Description:FIELD OF THE INVENTION

[0001] The present invention relates to an automated topical serums production device that is designed for the production of serums and topical creams by efficient processing and conversion of natural ingredients, such as flowers, into high-quality formulations with specific properties.

BACKGROUND OF THE INVENTION

[0002] Making serums has always been important in the beauty and healthcare industry, as these helps in treating skin and other health issues. Traditionally, making serums involved mixing ingredients like active compounds, water, and preservatives by hand, using basic tools like containers, mixers, and heat. This process, however, often led to inconsistency in the final product. The process was also slow and depended heavily on the person doing the work, which made quite easy to make mistakes. Additionally, it was difficult to produce large quantities of serum without affecting the quality, leading to challenges in ensuring each batch was the same.

[0003] Conventionally, serums were often produced in small batches in laboratories or local facilities. The methods used were simple and focused on blending active compounds like vitamins, proteins, or plant extracts with a liquid base, often water or oils. The ingredients were combined manually with basic stirring tools, followed by heating to ensure proper mixing and solubility. This was done in glass containers, which had to be sterilized carefully to prevent contamination. The manual nature of the process often led to inconsistencies in the quality of the serum, as the mixing times, temperatures, and ingredient quantities were not controlled precisely. Also, as demand grew, scaling up production was challenging without sacrificing the quality or consistency of the serum, making quite difficult to meet large-scale needs in the market.

[0004] EP3175920A1 discloses about an invention that includes a method for obtaining a serum comprising IL-1Ra from a blood sample. In the method a blood sample is added to a sealed tube with a round-bottom and configured for receiving a blood sample. The tube further comprises a sealing cap provided with a valve and a sealing membrane. Furthermore, the tube comprises a plurality of glass beads having a polished surface. After the blood sample has been added, the blood sample is agitated to induce the production of IL-1Ra. Thereafter, the serum comprising IL-1Ra is separated from the blood sample.

[0005] KR101162097B1 discloses about an invention that includes a serum preparation method and a serum preparation device capable of obtaining a large amount of serum at a time that can exhibit a high culture efficiency irrespective of the blood line used. In a serum preparation method for preparing serum from blood containing at least platelets, a platelet treatment step of treating a cell membrane of platelets in blood is provided. After the platelet treatment step, it is preferable to provide a precipitation step of depositing dimeric proteins in the blood and a removal step of removing the dimeric proteins deposited by the precipitation step.

[0006] Conventionally, many devices and methods have been introduced that are capable of performing topical serums. However, these devices are incapable of facilitating the efficient extraction and formulation of serums/creams as these devices are mostly dependent on manual processing of the formulations which increases the chances of errors in mixing of solutions. Additionally, these existing devices also fail to process ingredients in optimal quantities and ratios for producing high-quality products.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that facilitate the efficient extraction and formulation of serums and creams without requiring manual intervention, thereby ensuring consistency and accuracy. In addition, the developed device also ensure that ingredients are processed in optimal quantities and ratios for producing high-quality products tailored to varying skin types and conditions.

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 facilitate the efficient extraction and formulation of serums and creams without requiring manual intervention, thereby ensuring consistency and accuracy.

[0010] Another object of the present invention is to develop a device that ensure that ingredients are processed in optimal quantities and ratios for producing high-quality products tailored to varying skin types and conditions.

[0011] Yet another object of the present invention is to develop a device that provide controlled and hygienic environments for processing, cleaning, and handling ingredients to prevent contamination and maintain product integrity.

[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 topical serums production device that is capable of efficiently extracting and formulating serums and creams without the need for manual intervention, thereby ensuring consistent and accurate results throughout the process.

[0014] According to an embodiment of the present invention, an automated topical serums production device comprises of, a housing positioned on a fixed surface, installed with a first chamber that is accessed by a user for accommodating rhododendron arboretum flower inside the first chamber, an electronic spout is attached with a box stored with water and configured inside the first chamber, for continuously dispensing the water over the flower to clean the flower, the waste water tickles down via a sieve integrated on bottom of the first chamber, and gets collected inside a tray positioned beneath the first chamber, a touch interactive display panel is mounted on outer surface of the housing, enabling the user to provide input commands regarding production of serum gel, an artificial intelligence-based imaging unit installed inside the housing, to detect signs of chemical treatment or abnormal flower growths within the rhododendron arboretum, a V-shaped clamp mounted on a motorized ball-and-socket joint, for controlled placement and dropping of flower parts into a multi-sectioned mixing chamber installed inside the housing, each section designated for mixing different parts of the flower to create a serum with varied properties for different skin conditions, a motorized air blower is integrated inside each section of the multi-sectioned mixing chamber to dry the flower, and a motorized grinding unit housed inside the mixing sections, for ensuring thorough compression and transformation of flower into a finely mixed substance suitable for serum production.

