Description:FIELD OF THE INVENTION

[0001] The present invention relates to a water dispensing device that is accessed by a user to obtain water with enhanced quality suited to personal health requirements, by monitoring real-time characteristics of the water and regulates its quality by automatically adjusting specific parameters to ensure safety and suitability for consumption.

BACKGROUND OF THE INVENTION

[0002] Water is a fundamental necessity for sustaining human health. However, the quality of water available for consumption varies significantly across different regions and storage systems. Poor water quality, including imbalanced pH levels, excessive turbidity, high mineral content, and presence of harmful chemical substances, may result in adverse health effects. In many cases, users rely on traditional water purifiers that provide basic filtration without actively monitoring or adjusting specific water characteristics that can directly impact health, especially for individuals with specific medical conditions or dietary restrictions.

[0003] Conventional water purification solutions generally operate on fixed filtration mechanisms without dynamic sensing or real-time intervention. These solutions do not analyze detailed water parameters such as pH, chlorine levels, or ionic concentration, which are critical for ensuring safe and suitable drinking water. As a result, users may unknowingly consume water that may not be ideal for their personal well-being or medical needs, leading to potential health complications.

[0004] US6207046B1 discloses a drinking water dispenser according to the present invention functions to supply drinking water from a detachable water container. The drinking water dispenser includes a hot water tank, a chilled water tank, a supply pipe and a sterilization system. The hot water tank heats and stores the drinking water supplied from the water container. The supply pipe connects the water container with the hot water tank and the chilled water tank. The sterilization system sterilizes the tanks and the supply pipe by circulating hot water from the hot water tank among them. The dispenser is also sterilized because of it including a special 3-way connector between the detachable container and tanks which allows connector and container to be housed in a refrigerator, thus separating critical system components from warmer outside air and thus suppressing invasion and growth of microbes.

[0005] US6138869A discloses a water dispenser comprising a plurality of water filling stations located side by side in a single sink. Each station includes an intermediate shelf. A filling station is coupled to each of the stations and selectively provides one of a plurality of predetermined water volumes with a single actuation.

[0006] Conventionally, many devices are available in the market that are capable of water purification, however these existing devices are incapable of adjusting multiple water quality factors in real-time. In addition, these existing devices also lack personalization features which considers user-specific medical details or preferences when dispensing water.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that requires to dynamically monitor and maintain water quality parameters in real time, while also enabling personalized water conditioning based on user inputs or health profiles. Furthermore, the developed device also needs to ensure safe, suitable, and user-specific hydration by managing internal water managing processes, thereby improving both health and convenience.

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 automatically monitoring and adjusting water quality parameters such as acidity, chemical presence, and clarity, ensuring the water is consistently safe for consumption.

[0010] Another object of the present invention is to develop a device that is capable of customizing the properties of water to match individual health requirements and preferences, offering a customized hydration experience.

[0011] Another object of the present invention is to develop a device that is capable of detecting and correcting imbalances in water properties in real-time, removing the need for users to test or treat water manually.

[0012] Another object of the present invention is to develop a device that provides instant feedback and notifications regarding water condition and status, enhancing the user's control and understanding of what they consume.

[0013] Yet another object of the present invention is to develop a device that responds to user commands and environmental conditions, for reducing effort and ensuring ease of use.

[0014] 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

[0015] The present invention relates to a water dispensing device that is accessed by a user to receive purified and customized water based on individual preferences and medical needs. In addition, the device determines real-time characteristics of the water and automatically performs corrective actions to maintain those characteristics within acceptable thresholds, thereby offering water that is healthy and personalized.

[0016] According to an embodiment of the present invention, a water dispensing device, comprising a cuboidal housing for storage of water, having a plurality of suction cups arranged at a rear and bottom surfaces of the housing for affixing the housing on a surface, a motorised sliding door is provided with the housing to enable access to interior of the housing, a heating coil installed in the housing for heating of the water, a temperature sensor embedded in the housing for detecting temperature of the water to provide feedback to a connected microcontroller, a multi-section chamber provided on the housing, for storing a plurality of additives to be added in the water in the housing, an iris hole provided with each section of the chamber to dispense the additives into the housing, a user interface adapted to be installed with a computing unit, to enable a user to input preferences and medical details for availing a suitable type of water, a pH sensor embedded in the housing for detecting a pH of the water, a turbidity sensor provided in the housing to detect turbidity level of the water and a conductivity sensor provided in the housing to detect presence of ions in the water exceeding a threshold ion concentration.

