements, do not offer real-time virtual try-on capabilities, and fail to optimize fabric usage, leading to increased material wastage and additional expenses.

[0008] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that requires to enable users to design and create custom garments efficiently by providing accurate body measurements, real-time virtual visualization, and automated fabric handling and stitching, ensuring minimal material wastage and high-quality personalized clothing.

OBJECTS OF THE INVENTION

[0009] The principal object of the present invention is to overcome the disadvantages of the prior art.

[0010] An object of the present invention is to develop a device that is capable of analyzing user preferences, body measurements, and fashion trends to suggest most suitable styles, colors, and fabric choices, ensuring a tailored and flattering appearance.

[0011] Another object of the present invention is to develop a device that is capable of eliminating the need for manual measurements by automatically capturing precise body dimensions, ensuring a perfect fit and reducing errors in sizing.

[0012] Another object of the present invention is to develop a device that is capable of allowing users to preview different designs in real time, allowing them to visualize how various fabrics and styles that look before making a final decision, minimizing uncertainty and enhancing satisfaction.

[0013] Another object of the present invention is to develop a device that streamlines the entire clothing production process, from fabric selection to stitching, ensuring high-quality craftsmanship while reducing time and effort required for manual tailoring.

[0014] Another object of the present invention is to develop a device that is capable of calculating fabric requirements by optimizing material usage and accordingly suggests alternative designs when required, and re-purposes excess material for other items, promoting sustainability.

[0015] Yet another object of the present invention is to develop a device that is capable of allowing users to specify their lifestyle needs, such as physical activity levels and accordingly adjusts garment properties for flexibility, durability, and enhanced comfort in daily wear.

[0016] The foregoing and other objects, features, and advantages of the present invention will become readily apparent upon further review of the following detailed description of the preferred embodiment as illustrated in the accompanying drawings.

SUMMARY OF THE INVENTION

[0017] The present invention relates to a custom apparel crafting device that is accessed by a user for designing and creating customized garments as well as analyzing body dimensions of the user and fashion trends to recommend suitable fabric patterns and designs, ensuring that the selected garment is both aesthetically appealing and well-fitted.

[0018] According to an embodiment of the present invention, a custom apparel crafting device, comprising a housing having a hinged door to enable a user to enter within the housing, a touch interactive display panel is provided within the housing for enabling a user to provide garment preference, including type of garment, intended occasion, budget constraints as input into a user profile of the user, created in an integrated database for reference, a microcontroller linked with the display panel upon receiving the user commands activates plurality of artificial intelligence-based imaging unit installed inside the housing and paired with ultrasonic sensors provided inside the housing, enabling accurate measurements of user’s body dimensions, plurality of color sensors are integrated inside the housing that works in collaboration with the imaging units to detect skin tone of the user, a hologram projection unit installed inside the housing, configured to create a virtual version of user wearing selected fabric and design, updating in real-time as user adjusts the fabric, color, and design choices via the display panel, thereby enabling the user to preview different clothing styles before making a final decision, a shelf unit installed inside the housing for storing various fabrics, each organized by type, and equipped with an extendable horizontal bar and a motorized clamping unit to secure the fabric, preventing movement and wrinkles during handling, ensuring smooth and damage-free movement.

[0019] According to another embodiment of the present invention, the proposed device further comprises of a robotic gripper attached to the shelves, which picks up fabric rolls and places them onto a stitching table provided inside the housing, a motorized sewing unit is installed over the table that perform different stitching tasks, based on type of stitch required, ensuring precision in every stitch and preventing fabric damage, particularly during intricate stitching tasks or when sewing curves, a motorized slider installed along edges of the table to guide plurality of robotic arms installed over the slider to position the fabric correctly for stitching, the arms adjust fabric alignment as sewing unit works, ensuring precise stitching according to design specifications, an L-shaped telescopic link installed on the table, holding a cutting blade trims excess fabric, the cutting blade is mounted on a motorized ball-and-socket joint, adjusting orientation and cuts fabric in multiple directions, ensuring clean, precise, and minimal waste when trimming fabric and a battery is associated with the device for powering up electrical and electronically operated components associated with the device.

[0020] While the invention has been described and shown with particular reference to the preferred embodiment, it will be apparent that variations might be possible that would fall within the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
Figure 1 illustrates an isomeric view of a custom apparel crafting device.

