Our goal is to enhance corporate value, maintain sustainable long-term development and generate greater returns. In order to better achieve the above objectives, we have established good corporate governance practices following the principles of integrity, transparency, openness and efficiency.
Address: 801 Fortis Suites, Hospital Road, Upper Hill
Postal Address: P.O Box 76230 - 00508, Nairobi
Phones: (+254) 711 557788 (+254) 733 775550
E-mail: info@nemelkenya.co.ke nemelkenya@gmail.com
Eng. Emma Wanjiru has a wealth of experience in energy matters. She is a practicing Electrical Consultant as well as a Contractor. She has a Class A1 license in Electrical installations and class A3 license in solar installations.
Eng. Emma Wanjiru is a former chairperson of Energy Regulatory Board (ERC). ERC is the Commission that regulates the operations of power utilities in Kenya. Besides issuing power generation licences the body sets power both bulk and retail energy tariffs and approves power purchase agreements.
Emma served as a director of Rural Electrification Authority. Emma prides herself for being the first woman to be a Registered Consulting Engineer. She holds a Bachelor of Science in Electrical Engineering and Masters of Business Management both from the University of Nairobi. She is currently pursuing M. SC in Energy at the same university.
Eng. Kiilu is a former Managing Director of the Kenya Electricity Transmission Company Limited (Ketraco).
Eng. Joel Kiilu is a registered Electrical Engineer. He holds a Masters Degree in Business Administration (MBA) from the University of Nairobi and a Bachelor of Science (BSc.) degree in Electrical Engineering from the same University. He is currently pursuing PHD in business Leadership at Management University of Africa.
Eng. Kiilu has vast knowledge of the Power industrial. Having been the Chief Manager, Energy Transmission in Kenya Power and Lighting where he was in charge high voltage system design, construction, operations and maintenance.
He was in charge of power purchase agreements and energy dispatch, SCADA and Energy Management System. Eng. Kiilu participated in drafting and negotiating Power Purchase Agreements between:
As the Chief Executive Officer of Ketraco, he was responsible for the establishment of the organization, including the necessary structures, policies and procedures and overall operation of the organization. Under his leadership the company grew, in 6 years, from an asset base of US$80Million to over US$600Million.
Eng. Kiilu is a member of the Institution of Engineers of Kenya (MIEK), and the Institution of Electrical and Electronic Engineers (MIEEE).
The PD Alarm is an asset mounted device for indicating the presence of partial discharge in high voltage switchgear, ring main units (RMUs) and dry type transformers. Designed for use in small substations, the instrument can activate local and remote alarms in addition to local indication.
Key Features
The ASM-Remote is a PD monitoring system designed for application on critical EHV and distributed assets, where the monitoring point could be many hundreds of meters or tens of kilometers apart. Fiber linked monitoring points transmit PD data over long distances to the main monitoring unit, which then processes the data and displays the results on a secure customer web front end.
Benefits of ASM-Remote
Web Based Analysis
A client specific secure website is used for the review and analysis of individual asset conditions. This powerful tool allows users to drill down from a basic condition overview to highly detailed data, including sampled PD wave shapes when expert interpretation is required.
The ASM-P is a Portable PD Monitor for cables, switchgear and other high voltage assets. The ASM-P can be configured with up to 32 PD sensor channels. If excessive discharge is detected, the ASM-P raises an alarm that can be configured either locally or by email. This enables the long-term assessment of plant conditions to be carried out quickly and easily, from any remote computer.
Partial discharge data is automatically collected from the ASM-P and is stored on a central database and is hosted by IPEC. Customers have direct password-protected access to this data via the Internet, allowing them to browse the data and analyse plant condition from any PC.
Condition information presented like this can be used for targeting scheduled maintenance work before the failure happens, improving network reliability and prioritising asset replacement.
Based on the magnitude of activity levels recorded and the trend in that activity, a ‘League Table’ is automatically generated once every 24 hours. This table gives a clear and quantitative representation of the condition of monitored high voltage assets at any given moment.