[0017] According to another embodiment of the present invention, the device further includes a chlorine sensor provided in the housing to detect presence of chlorine in the water exceeding a threshold chlorine concentration, a ORP (oxidation-reduction potential)sensor provided in the housing to detect reactivity of the water exceeding a threshold reactivity, a nozzle is installed with the housing for dispensing the water, a proximity sensor installed with the housing for detection of container under the nozzle, a level sensor provided in the housing for detecting a level of water in the housing, a speaker provided on the housing to generate a warning regarding low water level, an eddy current sensor embedded on the housing to detect eddy current in the housing, a display is mounted on the housing for displaying instant characteristics of the water as detected by the sensors and a microphone is provided on the housing to enable the user to input voice commands to operate the device.

[0018] 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

[0019] 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 a water dispensing device.

DETAILED DESCRIPTION OF THE INVENTION

[0020] 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.

[0021] 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.

[0022] 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.

[0023] The present invention relates to a water dispensing device that is accessed by a user to obtain water that meets desired quality standards based on the health requirements of the user. In addition, the device also continuously monitors various water quality parameters in real-time and performs corrective measures to maintain optimal water condition, thereby ensuring convenient access to health-appropriate water.

[0024] Referring to Figure 1, an isometric view of a water dispensing device is illustrated, comprising a cuboidal housing 101, plurality of suction cups 102 arranged at bottom surfaces of the housing 101, a heating coil 103 installed in the housing 101, a multi-section chamber 104 provided on the housing 101, an iris hole 105 provided with each section of the chamber 104, a motorised sliding door 106 is provided with the housing 101, a nozzle 107 is installed with the housing 101, a speaker 108 provided on the housing 101, a display 109 is mounted on the housing 101 and a microphone 110 is provided on the housing 101.

[0025] The present invention discloses a device that is configured to provide water which is not only clean but also customized and optimized for individual user needs by monitoring, analyzing, and adjusting various water quality parameters in real time. The device comprises a cuboidal housing 101 designed for the storage of water. The housing 101 is provided with a plurality of suction cups 102 attached to its rear and bottom surfaces, enabling the secure fixation of the body onto flat surfaces such as walls or countertops, thereby enhancing stability during operation.

[0026] The suction cups 102 are used to create a vacuum seal between the surface and the housing 101. When the suction cups 102 are pressed against the surface, the initial contact creates a seal between the cup 102 and the surface, this seals off the area within the suction cup. The suction cup 102 is designed to maintain a relatively airtight seal.

[0027] To facilitate maintenance and refilling tasks, the housing 101 is integrated with a motorised sliding door 106, which provides automated access to the internal components and chambers 104 of the housing 101, which ensures convenient operation while maintaining a sealed and hygienic internal environment when not in use.

[0028] The motorized sliding door 106 consists of a door 106, a motor, and a rail unit integrated with ball bearings to allow smooth linear movement. As the motor rotates the rotational motion of the motor is converted into linear motion through a pair of belts and linkages. This linear motion provides a stable track and allows the translation of the door 106 to enable the user to access the interior of the housing 101.

[0029] A heating coil 103 is installed within the housing 101 for the purpose of raising the temperature of the stored water to a desired level. This is particularly beneficial for users requiring warm water for therapeutic, hygienic, or seasonal reasons. The heating coil 103 used herein is preferably a copper coil that generates heat when an electric current passes through the coil. When an electric current runs through a copper wire the electrons come across the resistive forces of the medium’s material, releasing energy that is expended in the form of heat energy. The copper coil is properly insulated to prevent any heat loss and also direct the generated heat toward the housing 101. The heating coil 103 begins to generate heat and as the heating element warms up, the housing 101 heats the water.