DETAILED DESCRIPTION OF THE INVENTION

[0022] The following description includes the preferred best mode of one embodiment of the present invention. It will be clear from this description of the invention that the invention is not limited to these illustrated embodiments but that the invention also includes a variety of modifications and embodiments thereto. Therefore, the present description should be seen as illustrative and not limiting. While the invention is susceptible to various modifications and alternative constructions, it should be understood, that there is no intention to limit the invention to the specific form disclosed, but, on the contrary, the invention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention as defined in the claims.

[0023] In any embodiment described herein, the open-ended terms "comprising," "comprises,” and the like (which are synonymous with "including," "having” and "characterized by") may be replaced by the respective partially closed phrases "consisting essentially of," consists essentially of," and the like or the respective closed phrases "consisting of," "consists of, the like.

[0024] As used herein, the singular forms “a,” “an,” and “the” designate both the singular and the plural, unless expressly stated to designate the singular only.

[0025] The present invention relates to a custom apparel crafting device that is accessed by a user for designing and customizing garments based on personalized preferences and further provides a virtual visualization of the garment on the user’s body in real time to enable informed decision-making, along with optimizing fabric usage to reduce material wastage, thereby enhancing both customization and sustainability in garment creation.

[0026] Referring to Figure 1, an isomeric view of a custom apparel crafting device is illustrated, comprising a housing 101 having a hinged door 102, a touch interactive display panel 103 is provided within the housing 101, plurality of artificial intelligence-based imaging unit 104 installed inside the housing 101, a hologram projection unit 105 installed inside the housing 101, a shelf unit 106 installed inside the housing 101, with an extendable horizontal bar 115 and a motorized clamping unit 107, a robotic gripper 108 attached to the shelves 105, a stitching table 109 provided inside the housing 101, a motorized sewing unit 110 is installed over the table 109, a motorized slider 112 installed along edges of the table 109, plurality of robotic arms 111 installed over the slider 112 and an L-shaped telescopic link 113 installed on the table 109, holding a cutting blade 114.

[0027] The device disclosed herein comprises a housing 101 that features a hinged door 102, which allows a user to enter inside for body measurement and garment customization. Inside the housing 101, a touch-interactive display panel 103 is provided, enabling users to input their garment preferences, including type of garment, intended occasion, and budget constraints. These inputs are stored within a user profile created in an integrated database, allowing for easy reference during future garment selection.

[0028] The touch interactive display panel 103 as mentioned herein is typically an LCD (Liquid Crystal Display) screen that presents output in a visible form. The screen is equipped with touch-sensitive technology, allowing the user to interact directly with the display using their fingers. A touch controller IC (Integrated Circuit) is responsible for processing the analog signals generated when the user inputs details regarding the garment preferences, including type of garment, intended occasion, and budget constraints. A touch controller is typically connected to the microcontroller through various interfaces which may include but are not limited to PI (Serial Peripheral Interface) or I2C (Inter-Integrated Circuit).

[0029] A microcontroller is linked with the display panel 103 to process user inputs. Upon receiving user commands, the microcontroller activates a plurality of artificial intelligence-based imaging units 104 installed within the housing 101. These imaging units 104, working in coordination with ultrasonic sensors, accurately capture user body dimensions to ensure a precise fit. The artificial intelligence-based imaging unit 104 is constructed with a camera lens and a processor, wherein the camera lens is adapted to capture a series of images of the user.

[0030] The processor carries out a sequence of image processing operations including pre-processing, feature extraction, and classification by utilizing machine learning and artificial intelligence protocols. The image captured by the imaging unit 104 is real-time images of the user. The artificial intelligence based imaging unit 104 in communication with a microcontroller. The artificial intelligence based imaging unit 104 transmits the captured image signal in the form of digital bits to the microcontroller.

[0031] Similarly, the ultrasonic sensor emits high-frequency waves toward the user and measures the time it takes for the waves to bounce back after hitting the body of the user. The sensor is typically oriented in a way that it measures the body dimensions of the user. The ultrasonic sensor collects a significant amount of data by scanning the entire body of the user and forms a 3D point cloud, which represents the shape of the user. The ultrasonic sensor sends the data to the microcontroller which processes the acquired data from the ultrasonic sensor and imaging unit 104 both and detects the body dimension of the user.

[0032] Additionally, a plurality of color sensors is integrated within the housing 101. These sensors work in conjunction with the imaging units 104 to detect the skin tone of the user. The color sensor emits a light, usually a white light onto the user. The fender reflects the white light, and the color sensor captures the reflected light. The color sensor measures the intensity of the reflected light across different wavelengths to determine the skin tone of the user. By comparing the intensity values, the color sensor classifies the skin tone of the user. The microcontroller receives data from both the color sensor and processes the data to assess the skin tone of the user.

