Description:FIELD OF THE INVENTION

[0001] The present invention relates to a wax therapy imparting device that is capable of providing wax therapy in an automated manner to remove the need for manual labor by heating and applying the wax to the user’s skin, and further capable of detecting any discomfort through the user’s facial expressions during wax application and adjusts the temperature as needed.

BACKGROUND OF THE INVENTION

[0002] Wax therapy, particularly paraffin wax therapy, is widely used for therapeutic and cosmetic purposes due to its ability to provide deep tissue warmth and promote healing. It is commonly used to alleviate pain, improve joint mobility, and treat skin conditions like dry skin, arthritis, and muscle stiffness. The heat from the melted wax helps to improve blood circulation, reduce muscle spasms, and relax stiff joints, offering relief for individuals suffering from chronic pain or inflammation. In addition, the wax seals moisture into the skin, making it an effective treatment for dry or cracked skin, leaving it soft and hydrated. The therapy is also beneficial for individuals recovering from injuries, as it enhances flexibility and promotes tissue repair. In cosmetic treatments, it helps smooth out the appearance of the skin, making it more supple and rejuvenated. The controlled application of wax can also aid in stress relief, providing a soothing, comforting experience.

[0003] Wax therapy, often used for pain relief, muscle relaxation, and improving skin conditions, typically requires specialized equipment to ensure effectiveness and safety. The primary equipment includes a wax bath or tank, where paraffin wax is melted and kept at a safe, consistent temperature. This bath allows users to dip their hands, feet, or other body parts into the warm wax for therapeutic treatment. Other equipment includes heat mitts or booties, which help to retain the warmth of the wax on the skin for longer periods, enhancing the treatment's effectiveness. Additionally, plastic liners are used to protect the wax from contamination after it is applied. Despite its benefits, there are several drawbacks to wax therapy equipment. One major issue is the risk of burns if the wax temperature is not properly regulated, potentially causing discomfort or injury. The time-consuming nature of the treatment can also be a downside, as users may need to wait for the wax to cool or for the treatment to take effect, which may not be convenient for everyone. Moreover, maintenance of the equipment is necessary, as the wax bath requires regular cleaning to prevent contamination, and the wax itself must be replaced periodically. The equipment's bulkiness also limits portability, making it less ideal for use outside dedicated therapy settings.

[0004] CN204971793U relates to a portable wax therapy device, including wax therapy bag crust, wax therapy bag body, outer bag, internal insulation bag, paraffin, electric heating element and outer plug, the rectangular form pocket of wax therapy bag crust for being used for holding wax therapy bag body, its edge have the zip fastener that a confession was opened or seal this wax therapy bag crust, the thread gluing area has on this wax therapy bag crust, fill in wax therapy bag crust for outer bag, and be provided with the internal insulation bag in being somebody's turn to do outer bag, the internal insulation bag includes the several sack of nai high temperature insulation, two rows of symmetrical arrangements about the sack of nai high temperature insulation is, electric heating element evenly arranges in between two rows of high temperature insulation sacks, outer plug is fixed to be set up on outer bag, and it is connected with electric heating element through the electric wire. The utility model has the advantages of: this portable wax therapy device portable conveniently buckles and bindes and unpick and wash, and material utilization rate is high, heat transfer is even, has reduced the uneven problem of heating that electric heating element slided and leads to.