For use in buildings, large complexes, mining, boats, and electric stations.
Weight: 8.370 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Packaging: Galvanized Metallic Material
Height: 41cm
Diameter: 28cm
Developed for special applications and military use due to the great conductivity, high strength and lightweight characteristics of graphene.
With its greater deionizing power, it is developed for maximum protection in yachts, cruises, cargo ships and military ships
Weight: 6.170 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Packaging: Galvanized Metallic Material
Height: 41cm
Diameter: 28cm
With its greater deionizing power, it is used in fishing or expedition boats of medium size, catamarans and small yachts.
Weight: 2.750 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Packaging: Galvanized Metallic Material
Height: 21cm
Diameter: 20cm
For use in small boats, sail boats, marine buoys
Weight: 1.062 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Packaging: Galvanized Metallic Material
Height: 21cm
Diameter: 20cm
Developed for installations in high temperature environments, for example, chimneys, industries, etc. Supports up to 400⁰C.
Weight: 8.370 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Packaging: Galvanized Metallic Material
Height: 41cm
Diameter: 28cm
Developed with the same characteristics of CMCE 120, but with a special design to avoid the falling of the equipment, especially for derricks.
Weight: 11.170 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Packaging: Galvanized Metallic Material
Height: 41cm
Diameter: 28cm
Same characteristics as the CMCE 120, but with a dark matt color design, to avoid disturbance to the environmental visual.
Weight: 8.370 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Packaging: Galvanized Metallic Material
Height: 41cm
Diameter: 28cm
Developed for small deposits, telecommunications towers, medium and high voltage power lines, traffic lights, small radars, road cameras and garitas.
Protection radius: 25m
Weight: 980 grams (Gross)
Measurements: 17cm Height × 10 cm diameter
Packaging: Galvanized Metallic Material
Designed for highly corrosive environments, since it is a steel with high resistance to corrosion, given that the chromium or other alloying metals it contains, have great affinity for oxygen and react with it forming a passivating layer, thus avoiding corrosion of iron.
Protection radius: 100m
Weight: 20 kilograms (Gross)
Measurements: ɸ24.17cm × 36.72cm
Developed to protect all types of structures on land, residences, small buildings and warehouses.
Protection radius: 55m
Weight: 2.460 kilograms (Gross)
Measurements: 24cm Height × 15.5 cm diameter
Packaging: Galvanized Metallic Material
IPEC’s UHF (Ultra High Frequency) sensors is used to detect PD in EHV cable terminations, GIS (Gas Insulated Switchgear), GIL (Gas Insulated transmission Lines) & GIT (Gas Insulated Transformers). The sensors pick up signals in the UHF range (200MHz-2.5GHz) and are mounted against the insulating barrier spacers that separate components of the HV asset. The sensors work with multiple IPEC monitoring systems.
Sensors are installed differently depending on the asset manufacturer and model and accessibility to insulating sections, gaskets, UHF windows, and accessibility. Please contact IPEC for specific applications
PD-SGS is a dual transducer PD detector for Switchgear. The instrument detects TEV signals generated by internal discharge as well as acoustic discharge generated by surface tracking or corona.
Partial Discharge activity inside metal clad high voltage plant induces small voltage impulses called Transient Earth Voltages on the surface of the metal panels. TEVs travel around the surface to the outside of the switchgear, where they can be picked up externally using the PD-SGS detector.
Defects on the surface of high voltage insulators are prone to a phenomenon known as surface tracking. Tracking causes carbon deposits that build up over time, ultimately leading to flashover and insulation failure. The PD-SGS is highly sensitive to the ultrasonic emissions produced by tracking and enable the onset to be detected before insulation failure.
PD-SG1 is used to detect, verify and locate PD activity in switchgear. The unit offers both TEV detection for internal discharge and ultrasonic detection for surface tracking and corona.