[0033] Based on these measurements and user specifications, the microcontroller displays fabric patterns, colors, and designs that complement the user's skin tone, ensuring that the garment is both aesthetically appealing and fashion-forward over the display panel 103.

[0034] A hologram projection unit 105 is installed inside the housing 101, configured to generate a virtual representation of the user wearing the selected fabric and design. The hologram updates in real-time as the user modifies the fabric, color, and design choices via the display panel 103, allowing the user to preview different clothing styles before making a final decision, which eliminates the need for physical trial fittings and enhances the garment selection experience.

[0035] The hologram projection unit 105 works by creating a three-dimensional virtual image of the user wearing the selected garment. This is achieved through a combination of 3D modeling, laser-based light diffraction, and real-time rendering. Once the user selects fabric, color, and design options through the touch-interactive display panel 103, the microcontroller applies these choices to the 3D model. The hologram projection unit 105 then uses laser projectors and beam splitters to project the 3D garment model into the air inside the housing 101. The light waves emitted by the projection unit 105 are manipulated to create a floating visual representation of the user wearing the selected garment.

[0036] As the user modifies fabric, color, or design choices via the display panel 103, the microcontroller processes these changes in real time, updating the hologram instantly, which allows the user to preview different styles without physically trying on the garment.

[0037] The device includes an organized shelf unit 106 installed inside the housing 101 for fabric storage. Each fabric is categorized by type and securely held by an extendable horizontal bar 115 and a motorized clamping unit 107, which ensures that the fabric remains in place, preventing wrinkles and damage during handling and movement within the device. The horizontal bar 115 powered by a pneumatic unit is designed to extend and retract as needed, adjusting to accommodate different fabric widths. When a fabric roll is selected for processing, the motorized clamping unit 107 activates to grip and hold the fabric firmly in place, which prevents the fabric from shifting, wrinkling, or folding during transfer, ensuring that it remains in its original condition.

[0038] A robotic gripper 108 is attached to the shelves 105 to facilitate the handling and transfer of fabric rolls. The gripper 108 picks up fabric from the shelves 105 and places it onto a stitching table 109 installed inside the housing 101. The robotic gripper 108 typically consists of two opposing arms or fingers that mimic a human hand-gripping motion. These arms are usually made of durable materials like metal or plastic to provide strength and flexibility. The robotic gripper 108 design incorporates springs to securely hold the fabric rolls and position the rolls onto the stitching table 109. Electric motors and servo motors are used to control the robotic gripper's movement. These motors provide the necessary force and precision to manipulate and position the rolls onto the stitching table 109. The motors are connected to the gripper 108 arms through an arrangement of gears and linkages, allowing for controlled positioning of the rolls onto the stitching table 109.

[0039] Above the table 109, a motorized sewing unit 110 is mounted to perform various stitching tasks based on the garment’s design. The sewing unit 110 ensures precision in every stitch, particularly when dealing with intricate sewing patterns or curved stitching, reducing the likelihood of fabric damage. In an embodiment of the present invention, the sewing unit 110 consists of a motorized needle mechanism, thread tensioning arrangement, presser foot, feed mechanism to execute precise stitching. A servo motor drives the needle mechanism, while the thread tensioning system and feed arrangement ensure smooth and consistent stitching.

[0040] A motorized slider 112 is installed along the edges of the stitching table 109, serving as a guide for a plurality of robotic arms 111 that operate in sync with the imaging units 104. These robotic arms 111 adjust the fabric alignment dynamically while the sewing unit 110 works, ensuring that the stitching follows the design specifications precisely. The motorized slider 112 consists of a linear track arrangement powered by servo motors, which allow smooth and precise movement along the edges of the table 109. The slider 112 acts as a guide rail for the robotic arms 111, enabling them to position themselves at different points on the fabric as needed. The servo motors control the speed and positioning of the slider 112, ensuring that the robotic arms 111 move accurately according to the garment’s design pattern.

DURING OPERATION, THE ROBOTIC ARMS PERFORM SEVERAL TASKS:

1. The robotic arms 111 adjust the fabric’s placement to ensure it remains in the correct position as stitching progresses. If the imaging unit 104 detects misalignment, the microcontroller commands the arms to make real-time adjustments.
2. The arms grip and stretch the fabric gently to prevent wrinkles and bunching, which ensures that stitches are placed evenly and that fabric remains taut but undamaged during sewing.
3. As the motorized sewing unit 110 stitches the fabric, the robotic arms 111 move in sync with the slider 112, repositioning the fabric as needed, which prevents fabric distortion and ensures stitch precision.
4. After stitching, the robotic arms 111 assist in guiding the fabric toward the L-shaped telescopic cutting blade 114, ensuring that excess fabric is trimmed accurately.

