AUTOMATED JADE BRACELET REPAIRING DEVICE

Abstract

An automated jade bracelet repairing device, comprising a hollow cuboidal body 101 developed to be positioned on a ground surface, a circular plate 102 is configured within body 101 to hold a jade bracelet , an imaging unit 103 is installed on body 101 to determine dimensions of bracelet, pulley arrangement 104 integrated on plate 102 for accommodating bracelet on plate 102, a rod 106 integrated with a rotatable brush 107 to clean bracelet, a chamber 108 configured inside body 101 for storing metallic pins, a robotic gripper 109 installed within body 101 to position pin over disjoint section, a soldering unit 110 configured with body 101 via a robotic arm 111 to perform soldering to join the disjoint, a blade 112 arranged on platform by means of a bar 113 to smoothen out repair and bracelet and cleaning unit 114 installed inside body 101 for cleaning debris.

Specification

Description:FIELD OF THE INVENTION

[0001] The present invention relates to an automated jade bracelet repairing device that is capable of detecting deformities and disjoints on surface of the bracelet and accordingly perform a soldering operation over the disjoint section in order to join the disjoint portion of the bracelet in a precise and automated manner.

BACKGROUND OF THE INVENTION

[0002] The jade bracelets are popular for their beauty and symbolism in various culture. They are often believed to bring luck, protection and health to the wearer. Jade bracelet, as a kind of daily decoration ornaments, is favored by numerous women, but owing to bracelet band is on hand, that is easy to cause breakage due to various collisions in daily life.

[0003] Traditionally, the broken jade bracelet is repaired manually by using various traditional method such as using adhesive solution, threading and knotting and metal riveting. In adhesive solution method, the user align the broken pieces carefully and glued together. In threading and knotting method, the user use to thread the broken part of the bracelet to secure the piece together. While these traditional method offer some benefits but they also pose several challenges and drawbacks. Most of the traditional methods involves manual repairing of the broken bracelet which is labor intensive and time consuming. Also manual repairing is not much efficient which might result in over time, the repaired area may be susceptible to weakening or loosening which cause failed in long term durability of the bracelet and required further maintenance.

[0004] CN105690581A The invention discloses a bracelet repair method. The bracelet repair method comprises the following steps that after a hole is punched in the relative position of jade, cleaned and filled with transparent jade glue, and a jade reinforcing nail is put in for fixation; then decorative patterns are engraved in the fractured position, spun gold is filled in to further reinforce the fractured position, the bracelet surface is flattened through a utility knife; and finally a bracelet is polished, cleaned and waxed, and repair of the bracelet is completed. Due to the fact that the fractured position of the repaired bracelet is subjected to secondary reinforcing, compared with traditional repair methods, the bracelet is firmer and more attractive. Although CN'581 is capable of repairing disjoint bracelet. However, the above mentioned invention lacks in preparing deformities and disjoint portion of the bangle in a precise and automated manner.

[0005] CN219578403U The utility model discloses a bracelet easy to repair, which consists of n modularized units, wherein each modularized unit is a block body and comprises an intrados surface, an extrados surface, a front connecting surface, a rear connecting surface, a left side surface and a right side surface, the intrados surface is a wrist contact surface, n is an integer greater than 3, 360/n is a natural number, the front connecting surface of each modularized unit is connected with the rear connecting surface of an adjacent modularized unit into a whole, and the rear connecting surface of the modularized unit is connected with the front connecting surface of another adjacent modularized unit into a whole. When the bracelet is locally damaged, the damaged modularized unit is only required to be replaced, so that the repair of the bracelet can be realized, and the value of the bracelet is recovered. Although CN'581 is capable of repairing disjoint bracelet. However, the above mentioned invention lacks detecting deformities in the bangle and accordingly repair disjoint bracelet in an automated manner with negligible error.

[0006] Conventionally, many devices exist that are capable of repairing broken bracelet, however these devices failed in evaluating deformities and disjoints on surface of the bracelet and accordingly perform a soldering operation over the disjoint section in order to join the disjoint portion of the bracelet in a precise and automated manner, and also failed in cleaning the metallic material and debris in real time while smoothing the bracelet.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that is capable of detecting deformities and disjoints on surface of the various dimension bracelet and accordingly repair and smoothen disjoints portion of the bracelet as well as removing metallic material and debris in real time while smoothing the bracelet.