[0030] The heating process is regulated by a temperature sensor embedded within the housing 101, which continuously monitors the water temperature. The temperature sensor is electronically linked to a microcontroller. The core component of the temperature sensor is the sensing element which may include but is not limited to thermistors, thermocouples, or resistance detectors. The sensing element detects temperature changes in the housing 101 by altering its electrical properties. As the temperature increases and decreases, the resistance of the sensing element changes accordingly. The microcontroller continuously monitors the data from the temperature sensor, which processes temperature data and adjusts the power supply to the heating coil 103 accordingly, ensuring the water temperature remains within a safe and predefined range.

[0031] A multi-section chamber 104 is mounted onto the housing 101 and stores various water additives, including minerals, neutralizers, coagulants, stabilizers, and other agents. Each section of the chamber 104 is designated for a specific additive. To facilitate precise and controlled dispensing, an iris hole 105 is associated with each chamber 104 section. These iris holes 105 are mechanically actuated to open and release a predetermined quantity of the corresponding additive into the water based on sensor feedback or user input. The iris holes 105 are typically composed of a series of thin, overlapping blades arranged in a circular pattern. The microcontroller sends signals to the motor of the iris holes 105 to regulate the flow of additives from the chamber 104. The motor then rotates or moves the iris blades to open the iris holes 105 to the desired position.

[0032] The device is equipped with a user interface, which is connected to a computing unit (e.g., laptop, smartphone and tablet). The user interface allows users to input preferences, health-related details, or specific water requirements. The computing unit is linked wirelessly with the microcontroller 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 user interface serves as a bridge between the user and the microcontroller, allowing for a user-friendly way to input commands regarding health-related details, or specific water requirements.

[0033] Based on this input, the microcontroller actuates the appropriate iris holes 105 to dispense relevant additives into the water. For instance, users with a calcium deficiency may choose to add calcium supplements, or those requiring low-chlorine water due to skin sensitivity may adjust settings accordingly. This ensures a personalized water output personalized to individual medical or lifestyle needs.

[0034] A pH sensor embedded in the housing 101 to detect the current acidity or alkalinity of the stored water. The pH sensor consists of a probe, usually made of glass or a special polymer, with a thin bulb at the end. This bulb contains a solution with known pH. A reference electrode is fabricated within the probe that remains at a constant pH, providing a stable reference point for comparison of pH of the water. The thin bulb contains an ion selective electrode that selectively interacts with the hydrogen ions in the water. This interaction generates a voltage proportional to the pH of the water. The generated voltage is sent to the microcontroller, which measures the pH value of the water based on the voltage received.

[0035] If the detected pH level falls outside a predetermined acceptable range, the microcontroller automatically actuates the iris hole 105 corresponding to the neutralizing additive, dispensing it into the water to restore the pH balance, which ensures the water remains non-corrosive and safe for both drinking and bodily absorption, preventing issues such as acidity, irritation, or scale buildup in appliances.

[0036] A turbidity sensor is also installed in the housing 101 for detecting the level of particulate matter or cloudiness in the water. The turbidity sensor operates using the principle of light scattering. A light source, typically an infrared LED, emits a beam through the water. Positioned at a right angle to the light path is a photodetector which measures the intensity of light scattered by the particles suspended in water. The higher the turbidity, the more light is scattered, and the greater the signal received by the photodetector. This analog signal is then converted into a digital reading, indicating the turbidity level.

[0037] When the turbidity level exceeds a defined threshold, the microcontroller activates the iris hole 105 connected to the chamber 104 containing a coagulant, which aggregates suspended particles, making them easier to filter or settle. This functionality significantly enhances water clarity and safety by reducing suspended impurities.

[0038] A conductivity sensor, installed in the housing 101 to monitor the concentration of dissolved ions in the water, particularly those contributing to water hardness. The conductivity sensor is used to determine the ionic concentration in the water, which correlates to the presence of dissolved salts and minerals. This sensor contains two or more electrodes placed a fixed distance apart within the water chamber 104. A small alternating electrical current is passed between the electrodes. The ease with which the current flows between them depends on the number of free ions in the water, higher ionic concentration means higher conductivity. The resulting current flow is measured and converted into a conductivity value.