[0015] According to another embodiment of the present invention, the proposed device further comprises of, a telescopic rod with a hinge joint is attached with each of the mixing section, that tilts and extends to move flower material into a conical-shaped extraction chamber installed inside the housing, an electronic nozzle with a collapsible pipe connected to a methanol and distilled water storage vessels, which dispense these liquids in predefined amounts into the extraction chamber, a first motorized stirrer unit is attached to the extraction chamber, which is responsible for blending materials to facilitate extraction of compounds from flower material and the blended material is transferred inside a second chamber installed underside the extraction chamber, a multi-sectioned compartment installed inside the second chamber, production of a topical cream or serum is performed in two phases: an oil phase and a water phase, in water phase, water-soluble ingredients such as glycerine and extracts are dispensed and heated to a predefined temperature, and in oil phase, oils such as cocoa butter and coconut oil are melted and mixed, a motorized pore is provided with the compartments to dispense cocoa butter, coconut oil, acacia, glycerin, SLS, and water inside the second chamber, a third chamber with a second motorized stirrer unit is provided inside the housing for production of a serum gel, in which ingredients such as carbopol, xanthan gum, propylparaben, glycerine, and distilled water are mixed, the ingredients are stored in inside a compartment segregated into plurality of slots, each slot installed with a motorized iris unit for precise dispensing of ingredients.

[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 a perspective view of an automated topical serums production 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 topical serums production device that is designed to simplify the extraction and formulation of serums and creams, in view of eliminating the need for manual intervention and ensuring consistent and accurate results. Additionally, the device ensures that ingredients are processed in precise quantities and ratios, thereby resulting in high-quality products suitable for various skin types and conditions.

[0022] Referring to Figure 1, a perspective view of an automated topical serums production device, is illustrated, respectively, comprising a housing 101 positioned on a fixed surface, installed with a first chamber 102, a touch interactive display panel 103 is mounted on outer surface of the housing 101, an artificial intelligence-based imaging unit 104 installed inside the housing 101, a V-shaped clamp 105 mounted inside the housing 101, a multi-sectioned mixing chamber 106 installed inside the housing 101, a motorized grinding unit 107 housed inside the mixing sections, a telescopic rod 108 with a hinge joint 109 is attached with each of the mixing section, a conical-shaped extraction chamber 110 installed inside the housing 101, an electronic nozzle 111 connected to water storage vessels 112, a first motorized stirrer unit 113 is attached to the extraction chamber 110, a second chamber 114 installed underside the extraction chamber 110, a multi-sectioned compartment 115 installed inside the second chamber 114, a third chamber 116 with a second motorized stirrer unit 117 is provided inside the housing 101, a compartment 118 segregated into plurality of slots, an electronic spout 119 is attached with a box 120 and configured inside the first chamber 102, a sieve 121 integrated on bottom of the first chamber 102, a tray 122 positioned beneath the first chamber 102, a motorized air blower 123 is integrated inside each section of the multi-sectioned mixing chamber 106.

[0023] The device disclosed herein comprises a housing 101 structured to be positioned on a fixed surface, wherein the housing 101 is designed to support and house the operational components of the device. Within this housing 101, a first chamber 102 is provided, which is specifically configured to accommodate the insertion of rhododendron arboretum flowers by the user. This first chamber 102 is accessible to the user for the purpose of placing the rhododendron arboretum flowers inside, thereby ensuring ease of access for the operator.

[0024] The chamber is designed to safely contain and store the flowers, providing an appropriate environment for subsequent processes or treatments as required. The design ensures that the flowers are securely housed and accessible for the user to interact with, offering both functionality and ease of use within the context of the device's operation.