OBJECTS OF THE INVENTION

[0008] The principal object of the present invention is to overcome the disadvantages of the prior art.

[0009] An object of the present invention is to develop a device that is capable of detecting deformities and disjoints on surface of the bracelet and accordingly perform a soldering operation over the disjoint section in order to join the disjoint portion of the bracelet in a precise and automated manner.

[0010] Another object of the present invention is to develop a device that is capable of that grind the extruded part on the repaired portion in view of smoothing the bracelet and enhancing the aesthetic appeal of the final product.

[0011] Yet another object of the present invention is to develop a device that is capable of detecting a presence of the metallic material and debris in surrounding of the smoothen bracelet and accordingly remove the dust in real time in order to aid the processes dust free.

[0012] 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

[0013] The present invention relates to an automated jade bracelet repairing device that is capable of accommodating various dimension of bracelet and accordingly determine a deformities and disjoint on the surface of the bracelet in order to repair the disjoint portion of the bracelet in a precise and an automated manner.

[0014] According to an embodiment of the present invention, An automated jade bracelet repairing device, comprising a hollow cuboidal body developed to be positioned on a ground surface and configured with plurality of supporting legs to position the body at a height from the surface, further a circular plate is configured within the body for allowing a user to accommodate a jade bracelet over the plate, an artificial intelligence-based imaging unit is installed on the body to determine dimensions of the bracelet, based on which the microcontroller actuates an expandable pulley arrangement integrated on the plate to get expanded for properly accommodating the bracelet on the plate, multiple of motorized clippers (ranging 4-6 clippers) integrated on periphery of the plate that are actuated by the microcontroller to acquire a grip on the bracelet for securing the bracelet on the plate, thereafter an IR (infrared) sensor is configured within the body to detect deformities and disjoints on surface of the bracelet, the microcontroller actuate a telescopically operated L-shaped rod arranged on the body and integrated with a motorized rotatable brush to perform scrubbing on the ornament in order to clean the bracelet for proper view of the determined deformities/disjoint.

[0015] According to another embodiment of the present invention, the proposed device further comprises of a chamber configured inside the body and stored with multiple metallic pins, further the microcontroller actuates a robotic gripper installed within the body to grip and position the pin over the disjoint section of the bracelet, followed by actuation of a soldering unit configured with the body via a robotic arm to perform soldering operation over ends of the pins in view of joining the disjoint portion of the bracelet, a grinding blade arranged on the platform by means of a telescopically operated L-shaped bar that is actuated by the microcontroller to extend/retract for positioning the blade in proximity to repaired portion on the bracelet, followed by actuation of the blade in sync with the imaging unit for grinding extruded part on the repaired portion in order to smoothen out the repair and bracelet, a dust sensor installed inside the body for detecting the presence of small metallic particles and debris in vicinity to the body during smoothening of the repaired portion, accordance to which the microcontroller actuates a vacuum based cleaning unit installed inside the body for cleaning the metallic particles and debris that are further stored inside a receptacle integrated with the cleaning unit, and additionally, a weight sensor is embedded within the receptacle for detecting amount of metallic particles and debris stored inside the receptacle, and in case the detected weight exceeds a threshold limit, the microcontroller sends a wireless notification on a computing unit accessed by the user to notify the user regarding the detected weight.

[0016] 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

[0017] 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 isometric view of an automated jade bracelet repairing device.

DETAILED DESCRIPTION OF THE INVENTION

[0018] 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.

[0019] 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.

[0020] 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.

[0021] The present invention relates to an automated jade bracelet repairing device that is capable of repairing damage bracelet of various dimension in an automated manner. Additionally, the proposed device is capable of removing the metallic particles and debris in a real time while smoothing repaired portion.