[0005] CN203280564U relates to a medical device for melting wax and manufacturing wax cakes, and aims at providing a medical wax-therapy device which saves time and labor of an operator, improves working efficiency and reduces working risks in the manufacturing process of the wax cakes. The medical wax-therapy device is mainly composed of a wax melting box and a wax cake manufacturing box, an electrothermal film is adhered to the periphery of the wax melting box, a thermal insulation layer is arranged between the wax melting box and the wax cake manufacturing box, the operator respectively controls temperature in the wax melting box and the wax cake manufacturing box through a temperature control instrument, solid wax in the wax melting box is cleaned, heated and melted, then a valve at the rear portion of the wax melting box is opened, liquid wax on the upper layer of the water surface can flow into a pipeline of the wax cake manufacturing box through a round hole, at the moment a flow signal of a flowmeter in the pipeline is received by the quantitative control instrument, a switch of a solenoid valve is controlled, the liquid wax is injected into a wax cake manufacturing disc in a quantitative mode, and the liquid wax is cooled to form the solid wax. Water in the wax melting box can flow out through a water outlet pipeline at the rear portion of the wax melting box, so that the water can be regularly replaced. The medical wax-therapy device utilizing the quantitative control system adopts the built-in wax liquid flowing-out pipeline, wax liquid flow is set by the quantitative control instrument, the wax liquid can automatically flow into the wax cake manufacturing disc in a quantitative mode, and manual wax taking and placing are directly replaced. The medical wax-therapy device utilizing the quantitative control system is simple and convenient to operate, the wax cakes of different sizes can be accurately manufactured, meanwhile the heating layer and the heat isolation layer can prevent the liquid wax from being consolidated in the pipeline, so that pipeline blockage is effectively avoided.

[0006] Conventionally, many devices have been developed to provide wax therapy, however these existing devices mentioned in the prior arts have limitations in regards to ensuring presence of any wounds on user’s skin and also fails in providing a means in preventing the wax from being applied to the wounds.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that requires to deliver automated wax therapy to a user, eliminating need for manual intervention by heating and applying wax directly to the skin. Additionally, the developed device needs to be capable of detecting user’s facial expressions during wax application, assessing any signs of discomfort and adjusting the wax temperature accordingly and also should further identify wounds on the user’s skin, to cover the wound such that ensures the wax is not applied to affected areas.

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 providing wax therapy to user in an automated manner in view of eliminating manual labor efforts by heating and applying wax to the user’s skin.

[0010] Another object of the present invention is to develop a device that is capable of detecting facial expression of the user when the wax is being dispensed on the user to evaluate any discomfort to the user and accordingly regulate temperature of the wax.

[0011] Yet another object of the present invention is to develop a device that is capable of covering a wound on skin of the user to prevent application of wax on the wound.

[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 a wax therapy imparting device that is capable of automating a wax therapy procedure by heating and applying wax to the user’s skin and further monitors the user’s facial expressions to gauge discomfort and adjusts the wax temperature to provide optimal comfort.

[0014] According to an embodiment of the present invention, a wax therapy imparting device, comprises of a housing having four perpendicularly installed telescopic rods with omnidirectional wheels at the ends, attached underneath the housing, for a locomotion of the housing, an ultrasonic sensor embedded in the housing detects a height of a user to trigger a microcontroller to actuate the rods to extend or retract as per the detected height, a chamber disposed within the housing to store paraffin wax, a lid is attached with the chamber by means of a drawer mechanism to enable an opening and closing of the chamber, a Peltier unit configured within the chamber to heat the wax to maintain the wax in a melted form, an articulated L-shaped telescopic link mounted on the housing, having a nozzle at an end, linked with the chamber by means of a conduit, to dispense the wax onto a body of the user.

[0015] According to another embodiment of the present invention, the proposed device comprises of a peristatic pump integrated with the conduit in synchronisation with a pressure sensor integrated with the pump, to detect pressure applied by the user pump to regulate flow through the pump, an artificial intelligence-based imaging unit, installed on the housing and integrated with a processor for recording and processing images in a vicinity of the housing to detect facial expression of user when the wax is being dispensed on the user and accordingly determine discomfort, an articulated L-shaped bar having a pliable flap at an end, attached on the housing, to spread the applied wax on skin of the user, an articulated L-shaped pole having a plate at an end, configured with a plurality of hinges, mounted on the housing, to cover a wound on skin of the user as detected by the imaging unit, to prevent application of wax on the wound, a weight sensor embedded in the chamber to detect a weight of the wax in the chamber.

