Description:FORM 2
THE PATENTS ACT, 1970
(39 of 1970)
&
THE PATENTS RULES, 2003
COMPLETE SPECIFICATION
(See section 10 and rule 13)
TITLE OF THE INVENTION
An automated system and a method thereof for energy monitoring, management, and control system of air conditioner (“AC”) at ATM centre
APPLICANT
LIGHTFORCE BUILDINT PVT LTD
Unit no 30, Madhubhan Industrial Estate, Mahakali Caves Road, Andheri East, Mumbai – 400093, Maharashtra, India

PREAMBLE TO THE DESCRIPTION
The following specification particularly describes the invention and the manner in which it is to be performed.

FIELD OF INVENTION
[0001] The present invention generally relates to the Internet of Things (IoT) and specifically relates to a system and method using the system thereof for energy management in an ATM centre. More specifically, the invention relates a system and a method thereof for measuring energy consumption, controlling the energy consumption by regulating a plurality of electrical and electronic assets of the ATM centre, and energy management of the ATM centre by remote access and control.
BACKGROUND OF THE INVENTION
[0002] ATM machine include several heat generating electronic components. These components need to ventilate or cooled to increase their life span. Thus, the air conditioners need to be switched on 24x7 to make sure the temperature inside the ATM centre is maintained. Infact not just the air conditions, but also the lights and various electrical components have to be continuously kept on. This means that the energy consumption of an ATM centre would be high. The following invention relates to a system and a method thereof that may be connected to a conventional AC wiring and utilised in a retrospective manner for monitoring, controlling and management of energy consumption in an ATM centre.

OBJECTIVES OF THE INVENTION
[0003] It is a primary object of the present invention to provide an energy monitoring system by a measuring and tracking of current, voltage, and power consumption of the ATM centre.
[0004] An objective of the present invention is to operate as a gateway for transferring calculated power consumption of the ATM centre to a remote server and a software interface for monitoring and regulation of power consumption.
[0005] An object of the present invention is to provide a logic-based schedule operation of various appliance allowing a controlled and regulated power consumption of the ATM centre.
[0006] Yet another objective of the present invention is to provide a system that controls and regulates the switching ON/ OFF of various appliance based on changes in various ambient parameters of the room, thus controlling and regulating the power consumption of the ATM centre.
[0007] Another objective of the present invention is to provide a system that controls and regulates the switching ON/ OFF of various appliance based on door status, thus allowing energy monitoring and regulation of the ATM centre.
[0008] Next objective of the present invention is to provide a real time alert mechanism to provide a health status and thus provide end to end monitoring solution of various electrical and electronic assets at the ATM centre.

SUMMARY OF THE INVENTION
[0009] The systems, methods, and devices of the present invention each have several aspects, no single one of which is solely responsible for the desirable attributes. The present invention relates to an automated system and method thereof for energy consumption – measuring, monitoring, and control for various electrical and electronic assets at ATM centre (hereinafter referred to as “system”). The present invention integrates and retrofits with the present ATM centre setup reducing overall costs of installations. The system has a preset function for calculating power consumption in kilowatt per hour, thus monitoring the power consumption of the ATM centre. Further, the system utilises a logic based pre-set scheduled with a configurable time factor for a switching on and a switching off of air conditioner in an alternating and cyclic fashion, thus regulating energy consumption. The system allows the switching on and the switching off of the air conditioner using a plurality of sensors based on changes in various ambient conditions in the ATM centre, further micromanaging to power consumption at the ATM centre. The system allows decision making based on the historical data collected for identification of effective ways to reduce consumption of power in the ATM centre.

BRIEF DESCRIPTION OF THE DRAWING(S)
[0010] Figure 1 is a schematic diagram of an air conditioning energy management and control system for the ATM vestibule.
[0011] Figure 2 illustrates a block schematic diagram showing an iATM box and its various components include a communication component, a processing component, a power measuring component, a sensor component, and a display component.