[0022] Referring to Figure 1, an isometric view of an automated jade bracelet repairing device is illustrated, comprising a hollow cuboidal body 101 developed to be positioned on a ground surface, a circular plate 102 is configured within the body 101, an artificial intelligence-based imaging unit 103 is installed on the body 101, an expandable pulley arrangement 104 integrated on the plate 102, plurality of motorized clippers 105 integrated on periphery of the plate 102, L-shaped rod 106 arranged on the body 101, motorized rotatable brush 107 integrated with the rod 106, a chamber 108 configured inside the body 101, a robotic gripper 109 installed within the body 101, a soldering unit 110 configured with the body 101 via a robotic arm 111, a grinding blade 112 arranged on the platform by means of a telescopically operated L-shaped bar 113, cleaning unit 114 installed inside the body 101.

[0023] The proposed invention is comprises of a hollow cuboidal body 101 developed to be positioned on a ground surface and configured with multiple of supporting legs (ranging between 4-6 legs) to position the body 101 at a height from the surface. The body 101 is cast with highly durable materials and is rigid in nature with a flat cuboidal shape, offering a large space to accommodate multiple mechanical and electrical units. The body 101 is constructed from sturdy and robust materials that may include but not limited to stainless steel, aluminum. These materials offer rigidness and robustness to the platform making the body 101 resistant to mechanical stress and pressure.

[0024] Further, a circular plate 102 made of stainless steel material in positioned within the body 101 for allowing the user to accommodate a jade bracelet over the plate 102. Upon positioning the bracelet over the plate 102, an inbuilt microcontroller activate an artificial intelligence-based imaging unit 103 is installed on the body 101 to determine dimensions of the bracelet. The imaging unit 103 comprises of an image capturing arrangement including a set of lenses that captures multiple images of the bracelet and the captured images are stored within a memory of the imaging unit 103 in form of an optical data.

[0025] The imaging unit 103 also comprises of a processor that is integrated with artificial intelligence protocols, such that the processor processes the optical data and extracts the required data from the captured images. The extracted data is further converted into digital pulses and bits and are further transmitted to the microcontroller. The microcontroller processes the received data and determines the dimensions of the bracelet.

[0026] Upon determining the dimension of the bracelet, the microcontroller actuate an expandable pulley arrangement 104 integrated on the plate 102 to get expanded for properly accommodating the bracelet on the plate 102. The expandable pulley arrangement 104 typically includes a set of pulleys installed on plate 102. These pulleys are engineered with a mechanism that allows them to expand or retract as needed. The expansion and retraction action are typically actuated by an external force or mechanism. When the pulley expands, the diameter of the plate 102 increases, which enables bracelet to properly accommodated on the plate 102.

[0027] Upon properly accommodation of the bracelet over the plate 102, the microcontroller actuate multiple motorized clippers 105 (ranging 4-6 clippers 105) integrated on periphery of the plate 102 to acquire a grip on the bracelet for securing the bracelet on the plate 102. The clippers 105 are operated by a pair of handles which are alternately squeezed together and released for griping or releasing the bracelet and are driven by the motor which makes the blade 112 of clip to oscillate from side to side. Upon actuation of the motorized clippers 105 by the microcontroller, the motor rotates the blade 112 to oscillate in order to acquire the grip on the bracelet for securing the bracelet on the plate 102.

[0028] Upon acquire grip over the bracelet, the microcontroller activate an IR (infrared) sensor is configured within the body 101 to detect deformities and disjoints on surface of the bracelet. The IR (infrared) sensor consists of an IR emitter and an IR receiver. The emitter emits infrared light towards the surface of the bracelet and are bounced back from the surface and returns to the receiver. The sensor then sends an electrical signal to the microcontroller for processing and based on which the microcontroller evaluate the deformities and disjoints present on surface of the bracelet.

[0029] As per the detected deformities over the surface of the bracelet, the microcontroller actuate a telescopically operated L-shaped rod 106 arranged on the body 101 and integrated with a motorized rotatable brush 107 to perform scrubbing on the ornament. The extension of the rod 106 is powered by a pneumatic unit associated with the device and includes an air compressor, air cylinder, air valves and piston. The air compressor used herein extract the air from surrounding and increases the pressure of the air by reducing the volume of the air. The air compressor is consist of two main parts including a motor and a pump. The motor propels the compressor pump which uses the energy from the motor drive to draw in atmospheric air and compress to elevated pressure. The compressed air is then sent through a discharge tube into the cylinder across the valve. The compressed air in the cylinder tends to pushes out the piston to extend which extends the rod 106 to position the brush 107 over the bracelet.