[0016] According to another embodiment of the present invention, the proposed device further comprises of a speaker provided on the housing to generate an audio alert regarding refilling of the chamber if the detected weight is below a threshold weight, a holographic projection unit installed on the housing, to project an image on skin of the user, to provide a visual guidance to user regarding region of skin where wax is to be applied to enable required adjustments, an articulated L-shaped limb having a scrapping tray at an end, disposed on the housing, to scrape and remove wax from skin of the user after therapy, a touch interactive display unit mounted on the housing to enable a user to provide touch input regarding initiating and terminating wax therapy, the display unit shows parameters of the therapy including temperature of the wax, weight of wax left, and a microphone is located on the housing to enable user to provide voice input to the microcontroller to operate the device.

[0017] 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

[0018] 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 wax therapy imparting device.

DETAILED DESCRIPTION OF THE INVENTION

[0019] 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.

[0020] 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.

[0021] 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.

[0022] The present invention relates to a wax therapy imparting device that is capable of offering automated wax therapy to a user, reducing need for manual intervention by heating and applying wax to the skin. Additionally, the proposed device ensures that skin wounds are covered, preventing wax from being applied directly to them.

[0023] Referring to Figure 1, an isometric view of a wax therapy imparting device is illustrated, comprises of a housing 101 having four perpendicularly installed telescopic rods 102 with motorized omnidirectional wheels 103, a chamber 104 disposed within the housing 101, an articulated L-shaped telescopic link 105 mounted on the housing 101, having a nozzle 106 at an end, linked with the chamber 104, an artificial intelligence-based imaging unit 107 installed on the housing 101, an articulated L-shaped bar 108 having a pliable flap at an end, attached on the housing 101, an articulated L-shaped pole 109 having a plate at an end, configured with a plurality of hinges mounted on the housing 101, a speaker 110 provided on the housing 101, a holographic projection unit 111 installed on the housing 101, an articulated L-shaped limb 112 having a scrapping tray at an end, disposed on the housing 101, and a microphone 113 located on the housing 101, and a touch interactive display unit 114 installed over the housing 101.

[0024] The proposed invention includes a housing 101 preferably in portable cuboidal shape incorporating various components associated with the device, developed to be positioned on a ground surface. The housing 101 is configured in a way such that comprise plurality of omnidirectional wheels 103 positioned underneath the housing 101 for translation of the housing 101 as per requirement. The wheels 103 are connected with the housing 101 by means of telescopic rods 102 which are pneumatically powered by a pneumatic arrangement associated with the device. The pneumatic arrangement constitutes extension/retraction of the rods 102 such that elevate the height of the height as per requirement. The housing 101 is made up of any material selected from but not limited to metal or alloy that ensures rigidity of the housing 101 for longevity of the device.

[0025] A user is required to access and presses a switch button arranged on the housing 101 to activate the device for associated processes of the device. The switch button when pressed by the user, opens up an electrical circuit and allows currents to flow for powering an associated microcontroller of the device for operating of all the linked components for performing their respective functions upon actuation.

[0026] The microcontroller, mentioned herein, is preferably an Arduino microcontroller. The Arduino microcontroller used herein controls the overall functionality of the components linked to it. The Arduino microcontroller is an open-source programming platform.

[0027] After the activation of the device, an ultrasonic sensor embedded in the housing 101 detects a height of the user. The ultrasonic sensor disclosed herein, consists of an emitter and a receiver that acts as a transducer. The emitter emits ultrasonic sound waves towards user. Then, the radiation strike to the user and reflect back which are captured by the receiver. The signal is sent to the microcontroller. The microcontroller processes the received signal from the ultrasonic sensor and on the basis of time lapse in between the sent and received radiations, the microcontroller determines the height of the user.

[0028] In accordance to the height of the user, the microcontroller actuates the rods 102 via the pneumatic arrangement to extend/retract the rods 102 for adjusting the height of the housing 101 as per requirement. The microcontroller actuates an air compressor and air valve associated with the pneumatic arrangement consisting of an air cylinder, air valve and piston which works in collaboration to aid in extension and retraction of the rods 102. The air valve allows entry/exit of compressed air from the compressor. Then, the valve opens and the compressed air enters inside the cylinder thereby increasing the air pressure of the cylinder. The piston is connected to the rods 102 and due to the increase in the air pressure, the piston extends. For the retraction of the piston, air is released from the cylinder to the air compressor via the valve. Thus, providing the required extension/retraction of the rods 102 for adjusting the height of the housing 101. All the pneumatically operated components associated with the device comprises of the same type of pneumatic arrangement.