[0012] Figure 3A illustrates the dashboard displayed on opening of the iATM application of the system; Figure 3B illustrates a location dashboard of the iATM application of the system; and Figure 3C illustrates an alert dashboard of the iATM application of the system.
[0013] Figure 4 illustrates a method of monitoring, managing, and controlling energy consumption at an ATM centre according to an embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0014] The following description in combination with the Figures is provided to assist in understanding the teachings disclosed herein. The following discussion will focus on specific implementations and embodiments of the teachings. This focus is provided to assist in describing the teachings and should not be interpreted as a limitation on the scope or applicability of the teachings. However, other teachings can certainly be utilized in this application. The teachings can also be utilized in other applications and with several different types of architectures such as distributed computing architectures, client/server architectures, or middleware server architectures and associated components.
[0015] As used herein, the terms “comprises,” “comprising,” “includes,” “including,” “has,” “having” or any other variation thereof, are intended to cover a non-exclusive inclusion. Also, the use of “a” or “an” is employed to describe elements and components described herein. This is done merely for convenience and to give a general sense of the scope of the invention. This description should be read to include one or at least one and the singular also includes the plural, or vice versa, unless it is clear that it is meant otherwise. For example, when a single device is described herein, more than one device may be used in place of a single device. Similarly, where more than one device is described herein, a single device may be substituted for that one device.
[0016] The present invention relates to an automated system and method thereof for energy consumption – measuring, monitoring, and control for various electrical and electronic assets at ATM centre (hereinafter referred to as “system”). The present invention integrates and retrofits with the present ATM centre setup reducing overall costs of installations. The system has a preset function for calculating power consumption in kilowatt per hour, thus monitoring the power consumption of the ATM centre. Further, the system utilises a logic based pre-set scheduled with a configurable time factor for a switching on and a switching off of air conditioner in an alternating and cyclic fashion, thus regulating energy consumption. The system allows the switching on and the switching off of the air conditioner using a plurality of sensors based on changes in various ambient conditions in the ATM centre, further micromanaging to power consumption at the ATM centre. The system allows decision making based on the historical data collected for identification of effective ways to reduce consumption of power in the ATM centre.
[0017] Figure 1 depicts an exemplary overview schematic representation of the system 100. The system 100 includes an i-ATM box 20 disposed in an ATM centre 500. A cloud-based server remotely networks the i-ATM box 20 at the ATM centre 500 to an iATM smart application (“application”) 80 on a user end. The iATM box 20 disposed and circuited to a main power supply 501 of the ATM centre 500 using a power cable 10. In a preferred embodiment of the present invention, the i-ATM box 20 is circuited with the main power supply 501 via an UPS 507. The i-ATM box 20 is powered through a UPS output of the UPS 507. This allows the i-ATM box 20 to be kept running even when electricity is unavailable, allowing to calculate of a period of unavailability of electricity to the ATM centre 500. Further, the iATM box 20 is circuited via the UPS 507 to an ATM machine 501, a pair of air conditioner 502, a signage 503, an ATM reboot 504, a lobby light 505, a VSAT 506 (together denoted as “electrical assets”) in the ATM centre 500, as depicted in Figure 1. Each of the air conditioner and a plurality of electric points at the ATM centre are circuited to each of the plurality of relays 55 of the i-ATM box 20.
