Description:FIELD OF THE DISCLOSURE
[001] The present disclosure relates to an industrial training system for industrial safety training designed to enhance safety training for users in various industrial environments. The system provides interactive training modules that simulate real-world scenarios, allowing users to practice safety measures and develop essential skills.
BACKGROUND OF THE DISCLOSURE
[002] In today’s industrial world, mechanically operated equipment plays a crucial role in enhancing productivity and efficiency. These machines are designed to automate tasks that would otherwise require significant manual labour. By doing so, they not only save time but also reduce the risk of human error, leading to more consistent and reliable results. Industries such as manufacturing, construction, and agriculture rely heavily on this type of equipment.
[003] In industrial settings, workers frequently encounter a range of challenges while handling various types of machinery and materials. Specifically, operations done on machines including mechanical calendar rollers, hydraulic presses, and the management of greasy, sharp, and thermally heated machines etc. present significant safety and efficiency concerns. Traditional methods of addressing these issues often fall short, necessitating the development of innovative solutions to enhance worker safety and operational efficacy. Workers operating mechanical calendar rollers face risks associated with entanglement, pinch points, and equipment malfunctions. The rotating rollers can cause serious injuries if proper safeguards are not in place, particularly during setup and maintenance. The operation of hydraulic presses requires precision and strength, exposing workers to potential accidents from improper handling. Sudden equipment failures can lead to severe injuries, and the risk of material ejection during pressing operations poses additional hazards. The handling of greasy components complicates operations, leading to slip hazards that can result in falls or equipment mishandling. Industries that deal with sharp materials must ensure stringent safety protocols. Cuts and puncture wounds are common injuries, and existing protective gear does not always provide adequate coverage or comfort, leading to compliance issues among workers. Workers handling thermally heated objects face burn risks and potential heat stress. Traditional heat protection equipment can be bulky and restrict movement, making it difficult to perform tasks efficiently and safely.
[004] Industrial safety is paramount in preventing accidents and ensuring the well-being of workers. Existing training methods often lack in preventing the workers from simulates hazardous situations.
[005] Historically, industries have relied on standard personal protective equipment (PPE), verbal training programs, and manual handling techniques to mitigate these risks. While PPE such as gloves, safety glasses, and aprons offers some level of protection, these solutions can be inadequate against the specific hazards presented by the machinery and materials. Verbal training programs have focused on educating workers about the risks; however, the dynamic nature of industrial operations means that workers often face unpredictable challenges that are not fully addressed in training sessions. In traditional methods, there are some devices which also provides practical training to the users. However, these devices and systems do not focus on the safety of the users that leads in causing serious injuries to the users.
[006] Accordingly, there exists a need to overcome shortcomings of the existing industrial training system for industrial safety training. For example, there exists a need of an industrial training system which provides training to one or multiple users regarding safety precautions that are required to be taken in industries while working on heavy machineries. Further, there is need of such industrial training system which ensures safety of the worker while the worker perform training.
SUMMARY OF THE DISCLOSURE
[007] In view of the foregoing disadvantages inherent in the prior art, the general purpose of the present disclosure is to provide an industrial training system for industrial safety training to include all advantages of the prior art, and to overcome the drawbacks inherent in the prior art.
[008] Therefore, an object of the present disclosure is to develop a system to train the user(s) regarding the necessary precautionary measures required in an industry to ensure safety of the user.
[009] Another objective of the present disclosure is to develop a system which is designed to adapt to various training modes based on user needs, promoting comprehensive learning in handling hazardous situations.
[0010] Yet another object of the present disclosure is to develop a system which cuts off the machineries upon matching of the applied pressure and temperature with a threshold value to ensure prevention of the user from safety hazards.
[0011] Yet another object of the present disclosure is to develop a system which enhances safety and effectiveness during industrial safety training.
[0012] Yet another object of the present disclosure is to develop a system which aims to create immersive training experiences that simulate real-world hazards, enabling users to develop critical skills and awareness while ensuring their safety through automated monitoring and responsive interventions.
[0013] In light of the above objects, in one aspect, a system is provided for industrial safety training. In one embodiment, the system includes a training structure arrangement having a plurality of training units.
[0014] In one embodiment, each of the plurality of training units is coupled to a circuitry arrangement. The circuitry arrangement collects one or more data related to a user’s activity while performing training on the respective training unit.