[0039] If the ion concentration surpasses a set threshold, the microcontroller actuates the iris hole 105 linked to the section containing a deionizing agent. This agent works to soften the water by reducing its ionic content, thereby making it more suitable for consumption, especially for individuals with kidney-related or mineral-sensitive health conditions.

[0040] A chlorine sensor is provided in the housing 101 to detect excessive levels of chlorine in the water. Chlorine, while often used as a disinfectant, is harmful when present in higher-than-necessary concentrations. The chlorine sensor detects residual chlorine levels in the water, crucial for ensuring the water is safe yet non-irritating. In an embodiment of the present invention, the sensor works on an amperometric principle, where a voltage is applied across electrochemical electrodes immersed in the water. The chlorine in the water undergoes a redox reaction at the electrodes, generating a measurable electric current that is directly proportional to the chlorine concentration. The microcontroller monitors this signal and compares it to a preset threshold.

[0041] When the sensor detects chlorine levels above the permissible limit, the microcontroller activates the iris hole 105 associated with a chlorine neutralizing agent, which is dispensed into the water to mitigate the chlorine concentration. This ensures the water is safe, especially for sensitive users like children or individuals with respiratory or skin issues.

[0042] An ORP (oxidation-reduction potential) sensor is included in the housing 101 to assess the reactivity of the water, which is an indicator of its ability to either oxidize or reduce other substances. High reactivity can suggest chemical instability. The ORP sensor is utilized to evaluate the chemical reactivity of the water by measuring its oxidizing or reducing capacity. It comprises a measuring electrode (often platinum) and a reference electrode. These electrodes are placed into the water where they sense the electron exchange between the water and the sensor’s surface.

[0043] A potential difference (measured in millivolts) is generated based on the redox reactions occurring in the water. A high ORP value indicates strong oxidizing potential (higher reactivity), while a low ORP value indicates reducing conditions. Upon detecting ORP levels above the desired threshold, the microcontroller actuates the appropriate iris hole 105 to release a stabilizing agent into the water, reducing its reactivity and making it more stable and safer for consumption.

[0044] The device includes a nozzle 107 for dispensing treated water. To prevent wastage or accidental spillage, the nozzle 107 is controlled by a proximity sensor which detects the presence of a container beneath it. The proximity sensor used herein is preferably an ultrasonic proximity sensor that uses ultrasonic waves to detect the presence of the container beneath it. The ultrasonic proximity sensor typically emits ultrasonic waves towards the surroundings and when the container is placed beneath the nozzle 107, the ultrasonic waves hit the container present beneath the nozzle 107 and bounce back to the sensor’s receiver. The receiver of the ultrasonic proximity sensor is sensitive to the emitted ultrasonic waves and listens for the reflected waves. When the emitted ultrasonic waves are received by the receiver the proximity sensor sends the data to the microcontroller which processes and analyzes the acquired data for detecting the presence of the container beneath the nozzle 107.

[0045] Only upon confirming the presence of a container does the microcontroller initiate water dispensing through the nozzle 107, ensuring efficient and mess-free operation. The nozzle 107 works by utilizing electrical energy to automize the flow solution in a controlled flow pattern by converting the pressure energy of a fluid into kinetic energy, which increases the fluid's velocity. Upon actuation of nozzle 107 by the microcontroller, the pump pressurizes the water, increasing its pressure significantly. High pressure enables the solution to be sprayed out with a force for water dispensing.

[0046] A level sensor is integrated within the housing 101 to monitor the quantity of water available. The level sensor typically emits high-frequency sound waves towards the water. The level sensor measures the time taken by the sound waves to bounce back which is used to calculate the distance to the water surface thereby determining the level of water in the surroundings. The microcontroller interprets the sensor’s output converts it into meaningful information such as water level in inches. The microcontroller linked with the level sensor continuously monitors the level sensor’s output and compares the output with the pre-determined threshold value.