[0018] The iATM box 20 has an outer shell 21 made of a mild steel with a powder material. The i-ATM box 20 has a dimension of 323mm of height, 260mm of length, and a 100mm of depth, thus the i-ATM box 20 is small and compact. It is also necessary to note that the i-ATM box 20 can be retrofitted, thus minimising cost related to such automated systems. As illustrated in Figure 1, a dashed line represents a wiring of the plurality of air conditioner 502 and a plurality of electric fixture 501- 506 of the ATM centre 500 to the i-ATM box 20. The iATM box 20 has several components that allows the iATM box 20 to monitor, manage, and control a power consumption at a particular ATM centre 500. Each of these components work in synchrony and consonance with each other to achieve the management of power consumption. The iATM box 20 includes a communication component 30, a processing component 40, a power measuring component 50, a sensor component 60, and a display component 70 as shown in Figure 2. The communication component 30 includes a Wi-Fi module 32. The Wi-Fi module 32 allows the iATM box 20 to connected to a router 34. In the preferred embodiment of the present invention, the router is a SIM-based router 34 for connecting with the Wi-Fi module 32 of the i-ATM box 20 20. The Wi-Fi module 32 allows the iATM box 20 to be remotely connected to the i-ATM application 80 via the cloud-based server and is indicated on the application 80 with an online status 81 with a desired colour preferably green. The iATM box 20 can function on Wi-Fi network that operate on standard frequencies of 120 seconds to send and receive data. The communication component 30 is configurable.
[0019] In the preferred embodiment, the processing component 40 of the iATM box 20 is a main CPU 42. The main CPU 42 is a Novoton M251 chip with a random-access memory (“RAM”). The main CPU 42 includes a serial communication, a serial peripheral interface, and an inter-integrated circuit (“I2C”). The main CPU 42 receives a plurality of inputs from a measuring component 50 of the iATM box 20. The measuring component 50 includes a plurality of potential transformers (“PT”) 52, and a plurality of current transformers (“CT”) 54. The plurality of PT 52 measures a high alternating voltage from each of electrical assets 501 – 506 via a MCB 51 to the main CPU 42. A voltage data 52a is transmitted, processed, and stored in the main CPU 42. Further, each of the plurality of CT 54 is circuited inward to the plurality of relay 55 and circuited outward to the main CPU 42. Each of the plurality of CT 54 measures a primary current in each of the relays 55. A current data 54a is transmitted and stored to the main CPU 42. The main CPU 42 calculates an electrical power every hour from each of electrical assets 501 – 506 using the voltage data 52a and the current data 54a. This allows the system 100 to measure an electrical power every hour passing through each of the from each of electrical assets 501 – 506 at the ATM centre 500. In the preferred embodiment of the present invention, the plurality of relay 55 includes 8 relays 55a – 55h in the iATM box 20. Each of the 8 relays 55a – 55h is wired to each of electrical assets 501 – 506. Each of the 8 relay 55a – 55h is connected to each of the 8 CT’s. This allows each of the CT 54 connected to the each of the 8 relay 55a – 55h to measure a current utilised by each of the electrical assets 501 – 506.
[0020] In the preferred embodiment, the sensor component 60 of the i-ATM box 20 includes a plurality of sensors 61. The plurality of sensors 61 allows the iATM box 20 to measure and monitor surrounding conditions in a real time at the ATM centre 500. A sensor data 62 from the plurality of sensors 61 is sent back to the cloud-based platform via the iATM box 20 and further to the application 80 for storage, analysis, and statistics. The sensor data 62 from the plurality of sensor 61 is used by the iATM box 20 in conjunction with an intelligent algorithm 63 in the application 80 for monitoring and regulation of power consumption of the ATM centre 500. Each of the sensor data from the plurality of sensors 61 is transmitted to the cloud-based server to the application. The sensor data 62 from each of the plurality of sensor 61 is compared to a preset level for each of the sensors 61 at the i-ATM application 80. A comparison of the sensor data 62 to the preset level allows the system 100 to either switch on or switch off the plurality of air conditioner 502 in the ATM centre 500. In the preferred embodiment of the present system 100, the plurality of sensors 61 includes an IR sensor 61a, a temperature sensor 61b, a humidity sensor 61c, an occupancy sensor 61d, and a door sensor 61e. In the present invention, the infrared sensor 61a detects 500 senses and monitor changes in various ambient conditions in the ATM centre 500. In the preferred embodiment of the present invention 100, the temperature sensor 61b detects changes in temperature of the ATM centre 500. If a real time temperature measured by the temperature sensor 61d is lower than a set temperature, the AC would be switched off. If a real time temperature measured by the temperature sensor 61b is higher than a set temperature at the i-ATM application 80, the first air conditioner 502a and a second air conditioner 502b would be switched on. In the preferred embodiment of the present invention 100, the occupancy sensor 61d detects a number of people in the ATM centre 500 and further regulates an operation of air conditioner 502 to modulate a temperature based on a temperature sensor data 62b. In the preferred embodiment of the present invention 100, the door sensor 61e detects whether a door to the ATM centre 500 is open or close.