[0029] The housing 101 is arranged with a chamber 104 storing paraffin wax. The chamber 104 is integrated with a lid by means of a drawer mechanism to enable opening and closing of the chamber 104 as per requirement. After the activation of the device, the user is enabled to provide voice command via a microphone 113 mounted on the housing 101 regarding to operate the device.

[0030] The microphone 113 turns the sound energy emitted by the user into electrical energy. The sound waves created by the user carry energy towards the microphone 113. Inside the microphone 113, a diaphragm, made of plastic, is present and moves back and forth when the sound wave hits the diaphragm. The coil attached to the diaphragm also moves in same way. The magnetic field produced by the permanent magnet cuts through the coil. As the coil moves, the electric current flows. The electric current from coil flows to an amplifier which convert the sound into electrical signal. The microcontroller linked to the microphone 113 recognize the voice and perform the operations according to the command given by the user to operate the device.

[0031] The user is required to manually open the chamber 104 by applying pulling force to the lid such that the drawer mechanism opens the chamber 104. The user is required to put wax into the chamber 104 for the wax therapy. The chamber 104 is integrated with a Peltier unit to heat the wax to maintain the wax in a melted form.

[0032] The Peltier unit is based on the Peltier effect that stated that the cooling of one junction and the heating of the other when electric current is maintained in a circuit of material consisting of two dissimilar conductors. The Peltier effect related to production or absorption of heat at the junction of two metals on the passage of a current such that melts the wax of the chamber 104.

[0033] After melting of the wax, the user accesses a touch interactive display unit 114 installed over the housing 101 for providing input regarding initiating of wax therapy. When the user touches the surface of the touch interactive display unit 114 to enter the input details, then an internal circuitry of the touch interactive display unit 114 senses the touches of the displayed option and synchronically, the internal circuitry converts the physical touch into the form of electric signal. The microcontroller processes the received signal from the display unit 114 in order to process the signal and determine the user selection and store the user response to a linked database for further associated functions related to the user input.

[0034] In accordance to the user’s input, the microcontroller actuates a holographic projection unit 111 installed on the housing 101, to project an image on skin of the user. The projection unit 111, consists of a lasing medium, a stimulating energy source and an optical resonator. The lasing medium is in crystals form and the stimulating energy source is called as a ‘pump’ that supplies energy to the laser medium for amplification of the light. Furthermore, the optical resonator is a pair of mirrors facing each other and placed on either side of the pump.

[0035] On activation of the projection unit 111 by the microcontroller, the stimulating energy source supplies energy that aids in interaction of incoming photons with an excited atomic electron resulting generation of optical amplified light. Further the amplified light travels through the lasing medium and bounces back/forth between the mirrors enhancing simulated emission within the pump, eventually being emitted through the partly reflective mirror to project the laser beam via a holographic film over the user’s skin. The projection unit 111 provide a visual guidance to user regarding region of skin where wax is to be applied to enable required adjustments.

[0036] The housing 101 is configured with an articulated L-shaped telescopic link. The link 105 is powered by the pneumatic arrangement associated with the device such that provides extension/retraction of the link. The end of the link 105 is integrated with a nozzle 106 which is connected with the chamber 104 via a conduit.

[0037] A peristatic pump is integrated with the conduit which is actuated by the microcontroller to pump wax from the chamber 104 to the conduit. The peristaltic pump is integrated with the conduit, along with a pressure sensor. The peristaltic pump is designed to move wax through the conduit by compressing and releasing a tube, creating a peristaltic motion. The pressure sensor is integrated with the pump to detect the pressure applied by the pump during the wax movement. The sensor continuously monitors the pressure inside the conduit and helps regulate the flow of wax through the pump. If the pressure reaches a certain threshold, the microcontroller adjusts the flow rate accordingly to maintain the desired pressure or prevent over-pressurization. This synchronization ensures that the wax flow is controlled and consistent for wax therapy.