[0047] If the water level drops below critical threshold, the microcontroller triggers a speaker 108 built on the housing 101 to emit an audio warning, prompting the user to refill the tank. The speaker 108 is capable of producing clear and natural sound and is capable of adjusting its volume based on ambient noise levels. The speaker 108 consists of audio information, which is in the form of recorded voice, synthesized voice, or other sounds, generated or stored as digital data. This data is often in the form of an audio file. The digital audio data is sent to a digital-to-analog converter (DAC). The DAC converts the digital data into analog electrical signals. The analog signal is often weak and needs to be amplified. An amplifier boosts the strength to a level so that the speaker 108 drives it effectively.

[0048] The amplified audio signal is then sent to the speaker 108. The core of the speaker 108 is an electromagnet attached to a flexible cone. These sound waves travel through the air as pressure waves and are picked by the user’s ear to ensure continuous availability of treated water and prevents dry operation.

[0049] An eddy current sensor is provided to detect the generation of eddy currents in or around the housing 101, which may arise due to malfunctioning electronic components or magnetic interference. The eddy current sensor detects unusual electromagnetic activity or metallic interference within or around the housing 101. This sensor functions by generating a high-frequency magnetic field using an internal coil. When a conductive material including water pipes, metallic particles, or user contact moves through this field, it induces eddy currents in that material.

[0050] These eddy currents, in turn, create their own magnetic field which alters the original field produced by the sensor. The sensor detects these changes and translates them into a signal. Upon detecting abnormal current behavior, the microcontroller actuates the speaker 108 to generate an alert, warning the user to avoid contact with the housing 101 until the issue is resolved. This feature improves safety during operation and maintenance.

[0051] A display 109 is mounted on the housing 101 to provide real-time updates about the water's condition, including temperature, pH, turbidity, conductivity, and other monitored parameters, which enables users to stay informed about the quality and status of their water, enhancing trust and transparency in the device's operation. The display 109 panel as mentioned herein is typically an LCD (Liquid Crystal display 109) screen that presents output in a visible form.

[0052] To improve accessibility and convenience, the device is equipped with a microphone 110 that allows users to input voice commands. This hands-free interaction makes it easier for users to control the device, adjust settings, or request status updates, especially beneficial for elderly users or those with limited mobility. The microphone 110 plays a crucial role by converting spoken words or commands into electrical signals which are then processed and analyzed to trigger specific actions. When the user speaks or commands to operate device, their vocal cords vibrate, creating sound waves. These sound waves travel through the air as variations in air pressure. The microphone 110 mentioned herein is a transducer that converts these variations in air into electric signals. The analog electrical signal is converted into digital form which is done by an analog-to-digital converter (ADC). The digital signal is then subjected to various signal processing techniques to enhance voice quality and eliminate noise.

[0053] The present invention works best in the following manner, where the cuboidal housing 101 as disclosed in the invention is fixed onto the surface using the suction cups 102 located on its rear and bottom surfaces. To access the internal components or refill water, the motorized sliding door 106 provides convenient and controlled entry. Once the water is stored, its heated using the heating coil 103 embedded within the housing 101. The temperature sensor continuously monitors the temperature of the water and sends real-time data to the connected microcontroller, which in turn regulates the heating coil 103 to maintain the desired temperature. Meanwhile, the level sensor keeps track of the water volume and triggers the speaker 108 to alert the user when the water level drops below the predefined threshold. The multi-section chamber 104, where each section holds the specific additive. These additives are dispensed into the water through their respective iris holes 105, which open as per specific requirements. User preferences and health-related inputs are provided through the user interface connected to the computing unit, which processes the data and actuates the relevant iris holes 105 accordingly. To ensure the water meets quality standards, various sensors are employed. The pH sensor checks for acidity or alkalinity and, if needed, actuates the iris hole 105 linked to the section containing the neutralizer. The turbidity sensor assesses the clarity of the water and triggers the section containing the coagulant if turbidity exceeds the threshold. The conductivity sensor detects the concentration of dissolved ions and, upon high levels, activates the section containing the deionizing agent to soften the water. Similarly, the chlorine sensor identifies excess chlorine and actuates the section with the chlorine neutralizing agent to balance the chlorine content.