[0021] In a second preferred embodiment of the present invention includes a radar sensor 61f . The radar sensor 61f detects a presence in a lobby of the ATM centre 500. A detection of the presence in the lobby triggers a logic that either switches on the plurality of air conditioners in the ATM centre 500 or waits to receive a maximum temperature data from the temperature sensor 61b. Thus, the plurality of sensors 61 work in consonance with each other.
[0022] The display component 70 of the i-ATM box 20 provides a visual status about various modes, conditions, and states of the system. In the preferred embodiment of the present system 100, the display component 70 provides real-time visual status of the current and voltage in KWH unit. In some embodiments, the present system includes a display screen 70 e.g., LCD screen that displays an operational and status information.
[0023] The iATM box 20 of the system 100 also includes an AC- to – DC voltage regulator 72a and a DC-to-DC voltage regulator 72b. In the preferred embodiment of the present invention 100, the power supply to the i-ATM box 20 utilises 230 volts of alternative power as an input and gives 12 volts of DC power as an output via an AC-to-DC voltage regulator 72a. DC power is used as the main power source for the main CPU 42 of the i-ATM box 20 20. Several components of the main CPU 42 of the i-ATM box 20 utilises less power (e.g., Sensors uses 3 volts), in such cases the power is supplied through the DC-to- DC voltage regulator 72b i.e., a step down the power.
[0024] In the preferred embodiment of the system 100 utilises a logic-based schedule 90. This logic-based schedule 90 is triggered through the i-ATM application 80. This logic- based schedule 90 is a cycle which in an alternate fashion switch on and switch off each of the plurality of air conditioner as a function of time. In the preferred embodiment of the present invention 100, the logic-based scheduled 90 via the i-ATM application 80 initiates with a first air conditioner to be switched on and the first air conditioner functions for 20 minutes. Following which the first AC is then switched off. The first air conditioner 502a and a second air conditioner 502b both remain turned off for 10 minutes. This is followed by switching on of the second air conditioner and function for 20 minutes.
[0025] The iATM application 80 is built using a Laravel framework and utilises a PHP language. The iATM application 80 includes a dashboard 81. Figure 3A – 3C illustrates various dashboards of the iATM application 80. Figure 3A illustrates the dashboard 81 displayed on opening of the iATM application 80. The dashboard 81 on its top bar displays three icons the dashboard 81, location 92, and alert 93 that can be accessed by clicking on each on the icon. The dashboard displays a total site 84 of iATM box 20 installed, a total number of active 85 of the iATM box 20, device alters 85 from each of the iATM box 20, a map 86 displaying a number of iATM box 20 having an online status 87 indicated in green and an offline status 88 indicated in red of each of various ATM centres 500. The dashboard 81 also displays the monthly energy consumption in forecasted energy consumption and actual energy consumption 89 at each ATM centre 500. [0026] Further, the iATM application 80 provides a location health 92 providing a consolidated data from every ATM centre 500, as shown in Figure 3A. The location health dashboard 82 displays the device IDs, the AC status, an average temperature, a main, UPS, signage, DVR, a lobby statue, a door status, earth IN and earth OUT status, and a date and time stamp for data received. The location health dashboard 92 allows to access individual detailed data for each ATM centre 500. The dashboard 81 of Figure displays a location ID, a location, and a device ID for iATM box 20 in each of the ATM centre 500. Further, the dashboard provides a power consumption details at each of the ATM centre 500. The iATM application 80 also provides a daily report dashboard. The daily report dashboard provides a detailed consumption pattern of the previous day at each of the ATM centre 500. The DVR dashboard displays a DVR status with camera status and a plurality of images with a date and time stamp.