PD Detection Partial Discharge activity inside metal clad high voltage plant induces small voltage impulses TEV (Transient Earth Voltages) on the surface of the metal cladding. TEVs travel around the cladding surface to the outside of the switchgear panel where they can be picked up externally using CC-TEV transducers.
The PD-SG1 has three modes: Level Mode, used to detect presence of both TEV and ultrasonic activity; Cycle Mode, Phase Resolved Partial Discharge Display (PRPD) enables the user to verify PD activity is genuine and not from electrical noise interference before taking further remedial action; Precedence Mode, dual sensor precedence allows users to pin-point the source of PD activity.
Partial Discharge activity inside metal clad high voltage plant induces small voltage impulses called Transient Earth Voltages on the surface of the metal panels. TEVs travel around the surface to the outside of the switchgear, where they can be picked up externally using the PD Detector.
Defects on the surface of high voltage insulators are prone to a phenomenon known as surface tracking. Tracking causes carbon deposits that build up over time, ultimately leading to flashover and insulation failure. The PD Detector is highly sensitive to the ultrasonic emissions produced by tracking and enable the onset to be detected before insulation failure.
Parabolic Reflector is an ultrasonic sensor for use when detecting partial discharge activity on exposed insulating surfaces. The reflector increases the sensitivity of the sensor allowing detection to be effective at up to 25m. It is commonly used in outdoor switchyards to detect surface discharge on string and post insulators, sealing ends and other exposed equipment.
Use of Parabolic Reflector
With the Parabolic Reflector connected to the PD-SGS, the reflector should be pointed at the HV equipment being inspected.
Look through the view finder with both eyes open and line up the red dot visible through the view finder with the centre of the inspection area.
The PD-SGS instrument should be operated in AE Mode (See PD-SGS Operation Manual) and it will register a dB reading on the user display. It will also generate an audible output according to the level of activity detected.
It is recommended that when using the Parabolic Reflector out of doors, the head phones are worn in order to minimise interference from outside noise sources.
Owing to the nature of acoustic PD detection and natural variations caused by environmental conditions, it is recommended that PD levels identified are appraised according to their relative values when compared with other similar plant and not in absolute terms.
HFCT 100 PD Sensor is a high frequency current transformer specifically designed for the passive detection of PD in HV and EHV cable circuits.
Partial Discharge activity in solid high voltage insulation induces small high frequency currents in the earth conductor of the electrical system. These impulses travel along the equipment earth to the substation earth. Using a high frequency current transformer, they can be detected as they pass through the CT.
The HFCT100 has a split core ferrite to allow retrospective fitting to earth straps without the need for disconnection. Its larger internal diameter makes it ideal for HV and EHV applications. The durable body has a hinge and a quick release latch making use quick and easy. The CT is constructed with an aluminum body to provide RF shielding and improved performance in noisy environments.
This transducer is ideal for all core, earth and neutral PD monitoring applications.
HFCT 48 PD Sensor is a high frequency transducer designed specifically for picking up partial discharge signals.
Partial discharge activity in solid high voltage insulation induces small high frequency currents in the earth conductor of the electrical system. These impulses travel along the equipment earth to the substation earth. Using a high frequency current transformer, they can be detected as they pass through the CT.
The HFCT48 has a split core ferrite to allow retrospective fitting to earth straps without the need for disconnection. The durable body has a hinge and a quick release latch making use quick and easy. The CT is constructed with an aluminum body to provide RF shielding and improved performance in noisy environments.
This transducer is ideal for all core, earth and neutral PD monitoring applications.
Partial Discharge activity inside metal clad high voltage plant induces small voltage impulses (called Transient Earth Voltages) on the surface of the metal cladding. TEV’s travel around the cladding surface to the outside of the switchgear panel where they can be picked up externally using capacitively coupled transducers (see picture above).