[0025] An electronic spout 119 is integrally attached to a box 120 containing water, which is positioned within the first chamber 102. This electronic spout 119 is configured to dispense water continuously over the rhododendron arboretum flower housed inside the first chamber 102. The dispensing operation is controlled and activated by a microcontroller, thereby ensuring precise regulation of the water flow. The water is dispensed over the flower for the purpose of cleaning of the flower, thereby facilitating the removal of dirt, dust, or other contaminants from the flower’s surface. This ensures that the cleaning process is efficient, consistent, and controlled, in view of maintaining the quality of the flower during its preparation for further treatment or processing.

[0026] Upon activation by the microcontroller, the spout 119 opens to allow a controlled flow of water to be dispensed over the rhododendron arboretum flower. The water flows through the spout 119, continuously washing the flower's surface to remove dirt and debris. The microcontroller regulates the duration and flow rate of water dispensation, ensuring the cleaning process is consistent and efficient. Once the set time or quantity of water has been dispensed, the spout 119 closes automatically, ceasing water flow until further activation.

[0027] The waste water, after being dispensed over the flower, trickles down through a sieve 121 that is integrated into the bottom of the first chamber 102. The sieve 121 serves to filter any solid particles or debris that may have been dislodged from the flower during the cleaning process. The filtered waste water then flows through the sieve 121 and is collected in a tray 122 positioned beneath the first chamber 102. This tray 122 acts as a reservoir for the wastewater, preventing any overflow and ensuring proper drainage. The collected water in the tray 122 is disposed of or processed further as needed.

[0028] On outer surface of the housing 101 a touch interactive display panel 103 is installed which facilitates a user in providing touch input command regarding production of serum gel. 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 production of serum gel. A touch controller is typically connected to the microcontroller through various interfaces which may include but are not limited to SPI (Serial Peripheral Interface) or I2C (Inter-Integrated Circuit).

[0029] The microcontroller analyzes the command of the user and accordingly actuates an artificial intelligence-based imaging unit 104 which is installed inside the housing 101. The imaging unit 104 disclosed herein comprises of an image capturing arrangement including a set of lenses that captures multiple images of the surroundings and the captured images are stored within memory of the imaging unit 104 in form of an optical data. The imaging unit 104 also comprises of the processor which processes the captured images.

[0030] This pre-processing involves tasks such as noise reduction, image stabilization, or color correction. The processed data is fed into AI protocols for analysis which utilizes machine learning techniques, such as deep learning neural networks, to extract meaningful information from the visual data which are processed by the microcontroller to detect signs of chemical treatment or abnormal flower growths within the rhododendron arboretum.

[0031] The housing 101 is installed with a V-shaped clamp 105, wherein the clamp 105 is installed by means of a motorized ball-and-socket joint. The motorized ball and socket joint mentioned here consists of a ball-shaped element that fits into a socket, which provides rotational freedom in various directions. The ball is connected to a motor, typically a servo motor which provides the controlled movement. The V-shaped clamp 105 is attached to the socket of the motorized ball and socket joint, the microcontroller sends precise instructions to the motor 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 V-shaped clamp 105. As the ball and socket joint move, it provides the necessary movement to the V-shaped clamp 105 in order to aid the clamp 105 in performing desired operation.

[0032] The V-shaped clamp 105 used herein has an open side and a curved side, forming a partial circle or a half-moon shape. At the open side of the V-shaped clamp 105, there is a screw mechanism which includes a threaded screw or spindle and an electric motor. As the motor rotates it causes the screw to move in or out, which in turn adjusts the width of the clamp 105 opening and eventually applies the required force to place and drop flower parts into a multi-sectioned mixing chamber 106 that is installed inside the housing 101.

[0033] The multi-sectioned mixing chamber 106, designed to facilitate the mixing of different parts of the flower to create a serum with specific properties for treating various skin conditions. Each section of the chamber is designated for processing a distinct part of the flower, such as petals, stems, or other botanical components. This separation allows for precise control over the extraction and blending process, ensuring each part of the flower contributes its unique compounds. The result is a serum that combines the beneficial properties of different flower parts, optimized for addressing specific skin concerns.

[0034] Inside each section of the multi-sectioned mixing chamber 106 a motorized air blower 123 is integrated which is synchronously actuated by the microcontroller. The air blower 123 consists of a motor-driven fan or impeller that generates a high-velocity stream of air. The air blower 123 is typically designed to be compact and energy efficient. The air blower 123 is strategically positioned within the multi-sectioned mixing chamber 106, to effectively dry out the flower.