[0015] In one embodiment, the plurality of training units is coupled to a training module by means of the circuitry arrangement. The training module is adapted to select at least one mode for training on a respective training unit of the plurality of training units. The training module receives the one or more data from the circuitry arrangement to analyses one or more data of the user’s activity received from the training module to provide one or more instruction or guidance to be followed by the user for achieving the training.
[0016] In one embodiment, the training module evaluates a threshold value for one or more parameters related to the respective training unit. The training module cuts off the respective training unit upon matching one or more parameters with the threshold value to ensure the safety of the user while performing training.
[0017] In one embodiment, one of the plurality of training units includes a first training unit that includes a pair of rollers which rotate in opposite directions with respect to each other. The pair of rollers includes a first roller and a second roller. The first roller is coupled to the training structure arrangement by means of a hydraulic rod which provides back and forth movement to the first roller. The second roller is coupled to the training structure arrangement by means of a fixing member to provide rotation along a longitudinal axis.
[0018] In one embodiment, the training module activates the hydraulic rod for positioning the first roller in proximity to the user’s hands to create an adjustable gap therebetween in order to apply appropriate pressure over the user’s hands. The training module activates the pair of rollers to rotate in an opposite direction to pull up the user’s hands up to a pre-fed length and upon matching the pulled length with the pre-fed length, the training module cuts off the pair of rollers to ensure the safety of the user while performing training.
[0019] In one embodiment, the plurality of training units includes a second training unit having a hydraulic press that provides back-and-forth movement to pressing plates of the extending/retracting hydraulic press for applying an appropriate pressure over the user’s hand.
[0020] In one embodiment, the plurality of training units includes a third training unit having a heating coil that allows the user to position the user’s hand over the heating coil to feel the heat experience. The training module cuts off the heating coil upon detection of the temperature of the heating coil is equal to the threshold value to ensure the safety of the user while performing training.
[0021] In one embodiment, the training structure arrangement includes a plurality of experiencing units having a first experiencing unit which allows the user to pick the slippery objects to provide training to the user to train for handling of the slippery objects. The first experiencing unit has a rope attached to each of the slippery objects as a result of which the user experiences a sudden force while picking the slippery objects to ensure proper training in handling the slippery objects.
[0022] In one embodiment, the plurality of experiencing units includes a second experiencing unit that stores multiple sharp objects of different shapes which are held by the users for experiencing handling of the sharp objects. The training structure arrangement includes a glove container that stores a plurality of gloves worn by the user upon the requirement for allowing the user to perform experience training with gloves to understand the importance of wearing the particular gloves while performing training over the respective experiencing unit.
[0023] This together with the other aspects of the present disclosure, along with the various features of novelty that characterize the present disclosure, is pointed out with particularity in the claims annexed hereto and forms a part of the present disclosure. For a better understanding of the present disclosure, its operating advantages, and the specified object attained by its uses, reference should be made to the accompanying drawings and descriptive matter in which there are illustrated exemplary embodiments of the present disclosure.
BRIEF DESCRIPTION OF THE DRAWINGS
[0024] The advantages and features of the present disclosure will become better understood with reference to the following detailed description taken in conjunction with the accompanying drawings, in which:
[0025] FIG. 1 illustrates a perspective view of an industrial training system for industrial safety training, in accordance with an exemplary embodiment of the present disclosure;
[0026] FIG. 2 illustrates a line diagram of the industrial training system for industrial safety training, in accordance with an exemplary embodiment of the present disclosure;
[0027] FIG. 3 illustrates an elaborated view of a first experiencing unit of the plurality of experiencing units, in accordance with an exemplary embodiment of the present disclosure; and
[0028] FIG. 4 illustrates an elaborated view of a second experiencing unit of the plurality of experiencing units, in accordance with an exemplary embodiment of the present disclosure.
[0029] Like reference numerals refer to like parts throughout the description of several views of the drawing.
DETAILED DESCRIPTION OF THE DISCLOSURE
[0030] The exemplary embodiments described herein detail for illustrative purposes are subject to many variations in implementation. The present disclosure provides an apparatus for arresting free fall of a worker from the roof top of the building. It should be emphasized, however, that the present disclosure is not limited to an apparatus for arresting free fall of a worker from the roof top of the building. It is understood that various omissions and substitutions of equivalents are contemplated as circumstances suggest or render expedient, but these are intended to cover the application or implementation without departing from the spirit or scope of the present disclosure.