[0054] In continuation, the ORP (oxidation-reduction potential) sensor evaluates the water's reactivity and engages the section with the stabilizing agent if reactivity surpasses the safe limit. For dispensing, the device includes the nozzle 107, which releases water upon detection of the container beneath it, sensed by the proximity sensor. In addition, the eddy current sensor monitors electromagnetic disturbances and, if detected, actuates the speaker 108 to issue the safety alert. the display 109 mounted on the housing 101 showcases real-time characteristics of the water based on sensor data, while the microphone 110 allows users to interact with the device using voice commands for hands-free operation.

[0055] 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 water dispensing device, comprising:

i) a cuboidal housing 101 for storage of water, having a plurality of suction cups 102 arranged at a rear and bottom surfaces of said housing 101 for affixing said housing 101 on a surface;
ii) a heating coil 103 installed in said housing 101 for heating of said water;
iii) a multi-section chamber 104 provided on said housing 101, for storing a plurality of additives to be added in said water in said housing 101, as per requirement;
iv) an iris hole 105 provided with each section of said chamber 104 to dispense said additives into said housing 101;
v) a pH sensor embedded in said housing 101 for detecting a pH of said water, to actuate one of said iris holes 105 corresponding to said section containing a neutraliser to dispense said neutraliser into said water to maintain pH of said water within a predetermined pH range, if pH of said water is detected to be outside an acceptable pH range;
vi) a turbidity sensor provided in said housing 101 to detect turbidity level of said water to actuate one of said iris holes 105 corresponding to said section containing a coagulant to dispense said coagulant into said water to reduce turbidity of said water if said detected turbidity level exceeds a threshold turbidity level;
vii) a conductivity sensor provided in said housing 101 to detect presence of ions in said water exceeding a threshold ion concentration to actuate one of said iris holes 105 corresponding said section containing a deionizing agent, to soften said water;
viii) a chlorine sensor provided in said housing 101 to detect presence of chlorine in said water exceeding a threshold chlorine concentration to actuate one of said iris holes 105 corresponding said section containing a chlorine neutralising agent, to neutralise chlorine in said water;
ix) a ORP (oxidation-reduction potential) sensor provided in said housing 101 to detect reactivity of said water exceeding a threshold reactivity to actuate one of said iris holes 105 corresponding said section containing a stabilising agent, to reduce reactivity of said water; and
x) a user interface adapted to be installed with a computing unit, to enable a user to input preferences and medical details for availing a suitable type of water, to actuate said iris holes 105 to dispense said additives to dispense said additives into said housing 101, to meet requirements of said user.

2) The device as claimed in claim 1, wherein a motorised sliding door 106 is provided with said housing 101 to enable access to interior of said housing 101.

3) The device as claimed in claim 1, wherein a temperature sensor embedded in said housing 101 for detecting temperature of said water to provide feedback to a connected microcontroller to enable said microcontroller to regulate said coil.

4) The device as claimed in claim 1, wherein a nozzle 107 is installed with said housing 101 for dispensing said water, upon detection of container under said nozzle 107 by a proximity sensor installed with said housing 101.

5) The device as claimed in claim 1, wherein a level sensor provided in said housing 101 for detecting a level of water in said housing 101, wherein upon detecting said water level to be below a threshold water level to actuate a speaker 108 provided on said housing 101 to generate a warning regarding low water level.

6) The device as claimed in claim 1, wherein an eddy current sensor embedded on said housing 101 to detect eddy current in said housing 101 to actuate said speaker 108 to generate an alert regarding preventing contact with said housing 101.

7) The device as claimed in claim 1, wherein a display 109 is mounted on said housing 101 for displaying 109 instant characteristics of said water as detected by said sensors.

8) The device as claimed in claim 1, wherein a microphone 110 is provided on said housing 101 to enable said user to input voice commands to operate said device.