[0027] Figure 4 illustrates a method of monitoring, managing, and controlling energy consumption at an ATM centre according to an embodiment of the present invention. Portions or all of the method of Figure 4 can be used with portions, or all of the systems, devices, or apparatuses disclosed herein, or any other type of system, controller, device, module, processor, or any combination thereof, operable to employ all, or portions of, the method of Figure. Additionally, the method can be embodied in various types of encoded logic including software, firmware, hardware, or other forms of digital storage mediums, computer readable mediums, or logic, or any combination thereof, operable to provide all, or portions, of the method of Figure 4.
[0028] The method begins generally at block 200. At a decision block 202, the method detects whether the iATM box 20 of the system 100 is an online status 82 on the i-ATM application 80 at a user end. For the i-ATM box 20 to be visible as online 82, the system 100 is turned on by pushing a power button 101 on the i-ATM box 20. The UPS 507 supplies power to the i-ATM box 20, which in turn powers up a Wi-Fi module 32. The Wi-Fi module 32 searches for a SIM based router 34 having a SSID 34a and a password 34b. The Wi-Fi module 32 is configured through a MQTT protocol and allows the i-ATM box 20 to change a status from offline to the online status 82 on the i-ATM application 80. At decision block 204, once the i-ATM box 20 is displays the online status 82, the i-ATM application 80 triggers a logic-based schedule 90. The logic-based schedule 90 triggers an automated switching on and a switching off of a plurality of air conditioners 502 in a cyclic and alternating fashion as a function of time. As per the logic-based schedule 90, each of the air conditioner 502 in the ATM centre 500 is alternately in a cyclic and timed manner switched off and switched on. In the preferred embodiment of the present invention 100, the ATM centre 500 has two air conditioners 502. A first air conditioner 502a is switched on for a first fixed period. After which the first air conditioner 502a is switched off for a second fixed period. It is necessary to note that in the second fixed period of the logic-based schedule 90 both the first air conditioner 502a and a second air conditioner 502b remain switched off for the second fixed period. This is followed by a switching on of the second air conditioner 502b and function for a third fixed period. The first fixed period, the second fixed period, and the third fixed period has a configurable time factor based on the various factors like weather condition, season etc. The time of the first fixed period, the second fixed period and the third fixed period is configurable through the i-ATM application 80. In a preferred embodiment of the present invention 100, the first fixed period is 20 minutes, where the first air conditioner 502a is switched on and functions. This period is followed by a switching off of the first air conditioner 502a for the second fixed period is 10 minutes. It is necessary to note that both the air conditioners 502 are switched off at the second fixed period. The third fixed period is 20 minutes, where the second air conditioner 502b is switched on and function. This cycle of alternately switching on and switching off of the air conditioners 502a and 502b is continuous. At the block decision 206, simultaneously, the i-ATM box 20 using the plurality of CT 52 and the plurality of PT 54 measures a real time current and a real time voltage from each of the electrical assets 501-506. The current data 54a from the plurality of CT 52 and the voltage data 52a from the plurality of PT 54 is transmitted to the main CPU 42 for storage and processing. The current data 54a and the voltage data 52a is utilised by the main CPU 42 to calculate and monitor the power consumption of the ATM centre 500 every hour. The main CPU 42 also transmits the data to the cloud-based server to the iATM application 80. At a block decision 208, the sensor component 30 of the iATM box 20. The plurality of sensors 60 detects a change in the various ambient conditions in the ATM centre 500. A sensor data 62 from each of the plurality of sensor 60 is transmitted to the main CPU 42 and further to the i-ATM application 90. A pre-set level for each of the plurality of sensors 60 is defined at the i-ATM application 80. This pre-set level defines a maximum value and a minimum value. is compared to the sensor data 62 from each of the plurality of sensor 60. If the sensor data 62 from each of the plurality of sensor 60 is higher than the pre-set level for each sensor, the AC 502 is turned on while if the sensor data 62 from each of the plurality of sensor 60 is lower than the pre-set level for each sensor, the AC is turned off. In the preferred embodiment of the present invention 100, sensor component 60 includes an IR sensor 61a, a temperature sensor 61b, a humidity sensor 61c, an occupancy sensor 61d, and a door sensor 61e. The sensor component 60 in consonance with the logic-based schedule 90 further alters and micromanages switching on and switching off of the two-air conditioner 502 in turn managing and controlling the energy consumption of the ATM centre 500.