[0031] The terms “a” and “an” herein do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced items.
[0032] The terms “having”, “comprising”, “including”, and variations thereof signify the presence of a component.
[0033] Referring to Figs 1&2, a perspective view of an industrial training system (100) for industrial safety training is illustrated, comprising a training structure arrangement (102), a plurality of training units (104), a circuitry arrangement (106) having a speaker (106a), a microphone (106b), a camera (106c), a plurality of pressure sensor (106d), a plurality of proximity sensor (106e), a plurality of temperature sensor (106f) and a plurality of Light Detection and Ranging (LiDAR) sensor (106g), a training module (108), a first training unit (110), a pair of rollers (112), a first roller (114), a hydraulic rod (116), a second roller (118), a fixing member (120), a second training unit (122), a hydraulic press (124), a pressing plate (126), a third training unit (128), a heating coil (130), a plurality of experiencing units (132), a first experiencing unit (134) having a plurality of slippery objects (134a) coupled with a rope (134b), a second experiencing unit (136) having multiple sharp objects (136a) and a glove container (138), .
[0034] The present disclosure provides an industrial training system (100) for industrial safety training. industrial training system (100) for industrial safety training is provided. The system includes the training structure arrangement (102). The training structure arrangement (102) is developed to be positioned on a fixed surface that includes but is not limited to a ground surface. The training structure arrangement (102) is constructed with a durable material that includes but is not limited to mild steel and aluminium which provides longevity to the training structure arrangement (102). The training structure arrangement (102) includes the plurality of training units (104). The plurality of training units (104) herein are adapted for providing training to the users.
[0035] Further, each of the plurality of training units (104) is coupled with the circuitry arrangement (106) as shown in FIG. 2. The circuitry arrangement (106) includes one or more sensors that include but are not limited to a proximity sensor (106e) and a Light Detection and Ranging (LiDAR) sensor (106g). The circuitry arrangement (106) collects one or more data related to a user’s activity while performing training on the respective training unit.
[0036] More specifically, the plurality of training units (104) is coupled with the training module (108) by means of the circuitry arrangement (106). The training module (108) allows the user to provide input regarding the selection of at least one mode of training on a respective training unit (104) of the plurality of training units (104) by one or more means that include but are not limited to by manually typing on a screen of the training module (108) or by voice commands. The training module (108) includes but is not limited to a processor, control unit, display screen and a keyboard or key switch etc. At least one mode includes a specific training mode, complete training mode or selective training mode that is selected by the user as per requirement.
[0037] In one embodiment, the user may provide input regarding selection of one of the mode of the at least one mode by providing voice commands via the microphone (106b) coupled with the circuitry arrangement (106).
[0038] Initially, the proximity sensor (106e) is activated by the circuitry arrangement (106) for emitting an infrared ray via a transmitter, within the surrounding of the training structure arrangement (102). When the user comes in proximity to the training structure arrangement (102) and in range of the emitted infrared ray, the infrared ray hits the user’s body and bounces back towards a receiver associated with the proximity sensor (106e). After receiving the bounced rays by the receiver, the proximity sensor (106e) analyses the received data and accordingly generates a collective digital signal. The collective signal is then transmitted to the circuitry arrangement (106) by the proximity sensor (106e). Further, the circuitry arrangement (106) processes the received data and accordingly detects the presence of the user in proximity to the training structure arrangement (102).
[0039] Further, the Light Detection and Ranging (LiDAR) sensor (106g) gets activated by the circuitry arrangement (106) for detecting the distance of the user from the training structure arrangement (102). The Light Detection and Ranging (LiDAR) sensor (106g) emits laser pulses at a high rate, sometimes a million per second in nearby surroundings. The laser pulses hit the user’s body and bounce back to the Light Detection and Ranging (LiDAR) sensor (106g). Then the sensor measures how long this takes for the laser pulses to reflect back from the user’s body. The Light Detection and Ranging (LiDAR) sensor (106g) uses the time that the laser pulses took to return for calculating the distance between the training structure arrangement (102) and the user. This is also known as the Time of Flight (ToF) method. The Light Detection and Ranging (LiDAR) sensor (106g) creates a point cloud by combining all the data from the laser pulses. The point cloud represents the shape and position of the user in 3-D (Three-dimensional) space. The Light Detection and Ranging (LiDAR) sensor (106g) then transmits the data to the circuitry arrangement (106). Further, the circuitry arrangement (106) processes the data received from the proximity sensor (106e) and Light Detection and Ranging (LiDAR) sensor (106g).