[0035] The air blower 123 is positioned so that its airflow is directed toward the flower and this is achieved by adjusting the louvers or ducts to focus the airflow. The microcontroller controls the speed and intensity of the air blower 123 and modulates the airflow based on the factors like number of flowers, and their moisture level. The microcontroller monitors the drying process and once the flower are dry, the microcontroller automatically turns off the air blower 123 to conserve energy.

[0036] A motorized grinding unit 107 is housed inside each section of the mixing chamber 106, with each unit being regulated by the microcontroller to ensure thorough compression and transformation of the flower into a finely mixed substance. The motorized grinding unit 107 are designed to efficiently break down the flower's components, such as petals, stems, and other botanical materials, into a uniform consistency. This process facilitates the extraction of essential compounds from the flower, ensuring that the resulting mixture is suitable for serum production. The microcontroller coordinates the operation of each grinding unit 107 to achieve optimal texture and consistency for effective serum formulation.

[0037] The motorized grinding unit 107 operates by rotating a set of grinding elements, such as blades or rollers, which exert pressure on the flower components. The rotation is powered by a motor controlled by the microcontroller, ensuring consistent speed and force. As the flower is fed into the grinding chamber, the grinding elements compress and break down the material into smaller particles. The finely ground substance is then collected in the mixing chamber 106.

[0038] A telescopic rod 108 with a hinge joint 109 is fixed to each mixing section within the housing 101, with one end attached to the chamber wall and the other connected to the extraction chamber 110. Based on user inputs specifying the type of serum gel to be produced, the microcontroller regulates the movement of the rod 108. The microcontroller controls the motorized actuation of the rod 108, causing it to extend and tilt via the hinge joint 109, directing the processed flower material into the conical-shaped extraction chamber 110.

[0039] The rod 108 is pneumatically actuated, wherein the pneumatic arrangement of the rod 108 comprises of a cylinder incorporated with an air piston and the air compressor, wherein the compressor controls discharging of compressed air into the cylinder via air valves which further leads to the extension/retraction of the piston. The piston is attached to the telescopic rod 108, wherein the extension/retraction of the piston corresponds to the extension/retraction of the rod 108. The actuated compressor allows extension of the rod 108 to move flower material into the conical-shaped extraction chamber 110.

[0040] Simultaneously, the hinge joint 109 mentioned above is preferably a motorized hinge joint 109 that involves the use of an electric motor to control the movement of the hinge and the connected component. The hinge joint 109 provides the pivot point around which the movement occurs. The motor is the core component responsible for generating the rotational motion. It converts the electrical energy into mechanical energy, producing the necessary torque that drives the hinge joint 109. As the motor rotates, the motorized hinge joint 109 tilts aid the rod 108 in performing transferring flower material into the conical-shaped extraction chamber 110.

[0041] An electronic nozzle 111, coupled with a collapsible pipe, is linked to the methanol and distilled water storage vessels 112. The nozzle 111 is controlled by the microcontroller, which regulates the dispensing of these liquids into the extraction chamber 110 in predefined amounts. Upon activation, the nozzle 111 releases a controlled stream of methanol and distilled water into the chamber, ensuring accurate proportions for the extraction process. The collapsible pipe adjusts in length as required, allowing flexibility for dispensing the liquids precisely into the chamber. This process aids in the extraction of essential compounds from the flower material, forming the base for the serum production.

[0042] Upon activation, the microcontroller opens the nozzle 111, allowing a predefined amount of methanol and distilled water to flow through the collapsible pipe into the extraction chamber 110. The nozzle 111 dispenses the liquids in a controlled manner, ensuring precise quantities are injected into the chamber based on the specifications. As the liquids are dispensed, the collapsible pipe adjusts its length, maintaining optimal flow and positioning to effectively introduce the liquids into the chamber for the extraction process, facilitating serum production.

[0043] A first motorized stirrer unit 113, positioned within the extraction chamber 110, is activated by the microcontroller to rotate and blend the flower material with the liquids inside the chamber. This blending action aids in the efficient extraction of essential compounds from the flower material. Upon activation by the microcontroller, the motorized stirrer 113 rotates at a pre-set speed. The stirring blades attached to the motorized unit move through the flower material and liquids, ensuring thorough mixing and facilitating the extraction of active compounds from the flower. The motion of the stirrer creates a consistent blend of flower material and liquid, helping to break down the plant cells and release essential compounds.