The Capacitive Coupler sensor detects TEVs as they pass over the cladding of the high voltage plant. The very fast output signals are recorded by the IPEC ASM Monitor. The sensor is enclosed in a durable silicon body for added protection. The body has powerful magnets embedded within it for mechanical coupling to steel enclosures.
Depending on the switchgear type, more accurate signals can be obtained by embedding the sensors inside the switchgear to be monitored. Note: The sensor is applicable to multiple locations outside / inside switchgear panels, the exact ideal positioning depends upon the switchgear type.
Surface tracking and corona in air can seriously damage high voltage insulating surfaces in a way that will ultimately lead to flashover and complete failure of the insulator.
This discharge activity creates acoustic emission that can be detected using an ultrasonic sensor. The magnitude of the acoustic emission is indicative of the degree and severity of discharge activity.
The acoustic probe is designed for use on air insulated terminations or other HV components where there is a clear sound path between the electrically stressed insulation and the probe. The sensor is extremely sensitive and can detect activity below 10pC. The probe has a magnetic base to allow mechanical coupling to steel enclosures and a swivel head so the detecting sensor can be aimed directly at the HV point.
In many applications, there is no external line of sight to the HV points. The sensor can be safely embedded inside the HV equipment to give optimal detection capability.
ASM is a Partial Discharge monitor for permanent testing of cables and switchgear. The latest ASM model has been upgraded offering fast data acquisition, and analysis. IPEC’s PD Monitoring system technology is installed in more substations than any other online PD monitoring system.
iSM is a customer specific secure website is used for review and analysis of individual asset condition. This powerful tool allows users to drill down from a basic condition overview to highly detailed data including sampled PD wave shapes.
• The Tap Changer & Winding Analyzer TWA40D is designed for six-winding resistance measurement and simultaneous three-phase on-load tap changer analysis of both the primary and the secondary transformer windings. Additional testing mode, Quick YN, is enabled by the DV-Win software. In this mode, it is possible to measure the resistances of three transformer windings in the YN configuration simultaneously. It is also possible to test the resistances of all tap changer positions of all three phases in a single pass through the tap changer positions.
• The Three-Phase Winding Ohmmeter TWA25A is designed for six-winding resistance measurement of both the primary and the secondary transformer windings. This is performed with a one single-step cable setup, with test currents of up to 25 A. Each transformer configuration has a special measurement algorithm which is optimized for the fast stabilization of test results.
• Test voltages from 1 V AC up to 250 V AC
• Ratio range 0,8 – 50 000
• The best ratio accuracy of 0,03%
• Built-in tap changer control unit
• Built-in USB flash drive
• True three-phase and single-phase test
• Automatic vector group detection
• Detailed analysis of test results using DV-Win software
• Pre-programming test-plans deploying DV-Win software
• Lightweight – only 9 kg
• Test voltages from 1 V AC up to 430 V AC
• Ratio range 0,8 – 50 000
• The best ratio accuracy of 0,03%
• Built-in tap changer control unit
• Built-in USB flash drive
• True three-phase and single-phase test voltages
• Automatic vector group detection
• Detailed analysis of test results
• Pre-programming test templates
• Lightweight – only 9 kg
• Powerful – up to 40 A
• Output voltage is selectable from 10 V to 300 V DC or from 10 V to 250 V AC.
• The set is equipped with thermal and over current protection. SAT40A is easy to use and has accessory cable-set with touch-proof contacts.
• The SAT40A has very high ability to cancel electrostatic and electromagnetic interference in the HV electric fields. It is achieved by very efficient filtration.
• Output voltage is selectable from 10 V to 300 V DC or from 10 V to 250 V AC.
• The set is equipped with thermal and over current protection.
• SAT30A is easy to use and has accessory cable-set with touch-proof contacts.
• The SAT30A has very high ability to cancel electrostatic and electromagnetic interference in the HV electric fields. It is achieved by very efficient filtration.
• Powerful – up to 30 A
The RMO60E is ideal for testing protective bonding (grounding) of equipment following the standard IEC 61010-1.