[0041] A L-shaped telescopic link 113 is installed on the table 109, equipped with a cutting blade 114 that trims excess fabric. The extension of the link 113 is powered by a pneumatic unit that utilizes the compressed air to extend or retract the link. The blade 114 is mounted on a motorized ball and socket joint, allowing it to rotate and cut fabric in multiple directions, which ensures clean, precise cuts with minimal fabric waste, optimizing efficiency in garment production. The motorized ball and socket joint consists of a ball-shaped element that fits into a socket, which provides rotational freedom in various directions.

[0042] The ball is connected to a motor, typically a servo-motor which provides the controlled movement. The blade 114 is attached to the socket of the motorized ball and socket joint. The motor responds by adjusting the ball and socket joint and rotates the ball in the desired direction, and this motion is transferred to the socket that holds the blade 114. As the ball and socket joint move, it provides the necessary angular movement to the blade 114 to cut fabric in multiple directions, which ensures clean, precise cuts with minimal fabric waste, optimizing efficiency in garment production.

[0043] In addition, the touch-interactive display panel 103 allows users to input information regarding their daily activity level, whether it involves frequent movement, athletic activities, or sedentary tasks. This information is processed by the microcontroller, which then adjusts the garment’s design, stitching pattern, and fabric properties accordingly.

[0044] For users with high activity levels, the microcontroller recommends stretchable, breathable fabrics that accommodate movement while ensuring comfort. The stitching patterns are adapted to reinforce durability and flexibility, ensuring that seams withstand repeated motion and stress. For example, for users engaging in low-movement activities, the microcontroller might recommend more structured or non-stretch fabrics, optimizing the garment for aesthetics and professional settings, which ensures that every garment is tailored to the user's comfort, lifestyle, and mobility needs.

[0045] If the user opts to provide their own fabric, the system is designed to assess its suitability for the selected garment design. The microcontroller calculates the required fabric dimensions based on the garment’s design specifications and compares them with the actual fabric size provided by the user. If the provided fabric is insufficient, the microcontroller notifies the user through the display panel 103, highlighting the shortage.

[0046] In such cases, the microcontroller suggests alternative garment designs that is created within the available fabric constraints. Additionally, it recommends ways to utilize excess fabric efficiently, such as by creating smaller matching accessories or additional garment elements, which ensures that users still make the best use of their materials while maintaining the desired style and design.

[0047] In cases where the provided fabric is larger than necessary, the device ensures optimal utilization of excess fabric. The microcontroller analyses the surplus material and suggests ways to repurpose it, minimizing waste. If the extra fabric is suitable for additional garments, the microcontroller suggests creating smaller clothing items such as scarves, detachable sleeves, or decorative accessories. The microcontroller also identifies areas where the remaining fabric is incorporated into the original garment, enhancing its design while reducing waste. This functionality supports sustainable fabric usage, ensuring that every material is maximized for utility rather than being discarded.

[0048] A battery is associated with the device to supply power to electrically powered components which are employed herein. The battery is comprised of a pair of electrode named as a cathode and an anode. The battery uses a chemical reaction of oxidation/reduction to do work on charge and produce a voltage between their anode and cathode and thus produces electrical energy that is used to do work in the device.

[0049] The present invention works best in the following manner, where the device begins its operation when the user enters the housing 101 and interacts with the touch interactive display panel 103 to provide garment preferences, including type of garment, intended occasion, and budget constraints. These inputs are stored in the integrated database within the microcontroller. The microcontroller, upon receiving these inputs, activates the plurality of artificial intelligence-based imaging unit 104 and ultrasonic sensors inside the housing 101 to capture the user’s body dimensions accurately. Based on the body dimensions and user preferences, the microcontroller processes the data and displays fabric options, recommended patterns, colors, and trending designs on the touch interactive display panel 103. The plurality of color sensors inside the housing 101 further enhances recommendations by analyzing the user’s skin tone, ensuring that the suggested fabric colors and designs complement the user’s appearance. To help visualize the final garment, the hologram projection unit 105 creates a virtual version of the user wearing the selected fabric and design. Any modifications made by the user in fabric, color, or design are updated in real-time within the holographic projection. Once the user finalizes the selection, the shelf unit 106 inside the housing 101 retrieves the appropriate fabric. The extendable horizontal bar 115 and motorized clamping unit 107 secure the fabric in place, preventing wrinkles and movement during handling. The robotic gripper 108 then picks up the fabric roll and transfers it to the stitching table 109, where the motorized sewing unit 110 performs the necessary stitching tasks based on the user’s design specifications.