[0030] Upon positioning the brush 107 over the bracelet, the microcontroller simultaneously actuate the motorized brush 107 to clean the bracelet. The motorized brush 107 is comprises of a tool with bristles made of synthetic fibers that are attached to a handle made of wood and powered by DC motor to rotate in clockwise/anticlockwise direction in a manner to provide movement to the brush 107 in view of cleaning the bracelet for proper view of the determined deformities/disjoint.

[0031] Upon cleaning the bracelet properly, the microcontroller actuate a robotic gripper 109 installed within the body 101 to grip the pin stored in a chamber 108 configured inside the body 101 and position over the disjoint section of the bracelet. The robotic gripper 109 includes a link connected with multiple motorized ball and socket joints and a gripper 109 for smooth and precise gripping of pin. The motorized ball and socket joint includes a motor powered by the microcontroller generating electrical current, a ball shaped element and a socket. The ball move freely within the socket. The motor rotates the ball in various directions that is controlled by the microcontroller that further commands the motor to position the ball precisely. The microcontroller further actuates the motor to generate electrical current to rotate in the joint for providing movement to the gripper 109 for gripping and positioning the pin over the disjoint section of the bracelet.

[0032] Simultaneously, the microcontroller activate an angle sensor is configured within the body 101 to detect angle of the disjoint with respect to the body 101. The angle sensor used herein is preferably an optical angle sensor that use light beams and optical detectors to measure changes in light reflection or transmission caused by the angle of the disjoint with respect to the body 101. As the angle changes, the amount of light reflected or transmitted varies, allowing the sensor to calculate the angle. The angle sensor provides an output signal to the microcontroller that represents the detected angle of the disjoint in accordance to regulate actuation of the robotic arm 111 to position the soldering unit 110 at an optimum position in proximity to the disjoint portion of bracelet.

[0033] Upon positioning the pin over the disjoint, the microcontroller actuate a robotic arm 111 integrated with a soldering unit 110 to perform soldering operation over ends of the pins. The robotic arm 111s are able to perform the designated task with high efficiency and accuracy, wherein the robotic arm 111s consists of mechanical joints and actuators, which are controlled by the microcontroller. The actuators allow various degrees of freedom and movement and the joints are actuated by a DC (Direct Current) motor, providing the necessary force and motion to position the soldering unit 110 in proximity to the ends of the pins.

[0034] Upon positioning the soldering unit 110 in proximity to end of the pin, the microcontroller actuate the soldering unit 110 to perform soldering operation over ends of the pins. The soldering unit 110 consists of a heating region and an insulated handle. On supplying electrical current to the soldering unit 110, the heating tip gets heated. Which melt down the soldering wire and put between disjoint and pin in order to connect them electrically and join the disjoint portion of the bracelet.

[0035] Upon joining the disjoint portion of the bracelet, the microcontroller actuate a telescopically operated L-shaped bar 113 arranged on the platform integrated with a grinding blade 112 to extend/retract for positioning the blade 112 in proximity to repaired portion on the bracelet. The bar 113 is operated on the same principle as that the rod 106 disclosed above, thus the bar 113 position the grinding blade 112 in proximity to repaired portion on the bracelet.

[0036] Upon positioning the blade 112 near to repaired portion on the bracelet, the microcontroller actuate the grinding blade 112 for grinding extruded part on the repaired portion. The blade 112 consists of motor connected to a set of blade 112 for cutting the extruded part on the repaired portion of the bracelet. The motor is the key component that converts electrical energy into mechanical energy to provide movement to the blade 112. Upon actuation of the blade 112 by the microcontroller, the motor starts rotating the blade 112 in a clockwise/anti-clockwise direction by imparting the rotational motion to the blade 112 thus cutting the length extruded part on the repaired portion in order to smoothen out the repair and bracelet.