[0044] Once the blending process is complete, the blended mixture is transferred through a controlled mechanism into a second chamber 114 located directly underneath the extraction chamber 110. This transfer ensures that the extracted compounds are collected and prepared for further processing, maintaining a smooth and continuous flow for serum production.

[0045] Inside the second chamber 114 a multi-sectioned compartment 115 is arranged, wherein the compartments 115 are integrated with a motorized pore. Prior actuation of the pore, the microcontroller evaluates the command of the user regarding the type of serum is to be produce. If the user provides command regarding production of topical serum in an oil phase. In the oil phase, oils like cocoa butter, coconut oil, or other emollients are melted and mixed. These oils are heated to a specific temperature to facilitate smooth blending, ensuring that these integrate well with other ingredients and form a consistent, homogenous mixture.

[0046] In the event the user provides command regarding production of topical serum in a water phase. Then in this phase, water-soluble ingredients, such as glycerine, plant extracts, or humectants, are dispensed into a designated container. The mixture is then heated to a precise, predefined temperature to ensure proper dissolution and activation of these ingredients. The temperature is carefully regulated to avoid denaturing the extracts or reducing their effectiveness.

[0047] A third chamber 116 with a second motorized stirrer unit 117 is provided inside the housing 101 for the production of a serum gel. In this chamber, various ingredients such as carbopol, xanthan gum, propylparaben, glycerine, and distilled water are added. The second motorized stirrer unit 117 works in the similar manner as of first motorized stirrer unit 113, and is controlled by the microcontroller, to blend these ingredients thoroughly, ensuring that the carbopol and xanthan gum are properly hydrated and dispersed to form a smooth gel consistency. The stirring process is carefully regulated to ensure proper mixing and uniformity of the serum gel, creating a stable, high-quality gel suitable for further processing or application.

[0048] The ingredients required for the serum gel production are stored inside a compartment 118 that is segregated into a plurality of slots. Each slot is equipped with a motorized iris unit, which is responsible for precisely dispensing the ingredients in controlled amounts. The motorized iris units are actuated by the microcontroller based on the formulation requirements. The actuation of each iris unit ensures the accurate release of specific ingredients, preventing over-dispensing or under-dispensing. This controlled dispensing mechanism guarantees that the correct proportions of each ingredient are used, which is critical for maintaining the quality and consistency of the serum gel.

[0049] Moreover, a battery is associated with the device for powering up electrical and electronically operated components associated with the device and supplying a voltage to the components. The battery used herein is preferably a Lithium-ion battery which is a rechargeable unit that demands power supply after getting drained. The battery stores the electric current derived from an external source in the form of chemical energy, which when required by the electronic component of the device, derives the required power from the battery for proper functioning of the device.

[0050] The present invention works in the best manner, where the housing 101 positioned on the fixed surface installed with the first chamber 102 that is accessed by the user for accommodating rhododendron arboretum flower inside the first chamber 102. Then the electronic spout 119 is attached with the box 120 stored with water and configured inside the first chamber 102 for continuously dispensing the water over the flower to clean the flower. Now the waste water tickles down via the sieve 121 integrated on bottom of the first chamber 102, and gets collected inside the tray 122 positioned beneath the first chamber 102. Thereafter the touch interactive display panel 103 enables the user to provide input commands regarding production of serum gel. Synchronously, the artificial intelligence-based imaging unit 104 detect signs of chemical treatment or abnormal flower growths within the rhododendron arboretum. Now the V-shaped clamp 105 mounted on the motorized ball-and-socket joint, for controlled placement and dropping of flower parts into the multi-sectioned mixing chamber 106. Each section designated for mixing different parts of the flower to create the serum with varied properties for different skin conditions. Then the motorized air blower 123 to dry the flower. Then the motorized grinding unit 107 housed inside the mixing sections, each regulated by the microcontroller ensuring thorough compression and transformation of flower into the finely mixed substance suitable for serum production. Afterwards the telescopic rod 108 with the hinge joint 109 to tilts and extends to move flower material into the conical-shaped extraction chamber 110 installed inside the housing 101.