[0038] As per the region projected over the user’s skin, the microcontroller actuates the L-shaped telescopic link 105 via the pneumatic arrangement to position nozzle 106 in proximity to the user as per requirement for the wax therapy. The extension/retraction of the link 105 is similar to the working of the rods 102 as mentioned above. The articulated movement of the link 105 is provided by an equipped ball and socket joint enabling multi-directional movement of the link 105 as per requirement.

[0039] Post positioning of the nozzle 106, the microcontroller actuates the nozzle 106 to dispense wax onto a body of the user. The nozzle 106, used herein, controls flow of wax by varying the size of the flow passage as directed by a signal from a microcontroller. This enables the direct control of flow rate and the consequential control of process quantities such as pressure, and wax level in view of dispensing the wax as per the requirement.

[0040] While dispensing of wax, the microcontroller generates a command to activate an artificial intelligence-based imaging unit 107 integrated on the housing 101 for capturing multiple images in a vicinity of the housing 101 to detect facial expression of user when the wax is being dispensed on the user. The imaging unit 107 incorporates a processor that is encrypted with an artificial intelligence protocol. The artificial intelligence protocol operates by following a set of predefined instructions to process data and perform tasks autonomously. Initially, data is collected and input into a database, which then employs protocol to analyze and interpret the captured images. The processor of the imaging unit 107 via the artificial intelligence protocol processes the captured images and sent the signal to the microcontroller.

[0041] In accordance to the detected facial expression of the user, the microcontroller evaluates discomfort to the user from the wax. The microcontroller then regulates the Peltier unit to reduce a temperature of the wax to prevent discomfort to the user.

[0042] The housing 101 is integrated with an articulated L-shaped bar 108 attached with a pliable flap at an end. The bar 108 is powered by the pneumatic arrangement to provide extension/retraction of the bar 108 to position the flap in contact with the user’s skin. The working of the bar 108 is similar to the working of the link 105 as mentioned above. The articulated movement of the flap spreads the applied wax on skin of the user.

[0043] The housing 101 is configured with an articulated L-shaped pole 109 having a plate at an end. The plate is integrated with hinges to tilt the plate as per requirement. While applying wax over the user’s skin, the microcontroller via the imaging unit 107 detects a wound present over user’s skin. The microcontroller accordingly aactuates the pole 109 via the pneumatic arrangement to cover the wound on skin of the user such that prevent application of wax on the wound.

[0044] The user accesses the display unit 114 or the microphone 113 to provide command to terminating the wax therapy. The housing 101 is integrated with an articulated L-shaped limb 112 configured with a scrapping tray at an end. The limb 112 is powered by the pneumatic unit and works similar to the working of the link 105 as mentioned above, to scrape and remove wax from skin of the user after therapy.

[0045] During the wax therapy, the user is notified regarding the parameters of the therapy including temperature of the wax, weight of wax left, via the display unit 114. While wax is consumed in the wax therapy, a weight sensor embedded in the chamber 104 to detect a weight of the wax in the chamber 104. The weight sensor used herein is a kind of a transducer. The weight sensor depends on the conversion of a load into an electronic signal. The signal is a change in voltage or current otherwise a frequency on the basis of load and the signal is sent to the microcontroller for processing in order to monitor weight of the wax available in the chamber 104. In case the microcontroller evaluates weight of the chamber 104 recedes a predetermined threshold value, the microcontroller notifies the user regarding refilling of the chamber 104 with wax for unhindered wax therapy.

[0046] A battery (not shown in figure) is associated with the device to supply power to electrically powered components which are employed herein. The battery is comprised of a pair of electrodes named as a cathode and an anode. The battery uses a chemical reaction of oxidation/reduction to do work on charge and produce a voltage between their anode and cathode and thus produces electrical energy that is used to do work in the device.