[0029] The above-disclosed subject matter is to be considered illustrative, and not restrictive, and the appended claims are intended to cover any and all such modifications, enhancements, and other embodiments that fall within the scope of the present invention. Thus, to the maximum extent allowed by law, the scope of the present invention is to be determined by the broadest permissible interpretation of the following claims and their equivalents and shall not be restricted or limited by the foregoing detailed description.
[0030] Although only a few exemplary embodiments have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of the embodiments of the present disclosure. Accordingly, all such modifications are intended to be included within the scope of the embodiments of the present disclosure as defined in the following claims. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures.
, C , Claims:
CLAIMS
We Claim,
1. An automated system 100 for an energy monitoring, management, and controlling in an ATM centre 500, comprises:
• an i-ATM box 20 circuited to and between a main power supply 508 and a plurality of electrical assets 501 – 506 and wherein the i-ATM box 20 comprises:
- a communication component 30 to remotely connect to an i-ATM application 80 to indicate an online status 82 of the i-ATM box 20;
- a sensor component 40 for detecting a real time change in an ambient condition of the ATM centre 500;
- a processing component 50 of the i-ATM box 20 to process a passage of an electrical power per hour through the plurality of electrical assets 501 – 506; and
- a measuring component 60 of the i-ATM box 20 includes a plurality of potential transformers 52 connected to a MCB 51 and a plurality of current transformers 54 circuited inward to a plurality of relay 55 and circuited outward to the processing unit 50; and
• a pre-set logic-based schedule 90 in a cyclic and alternating fashion for a switching on and a switching off each of the plurality of air conditioner 502 as a function of time, wherein the pre-set logic-based schedule cycle 90 includes:
- a first air conditioner 502a switched on for a first fixed period;
- a switching off of the first conditioner 502a and a second air conditioner 502b for a second fixed period; and
- a third fixed period for switching on the second air conditioner 502b; and wherein the first fixed period, the second fixed period; and the third fixed period of the pre-set logic-based schedule 90 is a configurable time based on a seasonal change at a location of the ATM centre 500; and
wherein a real-time current data 54a and a real-time voltage data 52a to calculate a power consumption kilowatt per hour to detect and monitor a status of each of the electrical assets 501 – 506, the pre-set logic-based schedule 90 is altered to further regulate the switching on and the switching off of the plurality of air conditioner 502 using a sensor data 62 based on the sensor component 60 that is either lower or higher to a pre-set value for the sensor component 60 to manage, and control power consumption at the ATM centre 500.
2. The automated system 100 as claimed in claim 1, wherein the communication component 30 includes a Wi-Fi module 32 to connect the iATM box 20 to the i-ATM application 80 via a SIM based router 34.
3. The automated system 100 as claimed in claim 1, wherein the communication component 30 remotely connects the i-ATM box 20 to the i-ATM application 80 via a cloud-based platform.
4. The automated system 100 as claimed in claim 1, wherein the sensor component 60 includes a plurality of sensors 61 selected from a group of an IR sensor 61a, a temperature sensor 61b, a humidity sensor 61c, an occupancy sensor 61d, and a door sensor 61e to measure and monitor surrounding conditions in a real time.