[0051] In continuation, then the electronic nozzle 111 with the collapsible pipe connected to the methanol and distilled water storage vessels 112, to dispense these liquids in predefined amounts into the extraction chamber 110. Thereafter the first motorized stirrer unit 113 is responsible for blending materials to facilitate extraction of compounds from flower material and the blended material is transferred inside the second chamber 114 installed underside the extraction chamber 110. Now the multi-sectioned compartment 115 installed inside the second chamber 114. Where the production of the topical cream or serum is performed in two phases: the oil phase and the water phase, in water phase, water-soluble ingredients such as glycerine and extracts are dispensed and heated to the predefined temperature, and in oil phase, oils such as cocoa butter and coconut oil are melted and mixed. Further the motorized pore is provided with the compartment 118 that is dynamically regulated by the microcontroller to dispense cocoa butter, coconut oil, acacia, glycerin, SLS, and water inside the second chamber 114. Simultaneously the materials are heated to the predefined temperature before mixing for production of topical cream or serum. Then the third chamber 116 with the second motorized stirrer unit 117 is provided inside the housing 101 for production of the serum gel, in which ingredients such as carbopol, xanthan gum, propylparaben, glycerine, and distilled water are mixed. Moreover, the ingredients are stored in inside the compartment 118 segregated into plurality of slots, each slot installed with the motorized iris unit for precise dispensing of ingredients.

[0052] 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. , C , C , Claims:1) An automated topical serum production device, comprising:

i) a housing 101 positioned on a fixed surface, installed with a first chamber 102 that is accessed by a user for accommodating rhododendron arboretum flower inside said first chamber 102, wherein a touch interactive display panel 103 is mounted on outer surface of said housing 101, enabling said user to provide input commands regarding production of serum gel;

ii) a microcontroller linked with said display panel 103 upon receiving said user’s commands activates an artificial intelligence-based imaging unit 104 installed inside said housing 101, and paired with a processor for capturing and processing multiple images of surroundings, respectively, to detect signs of chemical treatment or abnormal flower growths within said rhododendron arboretum;

iii) a V-shaped clamp 105 mounted on a motorized ball-and-socket joint, that is actuated by said microcontroller for controlled placement and dropping of flower parts into a multi-sectioned mixing chamber 106 installed inside said housing 101, each section designated for mixing different parts of said flower to create a serum with varied properties for different skin conditions;

iv) a motorized grinding unit 107 housed inside said mixing sections, each regulated by said microcontroller ensuring thorough compression and transformation of flower into a finely mixed substance suitable for serum production, wherein a telescopic rod 108 with a hinge joint 109 is attached with each of said mixing section, and based on user-specified type of serum gel said microcontroller regulates actuation of said rod 108 and hinge that tilts and extends to move flower material into a conical-shaped extraction chamber 110 installed inside said housing 101;

v) an electronic nozzle 111 with a collapsible pipe connected to a methanol and distilled water storage vessels 112, which dispense these liquids in predefined amounts into said extraction chamber 110, wherein a first motorized stirrer unit 113 is attached to said extraction chamber 110, which is responsible for blending materials to facilitate extraction of compounds from flower material and said blended material is transferred inside a second chamber 114 installed underside said extraction chamber 110;

vi) a multi-sectioned compartment 115 installed inside said second chamber 114, and a motorized pore is provided with said compartments 115 that is dynamically regulated by said microcontroller to dispense cocoa butter, coconut oil, acacia, glycerin, SLS, and water inside said second chamber 114, and said materials are heated to a predefined temperature before mixing for production of topical cream or serum; and

vii) a third chamber 116 with a second motorized stirrer unit 117 is provided inside said housing 101 for production of a serum gel, in which ingredients such as carbopol, xanthan gum, propylparaben, glycerine, and distilled water are mixed, wherein said ingredients are stored in inside a compartment 118 segregated into plurality of slots, each slots installed with a motorized iris unit for precise dispensing of ingredients.

2) The device as claimed in claim 1, wherein an electronic spout 119 is attached with a box 120 stored with water and configured inside said first chamber 102, that is activated by said microcontroller for continuously dispensing said water over said flower to clean said flower, and said waste water tickles down via a sieve 121 integrated on bottom of said first chamber 102, and gets collected inside a tray 122 positioned beneath said first chamber 102.

3) The device as claimed in claim 1, wherein a motorized air blower 123 is integrated inside each section of said multi-sectioned mixing chamber 106 that is actuated by said microcontroller to dry said flower.

4) The device as claimed in claim 1, wherein production of a topical cream or serum is performed in two phases: an oil phase and a water phase, in water phase, water-soluble ingredients such as glycerine and extracts are dispensed and heated to a predefined temperature, and in oil phase, oils such as cocoa butter and coconut oil are melted and mixed.