[0040] Further, the circuitry arrangement (106) sends one or more processed data to the training module. The training module (108) then analyses one or more data of the user’s activity to provide one or more instructions or guidance to be followed by the user for achieving the training.
[0041] In an embodiment, based on the data received from the circuitry arrangement (106), the training module (108) evaluates a threshold value for one or more parameters related to the respective training unit.
[0042] In an embodiment, one of the plurality of training units (104) includes the first training unit (110). The first training unit (110) is dedicated to providing training to the user for providing a catching experience to the user. In case the user desires to feel a catching experience, then the user is required to provide input regarding training on the first training unit (110). After providing input, the user is required to put the user’s hand thereof in between the pair of rollers (112) to feel a catch-up experience.
[0043] After receiving input from the user, the training module (108) processes the data and accordingly actuates the pair of rollers (112) that are configured within the first training unit (110). The pair of rollers (112) comprises the first (114) and the second roller (118). The first roller (114) of the pair of rollers (112) is coupled to the training structure arrangement (102) by means of the hydraulic rod (116). The hydraulic rod (116) is adapted to extend/retract in a back-and-forth motion to provide a back-and-forth movement to the first roller (114). The hydraulic rod (116) operates within a hydraulic system to convert fluid pressure into mechanical force, utilizing the principles of hydraulics based on Pascal's principle. The core components include a hydraulic cylinder, a piston, and a rod that extends from the piston. When hydraulic fluid, typically oil, is pumped into the cylinder, it generates pressure against the piston, causing the rod to either extend or retract in a back-and-forth direction, based on the direction of fluid flow. This movement is precisely controlled through valves that regulate the fluid's entry and exit, allowing for the smooth and accurate motion of the hydraulic rod (116), thereby providing back-and-forth movement to the first roller (114).
[0044] The hydraulic rod (116) provides movement to the first roller (114) in order to position the first roller (114) in proximity to the second roller (118) of the pair of rollers (112). The second roller (118) of the pair of rollers (112) is coupled to the training structure arrangement (102) by means of the fixing member (120). During movement of the hydraulic rod (116), the circuitry arrangement (106) activates the proximity sensor (106e), for detecting successful positioning of the first roller (114) in proximity to the second roller (118).
[0045] Further, based on successful positioning of the first roller (114) in proximity to the second roller (118), the training module (108) generates a command for the circuitry arrangement (106) to activate the proximity sensor (106e) for detecting the positioning of the user’s hand in between the rollers. After detecting the positioning of the user’s hand, the proximity sensor (106e) sends the detected data to the circuitry arrangement (106) which further sends the data to the training module.
[0046] As per the data received from the circuitry arrangement (106) and upon detection of the user’s hand positioning in between the pair of rollers (112), the training module (108) activates the hydraulic rod (116) for positioning the first roller (114) in proximity to the user’s hands to create an adjustable gap therebetween in order to apply appropriate pressure over the user’s hand.
[0047] Moreover, upon successful positioning of the first roller (114) with the second roller (118), the training module (108) generates a command for the activation of the pair of rollers (112) to rotate in an opposite direction to pull the user’s hand in between the first roller (114) and second roller (118) upto a pre-fed length. Herein, the second roller (118) provides rotation along a longitudinal axis.
[0048] While pulling of the user’s hands by the pair of rollers (112), the circuitry arrangement (106) activates the Light Detection and Ranging (LiDAR) sensor (106g) for continuously monitoring the length upto which the user’s hand gets pulled by the pair of rollers (112). Further, upon matching of the pulled length with the pre-fed length, the training module (108) cuts off the pair of rollers (112) to ensure the safety of the user while performing training.
[0049] In one embodiment, the camera (106c) is activated by the training module (108) via the circuitry arrangement (106) for continuously monitoring the training process of the user as well as maintaining a visual record of the training process of the user over a specific training unit (104).