5. The automated system 100 as claimed in claim 1, wherein the sensor component 60 includes a radar sensor 61f.
6. The automated system 100 as claimed in claim 1, wherein the i-ATM box 20 includes a AC-to-DC voltage regulator 72a and a DC-to-DC voltage regulator 72b.
7. The automated system 100 as claimed in claim 1, wherein the i-ATM box 20 is wired to a UPS system 507 to provide a backup in case of a power failure.
8. The automated system 100 as claimed in claim 1, wherein the plurality of potential transformers 52 measures a high alternate voltage from each of the electrical asset 501-506 and sends to the processing component 40.
9. The automated system 100 as claimed in claim 1, wherein the plurality of current transformers 54 measures a primary current from each of the electrical asset 501-506 and sends to the processing component 40.
10. The automated system 100 as claimed in claim 1, wherein the plurality of relay includes 8 relays and each of the 8 relays 55 is wired to an ATM machine 51, a first AC 502a, a second AC 502b, a signage 503, an ATM reboot 504, a lobby light 505, a VSAT 506, and one is spare.
11. The automated system 100 as claimed in claim 1, wherein the processing unit 40 is a main CPU 42 to process a current data 54a from a plurality of current transformers 54 and a voltage data 52a from a plurality of potential transformers 52 to calculate an electrical power kilo watt per hour (kwh).
12. The automated system 100 as claimed in claim 10, wherein the main CPU 42 includes a serial communication, a serial peripheral interface, and an inter-integrated circuit (“I2C”).
13. The automated system 100 as claimed in claim 1, wherein the i-ATM box 20 includes a display component 70 to provide a real-time visual status of the electrical power in kilowatt per hour.
14. The automated system 100 as claimed in claim 1, wherein the i-ATM application 80 uses a Laravel framework and a PHP language.
15. The automated system 100 as claimed in claim 1, wherein the i-ATM application 80 includes a dashboard 81 to display a location health 92, alert 93, a power consumption, a daily report, a DVR etc.
16. A method 1000 to monitor, manage, and control energy consumption in an ATM centre 500 using an automated system 100 comprising the steps of:
• turning on the automated system 100 by pushing a power button 101 to power a communication component 30 of an i-ATM box 20;
• connecting a Wi-Fi module of the communication component 30 to a SIM based router 34 having a SSID and a password;
• configuring the Wi-Fi module 32 of the communication component 30 is configured through a MQTT protocol to allows the i-ATM box 20 to change a status from offline to an online on an i-ATM application 80;
• switching on and switching off a plurality of air conditioner 502 using a logic-based schedule 90, wherein the pre-set logic-based schedule 90 includes:
- a first air conditioner 502 a switched on for a first period;
- a switching off of the first conditioner 502a for a second period; and
- a second air conditioner 502b switched on for a third period and wherein the first period, the second period, and the third period are a configurable time function.
• calculating and monitoring a power consumption every hour by a processing unit 42 using a plurality of current transformers 52 and a plurality of potential transformers 54 to measures a real time current and a real time voltage from each of the air conditioner 502 and plurality of electrical assets 501-506;
• detecting a change in various ambient conditions in the ATM centre 500 by a plurality of sensor component 60; and wherein comparing a sensor data 62 to a pre-set level to either switch on or switch off a plurality of air conditioner 502.
17. The method as claimed in claim 12, wherein the plurality of air conditioner 502 is switched on if the sensor data 62 from each of the plurality of sensor 60 is higher than a pre-set level for each sensor in the i-ATM application 80.
18. The method as claimed in claim 12, wherein the plurality of air conditioner 502 is switched off if the sensor data 62 from each of the plurality of sensor 60 is lower than a pre-set level for each sensor in the i-ATM application 80.

Dated 10th Day of December 2022.