The MK3000L is a state-of-the-art protective device designed to enhance the safety and reliability of electrical systems. It provides real-time monitoring and protection against overcurrent and earth fault conditions, ensuring equipment damage and system failures. The relay also detects negative sequence overcurrent, thermal overload, and autoreclose functionality, reducing downtime and enhancing system reliability. Its flexible setting ranges allow users to customize protection settings for specific applications. The MK3000L supports RS485 communication with Modbus protocol, allowing seamless integration into existing control systems for real-time monitoring and management. It is designed for industrial plants, commercial buildings, and utility applications, offering robust protection solutions tailored to diverse electrical environments. Its advanced features provide immediate protection and long-term operational efficiency, making it a vital asset for electrical engineers, system integrators, and facility managers.

A Stream Waste Shuttle System (WSS) which is one of the technology in Automated Waste Collection System (AWCS) is a modern and efficient method of waste management that uses advanced technology to collect, transport, and process waste with minimal human intervention. AWCS systems are designed to address the challenges of traditional waste collection methods by improving efficiency, reducing environmental impact, and enhancing cleanliness in urban and commercial areas as well as hospitals and transport hubs such as airports. Key Components of AWCS: 1. Waste Collection Points: These are strategically located in residential, commercial, or public areas where users deposit their waste. Collection points can include smart bins, chutes, or loading stations that are often designed to automatically sort or compact waste. 2. Pneumatic Systems: Waste is transported from the collection points to a central processing facility through underground waste pipeline with the use of pneumatic systems, air pressure is used to move waste quickly and efficiently. 3. Centralized Processing Facility: All the waste collected through the system is directed to a central facility where it can be sorted, compacted, recycled, or processed for energy recovery. This facility handles various types of waste, including solid waste, recyclables, and organic material. 4. Control and Monitoring System: AWCS is managed by a central control system that monitors waste levels, system performance, and collection schedules. The system uses data analytics and IoT (Internet of Things) sensors to optimize operations in real-time.

A Stream Gravity Vacuum System (GVS) which is one of the technology in Automated Waste Collection System (AWCS) is a modern and efficient method of waste management that uses advanced technology to collect, transport, and process waste with minimal human intervention. AWCS systems are designed to address the challenges of traditional waste collection methods by improving efficiency, reducing environmental impact, and enhancing cleanliness in urban and commercial areas as well as hospitals and transport hubs such as airports. Key Components of AWCS: 1. Waste Collection Points: These are strategically located in residential, commercial, or public areas where users deposit their waste. Collection points can include smart bins, chutes, or loading stations that are often designed to automatically sort or compact waste. 2. Pneumatic Systems: Waste is transported from the collection points to a central processing facility through underground waste pipeline with the use of pneumatic systems, air pressure is used to move waste quickly and efficiently. 3. Centralized Processing Facility: All the waste collected through the system is directed to a central facility where it can be sorted, compacted, recycled, or processed for energy recovery. This facility handles various types of waste, including solid waste, recyclables, and organic material. 4. Control and Monitoring System: AWCS is managed by a central control system that monitors waste levels, system performance, and collection schedules. The system uses data analytics and IoT (Internet of Things) sensors to optimize operations in real-time.

WE PROVIDE A CONTACT CENTRE SOLUTION CONSIST OF TELEPHONY, CHAT, VIDEO, EMAIL, WEB PORTAL, SOCIAL MEDIA AND CRM SYSTEM IN ONE SINGLE PLATFORM. WE COMBINE ALL THE CHANNELS INTO SINGLE PLATFORM.

LOOKA UTMS is a system designed for aviation industry application. The application of LOOKA UTMS is specifically made for Unmanned Aerial Vehicles (UAV) industry, also known as drones.   Currently in Malaysia, the normal process for drone users applying Approval To Fly (ATF) would usually take at least 6 weeks and the application will be sent via email to Civil Aviation Authority Malaysia (CAAM). As compared to the system used to monitor flying operations of manned aircrafts, there is no capable system used to monitor all flying operations of drones. So all flying operations are not monitored by the authorities.   Therefore, the purpose of LOOKA UTMS is to shorten the application time of ATF and to monitor and manage the flying operations of drones. LOOKA UTMS shall be utilised by drone users and managed by the respective authorities; i.e., CAAM, TUDM, JUPEM, and CGSO. On top of that, the potential to expand the services to other CAA regionally is possible.

We believe the traditional methods employed by hospitals before and during surgeries have significant limitations. These methods often rely on restricted 2D data for analysis, lack simulation capabilities for preoperative planning, and depend on in-situ decision-making rather than detailed preparation. Furthermore, determining implant dimensions is frequently a trial-and-error process, contributing to extended operation times and increased risks. Through 3D Gens, we provide advanced solutions to overcome these challenges. Our technology enables 3D data visualization and simulation, empowering surgeons with comprehensive insights for preoperative planning. In cases requiring a multidisciplinary approach, we offer 3D anatomical models to enhance collaboration and precision. With our LOGIC Patient-Specific Implants (PSI) tm, we eliminate the reliance on in-situ adjustments and trial-and-error techniques. These innovations result in shorter surgical times and significantly reduced risks, ultimately improving patient outcomes and operational efficiency.