[0050] In an exemplary embodiment, a pressure sensor is coupled with the circuitry arrangement (106) for detecting pressure applied by the pair of rollers (112) on the user’s hand. Upon detecting the applied pressure, the pressure sensor (106d) send the detected pressure to the circuitry arrangement (106). Then the circuitry arrangement (106) compares the detected pressure with a pre-saved threshold value. In case the detected pressure matches with the pre-saved threshold value, then the training module (108) cuts off the pair of rollers (112) in order to ensure the safety of the user while performing training.
[0051] In one embodiment, the plurality of training units (104) includes the second training unit (122). The second training unit (122) has the hydraulic press (124) that is coupled to the training structure arrangement (102). The hydraulic press (124) is coupled with a ceiling portion of the training structure arrangement (102). In case the user desires to experience a crushing experience, then the user is required to provide input regarding the selection of the particular mode from at least one mode via the circuitry arrangement (106).
[0052] Based on the user-entered input, the training module (108) guides the user to put the user’s hand underneath the hydraulic press (124) and simultaneously activates the hydraulic press (124) for extending/retracting in order to provide a back-and-forth movement to the pressing plate (126) of the hydraulic press (124).
[0053] Further, the circuitry arrangement (106) activates the proximity sensor (106e) for detecting successful positioning of the user’s hand underneath the hydraulic press (124). Upon successful detection of the user’s hand positioning underneath the hydraulic press (124) by means of the data received from the circuitry arrangement (106), the training module (108) activates the hydraulic press (124) for providing the back-and-forth movement to the pressing plate (126) in order to position the pressing plate (126) in proximity to the user’s hand for applying an appropriate pressure over the user’s hand.
[0054] In one embodiment, a pressure sensor (106d) is coupled with the second training unit (122) for monitoring pressure applied over the user’s hand by the hydraulic press (124). Upon detection of the pressure applied by the hydraulic press (124) is equal to the threshold value as per the data received from the circuitry arrangement (106), the hydraulic press (124) is cut off by the training module (108) to ensure safety of the user while performing training.
[0055] In one embodiment, the speaker (106a) is activated by the training module (108) via the circuitry arrangement (106) for providing vocal instructions to the user during the training process as means of guiding the user throughout the training process, thereby eliminating any chances of occurrence of mistakes during the training process.
[0056] Furthermore, the plurality of training units (104) includes the third training unit (128). The third training unit (128) herein includes the heating coil (130) that is adapted for allowing the user to position the user’s hand over the heating coil (130). The training module (108) conveys the information to the user via the circuitry arrangement (106). Further, the training module (108) directs the circuitry arrangement (106) for activating the proximity sensor (106e) as a means of detecting the proper placement of the user’s hand over the heating coil (130). Upon detection of the user’s hand positioning via the data received from the circuitry arrangement (106), the training module (108) activates the heating coil (130) to provide an experience of heat to the user.
[0057] In one embodiment, the temperature sensor (106f) is coupled with the circuitry arrangement (106) for detecting the temperature of the heating coil (130). Upon detection of the temperature of the heating coil (130) is equal to the threshold value as per the data received from the circuitry arrangement (106), the training module (108) cuts off the heating coil (130) to ensure the safety of the user while performing training.
[0058] Further, the training structure arrangement (102) includes the plurality of experiencing units (132). The plurality of experiencing units (132) includes the first experiencing unit (134) and the second experiencing unit (136). The first experiencing unit (134) is stored with slippery objects (134a) that allow the user to pick the slippery objects (134a) to provide training to the user to train for handling of the slippery objects (134a) as shown in FIG. 3. Herein, each of the slippery objects (134a) is coupled within the first experiencing unit (134) by means of a rope (134b). Initially, the user is required to pick the slippery objects (134a) with their hands without wearing gloves to experience difficulty regarding picking of the slippery objects (134a) as the objects (134a) get slipped away from the user’s hand. When the user picks the slippery objects (134a), the user experiences a sudden force while picking the slippery objects (134a) to ensure proper training in handling of the slippery objects (134a).