[0050] In continuation, to ensure stitching accuracy, the motorized slider 112, installed along the edges of the stitching table 109, acts as a guide for the plurality of robotic arms 111, dynamically adjusting fabric alignment during the stitching process. These robotic arms 111 operate in sync with the imaging units 104 to position the fabric correctly while the motorized sewing unit 110 stitches the material with precision. Once the garment is stitched, an L-shaped telescopic link 113 installed on the stitching table 109 activates the cutting blade 114, mounted on a motorized ball-and-socket joint, to trim excess fabric. The cutting blade 114 is capable of adjusting its orientation and cutting in multiple directions, ensuring clean and precise trimming with minimal fabric waste. If the microcontroller detects surplus fabric, it suggests alternative uses, such as smaller garments or accessories.

[0051] Although the field of the invention has been described herein with limited reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternate embodiments of the invention, will become apparent to persons skilled in the art upon reference to the description of the invention. , Claims:1) A custom apparel crafting device, comprising:

i) a housing 101 having a hinged door 102 to enable a user to enter within said housing 101, wherein a touch interactive display panel 103 is provided within said housing 101 for enabling a user to provide garment preference, including type of garment, intended occasion, budget constraints as input into a user profile of said user, created in an integrated database for reference;
ii) a microcontroller linked with said display panel 103, upon receiving said user commands, activates plurality of artificial intelligence-based imaging unit 104 installed inside said housing 101 and paired with ultrasonic sensors provided inside said housing 101, enabling accurate measurements of user’s body dimensions, wherein said microcontroller based on user’s body dimensions and input specifications, displays fabric options, recommending fabric patterns, colors, and current fashion trends, ensuring selected garment is both flattering and trendy;
iii) a hologram projection unit 105 installed inside said housing 101, configured to create a virtual version of user wearing selected fabric and design, updating in real-time as user adjusts the fabric, color, and design choices via said display panel 103, thereby enabling said user to preview different clothing styles before making a final decision;
iv) a shelf unit 106 installed inside said housing 101 for storing various fabrics, each organized by type, and equipped with an extendable horizontal bar 115 and a motorized clamping unit 107 to secure said fabric, preventing movement and wrinkles during handling, ensuring smooth and damage-free movement;
v) a robotic gripper 108 attached to said shelves 105, for picking up fabric rolls and placing them onto a stitching table 109 provided inside said housing 101, wherein a motorized sewing unit 110 is installed over said table 109 that performs different stitching tasks, based on type of stitch required, ensuring precision in every stitch and preventing fabric damage, particularly during intricate stitching tasks or when sewing curves; and
vi) a motorized slider 112 installed along edges of said table 109 to guide plurality of robotic arms 111 installed over said slider 112, wherein said robotic arms 111 are dynamically regulated by said microcontroller in sync with said imaging unit 104 to position said fabric correctly for stitching, said arms adjust fabric alignment as sewing unit 110 works, ensuring precise stitching according to design specifications.

2) The device as claimed in claim 1, wherein plurality of color sensors are integrated inside said housing 101 that works in collaboration with said imaging units 104 to detect skin tone of said user, in accordance to which said microcontroller recommends fabric patterns, colors, and designs to complement said user’s skin tone.

3) The device as claimed in claim 1, wherein a L-shaped telescopic link 113 installed on said table 109, holding a cutting blade 114 trims excess fabric, said cutting blade 114 is mounted on a motorized ball-and-socket joint, adjusting orientation and cuts fabric in multiple directions, ensuring clean, precise, and minimal waste when trimming fabric.

4) The device as claimed in claim 1, wherein said display panel 103 allows user to input their physical activity level, which is utilized to adjust garment's design and stitching pattern, customizing garment’s fabric properties and stretchability based on user's activity level, ensuring comfort and flexibility in strenuous physical activities.

5) The device as claimed in claim 1, wherein in case said user prompts to provide fabric for the intended garment, said microcontroller calculates required fabric dimensions for design and compares with available fabric size, notifying said user if fabric is insufficient and providing suggestions for alternative garment options or using excess fabric for smaller items, such as accessories or additional clothing items.

6) The device as claimed in claim 1 and 5, wherein if fabric is determined to be too large for garment, said microcontroller assesses surplus fabric and suggests alternative uses for remaining material, including smaller garments or accessories like scarves or sleeves, optimizing fabric use and minimizing waste.

7) The device as claimed in claim 1, wherein a battery is associated with said device for powering up electrical and electronically operated components associated with said device.