The RMO60E generates true DC current with automatically regulated test ramps. During the test RMO60E ramps with increasing current before measuring and decreasing current after the measurement. This eliminates magnetic transients. After the test current has been set, pressing the Ω button starts the automatic test procedure.
• test current from 5 to 200 A, weighs only 8 kg / 17.6 lbs
• Test current from 5 to 500 A, weighs only 9 kg / 20 lbs
• Three-channel winding resistance measurement.
• One temperature measurement channel.
• Demagnetization.
• Tap changer verification.
• Handheld, only 0,95 kg (2.1 lbs) weight
• IP54 mechanical protection rating
• Designed to make multiple measurements and full day’s work of testing without a battery recharge
• Safe testing in Both Sides Grounded (BSG) conditions
• Regulated, user selectable test current of up to 300 A.
• Measuring range: 0,1 μΩ – *999,9 mΩ (*499,9 mΩ for RMO800G)
• Resolution: 0,1 μΩ
• Typical accuracy: ± (0,1 % rdg + 0,1 % FS)
• Remote Control Unit (optional)
• Both Sides Grounded Unit (optional)
• SINGLE / CONTIN / BSG / DTRtest modes
• the Test current goes up to 800A for the RMO800G model
• Measuring range: 0,1 μΩ – 999,9 mΩ
• Resolution: 0,01 μΩ
• Typical accuracy: ± (0,1 % rdg + 0,1 % FS)
• Remote Control Unit (optional)
• Both Sides Grounded Unit (optional)
• SINGLE / CONTIN / BSG / DTRtest modes
• DEMAGNETIZATION feature
• Measuring range: 0,1 μΩ – 999,9 mΩ
• Resolution: 0,1 μΩ
• Typical accuracy: ± (0,1 % rdg + 0,1 % FS)
• Rmax function (pass/fail criteria)
• Protection rating: IP43
• Test currents 5 mA – 60 A DC
• On-load tap changer dynamic resistance measurement
• Three resistance measurement channels
• Rapid automatic demagnetization
• Tap changer motor current monitoring channel
• Automatic discharge circuit
• Built-in tap changer control unit
• Detailed analysis of test results using DV-Win software
• USB flash drive feature
• Test current up to 60 A
• On-load tap changer dynamic resistance measurement
• Three resistance measurement channels
• Four temperature measurement channels
• Automatic resistance/temperature measurement for the Heat Run test
• Rapid automatic demagnetization
• Vibration measurement
• Tap changer motor current monitoring channel
• Automatic discharge circuit
• Built-in tap changer control unit
• Detailed analysis of test results using DV-Win software
• Test current up to 100 A
• On-load tap changer dynamic resistance measurement
• Three resistance measurement channels
• Four temperature measurement channels
• Automatic resistance/temperature measurement for the Heat Run test
• Rapid automatic demagnetization
• Vibration measurement
• Tap changer motor current monitoring channel
• Automatic discharge circuit
• Built-in tap changer control unit
• Detailed analysis of test results using DV-Win software
First handheld micro ohmmeter (only 0,95 kg / 2.1 lbs) which generates regulated DC current up to 300 A!
The RMO-H micro ohmmeters are ideal for a number of applications for contact resistance measurements of non-inductive test objects. Typical applications are testing a circuit breakers and disconnecting switches, high-current bus bar joints, cable splices, welding joints, etc.
RMO-H series consists of three models:
Ground Grid Tester GGT500 is a test set specially designed for inspection of substation ground grids. During the measurement instrument generates 300 A during a time period of 60 s or longer. Current and voltage drop are measured and displayed during the test. Test is performed with one set of current cables. One cable is connected to the referent grounding point in substation, and the second cable is connected to the testing ground point in the substation. With additional current clamps, current flow through the grounding is being inspected. Based on the current values measured with current clamps the state of the ground grid under the substation can be determined
• Fully automatic demagnetization
• Demagnetization currents 5 mA – 60 A DC
• Demagnetization process graph
• Automatic discharging circuit
• Lightweight – 13,1 kg
The Circuit Breaker Analyzer & Timer CAT65 instrument utilizes the latest improvements for safe and fast testing, with unique technical capabilities for additional diagnostics of circuit breakers. Sophisticated design ensures efficient and reliable operations in high-voltage substations and industrial environments.