[0059] Moreover, the training structure arrangement (102) includes a glove container (138) that is stored with a plurality of gloves. Once the user completes the handling of the slippery objects (134a) without wearing gloves, then the user is required to wear a specific type of gloves upon the requirement to perform experience training with gloves to understand the importance of wearing the particular gloves while performing training over the respective experiencing unit.
[0060] Further, the user is required to pick the slippery objects (134a) by wearing gloves to experience an easiness in handling the slippery objects (134a) as the gloves provide an appropriate friction that helps in easy handling of the slippery objects (134a).
[0061] In addition, the plurality of experiencing units (132) includes the second experiencing unit (136). The second experiencing unit (136) is stored with multiple sharp projects of different shapes. To experience the difficulty level, the user is required to initially pick the sharp objects (136a) without wearing gloves to feel the difficulty and chances of cuts while handling the sharp objects (136a) as shown in FIG. 4. Further, the user is required to pick the sharp objects (136a) by wearing gloves to ensure safety and easiness while handling the sharp objects (136a).
[0062] In an exemplary embodiment, the user selects a specific training mode from at least one mode of training by providing input via the circuitry arrangement (106) for experiencing a specific training of a particular training unit (104) or experiencing unit. Further, the user selects a complete training mode from at least one mode of training by providing input via the circuitry arrangement (106) for experiencing complete training from the plurality of training units (104) or experiencing units to learn safety measures required while working on different types of machinery. Furthermore, the user selects a selective training mode from at least one mode of training by providing input via the circuitry arrangement (106) for experiencing selective training from some of the specific plurality of training units (104) or experiencing units to learn safety measures required while working on different types of machinery as per user’s requirement.
[0063] The present disclosure is advantageous to provide training to the user regarding required safety measures that are required to be taken while working on heavy machinery. Further, the present disclosure provides safety to the user while the user is performing training over the plurality of training units (104) or experiencing units.
[0064] The present disclosure should not be construed to be limited to the configuration of the apparatus and system as described herein only. Various configurations of the apparatus and system are possible which shall also lie within the scope of the present disclosure.
[0065] The foregoing descriptions of specific embodiments of the present disclosure have been presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the present disclosure to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the present disclosure and its practical application, and to thereby enable others skilled in the art to best utilize the present disclosure and various embodiments with various modifications as are suited to the particular use contemplated. It is understood that various omissions and substitutions of equivalents are contemplated as circumstances suggest or render expedient, but such omissions and substitutions are intended to cover the application or implementation without departing from the spirit or scope of the present disclosure.

LIST OF REFERRAL NUMBERS:
100 : Industrial training system
102 : Training structure arrangement
104 : Training units
106 : Circuitry arrangement
106a : Speaker
106b : Microphone
106c : Camera
106d : Pressure sensor
106e : Proximity sensor
106f : Temperature sensor
106g : Light detection and ranging (LiDAR) sensor
108 : Training module
110 : First training unit
112 : Pair of rollers
114 : First roller
116 : Hydraulic rod
118 : Second roller
120 : Fixing member
122 : Second training unit
124 : Hydraulic press
126 : Pressing plates
128 : Third training unit
130 : Heating coil
132 : Experiencing units
134 : First experiencing unit
134a : Slippery objects
134b : Rope
136 : Second experiencing unit
136a : Sharp objects
138 : Glove container
, Claims:I CLAIM:

1. An industrial training system (100) for industrial safety training, the industrial training system (100), comprising:
a training structure arrangement (102) having a plurality of training units (104);
a circuitry arrangement (106) coupled to each of the plurality of training units (104) to collect one or more data related to a user’s activity while performing training on the respective training unit (104); and
a training module (108) coupled to the plurality of training units (104), via the circuitry arrangement (106), to select at least one mode for training on a respective training unit (104) of the plurality of training units (104), wherein the training module (108) receives the one or more data from the circuitry arrangement (106) to analyses the one or more data of the user’s activity received from the training module (108) to provide one or more instruction or guidance to be followed by the user for achieving the training.
2. The industrial training system (100) as claimed in claim 1, wherein the training module (108), based on the data received from the circuitry arrangement (106), evaluates a threshold value for one or more parameters related to the respective training unit (104), and wherein the training module (108) cuts off the respective training unit (104) upon matching of the one or more parameters with the threshold value, to ensure safety of the user while performing training.