[0037] During smoothening of the repaired portion, the microcontroller activate a dust sensor installed inside the body 101 for detecting the presence of small metallic particles and debris in vicinity to the body 101. The dust sensor used herein is based on an optical sensing method to detect dust. The dust sensor consists of a photo sensor and an infrared light-emitting diode (IR LED). The IR- LED emits the IR rays on the debris and the photo-sensor receive the reflected IR LED rays from the debris. The reflected rays are processed by the microcontroller to detect the presence of the dust in vicinity to the body 101.

[0038] Based on the detected dust, the microcontroller activate a vacuum based cleaning unit 114 installed inside the body 101 for cleaning the metallic particles and debris. The cleaning unit 114 works on the principle of flow of air from area of high pressure to area of low pressure. An electric motor is attached to a fan that spins the fan at high velocities. The fast-spinning fan creates a region of low pressure inside a suction hose of the cleaning unit 114. Air, along with dust is sucked into the suction hose because of the pressure difference between the exterior and the interior of the suction hose and thus storing the dust, debris etc., within a receptacle integrated with the cleaning unit 114, thereby cleaning the surrounding of the body 101 in order to maintain smoothing processes dust free.

[0039] Thereafter, a weight sensor is embedded within the receptacle for detecting amount of metallic particles and debris stored inside the receptacle. The weight sensor comprises of a convoluted diaphragm and a sensing module. Due to the weight of debris in the receptacle, the size of the diaphragm changes which is detected by the sensing module. The sensing module detects the weight of metallic particles and debris and on the basis of the changes in sizes of the diaphragm, the acquired data is forwarded to the microcontroller in the form of a signal. Upon receiving the signal, the microcontroller evaluate amount of metallic particles and debris stored inside the receptacle through the pre-fed database integrated with the microcontroller.

[0040] Upon determining the detected weight of the metallic particles and debris stored in the receptacle, the microcontroller matched the determined amount of metallic particles and debris with the pre-fed database and in case detected weight exceeds a threshold limit the microcontroller sends a wireless notification on a computing unit accessed by the user to notify the user regarding the detected weight.

[0041] The microcontroller is wirelessly linked with the computing unit via a communication module which includes, but not limited to Wi-Fi (Wireless Fidelity) module, Bluetooth module, GSM (Global System for Mobile Communication) module. The communication module employed herein acts as an intermediate between various electronic components, wherein the module is used to establish the communication between the concerned people's computing unit and the microcontroller. The customized Global System for Mobile communication (GSM) module is designed for establishing a wireless connection between computing unit and the microcontroller and allows the microcontroller to notify the user through the computing unit to dispense the metallic particle and debris at suitable site.

[0042] 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 use 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.

[0043] The proposed invention is work well in the following manner, where the hollow cuboidal body 101 as disclosed in the invention is positioned on the ground surface and configured with plurality of supporting legs to position the body 101 at the height from the surface. Further, the circular plate 102 for allowing the user to accommodate the jade bracelet over the plate 102. Then, the artificial intelligence-based imaging unit 103 determined the dimensions of the bracelet. Based on which the microcontroller actuates an expandable pulley arrangement 104 for properly accommodating the bracelet on the plate 102. Then, the multiple of motorized clippers 105 to acquire the grip on the bracelet for securing the bracelet on the plate 102. Followed by the IR (infrared) sensor is detected the deformities and disjoints on surface of the bracelet. Then, the microcontroller actuate the telescopically operated L-shaped rod 106 to perform scrubbing on the ornament in order to clean the bracelet for proper view of the determined deformities/disjoint. Thereafter, the chamber 108 configured inside the body 101 and stored with multiple metallic pins, now the microcontroller actuates the robotic gripper 109 to grip and position the pin over the disjoint section of the bracelet. Followed by actuation of the soldering unit 110 to perform soldering operation over ends of the pins in view of joining the disjoint portion of the bracelet. Additionally, the angle sensor detect the angle of the disjoint with respect to the body 101. Based on which the microcontroller regulates the actuation of the robotic arm 111 to position the soldering unit 110 at an optimum position in proximity to the disjoint portion of bracelet. Then, the microcontroller actuate the bar 113 to extend/retract for positioning the blade 112 in proximity to repaired portion on the bracelet. Upon positioning the blade 112 in proximity to repaired portion, the microcontroller actuate the blade 112 in sync with the imaging unit 103 for grinding extruded part on the repaired portion in order to smoothen out the repair and bracelet. Then, the dust sensor for detecting the presence of small metallic particles and debris in vicinity to the body 101 during smoothening of the repaired portion. Based on which the microcontroller actuates the vacuum based cleaning unit 114 for cleaning the metallic particles and debris that are further stored inside the receptacle integrated with the cleaning unit 114. Furthermore, the weight sensor for detecting amount of metallic particles and debris stored inside the receptacle. In case the detected weight exceeds the threshold limit, the microcontroller sends the wireless notification on the computing unit accessed by the user to notify the user regarding the detected weight.