[0047] The present invention works best in the following manner, where the housing 101 as disclosed in the invention is developed to be equipped with four telescopic rods 102 with omnidirectional wheels 103, allowing to move freely based on the user's proximity detected by the ultrasonic sensor such that triggers the extension or retraction of the rods 102 to match the user's height. Inside the housing 101, the chamber 104 stores paraffin wax, which is kept melted by the Peltier unit. The articulated L-shaped telescopic link, connected to the chamber 104 by the conduit, dispenses the wax onto the user’s skin. The peristaltic pump regulates the wax flow, aided by the pressure sensor to ensure proper dispensing. The imaging unit 107 detects the user's facial expressions to gauge comfort and adjusts the wax temperature through the Peltier unit to prevent discomfort. The pliable flap and the plate mounted on articulated bars help spread and cover the wax as needed. Additionally, weight and holographic projection sensors enhance the therapy by monitoring wax levels and guiding the user in applying wax accurately. The microphone 113 allows voice control, and the touch-enabled display unit provides real-time therapy data. Furthermore, the scraping tray removes the wax after therapy, and the speaker 110 alerts the user when wax needs to be refilled based on the chamber 104 's weight sensor.

[0048] 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 wax therapy imparting device, comprising:

i) a housing 101 having four perpendicularly installed telescopic rods 102 with omnidirectional wheels 103 at the ends, attached underneath said housing 101, for a locomotion of said housing 101;

ii) an ultrasonic sensor embedded in said housing 101 detects a height of a user to trigger a microcontroller to actuate said rods 102 to extend or retract as per said detected height;

iii) a chamber 104 disposed within said housing 101 to store paraffin wax, wherein a lid is attached with said chamber 104 by means of a drawer mechanism to enable an opening and closing of said chamber 104;

iv) a Peltier unit configured within said chamber 104 to heat said wax to maintain said wax in a melted form;

v) an articulated L-shaped telescopic link 105 mounted on said housing 101, having a nozzle 106 at an end, linked with said chamber 104 by means of a conduit, to dispense said wax onto a body of said user;

vi) a peristatic pump integrated with said conduit in synchronisation with a pressure sensor integrated with said pump, to detect pressure applied by said user pump to regulate flow through said pump;

vii) an artificial intelligence-based imaging unit 107, installed on said housing 101 and integrated with a processor for recording and processing images in a vicinity of said housing 101 to detect facial expression of user when said wax is being dispensed on said user and accordingly determine discomfort trigger a microcontroller to actuate Peltier unit to reduce a temperature of said wax to prevent discomfort to said user;

viii) an articulated L-shaped bar 108 having a pliable flap at an end, attached on said housing 101, to spread said applied wax on skin of said user; and

ix) an articulated L-shaped pole 109 having a plate at an end, configured with a plurality of hinges, mounted on said housing 101, to cover a wound on skin of said user as detected by said imaging unit 107, to prevent application of wax on said wound.

2) The device as claimed in claim 1, wherein a weight sensor embedded in said chamber 104 to detect a weight of said wax in said chamber 104 to trigger a microcontroller to actuate a speaker 110 provided on said housing 101 to generate an audio alert regarding refilling of said chamber 104 if said detected weight is below a threshold weight.

3) The device as claimed in claim 1, wherein a holographic projection unit 111 installed on said housing 101, to project an image on skin of said user, to provide a visual guidance to user regarding region of skin where wax is to be applied to enable required adjustments.

4) The device as claimed in claim 1, wherein an articulated L-shaped limb 112 having a scrapping tray at an end, disposed on said housing 101, to scrape and remove wax from skin of said user after therapy.

5) The device as claimed in claim 1, wherein a touch enabled display unit mounted on said housing 101 to enable a user to provide touch input regarding initiating and terminating wax therapy, wherein said display unit shows parameters of said therapy including temperature of said wax, weight of wax left.

6) The device as claimed in claim 1, wherein a microphone 113 is located on said housing 101 to enable user to provide voice input to said microcontroller to operate said device.