Static resistance measurement
The built-in micro ohmmeter generates a true DC ripple free current with an automatically regulated test ramp.
DRM (Dynamic Resistance Measurement)
The built-in micro ohmmeter can also be used for the DRM. The DRM test is performed by injecting a current through the breaker contact and simultaneously monitoring the voltage drop across the breaker contact as well as the current flow during the operation of the breaker. The DRM test requires the circuit breaker analyzer with a high-resolution measurement. The resistance curve, as a function of a contact travel can be used to reveal potential problems related to the arcing contact condition. The injected current value should be as high as possible but not less than 100A to provide a reliable voltage drop reading, thus allowing an easier detection of the arcing contact. This model provides up to 200A.
The Circuit Breaker Analyzer & Timer CAT125 instrument utilizes the latest improvements for safe and fast testing, with unique technical capabilities for additional diagnostics of circuit breakers. Sophisticated design ensures efficient and reliable operations in high-voltage substations and industrial environments.
Static resistance measurement
The built-in micro ohmmeter generates a true DC ripple free current with an automatically regulated test ramp.
DRM (Dynamic Resistance Measurement)
The built-in micro ohmmeter can also be used for the DRM. The DRM test is performed by injecting a current through the breaker contact and simultaneously monitoring the voltage drop across the breaker contact as well as the current flow during the operation of the breaker. The DRM test requires the circuit breaker analyzer with a high-resolution measurement. The resistance curve, as a function of a contact travel can be used to reveal potential problems related to the arcing contact condition. The injected current value should be as high as possible but not less than 100A to provide a reliable voltage drop reading, thus allowing an easier detection of the arcing contact. This model provides up to 200A
• Simple & easy to operate
• Timing and motion measurement
• 6 timing channels for main and resistive contacts
• 3 timing channels for auxiliary inputs
• Resistance measurement of pre-insertion resistors
• 4 Analog Inputs + 1 Transducer Input
• Supports both digital and analog transducers
• Detailed analysis of test results using DV-Win software
• Simple & easy to operate
• Timing measurement
• 6 Channels for main contacts
• 3 Channels for auxiliary inputs
• TRIP & CLOSE coils current measurement
• Resistance measurement of pre-insertion resistors
• Detailed analysis of test results with DV-Win software
• Timing and motion measurement
• 12 timing channels (3×4) for main and resistive contacts
• 6 timing channels for auxiliary inputs
• 6 coil control channels
• 3 transducer input channels
• 6 additional analog input channels
• Built-in Micro Ohmmeter 500A
• Dynamic resistance measurement
• Detailed analysis of test results using DV-Win software
• First trip test (Online test)
• Main arcing-contacts operating time including bounce-time
• Timing and resistance measurement of the pre-insertion resistors (if present in the circuit breaker)
• Auxiliary contact operating time
• Actuation of circuit breaker’s TRIP and CLOSE coil via external module (Coil Control Module)
• TRIP and CLOSE coils current with values for specific points and corresponding graphics
• Voltage values and condition of a DC battery
• Main arcing-contacts operating time including bounce-time
• Timing and resistance measurement of the pre-insertion resistors (if present in the circuit breaker)
• Actuation of circuit breaker’s OPEN and CLOSE coil via Coil control (built-in)
• Auxiliary contact operating time
• CLOSE and OPEN coils current with values for specific points and corresponding graphics
• Voltage values and condition of a DC battery
• Handheld
• Automatically measures, time-stamps, stores voltages in less than 1 second
• Simultaneous string (cell) voltage and DC current measurement, for use in the discharge test
• Voltage measurement range: ± 600 V DC
• Cell (electrolyte) temperature
• Ambient temperature
• RFID cell recognition
• Easy transfer of measured data to DV-B Win software
• Lightweight – 20,6 kg (45.4 lb.)