[0044] 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 individuals skilled in the art upon reference to the description of the invention. , Claims:1) An automated jade bracelet repairing device, comprising:

i) a hollow cuboidal body 101 developed to be positioned on a ground surface and configured with plurality of supporting legs to position said body 101 at a height from said surface, wherein a circular plate 102 is configured within said body 101 for allowing a user to accommodate a jade bracelet over said plate 102;
ii) an artificial intelligence-based imaging unit 103 is installed on said body 101 and integrated with a processor for capturing and processing multiple images of said bracelet, respectively to determine dimensions of said bracelet, in accordance to which said microcontroller actuates an expandable pulley arrangement 104 integrated on said plate 102 to get expanded for properly accommodating said bracelet on said plate 102;
iii) plurality of motorized clippers 105 integrated on periphery of said plate 102 that are actuated by said microcontroller to acquire a grip on said bracelet for securing said bracelet on said plate 102, wherein an IR (infrared) sensor is configured within said body 101 to detect deformities and disjoints on surface of said bracelet;
iv) a telescopically operated L-shaped rod 106 arranged on said body 101 and integrated with a motorized rotatable brush 107 that is actuated by said microcontroller in sync with said imaging unit 103 to perform scrubbing on said ornament in order to clean said bracelet for proper view of said determined deformities/disjoint;
v) a chamber 108 configured inside said body 101 and stored with multiple metallic pins, wherein said microcontroller actuates a robotic gripper 109 installed within said body 101 to grip and position said pin over said disjoint section of said bracelet, followed by actuation of a soldering unit 110 configured with said body 101 via a robotic arm 111 to perform soldering operation over ends of said pins in view of joining said disjoint portion of said bracelet;
vi) a grinding blade 112 arranged on said platform by means of a telescopically operated L-shaped bar 113 that is actuated by said microcontroller to extend/retract for positioning said blade 112 in proximity to repaired portion on said bracelet, followed by actuation of said blade 112 in sync with said imaging unit 103 for grinding extruded part on said repaired portion in order to smoothen out said repair and bracelet; and
vii) a dust sensor installed inside said body 101 for detecting said presence of small metallic particles and debris in vicinity to said body 101 during smoothening of said repaired portion, wherein based on which said microcontroller actuates a vacuum based cleaning unit 114 installed inside said body 101 for cleaning said metallic particles and debris that are further stored inside a receptacle integrated with said cleaning unit 114.

2) The device as claimed in claim 1, wherein an angle sensor is configured within said body 101 to detect angle of said disjoint with respect to said body 101, in accordance to which said microcontroller regulates actuation of said robotic arm 111 to position said soldering unit 110 at an optimum position in proximity to said disjoint portion of bracelet.

3) The device as claimed in claim 1, wherein a weight sensor is embedded within said receptacle for detecting amount of metallic particles and debris stored inside said receptacle, and in case said detected weight exceeds a threshold limit, said microcontroller sends a wireless notification on a computing unit accessed by said user to notify said user regarding said detected weight.

4) The device as claimed in claim 1 and 4, wherein said microcontroller is wirelessly linked with said computing unit via a communication module which includes, but not limited to Wi-Fi (Wireless Fidelity) module, Bluetooth module, GSM (Global System for Mobile Communication) module.

5) 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.

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