3. The industrial training system (100) as claimed in claim 2, wherein one of the plurality of training units (104) comprises a first training unit (110), wherein the first training unit (110) comprises a pair of rollers (112) adapted to rotate in opposite direction with respect to each other, wherein the user puts hand thereof in between the pair of rollers (112) to feel a caught up experience.
4. The industrial training system (100) as claimed in claim 3, wherein:
a first roller (114) of the pair of rollers (112) is coupled to the training structure arrangement (102) via extending/retracting a hydraulic rod (116) to provide back and forth movement to the first roller (114);
a second roller (118) of the pair of rollers (112) is coupled to the training structure arrangement (102) via a fixing member (120) to provide rotation along a longitudinal axis thereof;
the training module (108), upon successful detection of the user’s hand positioning in between the pair of rollers (112) via the data received from the circuitry arrangement (106), activates the hydraulic rod (116) for positioning the first roller (114) in proximity to the user’s hands to create an adjustable gap therebetween to apply appropriate pressure over the user’s hand; and
the training module (108), upon successful positioning of the first roller (114) with the second roller (118) activates the pair of rollers (112) to rotate in an opposite direction to pull up the user’s hands upto a pre-fed length and upon pulling of the user’s hands to the pre-fed length and detection of the pressure applied by the pair of the rollers (112) is equal to the threshold value as per the data received from the circuitry arrangement (106), the pair of rollers (112) is cut off by the training module (108) to ensure safety of the user while performing training.
5. The industrial training system (100) as claimed in claim 2, wherein:
the plurality of training units (104) comprises a second training unit (122), wherein the second training unit (122) comprises extending/retracting of a hydraulic press (124) coupled to the training structure arrangement (102) to provide back-and-forth movement to a pressing plate (126) of the extending/retracting hydraulic press (124);
the user is required to put the user’s hand underneath the hydraulic press (124) and upon successful detection of the user’s hand positioning underneath the hydraulic press (124) via the data received from the circuitry arrangement (106), the training module (108) activates the hydraulic press (124) for providing movement to the pressing plate (126) for applying an appropriate pressure over the user’s hand, via the training module (108) and upon detection of the pressure applied by the hydraulic press (124) is equal to the threshold value as per the data received from the circuitry arrangement (106); and
the hydraulic press (124) is cut off by the training module (108) to ensure safety of the user while performing training.
6. The industrial training system (100) as claimed in claim 2, wherein the plurality of training units (104) comprises a third training unit (128), wherein the third training unit (128) comprises a heating coil (130) to allow the user to position the user’s hand over the heating coil (130) and upon successful detection of the user’s hand positioning via the data received from the circuitry arrangement (106), the training module (108) activate the heating coil (130) to provide an experience of heat to the user.
7. The industrial training system (100) as claimed in claim 6, wherein the heating coil (130) is cut off by the training module (108) upon detection of the temperature of the heating coil (130) is equal to the threshold value as per the data received from the circuitry arrangement (106) to ensure safety of the user while performing training.
8. The industrial training system (100) as claimed in claim 1, wherein training structure arrangement (102) comprises a plurality of experiencing units (132) including a first experiencing unit (134), wherein the first experiencing unit (134) allows the user to pick the slippery objects (134a) positioned within the first experiencing unit (134) to provide training to user to train for handling of the slippery objects (134a).
9. The industrial training system (100) as claimed in claim 8, wherein each of the slippery objects (134a) is attached within the first experiencing unit (134) via a rope (134b), wherein the user experience a sudden force while picking the slippery objects (134a) to ensure a proper training of handling of the slippery objects (134a).
10. The industrial training system (100) as claimed in claim 8, wherein the plurality of experiencing units (132) includes a second experiencing unit (136) that stores multiple sharp objects (136a) of different shapes that are held by the user(s) for experiencing handling of the sharp objects (136a).
11. The industrial training system (100) as claimed in claim 1, wherein the at least one mode includes a specific training mode, complete training mode or selective training mode that is selected by the user as per requirement.
12. The industrial training system (100) as claimed in claim 1, wherein the training structure arrangement (102) comprises a glove container (138) to store a plurality of gloves worn by the user upon requirement for allowing the user to perform experience training with gloves to demonstrate importance of wearing the particular gloves while performing training over respective experiencing unit (132).