• Powerful – discharge power up to 28,4 kW
• Battery voltage: 6 to 480 V DC (min 5,25 – max 500 V DC)
• Discharge current – up to 160 A DC
• Battery internal resistance measurement according to IEC 60896
• Expandable range for larger banks using BXL-V extra load units
• Current measurement range using Current Clamp 0 – 1 000 A DC
• User – adjustable alarm and shutdown parameters to prevent excessive discharge
• Testing without disconnecting the regular load
• Detailed test analysis using DV-B Win software
• Test resume feature in case of interrupted power supply
• Optimal for applications in telecommunication systems
• Lightweight – 15,1 kg (33 lb.)
• Powerful – discharge power up to 19,2 kW
• Voltage measurement range: up to 70,5 V DC
• Discharge current – up to 340 A DC
• Expandable range for larger banks using BXL-T extra load units
• Current measurement range using Current Probe 0 –300 / 1 000 A DC
• User – adjustable alarm and shutdown parameters to prevent excessive discharge
• Testing without disconnecting the regular load
• Detailed test analysis using DV-B Win software
• Test resume feature in case of interrupted power supply
• Used in a combination with a BLU220T device to increase load capacity
• Lightweight – 12,5 kg (28 lb.)
• Powerful – discharge power up to 17,5 kW
• Voltage measurement range: up to 75 V DC
• Discharge current – up to 310 A DC
• Measurement resolution – current 1 A, voltage 1 V
• Discharge process controlled by a BLU220T device
• Connects to battery terminals and parallel to BLU220T
• Used in a combination with BLU360V device to increase load capacity
• Lightweight – 16 kg (35 lb.)
• Powerful – discharge power up to 35 kW
• Voltage measurement range: 0 – 500 V DC
• Discharge current – up to 190 A DC
• Measurement resolution – current 1 A, voltage 1 V
• Discharge process controlled by BLU360V device
• Connects to battery terminals and parallel to BLU360V
Battery Capacity Tester – BLU200A
Battery Capacity Tester – BLU360V
Mr. Mäkängä is our software director. He has experience in power monitoring systems and IoT hardware that collect data. He is trained in python, php, c++ & java. He is also involved in our frontend web animation, php backend, android & database management system. He is also involved in charity work to help the community in the area he lives in to uplift the standards of living, culture & environment. He is also our lead in sustainable systems, he is researching solar, wave technology and wind energy. His goal is to create an environmental friendly eco-system of power production of clean energy and affordable electricity for rural homes. In achieving this goal he is able to reach out to his surroundings and improve the life of the common person through affirmative action and impact initiatives of concern for a better future.
Job, who holds an electrical engineering degree from the Technical University of Konstanz, Germany, has over 25 years’ experience in the energy sector. Job’s expertise spans medium and high voltage transmission lines and substations, distribution systems, generation engineering plant and infrastructure. Job has been involved in the energy transmission, distribution and generation sectors in Kenya, Uganda, Tanzania and South Sudan.
Specific experience includes design and construction supervision of transmission lines and substations including EPC contract administration and quality assurance procedures. Network reconfiguration commissioning, operation and maintenance of electrical equipment. Job is also an expert in negotiating Power Purchase Agreements.
Eng. Githinji has been involved in feasibility studies, conceptual designs, tender document preparation, tender evaluation and procurement of contractors for World Bank and African Development Bank funded projects. Job has an extensive understanding of the infrastructure development dynamics and potential in the African region, having been involved in business development of projects covering multipurpose dam with power generation, power transmission, water supply and irrigation components, roads and railways, ports and oil refineries.